PMC 20201216 pmc.key 4968113 CC BY-NC no 0 0 A. TEPLYAKOV ET AL. MABS 10.1080/19420862.2016.1190060 4968113 27210805 1190060 1045 6 Antibody structure CDR canonical structure CDR H3 phage library VH:VL packing This is an Open Access article distributed under the terms of the Creative Commons Attribution-Non-Commercial License (http://creativecommons.org/licenses/by-nc/3.0/), which permits unrestricted non-commercial use, distribution, and reproduction in any medium, provided the original work is properly cited. The moral rights of the named author(s) have been asserted. 1063 surname:Teplyakov;given-names:Alexey surname:Obmolova;given-names:Galina surname:Malia;given-names:Thomas J. surname:Luo;given-names:Jinquan surname:Muzammil;given-names:Salman surname:Sweet;given-names:Raymond surname:Almagro;given-names:Juan Carlos surname:Gilliland;given-names:Gary L. TITLE KEYWORDS front 8 2016 0 Structural diversity in a human antibody germline library 0.9945056 species cleaner0 2023-06-28T16:03:59Z MESH: human protein_type MESH: cleaner0 2023-06-28T15:45:47Z antibody ABSTRACT abstract_title_1 58 ABSTRACT ABSTRACT abstract 67 To support antibody therapeutic development, the crystal structures of a set of 16 germline variants composed of 4 different kappa light chains paired with 4 different heavy chains have been determined. All four heavy chains of the antigen-binding fragments (Fabs) have the same complementarity-determining region (CDR) H3 that was reported in an earlier Fab structure. The structure analyses include comparisons of the overall structures, canonical structures of the CDRs and the VH:VL packing interactions. The CDR conformations for the most part are tightly clustered, especially for the ones with shorter lengths. The longer CDRs with tandem glycines or serines have more conformational diversity than the others. CDR H3, despite having the same amino acid sequence, exhibits the largest conformational diversity. About half of the structures have CDR H3 conformations similar to that of the parent; the others diverge significantly. One conclusion is that the CDR H3 conformations are influenced by both their amino acid sequence and their structural environment determined by the heavy and light chain pairing. The stem regions of 14 of the variant pairs are in the ‘kinked’ conformation, and only 2 are in the extended conformation. The packing of the VH and VL domains is consistent with our knowledge of antibody structure, and the tilt angles between these domains cover a range of 11 degrees. Two of 16 structures showed particularly large variations in the tilt angles when compared with the other pairings. The structures and their analyses provide a rich foundation for future antibody modeling and engineering efforts. protein_type MESH: cleaner0 2023-06-28T15:45:48Z antibody 0.9971195 evidence cleaner0 2023-06-28T19:10:19Z DUMMY: crystal structures structure_element SO: cleaner0 2023-06-28T15:55:50Z kappa light chains structure_element SO: cleaner0 2023-06-28T15:56:14Z heavy chains structure_element SO: cleaner0 2023-06-28T15:56:24Z heavy chains structure_element SO: cleaner0 2023-06-28T15:58:19Z antigen-binding fragments 0.29639018 structure_element cleaner0 2023-06-28T15:58:45Z SO: Fabs 0.9439749 structure_element cleaner0 2023-06-29T08:49:24Z SO: complementarity-determining region 0.99692184 structure_element cleaner0 2023-06-28T16:25:21Z SO: CDR 0.93109226 structure_element cleaner0 2023-06-28T19:05:14Z SO: H3 0.37466994 structure_element cleaner0 2023-06-28T15:59:03Z SO: Fab 0.9929575 evidence cleaner0 2023-06-28T19:10:54Z DUMMY: structure 0.553402 experimental_method cleaner0 2023-06-29T09:05:49Z MESH: structure analyses 0.9943771 evidence cleaner0 2023-06-28T19:10:57Z DUMMY: structures 0.80576843 evidence cleaner0 2023-06-28T19:11:00Z DUMMY: structures 0.99496186 structure_element cleaner0 2023-06-28T19:04:38Z SO: CDRs complex_assembly GO: melaniev@ebi.ac.uk 2023-07-21T09:37:10Z VH:VL bond_interaction MESH: melaniev@ebi.ac.uk 2023-07-28T14:19:44Z packing interactions 0.97404987 structure_element cleaner0 2023-06-28T16:25:21Z SO: CDR 0.67458373 protein_state cleaner0 2023-06-29T09:26:48Z DUMMY: longer 0.9963917 structure_element cleaner0 2023-06-28T19:04:38Z SO: CDRs 0.95799243 residue_name cleaner0 2023-06-29T09:11:47Z SO: glycines 0.98402774 residue_name cleaner0 2023-06-29T09:11:50Z SO: serines structure_element SO: cleaner0 2023-06-28T16:25:21Z CDR structure_element SO: cleaner0 2023-06-28T19:05:14Z H3 0.99673104 evidence cleaner0 2023-06-28T19:11:02Z DUMMY: structures structure_element SO: cleaner0 2023-06-28T16:25:21Z CDR structure_element SO: cleaner0 2023-06-28T19:05:14Z H3 structure_element SO: cleaner0 2023-06-28T16:25:21Z CDR structure_element SO: cleaner0 2023-06-28T19:05:14Z H3 structure_element SO: cleaner0 2023-06-28T16:16:30Z heavy structure_element SO: cleaner0 2023-06-28T16:13:38Z light chain 0.9969053 structure_element cleaner0 2023-06-29T08:49:40Z SO: stem regions protein_state DUMMY: cleaner0 2023-06-29T07:42:04Z kinked protein_state DUMMY: cleaner0 2023-06-29T07:41:57Z extended 0.99790895 structure_element cleaner0 2023-06-29T08:49:44Z SO: VH 0.9977047 structure_element cleaner0 2023-06-28T19:10:07Z SO: VL protein_type MESH: cleaner0 2023-06-28T15:45:48Z antibody 0.9943786 evidence cleaner0 2023-06-28T19:11:05Z DUMMY: structure evidence DUMMY: cleaner0 2023-06-28T16:02:50Z tilt angles 0.9967739 evidence cleaner0 2023-06-28T19:11:08Z DUMMY: structures evidence DUMMY: cleaner0 2023-06-28T16:02:51Z tilt angles 0.9965509 evidence cleaner0 2023-06-28T19:11:13Z DUMMY: structures protein_type MESH: cleaner0 2023-06-28T15:45:48Z antibody INTRO title_1 1705 Introduction INTRO paragraph 1718 At present, therapeutic antibodies are the largest class of biotherapeutic proteins that are in clinical trials. The use of monoclonal antibodies as therapeutics began in the early 1980s, and their composition has transitioned from murine antibodies to generally less immunogenic humanized and human antibodies. The technologies currently used to obtain human antibodies include transgenic mice containing human antibody repertoires, cloning directly from human B cells, and in vitro selection from antibody libraries using various display technologies. Once a candidate antibody is identified, protein engineering is usually required to produce a molecule with the right biophysical and functional properties. All engineering efforts are guided by our understanding of the atomic structures of antibodies. In such efforts, the crystal structure of the specific antibody may not be available, but modeling can be used to guide the engineering efforts. Today's antibody modeling approaches, which normally focus on the variable region, are being developed by the application of structural principles and insights that are evolving as our knowledge of antibody structures continues to expand. protein_type MESH: cleaner0 2023-06-28T16:03:37Z antibodies protein_type MESH: cleaner0 2023-06-28T16:03:38Z antibodies 0.37784785 taxonomy_domain cleaner0 2023-06-28T16:06:23Z DUMMY: murine protein_type MESH: cleaner0 2023-06-28T16:03:38Z antibodies 0.52457434 species cleaner0 2023-06-28T16:03:59Z MESH: human protein_type MESH: cleaner0 2023-06-28T16:03:38Z antibodies 0.85534525 species cleaner0 2023-06-28T16:03:58Z MESH: human protein_type MESH: cleaner0 2023-06-28T16:03:38Z antibodies 0.36052313 taxonomy_domain cleaner0 2023-06-28T16:07:17Z DUMMY: mice 0.7995312 species cleaner0 2023-06-28T16:03:59Z MESH: human protein_type MESH: cleaner0 2023-06-28T15:45:48Z antibody 0.9800163 species cleaner0 2023-06-28T16:03:59Z MESH: human experimental_method MESH: cleaner0 2023-06-28T16:07:56Z in vitro selection 0.68230623 experimental_method cleaner0 2023-06-29T09:06:00Z MESH: antibody libraries protein_type MESH: cleaner0 2023-06-28T15:45:48Z antibody experimental_method MESH: cleaner0 2023-06-28T16:08:31Z protein engineering 0.96321344 evidence cleaner0 2023-06-28T16:08:57Z DUMMY: atomic structures protein_type MESH: cleaner0 2023-06-28T16:03:38Z antibodies 0.99743086 evidence cleaner0 2023-06-28T16:09:05Z DUMMY: crystal structure protein_type MESH: cleaner0 2023-06-28T15:45:48Z antibody protein_type MESH: cleaner0 2023-06-28T15:45:48Z antibody 0.9954084 structure_element cleaner0 2023-06-28T16:09:22Z SO: variable region protein_type MESH: cleaner0 2023-06-28T15:45:48Z antibody 0.9851259 evidence cleaner0 2023-06-28T19:11:18Z DUMMY: structures INTRO paragraph 2909 Our current structural knowledge of antibodies is based on a multitude of studies that used many techniques to gain insight into the functional and structural properties of this class of macromolecule. Five different antibody isotypes occur, IgG, IgD, IgE, IgA and IgM, and each isotype has a unique role in the adaptive immune system. IgG, IgD and IgE isotypes are composed of 2 heavy chains (HCs) and 2 light chains (LCs) linked through disulfide bonds, while IgA and IgM are double and quintuple versions of antibodies, respectively. Isotypes IgG, IgD and IgA each have 4 domains, one variable (V) and 3 constant (C) domains, while IgE and IgM each have the same 4 domains along with an additional C domain. These multimeric forms are linked with an additional J chain. The LCs that associate with the HCs are divided into 2 functionally indistinguishable classes, κ and λ. Both κ and λ polypeptide chains are composed of a single V domain and a single C domain. protein_type MESH: cleaner0 2023-06-28T16:03:38Z antibodies protein_type MESH: cleaner0 2023-06-28T15:45:48Z antibody 0.5808187 protein cleaner0 2023-06-28T16:10:07Z PR: IgG 0.579378 protein cleaner0 2023-06-28T16:10:20Z PR: IgD 0.4901906 protein cleaner0 2023-06-28T16:10:34Z PR: IgE 0.48674142 protein cleaner0 2023-06-28T16:10:53Z PR: IgA 0.5469069 protein cleaner0 2023-06-28T16:11:01Z PR: IgM 0.4615833 protein cleaner0 2023-06-28T16:10:08Z PR: IgG 0.5355316 protein cleaner0 2023-06-28T16:10:46Z PR: IgD 0.45904422 protein cleaner0 2023-06-28T16:10:35Z PR: IgE 0.91602886 structure_element cleaner0 2023-06-28T15:56:24Z SO: heavy chains 0.99714833 structure_element cleaner0 2023-06-28T16:11:31Z SO: HCs 0.8479442 structure_element cleaner0 2023-06-28T16:14:07Z SO: light chains 0.99629045 structure_element cleaner0 2023-06-28T16:11:38Z SO: LCs ptm MESH: melaniev@ebi.ac.uk 2023-07-06T15:17:35Z disulfide bonds 0.58396065 protein cleaner0 2023-06-28T16:10:55Z PR: IgA 0.6218557 protein cleaner0 2023-06-28T16:11:02Z PR: IgM protein_type MESH: cleaner0 2023-06-28T16:03:38Z antibodies 0.5306497 protein cleaner0 2023-06-28T16:10:08Z PR: IgG 0.51756364 protein cleaner0 2023-06-28T16:10:47Z PR: IgD 0.6528544 protein cleaner0 2023-06-28T16:10:55Z PR: IgA 0.99655485 structure_element cleaner0 2023-06-29T08:49:51Z SO: variable 0.9962674 structure_element cleaner0 2023-06-28T16:12:17Z SO: V 0.995513 structure_element cleaner0 2023-06-29T08:49:58Z SO: constant 0.9924636 structure_element cleaner0 2023-06-28T16:12:08Z SO: C 0.6833741 protein cleaner0 2023-06-28T16:10:35Z PR: IgE 0.7602459 protein cleaner0 2023-06-28T16:11:02Z PR: IgM structure_element SO: cleaner0 2023-06-29T08:13:46Z C domain 0.9844195 structure_element cleaner0 2023-06-29T08:50:04Z SO: J 0.99804425 structure_element cleaner0 2023-06-28T16:11:39Z SO: LCs 0.9981816 structure_element cleaner0 2023-06-28T16:11:32Z SO: HCs 0.91732925 structure_element cleaner0 2023-06-28T16:15:20Z SO: κ 0.809085 structure_element cleaner0 2023-06-28T16:15:35Z SO: λ 0.923577 structure_element cleaner0 2023-06-28T16:15:21Z SO: κ 0.8177861 structure_element cleaner0 2023-06-28T16:15:36Z SO: λ structure_element SO: melaniev@ebi.ac.uk 2023-07-06T15:14:51Z V domain structure_element SO: cleaner0 2023-06-29T08:13:25Z C domain INTRO paragraph 3893 The heavy and light chains are composed of structural domains that have ∼110 amino acid residues. These domains have a common folding pattern often referred to as the “immunoglobulin fold,” formed by the packing together of 2 anti-parallel β-sheets. All immunoglobulin chains have an N-terminal V domain followed by 1 to 4 C domains, depending upon the chain type. In antibodies, the heavy and light chain V domains pack together forming the antigen combining site. This site, which interacts with the antigen (or target), is the focus of current antibody modeling efforts. This interaction site is composed of 6 complementarity-determining regions (CDRs) that were identified in early antibody amino acid sequence analyses to be hypervariable in nature, and thus are responsible for the sequence and structural diversity of our antibody repertoire. 0.28037655 structure_element cleaner0 2023-06-29T08:50:09Z SO: heavy structure_element SO: cleaner0 2023-06-28T16:14:08Z light chains 0.8056854 structure_element cleaner0 2023-06-29T08:50:22Z SO: structural domains residue_range DUMMY: cleaner0 2023-06-29T09:14:08Z ∼110 amino acid residues 0.9660743 structure_element cleaner0 2023-06-29T08:50:29Z SO: immunoglobulin fold 0.98161864 structure_element cleaner0 2023-06-29T08:50:36Z SO: anti-parallel β-sheets 0.9119513 protein_type cleaner0 2023-06-28T19:09:00Z MESH: immunoglobulin chains structure_element SO: melaniev@ebi.ac.uk 2023-07-06T15:15:03Z V domain structure_element SO: cleaner0 2023-06-28T16:21:31Z C domains 0.5746893 protein_type cleaner0 2023-06-28T16:03:38Z MESH: antibodies structure_element SO: cleaner0 2023-06-28T20:43:25Z heavy and light chain structure_element SO: cleaner0 2023-06-28T16:21:51Z V domains 0.9981706 site cleaner0 2023-06-29T09:10:03Z SO: antigen combining site 0.774341 protein_type cleaner0 2023-06-28T15:45:48Z MESH: antibody 0.99761343 site cleaner0 2023-06-29T09:10:11Z SO: interaction site 0.9165287 structure_element cleaner0 2023-06-29T08:50:44Z SO: complementarity-determining regions 0.99350005 structure_element cleaner0 2023-06-28T19:04:38Z SO: CDRs 0.92376745 experimental_method cleaner0 2023-06-29T09:06:06Z MESH: antibody amino acid sequence analyses 0.99413955 protein_state cleaner0 2023-06-29T09:26:56Z DUMMY: hypervariable protein_type MESH: cleaner0 2023-06-28T15:45:48Z antibody INTRO paragraph 4750 The sequence diversity of the CDR regions presents a substantial challenge to antibody modeling. However, an initial structural analysis of the combining sites of the small set of structures of immunoglobulin fragments available in the 1980s found that 5 of the 6 hypervariable loops or CDRs had canonical structures (a limited set of main-chain conformations). A CDR canonical structure is defined by its length and conserved residues located in the hypervariable loop and framework residues (V-region residues that are not part of the CDRs). Furthermore, studies of antibody sequences revealed that the total number of canonical structures are limited for each CDR, indicating possibly that antigen recognition may be affected by structural restrictions at the antigen-binding site. Later studies found that the CDR loop length is the primary determining factor of antigen-binding site topography because it is the primary factor for determining a canonical structure. Additional efforts have led to our current understanding that the LC CDRs L1, L2, and L3 have preferred sets of canonical structures based on length and amino acid sequence composition. This was also found to be the case for the H1 and H2 CDRs. Classification schemes for the canonical structures of these 5 CDRs have emerged and evolved as the number of depositions in the Protein Data Bank of Fab fragments of antibodies grow. Recently, a comprehensive CDR classification scheme was reported identifying 72 clusters of conformations observed in antibody structures. The knowledge and predictability of these CDR canonical structures have greatly advanced antibody modeling efforts. 0.9892019 structure_element cleaner0 2023-06-29T08:50:50Z SO: CDR regions protein_type MESH: cleaner0 2023-06-28T15:45:48Z antibody 0.86392236 experimental_method cleaner0 2023-06-29T09:06:10Z MESH: structural analysis 0.9967412 site cleaner0 2023-06-29T09:10:17Z SO: combining sites 0.99583673 evidence cleaner0 2023-06-28T19:11:25Z DUMMY: structures 0.97308254 structure_element cleaner0 2023-06-29T08:50:55Z SO: hypervariable loops 0.9967535 structure_element cleaner0 2023-06-28T19:04:38Z SO: CDRs 0.79579794 structure_element cleaner0 2023-06-28T16:25:21Z SO: CDR 0.96811986 structure_element cleaner0 2023-06-29T08:51:00Z SO: hypervariable loop 0.79810786 structure_element cleaner0 2023-06-29T08:51:45Z SO: framework residues 0.93935466 structure_element cleaner0 2023-06-29T08:51:53Z SO: V-region 0.99704546 structure_element cleaner0 2023-06-28T19:04:38Z SO: CDRs protein_type MESH: cleaner0 2023-06-28T15:45:48Z antibody 0.9926368 structure_element cleaner0 2023-06-28T16:25:21Z SO: CDR 0.99790645 site cleaner0 2023-06-29T09:10:21Z SO: antigen-binding site 0.954146 structure_element cleaner0 2023-06-29T08:51:56Z SO: CDR loop 0.9959662 site cleaner0 2023-06-29T09:10:24Z SO: antigen-binding site 0.6664975 structure_element cleaner0 2023-06-28T16:24:54Z SO: LC 0.9848006 structure_element cleaner0 2023-06-28T19:04:38Z SO: CDRs 0.9951461 structure_element cleaner0 2023-06-28T16:26:29Z SO: L1 0.9955865 structure_element cleaner0 2023-06-28T20:09:53Z SO: L2 0.99560404 structure_element cleaner0 2023-06-29T08:52:03Z SO: L3 0.90607065 structure_element cleaner0 2023-06-28T19:04:09Z SO: H1 0.6061986 structure_element cleaner0 2023-06-28T16:26:20Z SO: H2 0.97096324 structure_element cleaner0 2023-06-28T19:04:37Z SO: CDRs 0.9894225 structure_element cleaner0 2023-06-28T19:04:38Z SO: CDRs 0.4258705 structure_element cleaner0 2023-06-28T15:59:04Z SO: Fab protein_type MESH: cleaner0 2023-06-28T16:03:38Z antibodies structure_element SO: cleaner0 2023-06-28T16:25:21Z CDR protein_type MESH: cleaner0 2023-06-28T15:45:48Z antibody 0.99535346 evidence cleaner0 2023-06-28T19:11:30Z DUMMY: structures 0.95264316 structure_element cleaner0 2023-06-28T16:25:19Z SO: CDR 0.65532506 evidence cleaner0 2023-06-28T19:11:33Z DUMMY: structures protein_type MESH: cleaner0 2023-06-28T15:45:48Z antibody INTRO paragraph 6405 In contrast to CDRs L1, L2, L3, H1 and H2, no canonical structures have been observed for CDR H3, which is the most variable in length and amino acid sequence. Some clustering of conformations was observed for the shortest lengths; however, for the longer loops, only the portions nearest the framework (torso, stem or anchor region) were found to have defined conformations. In the torso region, 2 primary groups could be identified, which led to sequence-based rules that can predict with some degree of reliability the conformation of the stem region. The “kinked” or “bulged” conformation is the most prevalent, but an “extended” or “non-bulged” conformation is also, but less frequently, observed. The cataloging and development of the rules for predicting the conformation of the anchor region of CDR H3 continue to be refined, producing new insight into the CDR H3 conformations and new tools for antibody engineering. 0.9609944 structure_element cleaner0 2023-06-28T19:04:38Z SO: CDRs 0.8862208 structure_element cleaner0 2023-06-28T16:26:30Z SO: L1 0.9949463 structure_element cleaner0 2023-06-28T20:09:53Z SO: L2 0.99527967 structure_element cleaner0 2023-06-29T08:52:14Z SO: L3 0.9794373 structure_element cleaner0 2023-06-28T19:04:10Z SO: H1 0.9499178 structure_element cleaner0 2023-06-28T16:26:21Z SO: H2 evidence DUMMY: cleaner0 2023-06-28T20:44:12Z structures structure_element SO: cleaner0 2023-06-28T19:06:45Z CDR structure_element SO: cleaner0 2023-06-28T19:05:14Z H3 0.9731328 structure_element cleaner0 2023-06-29T08:52:18Z SO: loops 0.9971501 structure_element cleaner0 2023-06-29T08:52:25Z SO: framework 0.99759847 structure_element cleaner0 2023-06-29T08:52:29Z SO: torso 0.9975243 structure_element cleaner0 2023-06-29T08:52:32Z SO: stem 0.9965924 structure_element cleaner0 2023-06-29T08:52:35Z SO: anchor region 0.99673957 structure_element cleaner0 2023-06-29T08:52:42Z SO: torso region 0.99730873 structure_element cleaner0 2023-06-29T08:52:49Z SO: stem region 0.9651129 protein_state cleaner0 2023-06-29T07:42:05Z DUMMY: kinked 0.9021778 protein_state cleaner0 2023-06-29T09:27:20Z DUMMY: bulged 0.9788072 protein_state cleaner0 2023-06-29T07:41:57Z DUMMY: extended 0.9845164 protein_state cleaner0 2023-06-29T09:27:24Z DUMMY: non-bulged 0.9973566 structure_element cleaner0 2023-06-29T08:52:56Z SO: anchor region structure_element SO: cleaner0 2023-06-28T16:25:21Z CDR structure_element SO: cleaner0 2023-06-28T19:05:13Z H3 0.8594353 structure_element cleaner0 2023-06-28T16:25:21Z SO: CDR 0.6657651 structure_element cleaner0 2023-06-28T19:05:14Z SO: H3 protein_type MESH: cleaner0 2023-06-28T15:45:48Z antibody INTRO paragraph 7347 Current antibody modeling approaches take advantage of the most recent advances in homology modeling, the evolving understanding of the CDR canonical structures, the emerging rules for CDR H3 modeling and the growing body of antibody structural data available from the PDB. Recent antibody modeling assessments show continued improvement in the quality of the models being generated by a variety of modeling methods. Although antibody modeling is improving, the latest assessment revealed a number of challenges that need to be overcome to provide accurate 3-dimensional models of antibody V regions, including accuracies in the modeling of CDR H3. The need for improvement in this area was also highlighted in a recent study reporting an approach and results that may influence future antibody modeling efforts. One important finding of the antibody modeling assessments was that errors in the structural templates that are used as the basis for homology models can propagate into the final models, producing inaccuracies that may negatively influence the predictive nature of the V region model. protein_type MESH: cleaner0 2023-06-28T15:45:48Z antibody 0.9942754 experimental_method cleaner0 2023-06-28T19:08:24Z MESH: homology modeling structure_element SO: cleaner0 2023-06-28T16:25:21Z CDR 0.46883506 evidence cleaner0 2023-06-28T19:11:39Z DUMMY: structures structure_element SO: cleaner0 2023-06-28T16:25:21Z CDR structure_element SO: cleaner0 2023-06-28T19:05:14Z H3 protein_type MESH: cleaner0 2023-06-28T15:45:48Z antibody 0.76543283 experimental_method cleaner0 2023-06-28T19:06:07Z MESH: antibody modeling assessments protein_type MESH: cleaner0 2023-06-28T15:45:48Z antibody protein_type MESH: cleaner0 2023-06-28T15:45:48Z antibody 0.9220402 structure_element cleaner0 2023-06-28T19:05:50Z SO: V regions structure_element SO: cleaner0 2023-06-28T16:25:21Z CDR structure_element SO: cleaner0 2023-06-28T19:05:14Z H3 protein_type MESH: cleaner0 2023-06-28T15:45:48Z antibody 0.8185734 experimental_method cleaner0 2023-06-28T19:06:09Z MESH: antibody modeling assessments 0.99114794 experimental_method cleaner0 2023-06-29T09:06:15Z MESH: homology models 0.94426894 structure_element cleaner0 2023-06-29T08:53:04Z SO: V region INTRO paragraph 8445 To support antibody engineering and therapeutic development efforts, a phage library was designed and constructed based on a limited number of scaffolds built with frequently used human germ-line IGV and IGJ gene segments that encode antigen combining sites suitable for recognition of peptides and proteins. This Fab library is composed of 3 HC germlines, IGHV1-69 (H1-69), IGHV3-23 (H3-23) and IGHV5-51(H5-51), and 4 LC germlines (all κ), IGKV1-39 (L1-39), IGKV3-11 (L3-11), IGKV3-20 (L3-20) and IGKV4-1 (L4-1). Selection of these genes was based on the high frequency of their use and their cognate canonical structures that were found binding to peptides and proteins, as well as their ability to be expressed in bacteria and displayed on filamentous phage. The implementation of the library involves the diversification of the human germline genes to mimic that found in natural human libraries. protein_type MESH: cleaner0 2023-06-28T15:45:48Z antibody 0.8285667 experimental_method cleaner0 2023-06-29T09:06:19Z MESH: phage library 0.99304044 species cleaner0 2023-06-28T16:03:59Z MESH: human 0.5477985 structure_element cleaner0 2023-06-29T09:37:42Z SO: IGV 0.37411508 structure_element cleaner0 2023-06-29T09:37:44Z SO: IGJ 0.9979419 site cleaner0 2023-06-29T09:10:29Z SO: antigen combining sites 0.22796038 structure_element cleaner0 2023-06-28T15:59:04Z SO: Fab 0.3749512 structure_element cleaner0 2023-06-29T08:55:32Z SO: HC mutant MESH: cleaner0 2023-06-28T21:02:43Z IGHV1-69 mutant MESH: cleaner0 2023-06-28T21:03:12Z H1-69 mutant MESH: cleaner0 2023-06-28T21:03:44Z IGHV3-23 mutant MESH: cleaner0 2023-06-28T21:04:11Z H3-23 mutant MESH: cleaner0 2023-06-28T21:04:40Z IGHV5-51 mutant MESH: cleaner0 2023-06-28T21:05:04Z H5-51 0.29352522 structure_element cleaner0 2023-06-28T16:24:55Z SO: LC 0.68899107 structure_element cleaner0 2023-06-28T16:15:21Z SO: κ mutant MESH: cleaner0 2023-06-28T21:05:26Z IGKV1-39 mutant MESH: cleaner0 2023-06-28T21:05:49Z L1-39 mutant MESH: cleaner0 2023-06-28T21:06:12Z IGKV3-11 mutant MESH: cleaner0 2023-06-28T21:06:33Z L3-11 mutant MESH: cleaner0 2023-06-28T21:06:55Z IGKV3-20 mutant MESH: cleaner0 2023-06-28T21:07:14Z L3-20 mutant MESH: cleaner0 2023-06-28T21:07:38Z IGKV4-1 mutant MESH: cleaner0 2023-06-28T21:07:59Z L4-1 evidence DUMMY: cleaner0 2023-06-28T20:53:28Z structures experimental_method MESH: cleaner0 2023-06-28T21:02:06Z expressed in bacteria experimental_method MESH: cleaner0 2023-06-28T21:02:13Z displayed on filamentous phage 0.9926621 species cleaner0 2023-06-28T16:03:59Z MESH: human 0.9930802 species cleaner0 2023-06-28T16:03:59Z MESH: human INTRO paragraph 9350 The crystal structure determinations and structural analyses of all germline Fabs in the library described above along with the structures of a fourth HC germline, IGHV3-53 (H3-53), paired with the 4 LCs of the library have been carried out to support antibody therapeutic development. All 16 HCs of the Fabs have the same CDR H3 that was reported in an earlier Fab structure. This is the first systematic study of the same VH and VL structures in the context of different pairings. The structure analyses include comparisons of the overall structures, canonical structures of the L1, L2, L3, H1 and H2 CDRs, the structures of all CDR H3s, and the VH:VL packing interactions. The structures and their analyses provide a foundation for future antibody engineering and structure determination efforts. 0.9365645 experimental_method cleaner0 2023-06-29T09:06:25Z MESH: crystal structure determinations 0.9690031 experimental_method cleaner0 2023-06-29T09:06:28Z MESH: structural analyses 0.18112527 structure_element cleaner0 2023-06-28T15:58:46Z SO: Fabs 0.99385357 evidence cleaner0 2023-06-28T19:11:45Z DUMMY: structures 0.4604112 structure_element cleaner0 2023-06-29T08:55:41Z SO: HC 0.9870631 mutant cleaner0 2023-06-29T09:25:45Z MESH: IGHV3-53 mutant MESH: cleaner0 2023-06-28T21:08:31Z H3-53 0.99305177 structure_element cleaner0 2023-06-28T16:11:39Z SO: LCs protein_type MESH: cleaner0 2023-06-28T15:45:48Z antibody 0.9857884 structure_element cleaner0 2023-06-28T16:11:32Z SO: HCs 0.23558842 structure_element cleaner0 2023-06-28T15:58:46Z SO: Fabs structure_element SO: cleaner0 2023-06-28T16:25:21Z CDR structure_element SO: cleaner0 2023-06-28T19:05:14Z H3 0.24147022 structure_element cleaner0 2023-06-28T15:59:04Z SO: Fab 0.9950139 evidence cleaner0 2023-06-28T19:11:56Z DUMMY: structure 0.9822842 structure_element cleaner0 2023-06-29T08:55:44Z SO: VH 0.956339 structure_element cleaner0 2023-06-28T19:10:07Z SO: VL 0.9961636 evidence cleaner0 2023-06-28T19:11:59Z DUMMY: structures 0.99412364 evidence cleaner0 2023-06-28T19:12:02Z DUMMY: structures 0.97373337 evidence cleaner0 2023-06-28T19:12:04Z DUMMY: structures 0.9947988 structure_element cleaner0 2023-06-28T16:26:30Z SO: L1 0.9907031 structure_element cleaner0 2023-06-28T20:09:53Z SO: L2 0.9922057 structure_element cleaner0 2023-06-29T08:55:50Z SO: L3 0.9905301 structure_element cleaner0 2023-06-28T19:04:10Z SO: H1 0.9891143 structure_element cleaner0 2023-06-28T16:26:21Z SO: H2 0.9166478 structure_element cleaner0 2023-06-28T19:04:38Z SO: CDRs 0.98723364 evidence cleaner0 2023-06-28T19:12:07Z DUMMY: structures structure_element SO: cleaner0 2023-06-28T16:25:21Z CDR structure_element SO: cleaner0 2023-06-28T19:07:47Z H3s complex_assembly GO: melaniev@ebi.ac.uk 2023-07-21T09:37:57Z VH:VL bond_interaction MESH: melaniev@ebi.ac.uk 2023-07-28T14:19:44Z packing interactions 0.98796034 evidence cleaner0 2023-06-28T19:12:10Z DUMMY: structures protein_type MESH: cleaner0 2023-06-28T15:45:48Z antibody RESULTS title_1 10150 Results RESULTS title_2 10158 Crystal structures 0.9969361 evidence cleaner0 2023-06-28T19:12:15Z DUMMY: Crystal structures d37e422.xml t0001 TABLE table_caption 10177 Crystal data, X-ray data, and refinement statistics. 0.99486244 evidence cleaner0 2023-06-28T19:12:18Z DUMMY: Crystal data 0.99513537 evidence cleaner0 2023-06-28T19:12:21Z DUMMY: X-ray data evidence DUMMY: cleaner0 2023-06-28T19:12:33Z refinement statistics d37e422.xml t0001 TABLE table <?xml version="1.0" encoding="UTF-8"?> <table frame="hsides" rules="groups"><colgroup><col width="86.4pt" align="left"/><col width="86.4pt" align="left"/><col width="86.4pt" align="left"/><col width="86.4pt" align="left"/><col width="86.4pt" align="left"/></colgroup><thead><tr><th align="left">Fab<hr/></th><th align="center">H1-69:L1-39<hr/></th><th align="center">H1-69:L3-11<hr/></th><th align="center">H1-69:L3-20<hr/></th><th align="center">H1-69:L4-1<hr/></th></tr><tr><th align="left"><italic>PDB identifier</italic></th><th align="center">5I15</th><th align="center">5I16</th><th align="center">5I17</th><th align="center">5I18</th></tr></thead><tbody><tr><td align="left">Crystal Data</td><td align="left"> </td><td align="left"> </td><td align="left"> </td><td align="left"> </td></tr><tr><td align="left">Crystallization Solution</td><td align="left"> </td><td align="left"> </td><td align="left"> </td><td align="left"> </td></tr><tr><td align="left"> Buffer, pH</td><td align="center">0.1 M MES- pH 6.5</td><td align="center">0.1 M MES pH 6.5</td><td align="center">0.1 M MES, pH 6.5</td><td align="center">0.1 M HEPES, pH 7.5</td></tr><tr><td align="left"> Precipitant<xref rid="t1fn0001" ref-type="fn"><sup>1</sup></xref></td><td align="center">5 M Na Formate</td><td align="center">25% PEG 3350</td><td align="center">2.0 M Amm Sulfate</td><td align="center">10% PEG 8000</td></tr><tr><td align="left"> Additive<xref rid="t1fn0001" ref-type="fn"><sup>1</sup></xref></td><td align="left"> </td><td align="center">0.2 M Na Formate</td><td align="center">5% MPD</td><td align="center">8% EG</td></tr><tr><td align="left"> Space Group</td><td align="center">P3<sub>1</sub>21</td><td align="center">C2</td><td align="center">P422</td><td align="center">P42<sub>1</sub>2</td></tr><tr><td align="left"> Molecules/AU</td><td align="center">1</td><td align="center">2</td><td align="center">2</td><td align="center">1</td></tr><tr><td align="left"> Unit Cell</td><td align="left"> </td><td align="left"> </td><td align="left"> </td><td align="left"> </td></tr><tr><td align="left"> a(Å)</td><td align="center">129.2</td><td align="center">212.0</td><td align="center">152.5</td><td align="center">120.0</td></tr><tr><td align="left"> b(Å)</td><td align="center">129.2</td><td align="center">55.1</td><td align="center">152.5</td><td align="center">120.0</td></tr><tr><td align="left"> c(Å)</td><td align="center">91.8</td><td align="center">80.3</td><td align="center">123.4</td><td align="center">64.2</td></tr><tr><td align="left"> β(°)</td><td align="center">90.0</td><td align="center">97.8</td><td align="center">90.0</td><td align="center">90.0</td></tr><tr><td align="left"> γ(°)</td><td align="center">120.0</td><td align="center">90.0</td><td align="center">90.0</td><td align="center">90.0</td></tr><tr><td align="left"> V<sub>m</sub> (Å<sup>3</sup>/Da)</td><td align="center">4.67</td><td align="center">2.44</td><td align="center">3.77</td><td align="center">2.39</td></tr><tr><td align="left"> Solvent Content (%)</td><td align="center">74</td><td align="center">50</td><td align="center">67</td><td align="center">48</td></tr><tr><td align="left">X-Ray Data<xref rid="t1fn0002" ref-type="fn"><sup>2</sup></xref></td><td align="left"> </td><td align="left"> </td><td align="left"> </td><td align="left"> </td></tr><tr><td align="left"> Resolution (Å)</td><td align="center">30-2.6 (2.7-2.6)</td><td align="center">30.0-1.9 (1.95-1.9)</td><td align="center">30.0-3.3 (3.4-3.3)</td><td align="center">30-1.9 (2.0-1.9)</td></tr><tr><td align="left"> Measured Reflections</td><td align="center">136,745 (8,650)</td><td align="center">241,145 (16,580)</td><td align="center">237,504 (15,007)</td><td align="center">801,080 (19,309)</td></tr><tr><td align="left"> Unique Reflections</td><td align="center">27,349 (1,730)</td><td align="center">71,932 (5,198)</td><td align="center">22,379 (1,590)</td><td align="center">35,965 (2,194)</td></tr><tr><td align="left"> Completeness (%)</td><td align="center">99.3 (98.7)</td><td align="center">99.0 (97.3)</td><td align="center">99.5 (96.8)</td><td align="center">98.5 (82.8)</td></tr><tr><td align="left"> Redundancy</td><td align="center">5.0 (5.0)</td><td align="center">3.4 (3.2)</td><td align="center">10.6 (9.4)</td><td align="center">22.3 (8.8)</td></tr><tr><td align="left"> R<sub>merge</sub></td><td align="center">0.048 (0.522)</td><td align="center">0.044 (0.245)</td><td align="center">0.086 (0.536)</td><td align="center">0.093 (0.231)</td></tr><tr><td align="left"> < I/σ ></td><td align="center">21.2 (3.9)</td><td align="center">17.8 (4.7)</td><td align="center">25.5 (4.5)</td><td align="center">29.2 (8.1)</td></tr><tr><td align="left"> B-factor (Å<sup>2</sup>)</td><td align="center">60.5</td><td align="center">33.2</td><td align="center">61.0</td><td align="center">19.6</td></tr><tr><td align="left">Refinement</td><td align="left"> </td><td align="left"> </td><td align="left"> </td><td align="left"> </td></tr><tr><td align="left"> Resolution (Å)</td><td align="center">15-2.6</td><td align="center">15-1.9</td><td align="center">15-3.3</td><td align="center">15-1.9</td></tr><tr><td align="left"> Number of Reflections</td><td align="center">26,238</td><td align="center">70,346</td><td align="center">21,197</td><td align="center">34,850</td></tr><tr><td align="left"> Number of All Atoms</td><td align="center">3,224</td><td align="center">6,975</td><td align="center">6,398</td><td align="center">3,695</td></tr><tr><td align="left"> Number of Waters</td><td align="center">2</td><td align="center">472</td><td align="center">0</td><td align="center">399</td></tr><tr><td align="left"> R-factor (%)</td><td align="center">20.5</td><td align="center">19.2</td><td align="center">20.2</td><td align="center">16.7</td></tr><tr><td align="left"> R-free (%)</td><td align="center">24.1</td><td align="center">22.2</td><td align="center">24.7</td><td align="center">21.3</td></tr><tr><td align="left">RMSD</td><td align="left"> </td><td align="left"> </td><td align="left"> </td><td align="left"> </td></tr><tr><td align="left"> Bond Lengths (Å)</td><td align="center">0.006</td><td align="center">0.005</td><td align="center">0.005</td><td align="center">0.008</td></tr><tr><td align="left"> Bond Angles (°)</td><td align="center">1.2</td><td align="center">1.1</td><td align="center">1.0</td><td align="center">1.1</td></tr><tr><td align="left"> Mean B-factor (Å<sup>2</sup>)</td><td align="center">65.3</td><td align="center">34.4</td><td align="center">80.1</td><td align="center">20.0</td></tr><tr><td align="left">Ramachandran Plot (%)</td><td align="left"> </td><td align="left"> </td><td align="left"> </td><td align="left"> </td></tr><tr><td align="left"> Outliers</td><td align="center">0.0</td><td align="center">0.0</td><td align="center">0.9</td><td align="center">0.0</td></tr><tr><td align="left"> Favored</td><td align="center">92.3</td><td align="center">96.9</td><td align="center">93.1</td><td align="center">96.9</td></tr></tbody></table> 10230 Fab H1-69:L1-39 H1-69:L3-11 H1-69:L3-20 H1-69:L4-1 PDB identifier 5I15 5I16 5I17 5I18 Crystal Data Crystallization Solution Buffer, pH 0.1 M MES- pH 6.5 0.1 M MES pH 6.5 0.1 M MES, pH 6.5 0.1 M HEPES, pH 7.5 Precipitant1 5 M Na Formate 25% PEG 3350 2.0 M Amm Sulfate 10% PEG 8000 Additive1 0.2 M Na Formate 5% MPD 8% EG Space Group P3121 C2 P422 P4212 Molecules/AU 1 2 2 1 Unit Cell a(Å) 129.2 212.0 152.5 120.0 b(Å) 129.2 55.1 152.5 120.0 c(Å) 91.8 80.3 123.4 64.2 β(°) 90.0 97.8 90.0 90.0 γ(°) 120.0 90.0 90.0 90.0 Vm (Å3/Da) 4.67 2.44 3.77 2.39 Solvent Content (%) 74 50 67 48 X-Ray Data2 Resolution (Å) 30-2.6 (2.7-2.6) 30.0-1.9 (1.95-1.9) 30.0-3.3 (3.4-3.3) 30-1.9 (2.0-1.9) Measured Reflections 136,745 (8,650) 241,145 (16,580) 237,504 (15,007) 801,080 (19,309) Unique Reflections 27,349 (1,730) 71,932 (5,198) 22,379 (1,590) 35,965 (2,194) Completeness (%) 99.3 (98.7) 99.0 (97.3) 99.5 (96.8) 98.5 (82.8) Redundancy 5.0 (5.0) 3.4 (3.2) 10.6 (9.4) 22.3 (8.8) Rmerge 0.048 (0.522) 0.044 (0.245) 0.086 (0.536) 0.093 (0.231) < I/σ > 21.2 (3.9) 17.8 (4.7) 25.5 (4.5) 29.2 (8.1) B-factor (Å2) 60.5 33.2 61.0 19.6 Refinement Resolution (Å) 15-2.6 15-1.9 15-3.3 15-1.9 Number of Reflections 26,238 70,346 21,197 34,850 Number of All Atoms 3,224 6,975 6,398 3,695 Number of Waters 2 472 0 399 R-factor (%) 20.5 19.2 20.2 16.7 R-free (%) 24.1 22.2 24.7 21.3 RMSD Bond Lengths (Å) 0.006 0.005 0.005 0.008 Bond Angles (°) 1.2 1.1 1.0 1.1 Mean B-factor (Å2) 65.3 34.4 80.1 20.0 Ramachandran Plot (%) Outliers 0.0 0.0 0.9 0.0 Favored 92.3 96.9 93.1 96.9 d37e422.xml t0001 TABLE table_footnote 12072 Abbreviations: Amm, ammonium;EG, ethylene glycol; PEG, polyethylene glycol. d37e422.xml t0001 TABLE table_footnote 12148 Values for high-resolution shell are in parentheses. d37e892.xml t0001 TABLE table_caption 12201 (Continued) Crystal data, X-ray data, and refinement statistics. 0.9933119 evidence cleaner0 2023-06-28T19:14:53Z DUMMY: Crystal data 0.98985547 evidence cleaner0 2023-06-28T19:14:56Z DUMMY: X-ray data evidence DUMMY: cleaner0 2023-06-28T19:15:10Z refinement statistics d37e892.xml t0001 TABLE table <?xml version="1.0" encoding="UTF-8"?> <table frame="hsides" rules="groups"><colgroup><col width="86.4pt" align="left"/><col width="86.4pt" align="left"/><col width="86.4pt" align="left"/><col width="86.4pt" align="left"/><col width="86.4pt" align="left"/></colgroup><thead><tr><th align="left">Fab<hr/></th><th align="center">H3-23:L1-39<hr/></th><th align="center">H3-23:L3-11<hr/></th><th align="center">H3-23:L3-20<hr/></th><th align="center">H3-23:L4-1<hr/></th></tr><tr><th align="left"><italic> PDB identifier</italic></th><th align="center">5I19</th><th align="center">5I1A</th><th align="center">5I1C</th><th align="center">5I1D</th></tr></thead><tbody><tr><td align="left">Crystal Data</td><td align="left"> </td><td align="left"> </td><td align="left"> </td><td align="left"> </td></tr><tr><td align="left">Crystallization Solution</td><td align="left"> </td><td align="left"> </td><td align="left"> </td><td align="left"> </td></tr><tr><td align="left"> Buffer, pH</td><td align="center">No Buffer</td><td align="center">0.1 M Na Acetate, pH 4.5</td><td align="center">0.1 M MES, pH 6.5</td><td align="center">0.1 M HEPES, pH 7.5</td></tr><tr><td align="left"> Precipitant<xref rid="t1fn0003" ref-type="fn"><sup>1</sup></xref></td><td align="center">20% PEG 3350</td><td align="center">2.0 M Amm Sulfate</td><td align="center">16% PEG 3350</td><td align="center">2.0 M Amm Sulfate</td></tr><tr><td align="left"> Additive<xref rid="t1fn0003" ref-type="fn"><sup>1</sup></xref></td><td align="center">0.2 M Li Citrate</td><td align="center">5% PEG 400</td><td align="center">0.2 M Amm Acetate</td><td align="center">2% PEG 400</td></tr><tr><td align="left"> Space Group</td><td align="center">P4<sub>1</sub>2<sub>1</sub>2</td><td align="center">P2<sub>1</sub>2<sub>1</sub>2<sub>1</sub></td><td align="center">P6<sub>2</sub>22</td><td align="center">P2<sub>1</sub>2<sub>1</sub>2<sub>1</sub></td></tr><tr><td align="left"> Molecules/AU</td><td align="center">1</td><td align="center">2</td><td align="center">1</td><td align="center">2</td></tr><tr><td align="left">Unit Cell</td><td align="left"> </td><td align="left"> </td><td align="left"> </td><td align="left"> </td></tr><tr><td align="left"> a(Å)</td><td align="center">96.6</td><td align="center">60.9</td><td align="center">121.5</td><td align="center">62.7</td></tr><tr><td align="left"> b(Å)</td><td align="center">96.6</td><td align="center">110.6</td><td align="center">121.5</td><td align="center">111.0</td></tr><tr><td align="left"> c(Å)</td><td align="center">105.4</td><td align="center">158.9</td><td align="center">160.4</td><td align="center">160.0</td></tr><tr><td align="left"> β(°)</td><td align="center">90</td><td align="center">90</td><td align="center">90</td><td align="center">90</td></tr><tr><td align="left"> V<sub>m</sub> (Å<sup>3</sup>/Da)</td><td align="center">2.60</td><td align="center">2.82</td><td align="center">3.60</td><td align="center">2.90</td></tr><tr><td align="left"> Solvent Content (%)</td><td align="center">53</td><td align="center">56</td><td align="center">66</td><td align="center">57</td></tr><tr><td align="left">X-Ray Data<xref rid="t1fn0004" ref-type="fn"><sup>2</sup></xref></td><td align="left"> </td><td align="left"> </td><td align="left"> </td><td align="left"> </td></tr><tr><td align="left"> Resolution (Å)</td><td align="center">30-2.8 (2.9-2.8)</td><td align="center">30-2.0 (2.1-2.0)</td><td align="center">30-2.25 (2.3-2.25)</td><td align="center">30-2.0 (2.1-2.0)</td></tr><tr><td align="left"> Measured Reflections</td><td align="center">177,681 (12,072)</td><td align="center">351,312 (8,634)</td><td align="center">887,349 (59,919)</td><td align="center">873,523 (49,118)</td></tr><tr><td align="left"> Unique Reflections</td><td align="center">12,678 (899)</td><td align="center">58,989 (2,870)</td><td align="center">32,572 (2,300)</td><td align="center">75,540 (5,343)</td></tr><tr><td align="left"> Completeness (%)</td><td align="center">99.5 (97.4)</td><td align="center">80.9 (54.2)</td><td align="center">96.9 (94.8)</td><td align="center">99.7 (96.9)</td></tr><tr><td align="left"> Redundancy</td><td align="center">14.0 (13.4)</td><td align="center">6.0 (3.0)</td><td align="center">27.2 (26.1)</td><td align="center">11.6 (9.2)</td></tr><tr><td align="left"> R<sub>merge</sub></td><td align="center">0.091 (0.594)</td><td align="center">0.066 (0.204)</td><td align="center">0.086 (0.478)</td><td align="center">0.094 (0.488)</td></tr><tr><td align="left"> < I/σ ></td><td align="center">31.2 (5.1)</td><td align="center">20.4 (4.6)</td><td align="center">37.0 (10.4)</td><td align="center">21.6 (5.0)</td></tr><tr><td align="left"> B-factor (Å<sup>2</sup>)</td><td align="center">42.8</td><td align="center">27.1</td><td align="center">33.7</td><td align="center">29.4</td></tr><tr><td align="left">Refinement</td><td align="left"> </td><td align="left"> </td><td align="left"> </td><td align="left"> </td></tr><tr><td align="left"> Resolution (Å)</td><td align="center">15-2.8</td><td align="center">15-2.0</td><td align="center">15-2.25</td><td align="center">15-2.0</td></tr><tr><td align="left"> Number of Reflections</td><td align="center">11,972</td><td align="center">57,599</td><td align="center">31,411</td><td align="center">74,238</td></tr><tr><td align="left"> Number of All Atoms</td><td align="center">3,234</td><td align="center">6,948</td><td align="center">3,472</td><td align="center">7,210</td></tr><tr><td align="left"> Number of Waters</td><td align="center">0</td><td align="center">416</td><td align="center">222</td><td align="center">635</td></tr><tr><td align="left"> R-factor (%)</td><td align="center">23.9</td><td align="center">20.5</td><td align="center">22.0</td><td align="center">21.6</td></tr><tr><td align="left"> R-free (%)</td><td align="center">31.5</td><td align="center">25.5</td><td align="center">26.6</td><td align="center">25.1</td></tr><tr><td align="left">RMSD</td><td align="left"> </td><td align="left"> </td><td align="left"> </td><td align="left"> </td></tr><tr><td align="left"> Bond Lengths (Å)</td><td align="center">0.009</td><td align="center">0.010</td><td align="center">0.005</td><td align="center">0.008</td></tr><tr><td align="left"> Bond Angles (°)</td><td align="center">1.3</td><td align="center">1.3</td><td align="center">1.0</td><td align="center">1.1</td></tr><tr><td align="left"> Mean B-factor (Å<sup>2</sup>)</td><td align="center">48.4</td><td align="center">36.7</td><td align="center">47.7</td><td align="center">46.4</td></tr><tr><td align="left">Ramachandran Plot (%)</td><td align="left"> </td><td align="left"> </td><td align="left"> </td><td align="left"> </td></tr><tr><td align="left"> Outliers</td><td align="center">0.0</td><td align="center">0.0</td><td align="center">0.0</td><td align="center">0.0</td></tr><tr><td align="left"> Favored</td><td align="center">92.3</td><td align="center">96.8</td><td align="center">97.5</td><td align="center">97.6</td></tr></tbody></table> 12266 Fab H3-23:L1-39 H3-23:L3-11 H3-23:L3-20 H3-23:L4-1 PDB identifier 5I19 5I1A 5I1C 5I1D Crystal Data Crystallization Solution Buffer, pH No Buffer 0.1 M Na Acetate, pH 4.5 0.1 M MES, pH 6.5 0.1 M HEPES, pH 7.5 Precipitant1 20% PEG 3350 2.0 M Amm Sulfate 16% PEG 3350 2.0 M Amm Sulfate Additive1 0.2 M Li Citrate 5% PEG 400 0.2 M Amm Acetate 2% PEG 400 Space Group P41212 P212121 P6222 P212121 Molecules/AU 1 2 1 2 Unit Cell a(Å) 96.6 60.9 121.5 62.7 b(Å) 96.6 110.6 121.5 111.0 c(Å) 105.4 158.9 160.4 160.0 β(°) 90 90 90 90 Vm (Å3/Da) 2.60 2.82 3.60 2.90 Solvent Content (%) 53 56 66 57 X-Ray Data2 Resolution (Å) 30-2.8 (2.9-2.8) 30-2.0 (2.1-2.0) 30-2.25 (2.3-2.25) 30-2.0 (2.1-2.0) Measured Reflections 177,681 (12,072) 351,312 (8,634) 887,349 (59,919) 873,523 (49,118) Unique Reflections 12,678 (899) 58,989 (2,870) 32,572 (2,300) 75,540 (5,343) Completeness (%) 99.5 (97.4) 80.9 (54.2) 96.9 (94.8) 99.7 (96.9) Redundancy 14.0 (13.4) 6.0 (3.0) 27.2 (26.1) 11.6 (9.2) Rmerge 0.091 (0.594) 0.066 (0.204) 0.086 (0.478) 0.094 (0.488) < I/σ > 31.2 (5.1) 20.4 (4.6) 37.0 (10.4) 21.6 (5.0) B-factor (Å2) 42.8 27.1 33.7 29.4 Refinement Resolution (Å) 15-2.8 15-2.0 15-2.25 15-2.0 Number of Reflections 11,972 57,599 31,411 74,238 Number of All Atoms 3,234 6,948 3,472 7,210 Number of Waters 0 416 222 635 R-factor (%) 23.9 20.5 22.0 21.6 R-free (%) 31.5 25.5 26.6 25.1 RMSD Bond Lengths (Å) 0.009 0.010 0.005 0.008 Bond Angles (°) 1.3 1.3 1.0 1.1 Mean B-factor (Å2) 48.4 36.7 47.7 46.4 Ramachandran Plot (%) Outliers 0.0 0.0 0.0 0.0 Favored 92.3 96.8 97.5 97.6 d37e892.xml t0001 TABLE table_footnote 14105 Abbreviations: Amm, ammonium; PEG, polyethylene glycol. d37e892.xml t0001 TABLE table_footnote 14161 Values for high-resolution shell are in parentheses. d37e1371.xml t0001 TABLE table_caption 14214 (Continued) Crystal data, X-ray data, and refinement statistics. 0.9933119 evidence cleaner0 2023-06-28T19:16:41Z DUMMY: Crystal data 0.98985547 evidence cleaner0 2023-06-28T19:16:44Z DUMMY: X-ray data evidence DUMMY: cleaner0 2023-06-28T19:15:41Z refinement statistics d37e1371.xml t0001 TABLE table <?xml version="1.0" encoding="UTF-8"?> <table frame="hsides" rules="groups"><colgroup><col width="86.4pt" align="left"/><col width="86.4pt" align="left"/><col width="86.4pt" align="left"/><col width="86.4pt" align="left"/><col width="86.4pt" align="left"/></colgroup><thead><tr><th align="left">Fab</th><th align="center">H3-53:L1-39</th><th align="center">H3-53:L3-11</th><th align="center">H3-53:L3-20</th><th align="center">H3-53:L4-1</th></tr></thead><tbody><tr><td align="left"><italic>PDB indentifier</italic></td><td align="center">5I1E</td><td align="center">5I1G</td><td align="center">5I1H</td><td align="center">5I1I</td></tr><tr><td align="left">Crystal Data</td><td align="left"> </td><td align="left"> </td><td align="left"> </td><td align="left"> </td></tr><tr><td align="left">Crystallization Solution</td><td align="left"> </td><td align="left"> </td><td align="left"> </td><td align="left"> </td></tr><tr><td align="left"> Buffer, pH</td><td align="center">No buffer</td><td align="center">0.1 M Na Acetate pH 4.5</td><td align="center">0.1 M Na Acetate pH 4.5</td><td align="center">0.1M MES, pH 6.5</td></tr><tr><td align="left"> Precipitant<xref rid="t1fn0005" ref-type="fn"><sup>1</sup></xref></td><td align="center">16% PEG 3350</td><td align="center">25% PEG 3350</td><td align="center">19% PEG 4000</td><td align="center">17% PEG 3350</td></tr><tr><td align="left"> Additive<xref rid="t1fn0005" ref-type="fn"><sup>1</sup></xref></td><td align="center">0.2 M Amm Sulfate 5% Dioxane</td><td align="center">0.2 M Li<sub>2</sub>SO<sub>4</sub></td><td align="center">0.2 M Amm Sulfate</td><td align="center">0.2 M Na Formate, 5% MPD</td></tr><tr><td align="left"> Space Group</td><td align="center">P6<sub>5</sub>22</td><td align="center">P6<sub>5</sub>22</td><td align="center">P6<sub>5</sub>22</td><td align="center">P3<sub>1</sub></td></tr><tr><td align="left"> Molecules/AU</td><td align="center">1</td><td align="center">1</td><td align="center">1</td><td align="center">1</td></tr><tr><td align="left">Unit Cell</td><td align="left"> </td><td align="left"> </td><td align="left"> </td><td align="left"> </td></tr><tr><td align="left"> a(Å)</td><td align="center">89.4</td><td align="center">88.1</td><td align="center">89.4</td><td align="center">68.1</td></tr><tr><td align="left"> b(Å)</td><td align="center">89.4</td><td align="center">88.1</td><td align="center">89.4</td><td align="center">68.1</td></tr><tr><td align="left"> c(Å)</td><td align="center">212.4</td><td align="center">219.6</td><td align="center">211.7</td><td align="center">95.6</td></tr><tr><td align="left"> β(°)</td><td align="center">90</td><td align="center">90</td><td align="center">90</td><td align="center">90</td></tr><tr><td align="left"> γ(°)</td><td align="center">120</td><td align="center">120</td><td align="center">120</td><td align="center">120</td></tr><tr><td align="left"> V<sub>m</sub> (Å<sup>3</sup>/Da)</td><td align="center">2.57</td><td align="center">2.64</td><td align="center">2.57</td><td align="center">2.64</td></tr><tr><td align="left"> Solvent Content (%)</td><td align="center">52</td><td align="center">53</td><td align="center">52</td><td align="center">53</td></tr><tr><td align="left">X-Ray Data<xref rid="t1fn0006" ref-type="fn"><sup>2</sup></xref></td><td align="left"> </td><td align="left"> </td><td align="left"> </td><td align="left"> </td></tr><tr><td align="left"> Resolution (Å)</td><td align="center">30-2.7 (2.8-2.7)</td><td align="center">30-2.3 (2.4-2.3)</td><td align="center">30-2.2 (2.3-2.0)</td><td align="center">30-2.5 (2.6-2.5)</td></tr><tr><td align="left"> Measured Reflections</td><td align="center">297,367 (19,369)</td><td align="center">333,739 (8,008)</td><td align="center">381,125 (1,591)</td><td align="center">137,992 (9,883)</td></tr><tr><td align="left"> Unique Reflections</td><td align="center">14,402 (1,003)</td><td align="center">21,683 (1,135)</td><td align="center">24,323 (964)</td><td align="center">16,727 (1,227)</td></tr><tr><td align="left"> Completeness (%)</td><td align="center">99.6 (96.8)</td><td align="center">93.8 (68.4)</td><td align="center">95.3 (52.0)</td><td align="center">98.6 (98.1)</td></tr><tr><td align="left"> Redundancy</td><td align="center">20.6 (19.3)</td><td align="center">15.4 (7.1)</td><td align="center">15.7 (1.7)</td><td align="center">8.2 (8.1)</td></tr><tr><td align="left"> R<sub>merge</sub></td><td align="center">0.095 (0.451)</td><td align="center">0.057 (0.324)</td><td align="center">0.062 (0.406)</td><td align="center">0.047 (0.445)</td></tr><tr><td align="left"> < I/σ ></td><td align="center">38.3 (8.1)</td><td align="center">36.7 (5.5)</td><td align="center">36.2 (1.6)</td><td align="center">31.6 (5.6)</td></tr><tr><td align="left"> B-factor (Å<sup>2</sup>)</td><td align="center">33.2</td><td align="center">37.3</td><td align="center">33.7</td><td align="center">54.8</td></tr><tr><td align="left">Refinement</td><td align="left"> </td><td align="left"> </td><td align="left"> </td><td align="left"> </td></tr><tr><td align="left"> Resolution (Å)</td><td align="center">15-2.7</td><td align="center">15-2.3</td><td align="center">15-2.2</td><td align="center">15-2.5</td></tr><tr><td align="left"> Number of Reflections</td><td align="center">13,583</td><td align="center">20,255</td><td align="center">24,962</td><td align="center">15,811</td></tr><tr><td align="left"> Number of All Atoms</td><td align="center">3,335</td><td align="center">3,271</td><td align="center">3,298</td><td align="center">3,239</td></tr><tr><td align="left"> Number of Waters</td><td align="center">88</td><td align="center">70</td><td align="center">71</td><td align="center">21</td></tr><tr><td align="left"> R-factor (%)</td><td align="center">19.1</td><td align="center">29.8</td><td align="center">22.8</td><td align="center">25.0</td></tr><tr><td align="left"> R-free (%)</td><td align="center">26.4</td><td align="center">38.3</td><td align="center">26.6</td><td align="center">33.7</td></tr><tr><td align="left">RMSD</td><td align="left"> </td><td align="left"> </td><td align="left"> </td><td align="left"> </td></tr><tr><td align="left"> Bond Lengths (Å)</td><td align="center">0.008</td><td align="center">0.005</td><td align="center">0.005</td><td align="center">0.006</td></tr><tr><td align="left"> Bond Angles (°)</td><td align="center">1.2</td><td align="center">1.0</td><td align="center">1.0</td><td align="center">1.1</td></tr><tr><td align="left"> Mean B-factor (Å<sup>2</sup>)</td><td align="center">49.1</td><td align="center">46.3</td><td align="center">51.7</td><td align="center">88.9</td></tr><tr><td align="left">Ramachandran Plot (%)</td><td align="left"> </td><td align="left"> </td><td align="left"> </td><td align="left"> </td></tr><tr><td align="left"> Outliers</td><td align="center">0.2</td><td align="center">0.2</td><td align="center">0.2</td><td align="center">1.2</td></tr><tr><td align="left"> Favored</td><td align="center">96.7</td><td align="center">97.1</td><td align="center">96.5</td><td align="center">90.9</td></tr></tbody></table> 14279 Fab H3-53:L1-39 H3-53:L3-11 H3-53:L3-20 H3-53:L4-1 PDB indentifier 5I1E 5I1G 5I1H 5I1I Crystal Data Crystallization Solution Buffer, pH No buffer 0.1 M Na Acetate pH 4.5 0.1 M Na Acetate pH 4.5 0.1M MES, pH 6.5 Precipitant1 16% PEG 3350 25% PEG 3350 19% PEG 4000 17% PEG 3350 Additive1 0.2 M Amm Sulfate 5% Dioxane 0.2 M Li2SO4 0.2 M Amm Sulfate 0.2 M Na Formate, 5% MPD Space Group P6522 P6522 P6522 P31 Molecules/AU 1 1 1 1 Unit Cell a(Å) 89.4 88.1 89.4 68.1 b(Å) 89.4 88.1 89.4 68.1 c(Å) 212.4 219.6 211.7 95.6 β(°) 90 90 90 90 γ(°) 120 120 120 120 Vm (Å3/Da) 2.57 2.64 2.57 2.64 Solvent Content (%) 52 53 52 53 X-Ray Data2 Resolution (Å) 30-2.7 (2.8-2.7) 30-2.3 (2.4-2.3) 30-2.2 (2.3-2.0) 30-2.5 (2.6-2.5) Measured Reflections 297,367 (19,369) 333,739 (8,008) 381,125 (1,591) 137,992 (9,883) Unique Reflections 14,402 (1,003) 21,683 (1,135) 24,323 (964) 16,727 (1,227) Completeness (%) 99.6 (96.8) 93.8 (68.4) 95.3 (52.0) 98.6 (98.1) Redundancy 20.6 (19.3) 15.4 (7.1) 15.7 (1.7) 8.2 (8.1) Rmerge 0.095 (0.451) 0.057 (0.324) 0.062 (0.406) 0.047 (0.445) < I/σ > 38.3 (8.1) 36.7 (5.5) 36.2 (1.6) 31.6 (5.6) B-factor (Å2) 33.2 37.3 33.7 54.8 Refinement Resolution (Å) 15-2.7 15-2.3 15-2.2 15-2.5 Number of Reflections 13,583 20,255 24,962 15,811 Number of All Atoms 3,335 3,271 3,298 3,239 Number of Waters 88 70 71 21 R-factor (%) 19.1 29.8 22.8 25.0 R-free (%) 26.4 38.3 26.6 33.7 RMSD Bond Lengths (Å) 0.008 0.005 0.005 0.006 Bond Angles (°) 1.2 1.0 1.0 1.1 Mean B-factor (Å2) 49.1 46.3 51.7 88.9 Ramachandran Plot (%) Outliers 0.2 0.2 0.2 1.2 Favored 96.7 97.1 96.5 90.9 d37e1371.xml t0001 TABLE table_footnote 16142 Abbreviations: Amm, ammonium; PEG, polyethylene glycol. d37e1371.xml t0001 TABLE table_footnote 16198 Values for high-resolution shell are in parentheses. d37e1852.xml t0001 TABLE table_caption 16251 (Continued) Crystal data, X-ray data, and refinement statistics. 0.9933119 evidence cleaner0 2023-06-28T19:16:05Z DUMMY: Crystal data 0.98985547 evidence cleaner0 2023-06-28T19:16:08Z DUMMY: X-ray data evidence DUMMY: cleaner0 2023-06-28T19:16:20Z refinement statistics d37e1852.xml t0001 TABLE table <?xml version="1.0" encoding="UTF-8"?> <table frame="hsides" rules="groups"><colgroup><col width="86.4pt" align="left"/><col width="86.4pt" align="left"/><col width="86.4pt" align="left"/><col width="86.4pt" align="left"/><col width="86.4pt" align="left"/></colgroup><thead><tr><th align="left">Fab<hr/></th><th align="center">H5-51:L1-39<hr/></th><th align="center">H5-51:L3-11<hr/></th><th align="center">H5-51:L3-20<hr/></th><th align="center">H5-51:L4-1<hr/></th></tr><tr><th align="left"><italic> PDB identifier</italic></th><th align="center">4KMT</th><th align="center">5I1J</th><th align="center">5I1K</th><th align="center">5I1L</th></tr></thead><tbody><tr><td align="left">Crystal Data</td><td align="left"> </td><td align="left"> </td><td align="left"> </td><td align="left"> </td></tr><tr><td align="left">Crystallization Solution</td><td align="left"> </td><td align="left"> </td><td align="left"> </td><td align="left"> </td></tr><tr><td align="left"> Buffer, pH</td><td align="center">0.1 M CHES, pH 9.5</td><td align="center">0.1 M Tris, pH 8.5</td><td align="center">0.1 M CHES, pH 9.5</td><td align="center">0.1 M Tris, pH 8.5</td></tr><tr><td align="left"> Precipitant<xref rid="t1fn0007" ref-type="fn"><sup>1</sup></xref></td><td align="center">1.8 M Amm Sulfate</td><td align="center">25% PEG 3350</td><td align="center">1.0 M Amm Sulfate</td><td align="center">24% PEG 3350</td></tr><tr><td align="left"> Additive<xref rid="t1fn0007" ref-type="fn"><sup>1</sup></xref></td><td align="center">5% dioxane</td><td align="center">0.2 M MgCl<sub>2</sub></td><td align="left"> </td><td align="center">0.2 M Amm Sulfate</td></tr><tr><td align="left"> Space Group</td><td align="center">P2<sub>1</sub>2<sub>1</sub>2<sub>1</sub></td><td align="center">P2<sub>1</sub>2<sub>1</sub>2<sub>1</sub></td><td align="center">P2<sub>1</sub>2<sub>1</sub>2<sub>1</sub></td><td align="center">P2<sub>1</sub></td></tr><tr><td align="left"> Molecules/AU</td><td align="center">1</td><td align="center">1</td><td align="center">1</td><td align="center">2</td></tr><tr><td align="left">Unit Cell</td><td align="left"> </td><td align="left"> </td><td align="left"> </td><td align="left"> </td></tr><tr><td align="left"> a(Å)</td><td align="center">63.7</td><td align="center">64.1</td><td align="center">63.8</td><td align="center">106.0</td></tr><tr><td align="left"> b(Å)</td><td align="center">73.8</td><td align="center">73.8</td><td align="center">74.1</td><td align="center">38.0</td></tr><tr><td align="left"> c(Å)</td><td align="center">103.1</td><td align="center">103.0</td><td align="center">103.0</td><td align="center">112.3</td></tr><tr><td align="left"> β(°)</td><td align="center">90</td><td align="center">90</td><td align="center">90</td><td align="center">100.4</td></tr><tr><td align="left"> V<sub>m</sub> (Å<sup>3</sup>/Da)</td><td align="center">2.53</td><td align="center">2.56</td><td align="center">2.54</td><td align="center">2.28</td></tr><tr><td align="left"> Solvent Content (%)</td><td align="center">51</td><td align="center">52</td><td align="center">51</td><td align="center">46</td></tr><tr><td align="left">X-Ray Data<xref rid="t1fn0008" ref-type="fn"><sup>2</sup></xref></td><td align="left"> </td><td align="left"> </td><td align="left"> </td><td align="left"> </td></tr><tr><td align="left"> Resolution (Å)</td><td align="center">30-2.1 (2.2-2.1)</td><td align="center">30-2.5 (2.6-2.5)</td><td align="center">30-1.65 (1.7-1.65)</td><td align="center">30-1.95 (2.0-1.95)</td></tr><tr><td align="left"> Measured Reflections</td><td align="center">131,839 (6,655)</td><td align="center">120,521 (7,988)</td><td align="center">246,750 (4,142)</td><td align="center">320,324 (12,119)</td></tr><tr><td align="left"> Unique Reflections</td><td align="center">27,026 (1,885)</td><td align="center">17,286 (1,236)</td><td align="center">53,058 (2,141)</td><td align="center">61,554 (3,243)</td></tr><tr><td align="left"> Completeness (%)</td><td align="center">93.6 (89.8)</td><td align="center">99.7 (97.3)</td><td align="center">89.8 (49.8)</td><td align="center">94.4 (67.1)</td></tr><tr><td align="left"> Redundancy</td><td align="center">4.9 (3.5)</td><td align="center">7.0 (6.5)</td><td align="center">4.7 (1.9)</td><td align="center">5.2 (3.7)</td></tr><tr><td align="left"> R<sub>merge</sub></td><td align="center">0.079 (0.278)</td><td align="center">0.080 (0.281)</td><td align="center">0.034 (0.131)</td><td align="center">0.060 (0.395)</td></tr><tr><td align="left"> < I/σ ></td><td align="center">16.8 (5.7)</td><td align="center">21.1(6.9)</td><td align="center">27.5 (5.8)</td><td align="center">19.7 (3.1)</td></tr><tr><td align="left"> B-factor (Å<sup>2</sup>)</td><td align="center">26.0</td><td align="center">27.0</td><td align="center">21.6</td><td align="center">31.4</td></tr><tr><td align="left">Refinement</td><td align="left"> </td><td align="left"> </td><td align="left"> </td><td align="left"> </td></tr><tr><td align="left"> Resolution (Å)</td><td align="center">15-2.1</td><td align="center">15-2.5</td><td align="center">15-1.65</td><td align="center">15-1.95</td></tr><tr><td align="left"> Number of Reflections</td><td align="center">25,857</td><td align="center">16,328</td><td align="center">51,882</td><td align="center">60,181</td></tr><tr><td align="left"> Number of All Atoms</td><td align="center">3,676</td><td align="center">3,454</td><td align="center">3,814</td><td align="center">7,175</td></tr><tr><td align="left"> Number of Waters</td><td align="center">302</td><td align="center">196</td><td align="center">527</td><td align="center">445</td></tr><tr><td align="left"> R-factor (%)</td><td align="center">17.1</td><td align="center">17.7</td><td align="center">17.2</td><td align="center">19.4</td></tr><tr><td align="left"> R-free (%)</td><td align="center">22.0</td><td align="center">25.8</td><td align="center">19.7</td><td align="center">25.8</td></tr><tr><td align="left">RMSD</td><td align="left"> </td><td align="left"> </td><td align="left"> </td><td align="left"> </td></tr><tr><td align="left"> Bond Lengths (Å)</td><td align="center">0.006</td><td align="center">0.009</td><td align="center">0.005</td><td align="center">0.009</td></tr><tr><td align="left"> Bond Angles (°)</td><td align="center">1.0</td><td align="center">1.3</td><td align="center">1.3</td><td align="center">1.3</td></tr><tr><td align="left"> Mean B-factor (Å<sup>2</sup>)</td><td align="center">25.2</td><td align="center">38.2</td><td align="center">20.0</td><td align="center">19.5</td></tr><tr><td align="left">Ramachandran Plot (%)</td><td align="left"> </td><td align="left"> </td><td align="left"> </td><td align="left"> </td></tr><tr><td align="left"> Outliers</td><td align="center">0.0</td><td align="center">0.0</td><td align="center">0.0</td><td align="center">0.0</td></tr><tr><td align="left"> Favored</td><td align="center">98.4</td><td align="center">97.9</td><td align="center">98.1</td><td align="center">98.0</td></tr></tbody></table> 16316 Fab H5-51:L1-39 H5-51:L3-11 H5-51:L3-20 H5-51:L4-1 PDB identifier 4KMT 5I1J 5I1K 5I1L Crystal Data Crystallization Solution Buffer, pH 0.1 M CHES, pH 9.5 0.1 M Tris, pH 8.5 0.1 M CHES, pH 9.5 0.1 M Tris, pH 8.5 Precipitant1 1.8 M Amm Sulfate 25% PEG 3350 1.0 M Amm Sulfate 24% PEG 3350 Additive1 5% dioxane 0.2 M MgCl2 0.2 M Amm Sulfate Space Group P212121 P212121 P212121 P21 Molecules/AU 1 1 1 2 Unit Cell a(Å) 63.7 64.1 63.8 106.0 b(Å) 73.8 73.8 74.1 38.0 c(Å) 103.1 103.0 103.0 112.3 β(°) 90 90 90 100.4 Vm (Å3/Da) 2.53 2.56 2.54 2.28 Solvent Content (%) 51 52 51 46 X-Ray Data2 Resolution (Å) 30-2.1 (2.2-2.1) 30-2.5 (2.6-2.5) 30-1.65 (1.7-1.65) 30-1.95 (2.0-1.95) Measured Reflections 131,839 (6,655) 120,521 (7,988) 246,750 (4,142) 320,324 (12,119) Unique Reflections 27,026 (1,885) 17,286 (1,236) 53,058 (2,141) 61,554 (3,243) Completeness (%) 93.6 (89.8) 99.7 (97.3) 89.8 (49.8) 94.4 (67.1) Redundancy 4.9 (3.5) 7.0 (6.5) 4.7 (1.9) 5.2 (3.7) Rmerge 0.079 (0.278) 0.080 (0.281) 0.034 (0.131) 0.060 (0.395) < I/σ > 16.8 (5.7) 21.1(6.9) 27.5 (5.8) 19.7 (3.1) B-factor (Å2) 26.0 27.0 21.6 31.4 Refinement Resolution (Å) 15-2.1 15-2.5 15-1.65 15-1.95 Number of Reflections 25,857 16,328 51,882 60,181 Number of All Atoms 3,676 3,454 3,814 7,175 Number of Waters 302 196 527 445 R-factor (%) 17.1 17.7 17.2 19.4 R-free (%) 22.0 25.8 19.7 25.8 RMSD Bond Lengths (Å) 0.006 0.009 0.005 0.009 Bond Angles (°) 1.0 1.3 1.3 1.3 Mean B-factor (Å2) 25.2 38.2 20.0 19.5 Ramachandran Plot (%) Outliers 0.0 0.0 0.0 0.0 Favored 98.4 97.9 98.1 98.0 d37e1852.xml t0001 TABLE table_footnote 18144 Abbreviations: Amm, ammonium; PEG, polyethylene glycol. d37e1852.xml t0001 TABLE table_footnote 18200 Values for high-resolution shell are in parentheses. RESULTS paragraph 18253 The crystal structures of a germline library composed of 16 Fabs generated by combining 4 HCs (H1-69, H3-23, H3-53 and H5-51) and 4 LCs (L1-39, L3-11, L3-20 and L4-1) have been determined. The Fab heavy and light chain sequences for the variants numbered according to Chothia are shown in Fig. S1. The four different HCs all have the same CDR H3 sequence, ARYDGIYGELDF. Crystallization of the 16 Fabs was previously reported. Three sets of the crystals were isomorphous with nearly identical unit cells (Table 1). These include (1) H3-23:L3-11 and H3-23:L4-1 in P212121, (2) H3-53:L1-39, H3-53:L3-11 and H3-53:L3-20 in P6522, and (3) H5-51:L1-39, H5-51:L3-11 and H5-51:L3-20 in P212121. Crystallization conditions for the 3 groups are also similar, but not identical (Table 1). Variations occur in the pH (buffer) and the additives, and, in group 3, PEG 3350 is the precipitant for one variants while ammonium sulfate is the precipitant for the other two. The similarity in the crystal forms is attributed in part to cross-seeding using the microseed matrix screening for groups 2 and 3. 0.9973289 evidence cleaner0 2023-06-28T19:16:52Z DUMMY: crystal structures experimental_method MESH: cleaner0 2023-06-29T09:07:12Z germline library 0.15716633 structure_element cleaner0 2023-06-28T15:58:46Z SO: Fabs 0.9913346 structure_element cleaner0 2023-06-28T16:11:32Z SO: HCs mutant MESH: cleaner0 2023-06-28T21:03:19Z H1-69 0.54475325 mutant cleaner0 2023-06-28T21:04:17Z MESH: H3-23 0.56800383 mutant cleaner0 2023-06-28T21:08:32Z MESH: H3-53 mutant MESH: cleaner0 2023-06-28T21:05:05Z H5-51 0.99582016 structure_element cleaner0 2023-06-28T16:11:39Z SO: LCs 0.78147143 mutant cleaner0 2023-06-28T21:05:50Z MESH: L1-39 0.8090814 mutant cleaner0 2023-06-28T21:06:34Z MESH: L3-11 0.78590775 mutant cleaner0 2023-06-28T21:07:15Z MESH: L3-20 0.4724779 mutant cleaner0 2023-06-28T21:08:00Z MESH: L4-1 structure_element SO: cleaner0 2023-06-28T15:59:04Z Fab structure_element SO: cleaner0 2023-06-28T16:13:49Z light chain 0.97605056 structure_element cleaner0 2023-06-28T16:11:32Z SO: HCs structure_element SO: cleaner0 2023-06-28T16:25:21Z CDR structure_element SO: cleaner0 2023-06-28T19:05:14Z H3 0.3840933 structure_element cleaner0 2023-06-29T08:56:41Z SO: ARYDGIYGELDF 0.7428561 experimental_method cleaner0 2023-06-29T09:07:21Z MESH: Crystallization 0.16106084 structure_element cleaner0 2023-06-28T15:58:46Z SO: Fabs 0.990274 evidence cleaner0 2023-06-28T19:17:00Z DUMMY: crystals complex_assembly GO: cleaner0 2023-06-28T21:12:09Z H3-23:L3-11 complex_assembly GO: cleaner0 2023-06-28T21:12:33Z H3-23:L4-1 complex_assembly GO: cleaner0 2023-06-28T21:13:03Z H3-53:L1-39 complex_assembly GO: cleaner0 2023-06-28T21:13:26Z H3-53:L3-11 complex_assembly GO: cleaner0 2023-06-28T21:13:46Z H3-53:L3-20 complex_assembly GO: cleaner0 2023-06-28T21:14:10Z H5-51:L1-39 complex_assembly GO: cleaner0 2023-06-28T21:14:30Z H5-51:L3-11 complex_assembly GO: cleaner0 2023-06-28T21:14:52Z H5-51:L3-20 0.93274474 chemical cleaner0 2023-06-29T09:24:13Z CHEBI: PEG 3350 0.9821999 chemical cleaner0 2023-06-29T09:24:17Z CHEBI: ammonium sulfate 0.94161546 evidence cleaner0 2023-06-28T19:17:05Z DUMMY: crystal forms 0.979331 experimental_method cleaner0 2023-06-29T09:07:27Z MESH: microseed matrix screening RESULTS paragraph 19344 The crystal structures of the 16 Fabs have been determined at resolutions ranging from 3.3 Å to 1.65 Å (Table 1). The number of Fab molecules in the crystallographic asymmetric unit varies from 1 (for 12 Fabs) to 2 (for 4 Fabs). Overall the structures are fairly complete, and, as can be expected, the models for the higher resolution structures are more complete than those for the lower resolution structures (Table S1). Invariably, the HCs have more disorder than the LCs. For the LC, the disorder is observed at 2 of the C-terminal residues with few exceptions. Apart from the C-terminus, only a few surface residues in LC are disordered. 0.9972463 evidence cleaner0 2023-06-28T19:16:53Z DUMMY: crystal structures 0.26109496 structure_element cleaner0 2023-06-28T15:58:46Z SO: Fabs 0.19023296 structure_element cleaner0 2023-06-28T15:59:04Z SO: Fab 0.30332693 structure_element cleaner0 2023-06-28T15:58:46Z SO: Fabs 0.28805926 structure_element cleaner0 2023-06-28T15:58:46Z SO: Fabs 0.9964563 evidence cleaner0 2023-06-28T19:17:25Z DUMMY: structures 0.9963349 evidence cleaner0 2023-06-28T19:17:28Z DUMMY: structures 0.996055 evidence cleaner0 2023-06-28T19:17:31Z DUMMY: structures 0.9984939 structure_element cleaner0 2023-06-28T16:11:32Z SO: HCs 0.92722005 protein_state cleaner0 2023-06-29T09:27:42Z DUMMY: disorder 0.9984347 structure_element cleaner0 2023-06-28T16:11:39Z SO: LCs 0.9984855 structure_element cleaner0 2023-06-28T16:24:55Z SO: LC 0.8974196 protein_state cleaner0 2023-06-29T09:27:45Z DUMMY: disorder 0.9983936 structure_element cleaner0 2023-06-28T16:24:55Z SO: LC 0.9923855 protein_state cleaner0 2023-06-29T09:27:48Z DUMMY: disordered RESULTS paragraph 19993 The HCs feature the largest number of disordered residues, with the lower resolution structures having the most. The C-terminal residues including the 6xHis tags are disordered in all 16 structures. In addition to these, 2 primary disordered stretches of residues are observed in a number of structures (Table S1). One involves the loop connecting the first 2 β-strands of the constant domain (in all Fabs except H3-23:L1-39, H3-23:L3-11 and H3-53:L1-39). The other is located in CDR H3 (in H5-51:L3-11, H5-51:L3-20 and in one of 2 copies of H3-23:L4-1). CDR H1 and CDR H2 also show some degree of disorder, but to a lesser extent. 0.9985374 structure_element cleaner0 2023-06-28T16:11:32Z SO: HCs 0.9899644 protein_state cleaner0 2023-06-29T09:27:51Z DUMMY: disordered 0.99663144 evidence cleaner0 2023-06-28T19:17:33Z DUMMY: structures 0.99440306 protein_state cleaner0 2023-06-29T09:27:55Z DUMMY: disordered 0.99707234 evidence cleaner0 2023-06-28T19:17:36Z DUMMY: structures 0.9967458 evidence cleaner0 2023-06-28T19:17:39Z DUMMY: structures 0.97793114 structure_element cleaner0 2023-06-29T08:56:00Z SO: loop 0.9568026 structure_element cleaner0 2023-06-29T08:56:03Z SO: β-strands 0.9960027 structure_element cleaner0 2023-06-29T08:56:05Z SO: constant domain 0.46980876 structure_element cleaner0 2023-06-28T15:58:46Z SO: Fabs complex_assembly GO: cleaner0 2023-06-28T21:15:27Z H3-23:L1-39 complex_assembly GO: cleaner0 2023-06-28T21:12:10Z H3-23:L3-11 complex_assembly GO: cleaner0 2023-06-28T21:13:04Z H3-53:L1-39 0.9980945 structure_element cleaner0 2023-06-28T16:25:21Z SO: CDR 0.8540226 structure_element cleaner0 2023-06-28T19:05:15Z SO: H3 complex_assembly GO: cleaner0 2023-06-28T21:14:32Z H5-51:L3-11 complex_assembly GO: cleaner0 2023-06-28T21:14:53Z H5-51:L3-20 complex_assembly GO: cleaner0 2023-06-28T21:12:34Z H3-23:L4-1 0.99790764 structure_element cleaner0 2023-06-28T16:25:21Z SO: CDR 0.97477245 structure_element cleaner0 2023-06-28T19:04:10Z SO: H1 0.99792707 structure_element cleaner0 2023-06-28T16:25:21Z SO: CDR 0.9856117 structure_element cleaner0 2023-06-28T16:26:21Z SO: H2 0.9067931 protein_state cleaner0 2023-06-29T09:27:58Z DUMMY: disorder RESULTS title_2 20628 CDR canonical structures 0.9833983 structure_element cleaner0 2023-06-28T16:25:21Z SO: CDR evidence DUMMY: cleaner0 2023-06-28T20:50:47Z structures RESULTS paragraph 20653 Several CDR definitions have evolved over decades of antibody research. Depending on the focus of the study, the CDR boundaries differ slightly between various definitions. In this work, we use the CDR definition of North et al., which is similar to that of Martin with the following exceptions: 1) CDRs H1 and H3 begin immediately after the Cys; and 2) CDR L2 includes an additional residue at the N-terminal side, typically Tyr. structure_element SO: cleaner0 2023-06-28T16:25:21Z CDR protein_type MESH: cleaner0 2023-06-28T15:45:48Z antibody structure_element SO: cleaner0 2023-06-28T16:25:21Z CDR structure_element SO: cleaner0 2023-06-28T16:25:21Z CDR 0.9945135 structure_element cleaner0 2023-06-28T19:04:38Z SO: CDRs 0.9963715 structure_element cleaner0 2023-06-28T19:04:10Z SO: H1 0.9967776 structure_element cleaner0 2023-06-28T19:05:15Z SO: H3 0.9913113 residue_name cleaner0 2023-06-29T09:11:56Z SO: Cys 0.996126 structure_element cleaner0 2023-06-28T16:25:21Z SO: CDR 0.99719477 structure_element cleaner0 2023-06-28T20:09:53Z SO: L2 0.9898846 residue_name cleaner0 2023-06-29T09:11:59Z SO: Tyr RESULTS title_2 21085 CDR H1 structure_element SO: cleaner0 2023-06-28T16:25:21Z CDR structure_element SO: cleaner0 2023-06-28T19:04:11Z H1 kmab-08-06-1190060-g001.jpg f0001 FIG fig_caption 21092 The superposition of CDR H1 backbones for all HC:LC pairs with heavy chains: (A) H1-69, (B) H3-23, (C) H3-53 and (D) H5-51. 0.99592435 experimental_method cleaner0 2023-06-29T09:07:33Z MESH: superposition structure_element SO: cleaner0 2023-06-28T16:25:21Z CDR structure_element SO: cleaner0 2023-06-28T19:04:11Z H1 0.9562733 complex_assembly cleaner0 2023-06-29T09:23:30Z GO: HC:LC structure_element SO: cleaner0 2023-06-28T15:56:24Z heavy chains 0.89844674 mutant cleaner0 2023-06-28T21:03:19Z MESH: H1-69 0.9519102 mutant cleaner0 2023-06-28T21:04:17Z MESH: H3-23 0.91820097 mutant cleaner0 2023-06-28T21:08:32Z MESH: H3-53 0.93086475 mutant cleaner0 2023-06-28T21:05:05Z MESH: H5-51 t0002.xml t0002 TABLE table_caption 21216 Canonical structures. t0002.xml t0002 TABLE table <?xml version="1.0" encoding="UTF-8"?> <table frame="hsides" rules="groups"><colgroup><col width="86.4pt" align="left"/><col width="86.4pt" align="left"/><col width="86.4pt" align="left"/><col width="86.4pt" align="left"/><col width="86.4pt" align="left"/></colgroup><thead><tr><th align="left">Pairs</th><th align="center">PDB</th><th align="center">CDR H1</th><th align="center">CDR H2</th><th align="center">CDR H3</th></tr></thead><tbody><tr><td align="left"><bold>H1-69</bold></td><td align="left"> </td><td align="left">KASGGTFSSYAIS</td><td align="left">GIIPIFGTAN</td><td align="left">ARYDGIYGELDF</td></tr><tr><td align="left"><bold>H1-69</bold>:L1-39</td><td align="center">5I15</td><td align="left">H1-13-4</td><td align="left">H2-10-1</td><td align="left">H3-12-1</td></tr><tr><td align="left"><bold>H1-69</bold>:L3-11</td><td align="center">5I16</td><td align="left">H1-13-1/H1-13-1</td><td align="left">H2-10-1/H2-10-1</td><td align="left">H3-12-1/H3-12-1</td></tr><tr><td align="left"><bold>H1-69</bold>:L3-20</td><td align="center">5I17</td><td align="left">H1-13-3/H1-13-6</td><td align="left">H2-10-1/NA</td><td align="left">H3-12-1/H3-12-1</td></tr><tr><td align="left"><bold>H1-69</bold>:L4-1</td><td align="center">5I18</td><td align="left">H1-13-10</td><td align="left">H2-10-1</td><td align="left">H3-12-1</td></tr><tr><td align="left"><bold>H3-23</bold></td><td align="left"> </td><td align="left">AASGFTFSSYAMS</td><td align="left">AISGSGGSTY</td><td align="left">AKYDGIYDGIYGELDF</td></tr><tr><td align="left"><bold>H3-23</bold>:L1-39</td><td align="center">5I19</td><td align="left">H1-13-1</td><td align="left">H2-10-2</td><td align="left">H3-12-1</td></tr><tr><td align="left"><bold>H3-23</bold>:L3-11</td><td align="center">5I1A</td><td align="left">H1-13-1/H1-13-1</td><td align="left">H2-10-2/H2-10-2</td><td align="left">H3-12-1/H3-12-1</td></tr><tr><td align="left"><bold>H3-23</bold>:L3-20</td><td align="center">5I1C</td><td align="left">H1-13-1</td><td align="left">H2-10-2</td><td align="left">H3-12-1</td></tr><tr><td align="left"><bold>H3-23</bold>:L4-1</td><td align="center">5I1D</td><td align="left">H1-13-1/H1-13-1</td><td align="left">H2-10-2/H2-10-2</td><td align="left">H3-12-1/NA</td></tr><tr><td align="left"><bold>H3-53</bold></td><td align="left"> </td><td align="left">AASGFTVSSNYMS</td><td align="left">VIYSGGSTY</td><td align="left">ARYDGIYGELDF</td></tr><tr><td align="left"><bold>H3-53</bold>:L1-39</td><td align="center">5I1E</td><td align="left">H1-13-1</td><td align="left">H2-9-3</td><td align="left">H3-12-1</td></tr><tr><td align="left"><bold>H3-53</bold>:L3-11</td><td align="center">5I1G</td><td align="left">H1-13-1</td><td align="left">H2-9-3</td><td align="left">H3-12-1</td></tr><tr><td align="left"><bold>H3-53</bold>:L3-20</td><td align="center">5I1H</td><td align="left">H1-13-1</td><td align="left">H2-9-3</td><td align="left">H3-12-1</td></tr><tr><td align="left"><bold>H3-53</bold>:L4-1</td><td align="center">5I1I</td><td align="left">H1-13-1</td><td align="left">H2-9-3</td><td align="left">NA</td></tr><tr><td align="left"><bold>H5-51</bold></td><td align="left"> </td><td align="left">KGSGYSFTSYWIG</td><td align="left">IIYPGDSDTR</td><td align="left">ARYDGIYGELDF</td></tr><tr><td align="left"><bold>H5-51</bold>:L1-39</td><td align="center">4KMT</td><td align="left">H1-13-1</td><td align="left">H2-10-1</td><td align="left">H3-12-1</td></tr><tr><td align="left"><bold>H5-51</bold>:L3-11</td><td align="center">5I1J</td><td align="left">H1-13-1</td><td align="left">H2-10-1</td><td align="left">NA</td></tr><tr><td align="left"><bold>H5-51</bold>:L3-20</td><td align="center">5I1K</td><td align="left">H1-13-1</td><td align="left">H2-10-1</td><td align="left">NA</td></tr><tr><td align="left"><bold>H5-51</bold>:L4-1</td><td align="center">5I1L</td><td align="left">H1-13-1/H1-13-1</td><td align="left">H2-10-1/H2-10-1</td><td align="left">H3-12-1/H3-12-1</td></tr><tr><td align="left"> </td><td align="left"> </td><td align="left"><bold>CDR L1</bold></td><td align="left"><bold>CDR L2</bold></td><td align="left"><bold>CDR L3</bold></td></tr><tr><td align="left"><bold>L1-39</bold></td><td align="left"> </td><td align="left">RASQSISSYLN</td><td align="left">YAASSLQS</td><td align="left">QQSYSTPLT</td></tr><tr><td align="left">H1-69:<bold>L1-39</bold></td><td align="center">5I15</td><td align="left">L1-11-1</td><td align="left">L2-8-1</td><td align="left">L3-9-cis7-1</td></tr><tr><td align="left">H3-23:<bold>L1-39</bold></td><td align="center">5I19</td><td align="left">L1-11-1</td><td align="left">L2-8-1</td><td align="left">L3-9-cis7-1</td></tr><tr><td align="left">H3-53:<bold>L1-39</bold></td><td align="center">5I1E</td><td align="left">L1-11-1</td><td align="left">L2-8-1</td><td align="left">L3-9-cis7-1</td></tr><tr><td align="left">H5-51:<bold>L1-39</bold></td><td align="center">4KMT</td><td align="left">L1-11-1</td><td align="left">L2-8-1</td><td align="left">L3-9-cis7-1</td></tr><tr><td align="left"><bold>L3-11</bold></td><td align="left"> </td><td align="left">RASQSVSSYLA</td><td align="left">YDASNRAT</td><td align="left">QQRSNWPLT</td></tr><tr><td align="left">H1-69:<bold>L3-11</bold></td><td align="center">5I16</td><td align="left">L1-11-1/L1-11-1</td><td align="left">L2-8-1/L2-8-1</td><td align="left">L3-9-cis7-1/L3-9-cis7-1</td></tr><tr><td align="left">H3-23:<bold>L3-11</bold></td><td align="center">5I1A</td><td align="left">L1-11-1/L1-11-1</td><td align="left">L2-8-1/L2-8-1</td><td align="left">L3-9-cis7-1/L3-9-cis7-1</td></tr><tr><td align="left">H3-53:<bold>L3-11</bold></td><td align="center">5I1G</td><td align="left">L1-11-1</td><td align="left">L2-8-1</td><td align="left">L3-9-cis7-1</td></tr><tr><td align="left">H5-51:<bold>L3-11</bold></td><td align="center">5I1J</td><td align="left">L1-11-1</td><td align="left">L2-8-1</td><td align="left">L3-9-cis7-1</td></tr><tr><td align="left"><bold>L3-20</bold></td><td align="left"> </td><td align="left">RASQSVSSSYLA</td><td align="left">YGASSRAT</td><td align="left">QQYGSSPLT</td></tr><tr><td align="left">H1-69:<bold>L3-20</bold></td><td align="center">5I17</td><td align="left">L1-12-2/L1-12-1</td><td align="left">L2-8-1/L2-8-1</td><td align="left">L3-9-cis7-1/L3-9-cis7-1</td></tr><tr><td align="left">H3-23:<bold>L3-20</bold></td><td align="center">5I1C</td><td align="left">L1-12-2</td><td align="left">L2-8-1</td><td align="left">L3-9-cis7-1</td></tr><tr><td align="left">H3-53:<bold>L3-20</bold></td><td align="center">5I1H</td><td align="left">L1-12-1</td><td align="left">L2-8-1</td><td align="left">L3-9-cis7-1</td></tr><tr><td align="left">H5-51:<bold>L3-20</bold></td><td align="center">5I1K</td><td align="left">L1-12-1</td><td align="left">L2-8-1</td><td align="left">L3-9-cis7-1</td></tr><tr><td align="left"><bold>L4-1</bold></td><td align="left"> </td><td align="left">KSSQSVLYSSNNKNYLA</td><td align="left">YWASTRES</td><td align="left">QQYYSTPLT</td></tr><tr><td align="left">H1-69:<bold>L4-1</bold></td><td align="center">5I18</td><td align="left">L1-17-1</td><td align="left">L2-8-1</td><td align="left">L3-9-cis7-1</td></tr><tr><td align="left">H3-23:<bold>L4-1</bold></td><td align="center">5I1D</td><td align="left">L1-17-1/L1-17-1</td><td align="left">L2-8-1/L2-8-1</td><td align="left">L3-9-cis7-1/L3-9-cis7-1</td></tr><tr><td align="left">H3-53:<bold>L4-1</bold></td><td align="center">5I1I</td><td align="left">L1-17-1</td><td align="left">L2-8-1</td><td align="left">L3-9-cis7-1</td></tr><tr><td align="left">H5-51:<bold>L4-1</bold></td><td align="center">5I1L</td><td align="left">L1-17-1/L1-17-1</td><td align="left">L2-8-1/L2-8-1</td><td align="left">L3-9-cis7-1/L3-9-cis7-1</td></tr></tbody></table> 21238 Pairs PDB CDR H1 CDR H2 CDR H3 H1-69 KASGGTFSSYAIS GIIPIFGTAN ARYDGIYGELDF H1-69:L1-39 5I15 H1-13-4 H2-10-1 H3-12-1 H1-69:L3-11 5I16 H1-13-1/H1-13-1 H2-10-1/H2-10-1 H3-12-1/H3-12-1 H1-69:L3-20 5I17 H1-13-3/H1-13-6 H2-10-1/NA H3-12-1/H3-12-1 H1-69:L4-1 5I18 H1-13-10 H2-10-1 H3-12-1 H3-23 AASGFTFSSYAMS AISGSGGSTY AKYDGIYDGIYGELDF H3-23:L1-39 5I19 H1-13-1 H2-10-2 H3-12-1 H3-23:L3-11 5I1A H1-13-1/H1-13-1 H2-10-2/H2-10-2 H3-12-1/H3-12-1 H3-23:L3-20 5I1C H1-13-1 H2-10-2 H3-12-1 H3-23:L4-1 5I1D H1-13-1/H1-13-1 H2-10-2/H2-10-2 H3-12-1/NA H3-53 AASGFTVSSNYMS VIYSGGSTY ARYDGIYGELDF H3-53:L1-39 5I1E H1-13-1 H2-9-3 H3-12-1 H3-53:L3-11 5I1G H1-13-1 H2-9-3 H3-12-1 H3-53:L3-20 5I1H H1-13-1 H2-9-3 H3-12-1 H3-53:L4-1 5I1I H1-13-1 H2-9-3 NA H5-51 KGSGYSFTSYWIG IIYPGDSDTR ARYDGIYGELDF H5-51:L1-39 4KMT H1-13-1 H2-10-1 H3-12-1 H5-51:L3-11 5I1J H1-13-1 H2-10-1 NA H5-51:L3-20 5I1K H1-13-1 H2-10-1 NA H5-51:L4-1 5I1L H1-13-1/H1-13-1 H2-10-1/H2-10-1 H3-12-1/H3-12-1 CDR L1 CDR L2 CDR L3 L1-39 RASQSISSYLN YAASSLQS QQSYSTPLT H1-69:L1-39 5I15 L1-11-1 L2-8-1 L3-9-cis7-1 H3-23:L1-39 5I19 L1-11-1 L2-8-1 L3-9-cis7-1 H3-53:L1-39 5I1E L1-11-1 L2-8-1 L3-9-cis7-1 H5-51:L1-39 4KMT L1-11-1 L2-8-1 L3-9-cis7-1 L3-11 RASQSVSSYLA YDASNRAT QQRSNWPLT H1-69:L3-11 5I16 L1-11-1/L1-11-1 L2-8-1/L2-8-1 L3-9-cis7-1/L3-9-cis7-1 H3-23:L3-11 5I1A L1-11-1/L1-11-1 L2-8-1/L2-8-1 L3-9-cis7-1/L3-9-cis7-1 H3-53:L3-11 5I1G L1-11-1 L2-8-1 L3-9-cis7-1 H5-51:L3-11 5I1J L1-11-1 L2-8-1 L3-9-cis7-1 L3-20 RASQSVSSSYLA YGASSRAT QQYGSSPLT H1-69:L3-20 5I17 L1-12-2/L1-12-1 L2-8-1/L2-8-1 L3-9-cis7-1/L3-9-cis7-1 H3-23:L3-20 5I1C L1-12-2 L2-8-1 L3-9-cis7-1 H3-53:L3-20 5I1H L1-12-1 L2-8-1 L3-9-cis7-1 H5-51:L3-20 5I1K L1-12-1 L2-8-1 L3-9-cis7-1 L4-1 KSSQSVLYSSNNKNYLA YWASTRES QQYYSTPLT H1-69:L4-1 5I18 L1-17-1 L2-8-1 L3-9-cis7-1 H3-23:L4-1 5I1D L1-17-1/L1-17-1 L2-8-1/L2-8-1 L3-9-cis7-1/L3-9-cis7-1 H3-53:L4-1 5I1I L1-17-1 L2-8-1 L3-9-cis7-1 H5-51:L4-1 5I1L L1-17-1/L1-17-1 L2-8-1/L2-8-1 L3-9-cis7-1/L3-9-cis7-1 t0002.xml t0002 TABLE table_footnote 23317 CDRs are defined using the Dunbrack convention [12]. Assignments for 2 copies of the Fab in the asymmetric unit are given for 5 structures. No assignment (NA) for CDRs with missing residues. 0.9826041 structure_element cleaner0 2023-06-28T19:04:38Z SO: CDRs 0.34516945 structure_element cleaner0 2023-06-28T15:59:05Z SO: Fab 0.9959 evidence cleaner0 2023-06-28T20:07:21Z DUMMY: structures 0.97968894 structure_element cleaner0 2023-06-28T19:04:38Z SO: CDRs RESULTS paragraph 23508 The four HCs feature CDR H1 of the same length, and their sequences are highly similar (Table 2). The CDR H1 backbone conformations for all variants for each of the HCs are shown in Fig. 1. Three of the HCs, H3-23, H3-53 and H5-51, have the same canonical structure, H1-13-1, and the backbone conformations are tightly clustered for each set of Fab structures as reflected in the rmsd values (Fig. 1B-D). Some deviation is observed for H3-53, mostly due to H3-53:L4-1, which exhibits a significant degree of disorder in CDR H1. The electron density for the backbone is weak and discontinuous, and completely missing for several side chains. 0.99611866 structure_element cleaner0 2023-06-28T16:11:33Z SO: HCs structure_element SO: cleaner0 2023-06-28T16:25:21Z CDR structure_element SO: cleaner0 2023-06-28T19:04:11Z H1 structure_element SO: cleaner0 2023-06-28T16:25:21Z CDR structure_element SO: cleaner0 2023-06-28T19:04:11Z H1 0.9957355 structure_element cleaner0 2023-06-28T16:11:33Z SO: HCs 0.9940059 structure_element cleaner0 2023-06-28T16:11:33Z SO: HCs 0.83604187 mutant cleaner0 2023-06-28T21:04:17Z MESH: H3-23 0.8691897 mutant cleaner0 2023-06-28T21:08:32Z MESH: H3-53 0.8163323 mutant cleaner0 2023-06-28T21:05:05Z MESH: H5-51 0.6929795 mutant cleaner0 2023-06-28T21:17:48Z MESH: H1-13-1 0.22198454 structure_element cleaner0 2023-06-28T15:59:05Z SO: Fab 0.9957462 evidence cleaner0 2023-06-28T20:07:16Z DUMMY: structures 0.9691633 evidence cleaner0 2023-06-28T20:07:24Z DUMMY: rmsd values 0.8695476 mutant cleaner0 2023-06-28T21:08:32Z MESH: H3-53 complex_assembly GO: cleaner0 2023-06-28T21:18:19Z H3-53:L4-1 structure_element SO: cleaner0 2023-06-28T16:25:21Z CDR structure_element SO: cleaner0 2023-06-28T19:04:11Z H1 0.9966054 evidence cleaner0 2023-06-28T20:07:28Z DUMMY: electron density RESULTS paragraph 24155 The CDR H1 structures with H1-69 shown in Fig. 1A are quite variable, both for the structures with different LCs and for the copies of the same Fab in the asymmetric unit, H1-69:L3-11 and H1-69:L3-20. In total, 6 independent Fab structures produce 5 different canonical structures, namely H1-13-1, H1-13-3, H1-13-4, H1-13-6 and H1-13-10. A major difference of H1-69 from the other germlines in the experimental data set is the presence of Gly instead of Phe or Tyr at position 27 (residue 5 of 13 in CDR H1). Glycine introduces the possibility of a higher degree of conformational flexibility that undoubtedly translates to the differences observed, and contributes to the elevated thermal parameters for the atoms in the amino acid residues in this region. structure_element SO: cleaner0 2023-06-28T16:25:21Z CDR structure_element SO: cleaner0 2023-06-28T19:04:11Z H1 0.99516606 evidence cleaner0 2023-06-28T20:07:31Z DUMMY: structures mutant MESH: cleaner0 2023-06-28T21:03:19Z H1-69 0.99432063 evidence cleaner0 2023-06-28T20:07:34Z DUMMY: structures 0.99687505 structure_element cleaner0 2023-06-28T16:11:39Z SO: LCs 0.21805374 structure_element cleaner0 2023-06-28T15:59:05Z SO: Fab complex_assembly GO: cleaner0 2023-06-28T21:18:58Z H1-69:L3-11 complex_assembly GO: cleaner0 2023-06-28T21:20:20Z H1-69:L3-20 0.36521375 structure_element cleaner0 2023-06-28T15:59:05Z SO: Fab 0.99359375 evidence cleaner0 2023-06-28T20:07:37Z DUMMY: structures 0.982238 evidence cleaner0 2023-06-28T20:07:40Z DUMMY: structures 0.97110045 mutant cleaner0 2023-06-29T09:25:57Z MESH: H1-13-1 0.97449195 mutant cleaner0 2023-06-29T09:26:01Z MESH: H1-13-3 0.9718064 mutant cleaner0 2023-06-29T09:26:04Z MESH: H1-13-4 0.96956253 mutant cleaner0 2023-06-29T09:26:07Z MESH: H1-13-6 0.9710226 mutant cleaner0 2023-06-29T09:26:10Z MESH: H1-13-10 0.78516006 mutant cleaner0 2023-06-28T21:03:20Z MESH: H1-69 0.9891431 residue_name cleaner0 2023-06-29T09:12:05Z SO: Gly 0.9896833 residue_name cleaner0 2023-06-29T09:12:08Z SO: Phe 0.9894337 residue_name cleaner0 2023-06-29T09:12:10Z SO: Tyr 0.956861 residue_number cleaner0 2023-06-29T09:19:14Z DUMMY: 27 structure_element SO: cleaner0 2023-06-28T16:25:21Z CDR structure_element SO: cleaner0 2023-06-28T19:04:11Z H1 0.9914665 residue_name cleaner0 2023-06-29T09:12:14Z SO: Glycine RESULTS title_2 24914 CDR H2 structure_element SO: cleaner0 2023-06-28T16:25:21Z CDR structure_element SO: cleaner0 2023-06-28T16:26:21Z H2 kmab-08-06-1190060-g002.jpg f0002 FIG fig_caption 24921 The superposition of CDR H2 backbones for all HC:LC pairs with heavy chains: (A) H1-69, (B) H3-23, (C) H3-53 and (D) H5-51. 0.99599445 experimental_method cleaner0 2023-06-29T09:07:39Z MESH: superposition structure_element SO: cleaner0 2023-06-28T16:25:21Z CDR structure_element SO: cleaner0 2023-06-28T16:26:21Z H2 0.9441673 complex_assembly cleaner0 2023-06-29T09:23:36Z GO: HC:LC structure_element SO: cleaner0 2023-06-28T15:56:24Z heavy chains 0.91638017 mutant cleaner0 2023-06-28T21:03:20Z MESH: H1-69 0.94655305 mutant cleaner0 2023-06-28T21:04:17Z MESH: H3-23 0.9128931 mutant cleaner0 2023-06-28T21:08:32Z MESH: H3-53 0.91781205 mutant cleaner0 2023-06-28T21:05:05Z MESH: H5-51 RESULTS paragraph 25045 The canonical structures of CDR H2 have fairly consistent conformations (Table 2, Fig. 2). Each of the 4 HCs adopts only one canonical structure regardless of the pairing LC. Germlines H1-69 and H5-51 have the same canonical structure assignment H2-10-1, H3-23 has H2-10-2, and H3-53 has H2-9-3. The conformations for all of these CDR H2s are tightly clustered (Fig. 2). In one case, in the second Fab of H1-69:L3-20, CDR H2 is partially disordered (Δ55-60). 0.9974942 structure_element cleaner0 2023-06-28T16:25:21Z SO: CDR 0.92632896 structure_element cleaner0 2023-06-28T16:26:21Z SO: H2 0.9952141 structure_element cleaner0 2023-06-28T16:11:33Z SO: HCs 0.8810361 structure_element cleaner0 2023-06-28T16:24:55Z SO: LC 0.69402623 mutant cleaner0 2023-06-28T21:03:20Z MESH: H1-69 mutant MESH: cleaner0 2023-06-28T21:05:05Z H5-51 mutant MESH: cleaner0 2023-06-28T21:22:12Z H2-10-1 0.70856994 mutant cleaner0 2023-06-28T21:04:17Z MESH: H3-23 0.70212114 mutant cleaner0 2023-06-28T21:22:37Z MESH: H2-10-2 0.7003109 mutant cleaner0 2023-06-28T21:08:32Z MESH: H3-53 0.79651135 mutant cleaner0 2023-06-28T21:22:52Z MESH: H2-9-3 structure_element SO: cleaner0 2023-06-28T16:25:21Z CDR structure_element SO: cleaner0 2023-06-28T21:23:32Z H2s 0.27054203 structure_element cleaner0 2023-06-28T15:59:05Z SO: Fab complex_assembly GO: cleaner0 2023-06-28T21:20:21Z H1-69:L3-20 0.9976173 structure_element cleaner0 2023-06-28T16:25:21Z SO: CDR 0.96096814 structure_element cleaner0 2023-06-28T16:26:21Z SO: H2 0.70799065 protein_state cleaner0 2023-06-29T09:29:04Z DUMMY: partially disordered mutant MESH: cleaner0 2023-06-28T21:24:07Z Δ55-60 RESULTS paragraph 25510 Although three of the germlines have CDR H2 of the same length, 10 residues, they adopt 2 distinctively different conformations depending mostly on the residue at position 71 from the so-called CDR H4. Arg71 in H3-23 fills the space between CDRs H2 and H4, and defines the conformation of the tip of CDR H2 so that residue 54 points away from the antigen binding site. Germlines H1-69 and H5-51 are unique in the human repertoire in having an Ala at position 71 that leaves enough space for H-Pro52a to pack deeper against CDR H4 so that the following residues 53 and 54 point toward the putative antigen. 0.99742055 structure_element cleaner0 2023-06-28T16:25:21Z SO: CDR 0.81681776 structure_element cleaner0 2023-06-28T16:26:21Z SO: H2 0.62872905 residue_range cleaner0 2023-06-29T09:14:33Z DUMMY: 10 residues 0.9469733 residue_number cleaner0 2023-06-29T09:19:32Z DUMMY: 71 0.9968274 structure_element cleaner0 2023-06-28T16:25:21Z SO: CDR 0.9557131 structure_element cleaner0 2023-06-29T08:58:17Z SO: H4 0.99837995 residue_name_number cleaner0 2023-06-29T09:21:11Z DUMMY: Arg71 0.85665005 mutant cleaner0 2023-06-28T21:04:17Z MESH: H3-23 0.9966505 structure_element cleaner0 2023-06-28T19:04:38Z SO: CDRs 0.99316376 structure_element cleaner0 2023-06-28T16:26:21Z SO: H2 0.9950023 structure_element cleaner0 2023-06-29T08:58:20Z SO: H4 0.9970299 structure_element cleaner0 2023-06-28T16:25:21Z SO: CDR 0.92691565 structure_element cleaner0 2023-06-28T16:26:21Z SO: H2 0.94479257 residue_number cleaner0 2023-06-29T09:19:37Z DUMMY: 54 0.9975385 site cleaner0 2023-06-29T09:10:35Z SO: antigen binding site mutant MESH: cleaner0 2023-06-28T21:03:20Z H1-69 mutant MESH: cleaner0 2023-06-28T21:05:05Z H5-51 0.9952029 species cleaner0 2023-06-28T16:03:59Z MESH: human 0.98539925 residue_name cleaner0 2023-06-29T09:12:19Z SO: Ala 0.9392848 residue_number cleaner0 2023-06-29T09:19:40Z DUMMY: 71 structure_element SO: cleaner0 2023-06-28T21:25:30Z H residue_name_number DUMMY: cleaner0 2023-06-28T21:25:20Z Pro52a 0.9970763 structure_element cleaner0 2023-06-28T16:25:21Z SO: CDR 0.9823167 structure_element cleaner0 2023-06-29T08:58:24Z SO: H4 0.91533685 residue_number cleaner0 2023-06-29T09:19:43Z DUMMY: 53 0.9325063 residue_number cleaner0 2023-06-29T09:19:46Z DUMMY: 54 RESULTS paragraph 26116 Conformations of CDR H2 in H1-69 and H5-51, both of which have canonical structure H2-10-1, show little deviation within each set of 4 structures. However, there is a significant shift of the CDR as a rigid body when the 2 sets are superimposed. Most likely this is the result of interaction of CDR H2 with CDR H1, namely with the residue at position 33 (residue 11 of 13 in CDR H1). Germline H1-69 has Ala at position 33 whereas in H5-51 position 33 is occupied by a bulky Trp, which stacks against H-Tyr52 and drives CDR H2 away from the center. 0.995761 structure_element cleaner0 2023-06-28T16:25:21Z SO: CDR 0.66203463 structure_element cleaner0 2023-06-28T16:26:21Z SO: H2 0.6642932 mutant cleaner0 2023-06-28T21:03:20Z MESH: H1-69 mutant MESH: cleaner0 2023-06-28T21:05:05Z H5-51 mutant MESH: cleaner0 2023-06-28T21:26:12Z H2-10-1 0.99680835 evidence cleaner0 2023-06-28T20:08:11Z DUMMY: structures 0.9964696 structure_element cleaner0 2023-06-28T16:25:22Z SO: CDR 0.9532751 experimental_method cleaner0 2023-06-28T20:08:15Z MESH: superimposed 0.9950335 structure_element cleaner0 2023-06-28T16:25:22Z SO: CDR 0.615978 structure_element cleaner0 2023-06-28T16:26:21Z SO: H2 0.99527454 structure_element cleaner0 2023-06-28T16:25:22Z SO: CDR 0.874357 structure_element cleaner0 2023-06-28T19:04:11Z SO: H1 0.9602763 residue_number cleaner0 2023-06-29T09:19:49Z DUMMY: 33 structure_element SO: cleaner0 2023-06-28T16:25:22Z CDR structure_element SO: cleaner0 2023-06-28T19:04:11Z H1 mutant MESH: cleaner0 2023-06-28T21:03:20Z H1-69 0.9874812 residue_name cleaner0 2023-06-29T09:12:25Z SO: Ala 0.9624215 residue_number cleaner0 2023-06-29T09:19:54Z DUMMY: 33 mutant MESH: cleaner0 2023-06-28T21:05:05Z H5-51 0.9566874 residue_number cleaner0 2023-06-29T09:19:56Z DUMMY: 33 0.98665047 residue_name cleaner0 2023-06-29T09:12:28Z SO: Trp structure_element SO: cleaner0 2023-06-28T21:26:43Z H 0.98908526 residue_name_number cleaner0 2023-06-29T09:21:15Z DUMMY: Tyr52 0.99542576 structure_element cleaner0 2023-06-28T16:25:22Z SO: CDR 0.57297033 structure_element cleaner0 2023-06-28T16:26:21Z SO: H2 RESULTS title_2 26664 CDR L1 structure_element SO: cleaner0 2023-06-28T16:25:22Z CDR structure_element SO: cleaner0 2023-06-28T16:26:30Z L1 kmab-08-06-1190060-g003.jpg f0003 FIG fig_caption 26671 The superposition of CDR L1 backbones for all HC:LC pairs with light chains: (A) L1-39, (B) L3-11, (C) L3-20 and (D) L4-1. 0.99590635 experimental_method cleaner0 2023-06-29T09:07:44Z MESH: superposition structure_element SO: cleaner0 2023-06-28T16:25:22Z CDR structure_element SO: cleaner0 2023-06-28T16:26:30Z L1 0.951538 complex_assembly cleaner0 2023-06-29T09:23:41Z GO: HC:LC structure_element SO: cleaner0 2023-06-28T16:14:08Z light chains 0.7258582 mutant cleaner0 2023-06-28T21:05:50Z MESH: L1-39 0.78686476 mutant cleaner0 2023-06-28T21:06:35Z MESH: L3-11 0.8088053 mutant cleaner0 2023-06-28T21:07:16Z MESH: L3-20 0.78025514 mutant cleaner0 2023-06-28T21:08:00Z MESH: L4-1 RESULTS paragraph 26794 The four LC CDRs L1 feature 3 different lengths (11, 12 and 17 residues) having a total of 4 different canonical structure assignments. Of these LCs, L1-39 and L3-11 have the same canonical structure, L1-11-1, and superimpose very well (Fig. 3A, B). For the remaining 2, L3-20 has 2 different assignments, L1-12-1 and L1-12-2, while L4-1 has a single assignment, L1-17-1. 0.8353525 structure_element cleaner0 2023-06-28T16:24:55Z SO: LC 0.99589455 structure_element cleaner0 2023-06-28T19:04:38Z SO: CDRs 0.9921481 structure_element cleaner0 2023-06-28T16:26:30Z SO: L1 0.7752541 residue_range cleaner0 2023-06-29T09:14:46Z DUMMY: 11 0.60394007 residue_range cleaner0 2023-06-29T09:14:49Z DUMMY: 12 0.53114396 residue_range cleaner0 2023-06-29T09:14:52Z DUMMY: 17 0.84663665 structure_element cleaner0 2023-06-28T16:11:39Z SO: LCs 0.86617535 mutant cleaner0 2023-06-28T21:05:50Z MESH: L1-39 mutant MESH: cleaner0 2023-06-28T21:06:35Z L3-11 0.73787403 mutant cleaner0 2023-06-28T21:28:31Z MESH: L1-11-1 0.992374 experimental_method cleaner0 2023-06-29T09:07:49Z MESH: superimpose mutant MESH: cleaner0 2023-06-28T21:07:16Z L3-20 0.91584176 mutant cleaner0 2023-06-28T21:28:41Z MESH: L1-12-1 0.8342571 mutant cleaner0 2023-06-28T21:28:51Z MESH: L1-12-2 mutant MESH: cleaner0 2023-06-28T21:08:00Z L4-1 0.9382731 mutant cleaner0 2023-06-28T21:29:01Z MESH: L1-17-1 RESULTS paragraph 27169 L4-1 has the longest CDR L1, composed of 17 amino acid residues (Fig. 3D). Despite this, the conformations are tightly clustered (rmsd is 0.20 Å). The backbone conformations of the stem regions superimpose well. Some changes in conformation occur between residues 30a and 30f (residues 8 and 13 of 17 in CDR L1). This is the tip of the loop region, which appears to have similar conformations that fan out the structures because of the slight differences in torsion angles in the backbone near Tyr30a and Lys30f. 0.97578 mutant cleaner0 2023-06-28T21:08:00Z MESH: L4-1 structure_element SO: cleaner0 2023-06-28T16:25:22Z CDR structure_element SO: cleaner0 2023-06-28T16:26:31Z L1 residue_range DUMMY: cleaner0 2023-06-29T09:15:15Z 17 amino acid residues 0.99481165 evidence cleaner0 2023-06-28T20:08:29Z DUMMY: rmsd 0.9976742 structure_element cleaner0 2023-06-28T20:08:32Z SO: stem regions residue_number DUMMY: cleaner0 2023-06-29T09:17:33Z 30a residue_number DUMMY: cleaner0 2023-06-29T09:17:47Z 30f residue_number DUMMY: cleaner0 2023-06-29T09:17:59Z 8 residue_number DUMMY: cleaner0 2023-06-29T09:18:10Z 13 residue_number DUMMY: cleaner0 2023-06-29T09:18:21Z 17 structure_element SO: cleaner0 2023-06-28T16:25:22Z CDR structure_element SO: cleaner0 2023-06-28T16:26:31Z L1 0.9900733 structure_element cleaner0 2023-06-28T20:08:36Z SO: loop region 0.99666256 evidence cleaner0 2023-06-28T20:08:39Z DUMMY: structures 0.99906737 residue_name_number cleaner0 2023-06-29T09:21:20Z DUMMY: Tyr30a 0.9990594 residue_name_number cleaner0 2023-06-29T09:21:23Z DUMMY: Lys30f RESULTS paragraph 27685 L3-20 is the most variable in CDR L1 among the 4 germlines as indicated by an rmsd of 0.54 Å (Fig. 3C). Two structures, H3-53:L3-20 and H5-51:L3-20 are assigned to canonical structure L1-12-1 with virtually identical backbone conformations. The third structure, H3-23:L3-20, has CDR L1 as L1-12-2, which deviates from L1-12-1 at residues 29-32, i.e., at the site of insertion with respect to the 11-residue CDR. The fourth member of the set, H1-69:L3-20, was crystallized with 2 Fabs in the asymmetric unit. The conformation of CDR L1 in these 2 Fabs is slightly different, and both conformations fall somewhere between L1-12-1 and L1-12-2. This reflects the lack of accuracy in the structure due to low resolution of the X-ray data (3.3 Å). 0.44628587 mutant cleaner0 2023-06-28T21:07:16Z MESH: L3-20 structure_element SO: cleaner0 2023-06-28T16:25:22Z CDR structure_element SO: cleaner0 2023-06-28T16:26:31Z L1 0.99455017 evidence cleaner0 2023-06-28T20:09:20Z DUMMY: rmsd 0.99346644 evidence cleaner0 2023-06-28T20:09:24Z DUMMY: structures complex_assembly GO: cleaner0 2023-06-28T21:13:47Z H3-53:L3-20 complex_assembly GO: cleaner0 2023-06-28T21:14:53Z H5-51:L3-20 mutant MESH: cleaner0 2023-06-28T21:30:26Z L1-12-1 0.7816724 complex_assembly cleaner0 2023-06-28T21:30:52Z GO: H3-23:L3-20 structure_element SO: cleaner0 2023-06-28T16:25:22Z CDR structure_element SO: cleaner0 2023-06-28T16:26:31Z L1 0.76978254 mutant cleaner0 2023-06-28T21:30:02Z MESH: L1-12-2 0.73867476 mutant cleaner0 2023-06-28T21:31:11Z MESH: L1-12-1 0.9205847 residue_range cleaner0 2023-06-29T09:18:29Z DUMMY: 29-32 residue_range DUMMY: cleaner0 2023-06-29T09:20:29Z 11-residue 0.997166 structure_element cleaner0 2023-06-28T16:25:22Z SO: CDR 0.8665576 complex_assembly cleaner0 2023-06-28T21:20:21Z GO: H1-69:L3-20 0.98529875 experimental_method cleaner0 2023-06-28T20:09:16Z MESH: crystallized 0.48778555 structure_element cleaner0 2023-06-28T15:58:47Z SO: Fabs structure_element SO: cleaner0 2023-06-28T16:25:22Z CDR structure_element SO: cleaner0 2023-06-28T16:26:31Z L1 0.28599226 structure_element cleaner0 2023-06-28T15:58:47Z SO: Fabs mutant MESH: cleaner0 2023-06-28T21:31:55Z L1-12-1 0.7995807 mutant cleaner0 2023-06-28T21:32:11Z MESH: L1-12-2 0.9954146 evidence cleaner0 2023-06-28T20:09:28Z DUMMY: structure 0.9856711 evidence cleaner0 2023-06-28T20:09:30Z DUMMY: X-ray data RESULTS title_2 28432 CDR L2 structure_element SO: cleaner0 2023-06-28T16:25:22Z CDR structure_element SO: cleaner0 2023-06-28T20:09:54Z L2 kmab-08-06-1190060-g004.jpg f0004 FIG fig_caption 28439 The superposition of CDR L2 backbones for all HC:LC pairs with light chains: (A) L1-39, (B) L3-11, (C) L3-20 and (D) L4-1. 0.99593866 experimental_method cleaner0 2023-06-29T09:07:59Z MESH: superposition structure_element SO: cleaner0 2023-06-28T16:25:22Z CDR structure_element SO: cleaner0 2023-06-28T20:09:52Z L2 0.95072794 complex_assembly cleaner0 2023-06-29T09:23:46Z GO: HC:LC structure_element SO: cleaner0 2023-06-28T16:14:08Z light chains 0.73722893 mutant cleaner0 2023-06-28T21:05:50Z MESH: L1-39 0.7577236 mutant cleaner0 2023-06-28T21:06:35Z MESH: L3-11 0.81435376 mutant cleaner0 2023-06-28T21:07:16Z MESH: L3-20 0.76888275 mutant cleaner0 2023-06-28T21:08:00Z MESH: L4-1 RESULTS paragraph 28562 All four LCs have CDR L2 of the same length and canonical structure, L2-8-1 (Table 2). The CDR L2 conformations for each of the LCs paired with the 4 HCs are clustered more tightly than any of the other CDRs (rmsd values are in the range 0.09-0.16 Å), and all 4 sets have virtually the same conformation despite the sequence diversity of the loop. No significant conformation outliers are observed (Fig. 4). 0.47755066 structure_element cleaner0 2023-06-28T16:11:39Z SO: LCs structure_element SO: cleaner0 2023-06-28T16:25:22Z CDR structure_element SO: cleaner0 2023-06-28T20:09:54Z L2 0.96698934 mutant cleaner0 2023-06-28T21:32:49Z MESH: L2-8-1 structure_element SO: cleaner0 2023-06-28T16:25:22Z CDR structure_element SO: cleaner0 2023-06-28T20:09:54Z L2 0.6896999 structure_element cleaner0 2023-06-28T16:11:39Z SO: LCs 0.94972163 structure_element cleaner0 2023-06-28T16:11:33Z SO: HCs 0.9946795 structure_element cleaner0 2023-06-28T19:04:38Z SO: CDRs 0.99516016 evidence cleaner0 2023-06-28T20:10:11Z DUMMY: rmsd 0.9969625 structure_element cleaner0 2023-06-29T08:58:52Z SO: loop RESULTS title_2 28976 CDR L3 structure_element SO: cleaner0 2023-06-28T16:25:22Z CDR structure_element SO: cleaner0 2023-06-28T20:10:26Z L3 kmab-08-06-1190060-g005.jpg f0005 FIG fig_caption 28983 The superposition of CDR L3 backbones for all HC:LC pairs with light chains: (A) L1-39, (B) L3-11, (C) L3-20 and (D) L4-1. 0.99597675 experimental_method cleaner0 2023-06-29T09:08:03Z MESH: superposition structure_element SO: cleaner0 2023-06-28T16:25:22Z CDR structure_element SO: cleaner0 2023-06-28T20:10:43Z L3 0.9498575 complex_assembly cleaner0 2023-06-29T09:23:51Z GO: HC:LC structure_element SO: cleaner0 2023-06-28T16:14:08Z light chains 0.770716 mutant cleaner0 2023-06-28T21:05:50Z MESH: L1-39 mutant MESH: cleaner0 2023-06-28T21:06:35Z L3-11 0.7661131 mutant cleaner0 2023-06-28T21:07:16Z MESH: L3-20 mutant MESH: cleaner0 2023-06-28T21:08:01Z L4-1 RESULTS paragraph 29106 As with CDR L2, all 4 LCs have CDR L3 of the same length and canonical structure, L3-9-cis7-1 (Table 2). The conformations of CDR L3 for L1-39, L3-11, and particularly for L320, are not as tightly clustered as those of L4-1 (Fig. 5). The slight conformational variability occurs in the region of amino acid residues 90-92, which is in contact with CDR H3. structure_element SO: cleaner0 2023-06-28T16:25:22Z CDR structure_element SO: cleaner0 2023-06-28T20:09:54Z L2 0.7866458 structure_element cleaner0 2023-06-28T16:11:39Z SO: LCs structure_element SO: cleaner0 2023-06-28T16:25:22Z CDR structure_element SO: cleaner0 2023-06-28T20:11:10Z L3 0.9468112 evidence cleaner0 2023-06-28T20:10:48Z DUMMY: structure 0.9630782 mutant cleaner0 2023-06-29T09:26:16Z MESH: L3-9-cis7-1 structure_element SO: cleaner0 2023-06-28T16:25:22Z CDR structure_element SO: cleaner0 2023-06-28T20:11:25Z L3 mutant MESH: cleaner0 2023-06-28T21:05:50Z L1-39 mutant MESH: cleaner0 2023-06-28T21:06:35Z L3-11 0.7602481 mutant cleaner0 2023-06-28T21:08:01Z MESH: L4-1 0.9677697 residue_range cleaner0 2023-06-29T09:18:44Z DUMMY: 90-92 0.9951101 structure_element cleaner0 2023-06-28T16:25:22Z SO: CDR 0.5268623 structure_element cleaner0 2023-06-28T19:05:15Z SO: H3 RESULTS title_2 29466 CDR H3 conformational diversity structure_element SO: cleaner0 2023-06-28T16:25:22Z CDR structure_element SO: cleaner0 2023-06-28T19:05:15Z H3 RESULTS paragraph 29498 As mentioned earlier, all 16 Fabs have the same CDR H3, for which the amino acid sequence is derived from the anti-CCL2 antibody CNTO 888. The loop and the 2 β-strands of the CDR H3 in this ‘parent’ structure are stabilized by H-bonds between the carbonyl oxygen and peptide nitrogen atoms in the 2 strands. An interesting feature of these CDR H3 structures is the presence of a water molecule that interacts with the peptide nitrogens and carbonyl oxygens near the bridging loop connecting the 2 β-strands. This water is present in both the bound (4DN4) and unbound (4DN3) forms of CNTO 888. The stem region of CDR H3 in the parental Fab is in a ‘kinked’ conformation, in which the indole nitrogen of Trp103 forms a hydrogen bond with the carbonyl oxygen of Leu100b. The carboxyl group of Asp101 forms a salt bridge with Arg94. These interactions are illustrated in Fig. S2. 0.28241646 structure_element cleaner0 2023-06-28T15:58:47Z SO: Fabs structure_element SO: cleaner0 2023-06-28T16:25:22Z CDR structure_element SO: cleaner0 2023-06-28T19:05:15Z H3 protein_type MESH: cleaner0 2023-06-28T15:45:48Z antibody chemical CHEBI: cleaner0 2023-06-29T09:24:49Z CNTO 888 0.9973061 structure_element cleaner0 2023-06-29T08:58:58Z SO: loop 0.8799594 structure_element cleaner0 2023-06-29T08:59:01Z SO: β-strands structure_element SO: cleaner0 2023-06-28T16:25:22Z CDR structure_element SO: cleaner0 2023-06-28T19:05:15Z H3 0.99561113 evidence cleaner0 2023-06-28T20:11:37Z DUMMY: structure bond_interaction MESH: melaniev@ebi.ac.uk 2023-07-28T14:19:44Z H-bonds structure_element SO: cleaner0 2023-06-28T16:25:22Z CDR structure_element SO: cleaner0 2023-06-28T19:05:15Z H3 0.9962054 evidence cleaner0 2023-06-28T20:11:40Z DUMMY: structures 0.99835867 chemical cleaner0 2023-06-29T09:24:59Z CHEBI: water 0.99427104 structure_element cleaner0 2023-06-29T08:59:04Z SO: loop 0.9647501 structure_element cleaner0 2023-06-29T08:59:06Z SO: β-strands 0.99842465 chemical cleaner0 2023-06-29T09:25:01Z CHEBI: water 0.99691653 protein_state cleaner0 2023-06-29T09:29:33Z DUMMY: bound 0.9966217 protein_state cleaner0 2023-06-29T09:29:36Z DUMMY: unbound 0.7319946 chemical cleaner0 2023-06-29T09:24:50Z CHEBI: CNTO 888 0.9975282 structure_element cleaner0 2023-06-29T08:59:08Z SO: stem region structure_element SO: cleaner0 2023-06-28T16:25:22Z CDR structure_element SO: cleaner0 2023-06-28T19:05:15Z H3 0.14281757 structure_element cleaner0 2023-06-28T15:59:05Z SO: Fab 0.8321708 protein_state cleaner0 2023-06-29T07:42:05Z DUMMY: kinked 0.99914753 residue_name_number cleaner0 2023-06-29T09:22:08Z DUMMY: Trp103 bond_interaction MESH: melaniev@ebi.ac.uk 2023-07-28T14:19:44Z hydrogen bond 0.9991297 residue_name_number cleaner0 2023-06-29T09:22:11Z DUMMY: Leu100b 0.9991573 residue_name_number cleaner0 2023-06-29T09:22:14Z DUMMY: Asp101 bond_interaction MESH: melaniev@ebi.ac.uk 2023-07-28T14:19:44Z salt bridge 0.999151 residue_name_number cleaner0 2023-06-29T09:22:16Z DUMMY: Arg94 kmab-08-06-1190060-g006.jpg f0006 FIG fig_caption 30385 Ribbon representations of (A) the superposition of all CDR H3s of the structures with complete backbone traces. (B) The CDR H3s rotated 90° about the y axis of the page. The structure of each CDR H3 is represented with a different color. 0.99487334 experimental_method cleaner0 2023-06-28T20:12:34Z MESH: superposition structure_element SO: cleaner0 2023-06-28T16:25:22Z CDR structure_element SO: cleaner0 2023-06-28T20:13:06Z H3s 0.99505204 evidence cleaner0 2023-06-28T20:12:38Z DUMMY: structures structure_element SO: cleaner0 2023-06-28T16:25:22Z CDR structure_element SO: cleaner0 2023-06-28T20:12:58Z H3s 0.9879155 evidence cleaner0 2023-06-28T20:12:40Z DUMMY: structure structure_element SO: cleaner0 2023-06-28T16:25:22Z CDR structure_element SO: cleaner0 2023-06-28T19:05:15Z H3 RESULTS paragraph 30624 Despite having the same amino acid sequence in all variants, CDR H3 has the highest degree of structural diversity and disorder of all of the CDRs in the experimental set. Three of the 21 Fab structures (including multiple copies in the asymmetric unit), H5-51:L3-11, H551:L3-20 and H3-23:L4-1 (one of the 2 Fabs), have missing (disordered) residues at the apex of the CDR loop. Another four of the Fabs, H3-23:L1-39, H3-53:L1-39, H3-53:L3-11 and H3-53:L4-1 have missing side-chain atoms. The variations in CDR H3 conformation are illustrated in Fig. 6 for the 18 Fab structures that have ordered backbone atoms. 0.9960975 structure_element cleaner0 2023-06-28T16:25:22Z SO: CDR 0.5586551 structure_element cleaner0 2023-06-28T19:05:16Z SO: H3 0.99367166 structure_element cleaner0 2023-06-28T19:04:38Z SO: CDRs 0.18316415 structure_element cleaner0 2023-06-28T15:59:05Z SO: Fab 0.99480397 evidence cleaner0 2023-06-28T20:13:14Z DUMMY: structures complex_assembly GO: cleaner0 2023-06-28T21:14:32Z H5-51:L3-11 complex_assembly GO: cleaner0 2023-06-28T21:34:46Z H551:L3-20 complex_assembly GO: cleaner0 2023-06-28T21:12:34Z H3-23:L4-1 0.31031048 structure_element cleaner0 2023-06-28T15:58:47Z SO: Fabs 0.50068367 protein_state cleaner0 2023-06-29T09:29:55Z DUMMY: missing 0.76184237 protein_state cleaner0 2023-06-29T09:29:58Z DUMMY: disordered 0.9971243 structure_element cleaner0 2023-06-28T20:13:25Z SO: CDR loop 0.26492673 structure_element cleaner0 2023-06-28T15:58:47Z SO: Fabs complex_assembly GO: cleaner0 2023-06-28T21:15:28Z H3-23:L1-39 complex_assembly GO: cleaner0 2023-06-28T21:13:04Z H3-53:L1-39 complex_assembly GO: cleaner0 2023-06-28T21:13:26Z H3-53:L3-11 complex_assembly GO: cleaner0 2023-06-28T21:18:20Z H3-53:L4-1 structure_element SO: cleaner0 2023-06-28T16:25:22Z CDR structure_element SO: cleaner0 2023-06-28T19:05:16Z H3 0.18022169 structure_element cleaner0 2023-06-28T15:59:05Z SO: Fab 0.9938689 evidence cleaner0 2023-06-28T20:13:17Z DUMMY: structures kmab-08-06-1190060-g007.jpg f0007 FIG fig_caption 31240 A comparison of representatives of the “kinked” and “extended” structures. (A) The “kinked” CDR H3 of H1-69:L3-11 with purple carbon atoms and yellow dashed lines connecting the H-bond pairs for Leu100b O and Trp103 NE1, Arg94 NE and Asp101 OD1, and Arg94 NH2 and Asp101 OD2. (B) The “extended” CDR H3 of H1-69:L3-20 with green carbon atoms and yellow dashed lines connecting the H-bond pairs for Asp101 OD1 and OD2 and Trp103 NE1. 0.9908119 protein_state cleaner0 2023-06-29T07:42:05Z DUMMY: kinked 0.9959126 protein_state cleaner0 2023-06-29T07:41:57Z DUMMY: extended 0.99503183 evidence cleaner0 2023-06-28T20:13:38Z DUMMY: structures 0.9928145 protein_state cleaner0 2023-06-29T07:42:05Z DUMMY: kinked structure_element SO: cleaner0 2023-06-28T16:25:22Z CDR structure_element SO: cleaner0 2023-06-28T19:05:16Z H3 0.81869656 complex_assembly cleaner0 2023-06-28T21:36:23Z GO: H1-69:L3-11 0.999046 residue_name_number cleaner0 2023-06-29T09:22:22Z DUMMY: Leu100b 0.99903286 residue_name_number cleaner0 2023-06-29T09:22:25Z DUMMY: Trp103 0.99903893 residue_name_number cleaner0 2023-06-29T09:22:27Z DUMMY: Arg94 0.9990128 residue_name_number cleaner0 2023-06-29T09:22:32Z DUMMY: Asp101 0.99903846 residue_name_number cleaner0 2023-06-29T09:22:35Z DUMMY: Arg94 0.9990054 residue_name_number cleaner0 2023-06-29T09:22:37Z DUMMY: Asp101 0.99604356 protein_state cleaner0 2023-06-29T07:41:57Z DUMMY: extended structure_element SO: cleaner0 2023-06-28T16:25:22Z CDR structure_element SO: cleaner0 2023-06-28T19:05:16Z H3 complex_assembly GO: cleaner0 2023-06-28T21:20:21Z H1-69:L3-20 0.9990422 residue_name_number cleaner0 2023-06-29T09:22:40Z DUMMY: Asp101 0.9990233 residue_name_number cleaner0 2023-06-29T09:22:43Z DUMMY: Trp103 RESULTS paragraph 31688 In 10 of the 18 Fab structures, H1-69:L1-39, H1-69:L3-11 (2 Fabs), H1-69:L4-1, H3-23:L3-11 (2 Fabs), H3-23:L3-20, H3-53:L3-11, H3-53:L3-20 and H5-51:L1-39, the CDRs have similar conformations to that found in 4DN3. The bases of these structures have the ‘kinked’ conformation with the H-bond between Trp103 and Leu100b. A representative CDR H3 structure for H1-69:L1-39 illustrating this is shown in Fig. 7A. The largest backbone conformational deviation for the set is at Tyr99, where the C=O is rotated by 90° relative to that observed in 4DN3. Also, it is worth noting that only one of these structures, H1-69:L4-1, has the conserved water molecule in CDR H3 observed in the 4DN3 and 4DN4 structures. In fact, it is the only Fab in the set that has a water molecule present at this site. The CDR H3 for this structure is shown in Fig. S3. 0.23736683 structure_element cleaner0 2023-06-28T15:59:05Z SO: Fab 0.99279636 evidence cleaner0 2023-06-28T20:14:41Z DUMMY: structures complex_assembly GO: cleaner0 2023-06-28T21:37:02Z H1-69:L1-39 complex_assembly GO: cleaner0 2023-06-28T21:37:23Z H1-69:L3-11 structure_element SO: cleaner0 2023-06-28T15:58:47Z Fabs complex_assembly GO: cleaner0 2023-06-28T21:37:43Z H1-69:L4-1 complex_assembly GO: cleaner0 2023-06-28T21:12:10Z H3-23:L3-11 structure_element SO: cleaner0 2023-06-28T15:58:47Z Fabs complex_assembly GO: cleaner0 2023-06-28T21:38:15Z H3-23:L3-20 complex_assembly GO: cleaner0 2023-06-28T21:13:26Z H3-53:L3-11 complex_assembly GO: cleaner0 2023-06-28T21:13:47Z H3-53:L3-20 complex_assembly GO: cleaner0 2023-06-28T21:14:11Z H5-51:L1-39 0.99718827 structure_element cleaner0 2023-06-28T19:04:38Z SO: CDRs 0.9816032 evidence cleaner0 2023-06-28T20:14:43Z DUMMY: structures 0.755971 protein_state cleaner0 2023-06-29T07:42:05Z DUMMY: kinked 0.9990682 residue_name_number cleaner0 2023-06-29T09:22:48Z DUMMY: Trp103 0.9990772 residue_name_number cleaner0 2023-06-29T09:22:50Z DUMMY: Leu100b structure_element SO: cleaner0 2023-06-28T16:25:22Z CDR structure_element SO: cleaner0 2023-06-28T19:05:16Z H3 0.9840614 evidence cleaner0 2023-06-28T20:14:46Z DUMMY: structure complex_assembly GO: cleaner0 2023-06-28T21:39:19Z H1-69:L1-39 0.9991266 residue_name_number cleaner0 2023-06-29T09:22:55Z DUMMY: Tyr99 0.9504556 evidence cleaner0 2023-06-28T20:14:58Z DUMMY: structures complex_assembly GO: cleaner0 2023-06-28T21:39:43Z H1-69:L4-1 0.98424697 protein_state cleaner0 2023-06-29T09:30:13Z DUMMY: conserved 0.99795204 chemical cleaner0 2023-06-29T09:25:01Z CHEBI: water structure_element SO: cleaner0 2023-06-28T16:25:22Z CDR structure_element SO: cleaner0 2023-06-28T19:05:16Z H3 0.9916455 evidence cleaner0 2023-06-28T20:15:00Z DUMMY: structures 0.17939177 structure_element cleaner0 2023-06-28T15:59:05Z SO: Fab 0.9982192 chemical cleaner0 2023-06-29T09:25:01Z CHEBI: water structure_element SO: cleaner0 2023-06-28T16:25:22Z CDR structure_element SO: cleaner0 2023-06-28T19:05:16Z H3 0.9559372 evidence cleaner0 2023-06-28T20:15:04Z DUMMY: structure RESULTS paragraph 32539 The remaining 8 Fabs can be grouped into 5 different conformational classes. Three of the Fabs, H3-23:L1-39, H3-23:L4-1 and H3-53:L1-39, have distinctive conformations. The stem regions in these 3 cases are in the ‘kinked’ conformation consistent with that observed for 4DN3. The five remaining Fabs, H5-51:L4-1 (2 copies), H1-69:L3-20 (2 copies) and H3-53:L4-1, have 3 different CDR H3 conformations (Fig. S4). The stem regions of CDR H3 for the H5-51:L4-1 Fabs are in the ‘kinked’ conformation while, surprisingly, those of the H1-69:L3-20 pair and H3-53:L4-1 are in the ‘extended’ conformation (Fig. 7B). 0.22445008 structure_element cleaner0 2023-06-28T15:58:47Z SO: Fabs 0.25196815 structure_element cleaner0 2023-06-28T15:58:47Z SO: Fabs complex_assembly GO: cleaner0 2023-06-28T21:15:28Z H3-23:L1-39 complex_assembly GO: cleaner0 2023-06-28T21:12:34Z H3-23:L4-1 complex_assembly GO: cleaner0 2023-06-28T21:13:04Z H3-53:L1-39 0.9969319 structure_element cleaner0 2023-06-28T20:15:20Z SO: stem regions 0.9289319 protein_state cleaner0 2023-06-28T20:15:22Z DUMMY: kinked 0.3686641 structure_element cleaner0 2023-06-28T15:58:47Z SO: Fabs complex_assembly GO: cleaner0 2023-06-28T21:40:48Z H5-51:L4-1 complex_assembly GO: cleaner0 2023-06-28T21:20:21Z H1-69:L3-20 complex_assembly GO: cleaner0 2023-06-28T21:18:21Z H3-53:L4-1 structure_element SO: cleaner0 2023-06-28T16:25:22Z CDR structure_element SO: cleaner0 2023-06-28T19:05:16Z H3 0.9966538 structure_element cleaner0 2023-06-29T08:59:58Z SO: stem regions structure_element SO: cleaner0 2023-06-28T16:25:23Z CDR structure_element SO: cleaner0 2023-06-28T19:05:16Z H3 complex_assembly GO: cleaner0 2023-06-28T21:41:35Z H5-51:L4-1 structure_element SO: cleaner0 2023-06-28T15:58:47Z Fabs 0.97828144 protein_state cleaner0 2023-06-28T20:15:25Z DUMMY: kinked complex_assembly GO: cleaner0 2023-06-28T21:20:21Z H1-69:L3-20 complex_assembly GO: cleaner0 2023-06-28T21:18:21Z H3-53:L4-1 0.99039197 protein_state cleaner0 2023-06-29T07:41:56Z DUMMY: extended RESULTS title_2 33161 VH:VL domain packing complex_assembly GO: melaniev@ebi.ac.uk 2023-07-06T15:18:10Z VH:VL RESULTS paragraph 33182 The VH and VL domains have a β-sandwich structure (also often referred as a Greek key motif) and each is composed of a 4-stranded and a 5-stranded antiparallel β-sheets. The two domains pack together such that the 5-stranded β-sheets, which have hydrophobic surfaces, interact with each other bringing the CDRs from both the VH and VL domains into close proximity. The domain packing of the variants was assessed by computing the domain interface interactions, the VH:VL tilt angles, the buried surface area and surface complementarity. The results of these analyses are shown in Tables 3, 4 and S2. 0.9976998 structure_element cleaner0 2023-06-29T09:00:01Z SO: VH 0.9978058 structure_element cleaner0 2023-06-28T19:10:07Z SO: VL 0.9875603 structure_element cleaner0 2023-06-29T09:00:04Z SO: β-sandwich structure 0.99606323 structure_element cleaner0 2023-06-29T09:00:07Z SO: Greek key motif structure_element SO: cleaner0 2023-06-29T09:00:27Z 4-stranded and a 5-stranded antiparallel β-sheets 0.99740285 structure_element cleaner0 2023-06-29T09:00:40Z SO: 5-stranded β-sheets 0.997398 structure_element cleaner0 2023-06-28T19:04:38Z SO: CDRs 0.99764204 structure_element cleaner0 2023-06-29T09:00:43Z SO: VH 0.99792 structure_element cleaner0 2023-06-28T19:10:07Z SO: VL site SO: cleaner0 2023-06-29T09:11:11Z domain interface complex_assembly GO: melaniev@ebi.ac.uk 2023-07-06T15:18:10Z VH:VL evidence DUMMY: cleaner0 2023-06-28T16:02:51Z tilt angles RESULTS title_3 33791 VH:VL interface amino acid residue interactions 0.98834515 site cleaner0 2023-06-28T20:18:37Z SO: VH:VL interface kmab-08-06-1190060-g008.jpg f0008 FIG fig_caption 33839 The conserved VH:VL interactions as viewed along the VH/VL axis. The VH residues are in blue, the VL residues are in orange. 0.99727947 protein_state cleaner0 2023-06-29T09:30:27Z DUMMY: conserved complex_assembly GO: melaniev@ebi.ac.uk 2023-07-06T15:18:10Z VH:VL 0.79262924 structure_element cleaner0 2023-06-29T09:00:50Z SO: VH structure_element SO: cleaner0 2023-06-28T19:10:07Z VL 0.99668914 structure_element cleaner0 2023-06-29T09:00:53Z SO: VH 0.997074 structure_element cleaner0 2023-06-28T19:10:07Z SO: VL RESULTS paragraph 33964 The VH:VL interface is pseudosymmetric, and involves 2 stretches of the polypeptide chain from each domain, namely CDR3 and the framework region between CDRs 1 and 2. These stretches form antiparallel β-hairpins within the internal 5-stranded β-sheet. There are a few principal inter-domain interactions that are conserved not only in the experimental set of 16 Fabs, but in all human antibodies. They include: 1) a bidentate hydrogen bond between L-Gln38 and H-Gln39; 2) H-Leu45 in a hydrophobic pocket between L-Phe98, L-Tyr87 and L-Pro44; 3) L-Pro44 stacked against H-Trp103; and 4) L-Ala43 opposite the face of H-Tyr91 (Fig. 8). With the exception of L-Ala43, all other residues are conserved in human germlines. Position 43 may be alternatively occupied by Ser, Val or Pro (as in L4-1), but the hydrophobic interaction with H-Tyr91 is preserved. These core interactions provide enough stability to the VH:VL dimer so that additional VH-VL contacts can tolerate amino acid sequence variations in CDRs H3 and L3 that form part of the VH:VL interface. 0.99136263 site cleaner0 2023-06-28T20:18:37Z SO: VH:VL interface 0.53883225 protein_state cleaner0 2023-06-29T09:30:34Z DUMMY: pseudosymmetric 0.9983753 structure_element cleaner0 2023-06-29T09:01:18Z SO: CDR3 0.9973372 structure_element cleaner0 2023-06-29T09:00:57Z SO: framework region 0.99737406 structure_element cleaner0 2023-06-29T09:01:20Z SO: CDRs 1 and 2 0.993996 structure_element cleaner0 2023-06-29T09:01:01Z SO: antiparallel β-hairpins 0.9913381 structure_element cleaner0 2023-06-29T09:01:03Z SO: 5-stranded β-sheet 0.95069045 structure_element cleaner0 2023-06-28T15:58:47Z SO: Fabs 0.9924118 species cleaner0 2023-06-28T16:03:59Z MESH: human 0.67610204 protein_type cleaner0 2023-06-28T16:03:38Z MESH: antibodies bond_interaction MESH: melaniev@ebi.ac.uk 2023-07-28T14:19:44Z hydrogen bond structure_element SO: cleaner0 2023-06-28T20:19:40Z L residue_name_number DUMMY: cleaner0 2023-06-28T20:19:27Z Gln38 0.8804055 structure_element cleaner0 2023-06-28T20:19:52Z SO: H 0.84093565 residue_name_number cleaner0 2023-06-29T09:23:04Z DUMMY: Gln39 0.973559 structure_element cleaner0 2023-06-28T20:20:04Z SO: H 0.692089 residue_name_number cleaner0 2023-06-29T09:23:07Z DUMMY: Leu45 0.99601036 site cleaner0 2023-06-28T20:18:42Z SO: hydrophobic pocket structure_element SO: cleaner0 2023-06-28T20:20:25Z L 0.6455791 residue_name_number cleaner0 2023-06-28T20:20:11Z DUMMY: Phe98 structure_element SO: cleaner0 2023-06-28T20:20:47Z L 0.75837576 residue_name_number cleaner0 2023-06-28T20:20:31Z DUMMY: Tyr87 structure_element SO: cleaner0 2023-06-28T20:21:11Z L 0.7018562 residue_name_number cleaner0 2023-06-28T20:20:51Z DUMMY: Pro44 structure_element SO: cleaner0 2023-06-28T20:21:27Z L 0.58544266 residue_name_number cleaner0 2023-06-28T20:21:15Z DUMMY: Pro44 0.9149529 structure_element cleaner0 2023-06-28T20:21:36Z SO: H 0.9516314 residue_name_number cleaner0 2023-06-28T20:21:38Z DUMMY: Trp103 structure_element SO: cleaner0 2023-06-28T20:22:09Z L residue_name_number DUMMY: cleaner0 2023-06-28T20:21:58Z Ala43 0.9800174 structure_element cleaner0 2023-06-28T20:22:22Z SO: H 0.5058213 residue_name_number cleaner0 2023-06-29T09:23:13Z DUMMY: Tyr91 structure_element SO: cleaner0 2023-06-28T20:22:51Z L residue_name_number DUMMY: cleaner0 2023-06-28T20:22:39Z Ala43 0.993141 species cleaner0 2023-06-28T16:03:59Z MESH: human 0.9463635 residue_number cleaner0 2023-06-29T09:20:38Z DUMMY: 43 0.98263526 residue_name cleaner0 2023-06-29T09:12:33Z SO: Ser 0.98448217 residue_name cleaner0 2023-06-29T09:12:38Z SO: Val 0.9818835 residue_name cleaner0 2023-06-29T09:12:41Z SO: Pro 0.914598 mutant cleaner0 2023-06-28T21:08:01Z MESH: L4-1 bond_interaction MESH: melaniev@ebi.ac.uk 2023-07-28T14:19:44Z hydrophobic interaction 0.9252548 structure_element cleaner0 2023-06-28T20:23:55Z SO: H 0.58144456 residue_name_number cleaner0 2023-06-29T09:23:17Z DUMMY: Tyr91 0.91734785 complex_assembly cleaner0 2023-06-29T09:23:56Z GO: VH:VL 0.9946301 oligomeric_state cleaner0 2023-06-29T09:23:22Z DUMMY: dimer site SO: cleaner0 2023-06-28T20:23:28Z VH-VL contacts 0.99753404 structure_element cleaner0 2023-06-28T19:04:38Z SO: CDRs 0.99678314 structure_element cleaner0 2023-06-28T19:05:16Z SO: H3 0.9974498 structure_element cleaner0 2023-06-29T09:01:23Z SO: L3 0.99011016 site cleaner0 2023-06-28T20:18:35Z SO: VH:VL interface RESULTS paragraph 35026 In total, about 20 residues are involved in the VH:VL interactions on each side (Fig. S5). Half of them are in the framework regions and those residues (except residue 61 in HC, which is actually in CDR2 in Kabat's definition) are conserved in the set of 16 Fabs. The side chain conformations of these conserved residues are also highly similar. One notable exception is H-Trp47, which exhibits 2 conformations of the indole ring. In most of the structures, it has the χ2 angle of ∼80°, while the ring is flipped over (χ2 = −100°) in H5-51:L3:11 and H5-51:L3-20. Interestingly, these are the only 2 structures with residues missing in CDR H3 because of disorder, although both structures are determined at high resolution and the rest of the structure is well defined. Apparently, residues flanking CDR H3 in the 2 VH:VL pairings are inconsistent with any stable conformation of CDR H3, which translates into a less restricted conformational space for some of them, including H-Trp47. residue_range DUMMY: cleaner0 2023-06-29T09:32:11Z 20 residues complex_assembly GO: melaniev@ebi.ac.uk 2023-07-06T15:18:10Z VH:VL 0.9973575 structure_element cleaner0 2023-06-29T09:01:26Z SO: framework regions 0.91451746 residue_number cleaner0 2023-06-29T09:20:44Z DUMMY: 61 0.99835485 structure_element cleaner0 2023-06-29T09:02:52Z SO: HC 0.9977931 structure_element cleaner0 2023-06-29T09:02:23Z SO: CDR2 0.793795 structure_element cleaner0 2023-06-28T15:58:47Z SO: Fabs structure_element SO: cleaner0 2023-06-28T20:25:28Z H residue_name_number DUMMY: cleaner0 2023-06-28T20:25:18Z Trp47 0.9964148 evidence cleaner0 2023-06-28T20:24:25Z DUMMY: structures 0.9833544 evidence cleaner0 2023-06-28T20:24:31Z DUMMY: χ2 0.9682395 evidence cleaner0 2023-06-28T20:24:34Z DUMMY: χ2 complex_assembly GO: cleaner0 2023-06-28T21:42:48Z H5-51:L3:11 complex_assembly GO: cleaner0 2023-06-28T21:14:53Z H5-51:L3-20 0.99607605 evidence cleaner0 2023-06-28T20:26:34Z DUMMY: structures 0.98517585 protein_state cleaner0 2023-06-29T09:31:44Z DUMMY: missing structure_element SO: cleaner0 2023-06-28T16:25:23Z CDR structure_element SO: cleaner0 2023-06-28T19:05:16Z H3 0.9922267 evidence cleaner0 2023-06-28T20:24:37Z DUMMY: structures 0.9962059 evidence cleaner0 2023-06-28T20:24:39Z DUMMY: structure structure_element SO: cleaner0 2023-06-28T16:25:23Z CDR structure_element SO: cleaner0 2023-06-28T19:05:16Z H3 complex_assembly GO: melaniev@ebi.ac.uk 2023-07-06T15:18:10Z VH:VL 0.965915 protein_state cleaner0 2023-06-29T09:31:42Z DUMMY: stable structure_element SO: cleaner0 2023-06-28T16:25:23Z CDR structure_element SO: cleaner0 2023-06-28T19:05:16Z H3 structure_element SO: cleaner0 2023-06-28T20:25:05Z H residue_name_number DUMMY: cleaner0 2023-06-28T20:24:55Z Trp47 RESULTS title_2 36020 VH:VL tilt angles complex_assembly GO: melaniev@ebi.ac.uk 2023-07-06T15:18:10Z VH:VL 0.78827584 evidence cleaner0 2023-06-28T16:02:51Z DUMMY: tilt angles RESULTS paragraph 36038 The relative orientation of VH and VL has been measured in a number of different ways. Presented here are the results of 2 different approaches for determining the orientation of one domain relative to the other. 0.99675924 structure_element cleaner0 2023-06-29T09:02:25Z SO: VH 0.99686 structure_element cleaner0 2023-06-28T19:10:07Z SO: VL RESULTS paragraph 36251 The first approach uses ABangles, the results of which are shown in Table S2. The four LCs all are classified as Type A because they have a proline at position 44, and the results for each orientation parameter are within the range of values of this type reported by Dunbar and co-workers. In fact, the parameter values for the set of 16 Fabs are in the middle of the distribution observed for 351 non-redundant antibody structures determined at 3.0 Å resolution or better. The only exception is HC1, which is shifted toward smaller angles with the mean value of 70.8° as compared to the distribution centered at 72° for the entire PDB. This probably reflects the invariance of CDR H3 in the current set as opposed to the CDR H3 diversity in the PDB. 0.99128175 experimental_method cleaner0 2023-06-29T09:08:25Z MESH: ABangles 0.52872384 structure_element cleaner0 2023-06-28T16:11:39Z SO: LCs 0.9892429 residue_name cleaner0 2023-06-29T09:12:47Z SO: proline 0.96477294 residue_number cleaner0 2023-06-29T09:20:49Z DUMMY: 44 0.76806116 evidence cleaner0 2023-06-28T20:27:21Z DUMMY: orientation parameter 0.14618859 structure_element cleaner0 2023-06-28T15:58:47Z SO: Fabs protein_type MESH: cleaner0 2023-06-28T15:45:48Z antibody 0.9953317 evidence cleaner0 2023-06-28T20:27:24Z DUMMY: structures 0.99818486 structure_element cleaner0 2023-06-29T09:02:55Z SO: HC1 structure_element SO: cleaner0 2023-06-28T16:25:23Z CDR structure_element SO: cleaner0 2023-06-28T19:05:16Z H3 structure_element SO: cleaner0 2023-06-28T16:25:23Z CDR structure_element SO: cleaner0 2023-06-28T19:05:16Z H3 RESULTS paragraph 37007 The second approach used for comparing tilt angles involved computing the difference in the tilt angles between all pairs of structures. For structures with 2 copies of the Fab in the asymmetric unit, only one structure was used. The differences between independent Fabs in the same structure are 4.9° for H1-69:L3-20, 1.6° for H1-69:L3-11, 1.4° for H3-23:L4-1, 3.3° for H3-23:L3-11, and 2.5° for H5-51:L4-1. With the exception of H1-69:L3-20, the angles are within the range of 2-3° as are observed in the identical structures in the PDB. In H1-69:L3-20, one of the Fabs is substantially disordered so that part of CDR H2 (the outer β-strand, residues 55-60) is completely missing. This kind of disorder may compromise the integrity of the VH domain and its interaction with the VL. Indeed, this Fab has the largest twist angle HC2 within the experimental set that exceeds the mean value by 2.5 standard deviations (Table S2). 0.99319816 evidence cleaner0 2023-06-28T16:02:51Z DUMMY: tilt angles 0.73657733 evidence cleaner0 2023-06-28T20:27:39Z DUMMY: difference 0.98982793 evidence cleaner0 2023-06-28T16:02:51Z DUMMY: tilt angles 0.9951414 evidence cleaner0 2023-06-28T20:27:45Z DUMMY: structures 0.9731836 evidence cleaner0 2023-06-28T20:27:48Z DUMMY: structures structure_element SO: cleaner0 2023-06-28T15:59:05Z Fab 0.9942374 evidence cleaner0 2023-06-28T20:27:51Z DUMMY: structure 0.14642434 structure_element cleaner0 2023-06-28T15:58:47Z SO: Fabs 0.9922145 evidence cleaner0 2023-06-28T20:27:53Z DUMMY: structure 0.730512 complex_assembly cleaner0 2023-06-28T21:20:21Z GO: H1-69:L3-20 0.7319917 complex_assembly cleaner0 2023-06-28T21:43:25Z GO: H1-69:L3-11 complex_assembly GO: cleaner0 2023-06-28T21:12:34Z H3-23:L4-1 0.678943 complex_assembly cleaner0 2023-06-28T21:12:10Z GO: H3-23:L3-11 complex_assembly GO: cleaner0 2023-06-28T21:44:05Z H5-51:L4-1 complex_assembly GO: cleaner0 2023-06-28T21:20:21Z H1-69:L3-20 0.99507105 evidence cleaner0 2023-06-28T20:28:06Z DUMMY: structures 0.92975956 complex_assembly cleaner0 2023-06-28T21:20:21Z GO: H1-69:L3-20 0.19363964 structure_element cleaner0 2023-06-28T15:58:47Z SO: Fabs 0.76591015 protein_state cleaner0 2023-06-29T09:33:14Z DUMMY: disordered structure_element SO: cleaner0 2023-06-28T16:25:23Z CDR structure_element SO: cleaner0 2023-06-28T16:26:21Z H2 0.948555 structure_element cleaner0 2023-06-29T09:03:03Z SO: β-strand 0.9751329 residue_range cleaner0 2023-06-29T09:18:50Z DUMMY: 55-60 0.9974107 structure_element cleaner0 2023-06-29T09:02:36Z SO: VH 0.9971015 structure_element cleaner0 2023-06-28T19:10:07Z SO: VL 0.25028703 structure_element cleaner0 2023-06-28T15:59:05Z SO: Fab 0.9712751 evidence cleaner0 2023-06-28T20:28:11Z DUMMY: twist angle structure_element SO: cleaner0 2023-06-28T20:28:21Z HC2 kmab-08-06-1190060-g009.jpg f0009 FIG fig_caption 37943 An illustration of the difference in tilt angle for 2 pairs of variants by the superposition of the VH domains of (A) H1-69:L3-20 on that of H5-51:L1-39 (the VL domain is off by a rigid-body roatation of 10.5°) and (B) H1-69:L4-1 on that of H5-51:L1-39 (the VL domain is off by a rigid-body roatation of 1.6°). 0.99561775 experimental_method cleaner0 2023-06-28T20:28:35Z MESH: superposition 0.99801207 structure_element cleaner0 2023-06-29T09:03:16Z SO: VH 0.93959236 complex_assembly cleaner0 2023-06-28T21:20:21Z GO: H1-69:L3-20 0.9412726 complex_assembly cleaner0 2023-06-28T21:14:11Z GO: H5-51:L1-39 0.9981108 structure_element cleaner0 2023-06-28T19:10:07Z SO: VL complex_assembly GO: cleaner0 2023-06-28T21:45:10Z H1-69:L4-1 0.9760524 complex_assembly cleaner0 2023-06-28T21:14:11Z GO: H5-51:L1-39 0.9981937 structure_element cleaner0 2023-06-28T19:10:07Z SO: VL t0003.xml t0003 TABLE table_caption 38256 Differences in VH:VL tilt angles. complex_assembly GO: melaniev@ebi.ac.uk 2023-07-06T15:18:10Z VH:VL evidence DUMMY: cleaner0 2023-06-28T16:02:51Z tilt angles t0003.xml t0003 TABLE table <?xml version="1.0" encoding="UTF-8"?> <table frame="hsides" rules="groups"><colgroup><col width="86.4pt" align="left"/><col width="86.4pt" align="left"/><col width="86.4pt" align="left"/><col width="86.4pt" align="left"/><col width="86.4pt" align="left"/><col width="86.4pt" align="left"/><col width="86.4pt" align="left"/><col width="86.4pt" align="left"/><col width="86.4pt" align="left"/><col width="86.4pt" align="left"/><col width="86.4pt" align="left"/><col width="86.4pt" align="left"/><col width="86.4pt" align="left"/><col width="86.4pt" align="left"/><col width="86.4pt" align="left"/><col width="86.4pt" align="left"/><col width="86.4pt" align="left"/></colgroup><tbody><tr><td align="left"> <hr/></td><td align="center">H1-69:L1-39<hr/></td><td align="center">H1-69:L3-11<hr/></td><td align="center">H1-69:L3-20<hr/></td><td align="center">H1-69:L4-1<hr/></td><td align="center">H3-23:L1-39<hr/></td><td align="center">H3-23:L3-11<hr/></td><td align="center">H3-23:L3-20<hr/></td><td align="center">H3-23:L4-1<hr/></td><td align="center">H3-53:L1-39<hr/></td><td align="center">H3-53:L3-11<hr/></td><td align="center">H3-53:L3-20<hr/></td><td align="center">H3-53:L4-1<hr/></td><td align="center">H5-51:L1-39<hr/></td><td align="center">H5-51:L3-11<hr/></td><td align="center">H5-51:L3-20<hr/></td><td align="center">H5-51:L4-1<hr/></td></tr><tr><td align="center">H1-69:L1-39</td><td align="center"><bold>0</bold></td><td align="char" char="."><bold>2.1</bold></td><td align="center"><bold>8.9</bold></td><td align="char" char="."><bold>1.1</bold></td><td align="char" char="."><bold>4.2</bold></td><td align="center"><bold>3.0</bold></td><td align="center"><bold>9.5</bold></td><td align="char" char="."><bold>1.5</bold></td><td align="center"><bold>3.3</bold></td><td align="char" char="."><bold>3.6</bold></td><td align="char" char="."><bold>3.1</bold></td><td align="char" char="."><bold>1.6</bold></td><td align="center"><bold>1.8</bold></td><td align="char" char="."><bold>2.9</bold></td><td align="char" char="."><bold>2.4</bold></td><td align="char" char="."><bold>5.2</bold></td></tr><tr><td align="center">H1-69:L3-11</td><td align="center"> </td><td align="center"><bold>0</bold></td><td align="center"><bold>7.3</bold></td><td align="char" char="."><bold>2.9</bold></td><td align="char" char="."><bold>2.5</bold></td><td align="char" char="."><bold>2.0</bold></td><td align="center"><bold>8.4</bold></td><td align="char" char="."><bold>1.3</bold></td><td align="center"><bold>2.6</bold></td><td align="char" char="."><bold>2.9</bold></td><td align="char" char="."><bold>3.2</bold></td><td align="char" char="."><bold>1.8</bold></td><td align="char" char="."><bold>3.9</bold></td><td align="char" char="."><bold>4.6</bold></td><td align="char" char="."><bold>4.4</bold></td><td align="char" char="."><bold>5.0</bold></td></tr><tr><td align="center">H1-69:L3-20</td><td align="center"> </td><td align="center"> </td><td align="center"><bold>0</bold></td><td align="center"><bold>9.2</bold></td><td align="center"><bold>5.0</bold></td><td align="center"><bold>8.7</bold></td><td align="center"><bold>7.4</bold></td><td align="center"><bold>7.6</bold></td><td align="center"><bold>8.9</bold></td><td align="center"><bold>8.6</bold></td><td align="center"><bold>9.4</bold></td><td align="center"><bold>7.9</bold></td><td align="center"><bold>10.5</bold></td><td align="center"><bold>10.1</bold></td><td align="center"><bold>11.0</bold></td><td align="center"><bold>9.7</bold></td></tr><tr><td align="center">H1-69:L4-1</td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"><bold>0</bold></td><td align="char" char="."><bold>4.6</bold></td><td align="char" char="."><bold>3.9</bold></td><td align="center"><bold>10.1</bold></td><td align="char" char="."><bold>1.8</bold></td><td align="char" char="."><bold>4.4</bold></td><td align="char" char="."><bold>4.7</bold></td><td align="char" char="."><bold>4.1</bold></td><td align="char" char="."><bold>2.3</bold></td><td align="char" char="."><bold>1.6</bold></td><td align="char" char="."><bold>2.5</bold></td><td align="char" char="."><bold>2.3</bold></td><td align="char" char="."><bold>6.2</bold></td></tr><tr><td align="center">H3-23:L1-39</td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"><bold>0</bold></td><td align="center"><bold>4.0</bold></td><td align="center"><bold>8.0</bold></td><td align="char" char="."><bold>2.8</bold></td><td align="char" char="."><bold>4.8</bold></td><td align="char" char="."><bold>4.8</bold></td><td align="char" char="."><bold>5.4</bold></td><td align="char" char="."><bold>3.6</bold></td><td align="char" char="."><bold>6.0</bold></td><td align="char" char="."><bold>6.2</bold></td><td align="char" char="."><bold>6.6</bold></td><td align="char" char="."><bold>6.6</bold></td></tr><tr><td align="center">H3-23:L3-11</td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"><bold>0</bold></td><td align="center"><bold>9.3</bold></td><td align="char" char="."><bold>3.0</bold></td><td align="char" char="."><bold>2.1</bold></td><td align="char" char="."><bold>2.9</bold></td><td align="char" char="."><bold>3.3</bold></td><td align="char" char="."><bold>3.3</bold></td><td align="char" char="."><bold>4.6</bold></td><td align="char" char="."><bold>5.8</bold></td><td align="char" char="."><bold>5.0</bold></td><td align="char" char="."><bold>5.2</bold></td></tr><tr><td align="center">H3-23:L3-20</td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"><bold>0</bold></td><td align="center"><bold>8.9</bold></td><td align="center"><bold>7.9</bold></td><td align="center"><bold>7.0</bold></td><td align="center"><bold>7.6</bold></td><td align="center"><bold>7.9</bold></td><td align="center"><bold>10.5</bold></td><td align="center"><bold>9.7</bold></td><td align="center"><bold>10.7</bold></td><td align="center"><bold>6.2</bold></td></tr><tr><td align="center">H3-23:L4-1</td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"><bold>0</bold></td><td align="char" char="."><bold>3.6</bold></td><td align="char" char="."><bold>3.8</bold></td><td align="char" char="."><bold>3.7</bold></td><td align="char" char="."><bold>1.5</bold></td><td align="char" char="."><bold>3.2</bold></td><td align="char" char="."><bold>3.7</bold></td><td align="char" char="."><bold>3.8</bold></td><td align="char" char="."><bold>5.6</bold></td></tr><tr><td align="center">H3-53:L1-39</td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="char" char="."><bold>0</bold></td><td align="char" char="."><bold>1.0</bold></td><td align="char" char="."><bold>1.6</bold></td><td align="char" char="."><bold>2.9</bold></td><td align="char" char="."><bold>4.6</bold></td><td align="char" char="."><bold>5.3</bold></td><td align="char" char="."><bold>4.8</bold></td><td align="char" char="."><bold>3.1</bold></td></tr><tr><td align="center">H3-53:L3-11</td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"><bold>0</bold></td><td align="char" char="."><bold>1.3</bold></td><td align="char" char="."><bold>2.9</bold></td><td align="char" char="."><bold>4.8</bold></td><td align="char" char="."><bold>5.2</bold></td><td align="char" char="."><bold>5.0</bold></td><td align="char" char="."><bold>2.3</bold></td></tr><tr><td align="center">H3-53:L3-20</td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="char" char="."><bold>0</bold></td><td align="char" char="."><bold>2.5</bold></td><td align="char" char="."><bold>3.8</bold></td><td align="char" char="."><bold>4.2</bold></td><td align="char" char="."><bold>3.9</bold></td><td align="char" char="."><bold>2.2</bold></td></tr><tr><td align="center">H3-53:L4-1</td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"><bold>0</bold></td><td align="char" char="."><bold>2.9</bold></td><td align="char" char="."><bold>3.0</bold></td><td align="char" char="."><bold>3.3</bold></td><td align="char" char="."><bold>4.2</bold></td></tr><tr><td align="center">H5-51:L1-39</td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"><bold>0</bold></td><td align="char" char="."><bold>1.9</bold></td><td align="char" char="."><bold>0.6</bold></td><td align="char" char="."><bold>5.8</bold></td></tr><tr><td align="center">H5-51:L3-11</td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"><bold>0</bold></td><td align="center"><bold>1.9</bold></td><td align="char" char="."><bold>5.7</bold></td></tr><tr><td align="center">H5-51:L3-20</td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"><bold>0</bold></td><td align="char" char="."><bold>5.8</bold></td></tr><tr><td align="center">H5-51:L4-1</td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"> </td><td align="center"><bold>0</bold></td></tr></tbody></table> 38290 H1-69:L1-39 H1-69:L3-11 H1-69:L3-20 H1-69:L4-1 H3-23:L1-39 H3-23:L3-11 H3-23:L3-20 H3-23:L4-1 H3-53:L1-39 H3-53:L3-11 H3-53:L3-20 H3-53:L4-1 H5-51:L1-39 H5-51:L3-11 H5-51:L3-20 H5-51:L4-1 H1-69:L1-39 0 2.1 8.9 1.1 4.2 3.0 9.5 1.5 3.3 3.6 3.1 1.6 1.8 2.9 2.4 5.2 H1-69:L3-11 0 7.3 2.9 2.5 2.0 8.4 1.3 2.6 2.9 3.2 1.8 3.9 4.6 4.4 5.0 H1-69:L3-20 0 9.2 5.0 8.7 7.4 7.6 8.9 8.6 9.4 7.9 10.5 10.1 11.0 9.7 H1-69:L4-1 0 4.6 3.9 10.1 1.8 4.4 4.7 4.1 2.3 1.6 2.5 2.3 6.2 H3-23:L1-39 0 4.0 8.0 2.8 4.8 4.8 5.4 3.6 6.0 6.2 6.6 6.6 H3-23:L3-11 0 9.3 3.0 2.1 2.9 3.3 3.3 4.6 5.8 5.0 5.2 H3-23:L3-20 0 8.9 7.9 7.0 7.6 7.9 10.5 9.7 10.7 6.2 H3-23:L4-1 0 3.6 3.8 3.7 1.5 3.2 3.7 3.8 5.6 H3-53:L1-39 0 1.0 1.6 2.9 4.6 5.3 4.8 3.1 H3-53:L3-11 0 1.3 2.9 4.8 5.2 5.0 2.3 H3-53:L3-20 0 2.5 3.8 4.2 3.9 2.2 H3-53:L4-1 0 2.9 3.0 3.3 4.2 H5-51:L1-39 0 1.9 0.6 5.8 H5-51:L3-11 0 1.9 5.7 H5-51:L3-20 0 5.8 H5-51:L4-1 0 RESULTS paragraph 39582 The differences in the tilt angle are shown for all pairs of V regions in Table 3. They range from 0.6° to 11.0°. The smallest differences in the tilt angle are between the Fabs in isomorphous crystal forms. The largest deviations in the tilt angle, up to 11.0°, are found for 2 structures, H1-69:L3-20 and H3-23:L3-20, that stand out from the other Fabs. One of the 2 structures, H1-69:L3-20, has its CDR H3 in the ‘extended’ conformation; the other structure has it in the ‘kinked’ conformation. Two examples illustrating large (10.5°) and small (1.6°) differences in the tilt angles are shown in Fig. 9. 0.8249283 evidence cleaner0 2023-06-28T20:29:14Z DUMMY: differences 0.98597944 evidence cleaner0 2023-06-28T20:29:17Z DUMMY: tilt angle 0.99408334 structure_element cleaner0 2023-06-28T19:05:51Z SO: V regions 0.98391706 evidence cleaner0 2023-06-28T20:29:28Z DUMMY: tilt angle 0.26356268 structure_element cleaner0 2023-06-28T15:58:47Z SO: Fabs 0.885286 evidence cleaner0 2023-06-28T20:29:31Z DUMMY: crystal forms 0.9822982 evidence cleaner0 2023-06-28T20:29:34Z DUMMY: tilt angle 0.98341817 evidence cleaner0 2023-06-28T20:29:37Z DUMMY: structures complex_assembly GO: cleaner0 2023-06-28T21:20:21Z H1-69:L3-20 complex_assembly GO: cleaner0 2023-06-28T21:46:07Z H3-23:L3-20 0.33730918 structure_element cleaner0 2023-06-28T15:58:47Z SO: Fabs 0.9868803 evidence cleaner0 2023-06-28T20:29:40Z DUMMY: structures complex_assembly GO: cleaner0 2023-06-28T21:20:21Z H1-69:L3-20 0.9975684 structure_element cleaner0 2023-06-28T16:25:23Z SO: CDR 0.64334047 structure_element cleaner0 2023-06-28T19:05:17Z SO: H3 protein_state DUMMY: cleaner0 2023-06-29T07:41:57Z extended protein_state DUMMY: cleaner0 2023-06-29T07:42:05Z kinked 0.97952867 evidence cleaner0 2023-06-28T16:02:51Z DUMMY: tilt angles RESULTS title_2 40207 VH:VL buried surface area and complementarity complex_assembly GO: melaniev@ebi.ac.uk 2023-07-06T15:18:10Z VH:VL t0004.xml t0004 TABLE table_caption 40253 VH:VL surface areas and surface complementarity. complex_assembly GO: melaniev@ebi.ac.uk 2023-07-06T15:18:10Z VH:VL t0004.xml t0004 TABLE table <?xml version="1.0" encoding="UTF-8"?> <table frame="hsides" rules="groups"><colgroup><col width="86.4pt" align="left"/><col width="86.4pt" align="left"/><col width="86.4pt" align="left"/><col width="86.4pt" align="left"/><col width="86.4pt" align="left"/><col width="86.4pt" align="left"/></colgroup><thead><tr><th align="left">Chain Pairs</th><th align="center">PDB</th><th align="center">Contact surfaceVH (Å<sup>2</sup>)</th><th align="center">Contact surfaceVL (Å<sup>2</sup>)</th><th align="center">Interface(Å<sup>2</sup>)</th><th align="center">Surface complementarity</th></tr></thead><tbody><tr><td align="center"><bold>H1-69:L1-39</bold></td><td align="center">5I15</td><td align="center">727</td><td align="center">771</td><td align="center">749</td><td align="char" char=".">0.743</td></tr><tr><td align="center"><bold>H1-69:L3-11</bold></td><td align="center">5I16</td><td align="center">802</td><td align="center">870</td><td align="center">836</td><td align="char" char=".">0.762</td></tr><tr><td align="center"><bold>H1-69:L3-20</bold></td><td align="center">5I17</td><td align="center">713</td><td align="center">736</td><td align="center">725</td><td align="char" char=".">0.723</td></tr><tr><td align="center"><bold>H1-69:L4-1</bold></td><td align="center">5I18</td><td align="center">729</td><td align="center">736</td><td align="center">733</td><td align="char" char=".">0.734</td></tr><tr><td align="center">H3-23:L1-39<xref ref-type="bibr" rid="cit0001"><sup><bold>1</bold></sup></xref></td><td align="center">5I19</td><td align="center">795</td><td align="center">817</td><td align="center">806</td><td align="char" char=".">0.722</td></tr><tr><td align="center"><bold>H3-23:L3-11</bold></td><td align="center">5I1A</td><td align="center">822</td><td align="center">834</td><td align="center">828</td><td align="char" char=".">0.725</td></tr><tr><td align="center"><bold>H3-23:L3-20</bold></td><td align="center">5I1C</td><td align="center">670</td><td align="center">698</td><td align="center">684</td><td align="char" char=".">0.676</td></tr><tr><td align="center"><bold>H3-23:L4-1</bold></td><td align="center">5I1D</td><td align="center">743</td><td align="center">770</td><td align="center">757</td><td align="char" char=".">0.708</td></tr><tr><td align="center">H3-53:L1-39<xref ref-type="bibr" rid="cit0001"><sup><bold>1</bold></sup></xref></td><td align="center">5I1E</td><td align="center">698</td><td align="center">719</td><td align="center">709</td><td align="center">0.712</td></tr><tr><td align="center">H3-53:L3-11<xref ref-type="bibr" rid="cit0001"><sup><bold>1</bold></sup></xref></td><td align="center">5I1G</td><td align="center">747</td><td align="center">758</td><td align="center">753</td><td align="center">0.690</td></tr><tr><td align="center"><bold>H3-53:L3-20</bold></td><td align="center">5I1H</td><td align="center">743</td><td align="center">735</td><td align="center">739</td><td align="char" char=".">0.687</td></tr><tr><td align="center"><bold>H3-53:L4-1</bold></td><td align="center">5I1I</td><td align="center">689</td><td align="center">693</td><td align="center">691</td><td align="char" char=".">0.711</td></tr><tr><td align="center"><bold>H5-51:L1-39</bold></td><td align="center">4KMT</td><td align="center">761</td><td align="center">808</td><td align="center">785</td><td align="char" char=".">0.728</td></tr><tr><td align="center">H5-51:L3-11<xref ref-type="bibr" rid="cit0002"><sup><bold>2</bold></sup></xref></td><td align="center">5I1J</td><td align="center">648</td><td align="center">714</td><td align="center">681</td><td align="center">0.717</td></tr><tr><td align="center">H5-51:L3-20<xref ref-type="bibr" rid="cit0002"><sup><bold>2</bold></sup></xref></td><td align="center">5I1K</td><td align="center">622</td><td align="center">643</td><td align="center">633</td><td align="center">0.740</td></tr><tr><td align="center"><bold>H5-51:L4-1</bold></td><td align="center">5I1L</td><td align="center">790</td><td align="center">792</td><td align="center">791</td><td align="char" char=".">0.704</td></tr></tbody></table> 40302 Chain Pairs PDB Contact surfaceVH (Å2) Contact surfaceVL (Å2) Interface(Å2) Surface complementarity H1-69:L1-39 5I15 727 771 749 0.743 H1-69:L3-11 5I16 802 870 836 0.762 H1-69:L3-20 5I17 713 736 725 0.723 H1-69:L4-1 5I18 729 736 733 0.734 H3-23:L1-39 5I19 795 817 806 0.722 H3-23:L3-11 5I1A 822 834 828 0.725 H3-23:L3-20 5I1C 670 698 684 0.676 H3-23:L4-1 5I1D 743 770 757 0.708 H3-53:L1-39 5I1E 698 719 709 0.712 H3-53:L3-11 5I1G 747 758 753 0.690 H3-53:L3-20 5I1H 743 735 739 0.687 H3-53:L4-1 5I1I 689 693 691 0.711 H5-51:L1-39 4KMT 761 808 785 0.728 H5-51:L3-11 5I1J 648 714 681 0.717 H5-51:L3-20 5I1K 622 643 633 0.740 H5-51:L4-1 5I1L 790 792 791 0.704 t0004.xml t0004 TABLE table_footnote 40999 Some side chain atoms in CDR H3 are missing. structure_element SO: cleaner0 2023-06-28T16:25:23Z CDR structure_element SO: cleaner0 2023-06-28T19:05:17Z H3 t0004.xml t0004 TABLE table_footnote 41044 Residues in CDR H3 are missing: YGE in H5-51:L3-11, GIY in H5-51:L3-20. structure_element SO: cleaner0 2023-06-28T16:25:23Z CDR structure_element SO: cleaner0 2023-06-28T19:05:17Z H3 0.9964439 structure_element cleaner0 2023-06-29T07:43:58Z SO: YGE complex_assembly GO: cleaner0 2023-06-28T21:14:32Z H5-51:L3-11 0.9953916 structure_element cleaner0 2023-06-29T07:44:08Z SO: GIY complex_assembly GO: cleaner0 2023-06-28T21:14:53Z H5-51:L3-20 RESULTS paragraph 41116 The results of the PISA contact surface calculation and surface complementarity calculation are shown in Table 4. The interface areas are calculated as the average of the VH and VL contact surfaces. Six of the 16 structures have CDR H3 side chains or complete residues missing, and therefore their interfaces are much smaller than in the other 10 structures with complete CDRs (the results are provided for all Fabs for completeness). Among the complete structures, the interface areas range from 684 to 836 Å2. Interestingly, the 2 structures that have the largest tilt angle differences with the other variants, H3-23:L3-20 and H1-69:L3-20, have the smallest VH:VL interfaces, 684 and 725 Å2, respectively. H3-23:L3-20 is also unique in that it has the lowest value (0.676) of surface complementarity. 0.99178493 experimental_method cleaner0 2023-06-28T20:32:34Z MESH: PISA 0.9650426 experimental_method cleaner0 2023-06-28T20:32:42Z MESH: contact surface calculation 0.96886826 experimental_method cleaner0 2023-06-28T20:32:54Z MESH: surface complementarity calculation 0.5817277 site cleaner0 2023-06-29T08:16:00Z SO: interface site SO: cleaner0 2023-06-29T08:16:44Z VH and VL contact surfaces 0.992105 evidence cleaner0 2023-06-29T08:41:06Z DUMMY: structures structure_element SO: cleaner0 2023-06-28T16:25:23Z CDR structure_element SO: cleaner0 2023-06-28T19:05:17Z H3 0.6253964 protein_state cleaner0 2023-06-29T09:33:23Z DUMMY: missing 0.8131186 site cleaner0 2023-06-29T09:11:20Z SO: interfaces 0.9851922 evidence cleaner0 2023-06-29T08:41:10Z DUMMY: structures 0.9952638 protein_state cleaner0 2023-06-29T09:33:29Z DUMMY: complete 0.9972295 structure_element cleaner0 2023-06-28T19:04:38Z SO: CDRs 0.28258172 structure_element cleaner0 2023-06-28T15:58:47Z SO: Fabs 0.9950252 protein_state cleaner0 2023-06-29T09:33:35Z DUMMY: complete 0.9946089 evidence cleaner0 2023-06-29T08:41:13Z DUMMY: structures 0.49001282 site cleaner0 2023-06-29T08:41:22Z SO: interface 0.9873541 evidence cleaner0 2023-06-29T08:41:29Z DUMMY: structures 0.9782131 evidence cleaner0 2023-06-29T08:41:32Z DUMMY: tilt angle differences 0.9572224 complex_assembly cleaner0 2023-06-29T07:44:30Z GO: H3-23:L3-20 0.9546193 complex_assembly cleaner0 2023-06-28T21:20:21Z GO: H1-69:L3-20 0.87709194 site cleaner0 2023-06-29T09:11:25Z SO: VH:VL interfaces 0.98440266 complex_assembly cleaner0 2023-06-29T07:45:05Z GO: H3-23:L3-20 evidence DUMMY: cleaner0 2023-06-29T08:42:18Z surface complementarity RESULTS title_3 41927 Stability of germline pairings t0005.xml t0005 TABLE table_caption 41958 Melting temperatures for the 16 Fabs. 0.99553233 evidence cleaner0 2023-06-29T08:42:23Z DUMMY: Melting temperatures 0.5436273 structure_element cleaner0 2023-06-28T15:58:47Z SO: Fabs t0005.xml t0005 TABLE table <?xml version="1.0" encoding="UTF-8"?> <table frame="hsides" rules="groups"><colgroup><col width="86.4pt" align="left"/><col width="86.4pt" align="left"/><col width="86.4pt" align="left"/><col width="86.4pt" align="left"/><col width="86.4pt" align="left"/><col width="86.4pt" align="left"/></colgroup><thead><tr><th align="left"> </th><th align="center">L3-20</th><th align="center">L4-1</th><th align="center">L3-11</th><th align="center">L1-39</th><th align="center">HC average</th></tr></thead><tbody><tr><td align="char" char=".">H1-69</td><td align="char" char=".">73.6</td><td align="char" char=".">74.8</td><td align="char" char=".">75.6</td><td align="char" char=".">80.3</td><td align="char" char=".">76.1</td></tr><tr><td align="left">H3-23</td><td align="char" char=".">74.8</td><td align="char" char=".">75.2</td><td align="char" char=".">4.8</td><td align="char" char=".">81.5</td><td align="char" char=".">76.6</td></tr><tr><td align="left">H3-53</td><td align="char" char=".">68.4</td><td align="char" char=".">68.0</td><td align="char" char=".">71.5</td><td align="char" char=".">73.9</td><td align="char" char=".">70.5</td></tr><tr><td align="left">H5-51</td><td align="char" char=".">68.4</td><td align="char" char=".">68.4</td><td align="char" char=".">71.9</td><td align="char" char=".">77.0</td><td align="char" char=".">71.4</td></tr><tr><td align="left">LC average</td><td align="center">71.3</td><td align="char" char=".">71.6</td><td align="char" char=".">73.5</td><td align="char" char=".">78.2</td><td align="center"> </td></tr></tbody></table> 41996 L3-20 L4-1 L3-11 L1-39 HC average H1-69 73.6 74.8 75.6 80.3 76.1 H3-23 74.8 75.2 4.8 81.5 76.6 H3-53 68.4 68.0 71.5 73.9 70.5 H5-51 68.4 68.4 71.9 77.0 71.4 LC average 71.3 71.6 73.5 78.2 t0005.xml t0005 TABLE table_footnote 42203 Colors: blue (Tm < 70°C), green (70°C < Tm < 73°C), yellow (73°C < Tm < 78°C), orange (Tm > 78°C). 0.78301543 evidence cleaner0 2023-06-29T08:42:28Z DUMMY: Tm 0.8056168 evidence cleaner0 2023-06-29T08:42:31Z DUMMY: Tm 0.90112174 evidence cleaner0 2023-06-29T08:42:33Z DUMMY: Tm 0.54672956 evidence cleaner0 2023-06-29T08:42:36Z DUMMY: Tm RESULTS paragraph 42308 Melting temperatures (Tm) were measured for all Fabs using differential scanning calorimetry (Table 5). It appears that for each given LC, the Fabs with germlines H1-69 and H3-23 are substantially more stable than those with germlines H3-53 and H5-51. In addition, L1-39 provides a much higher degree of stabilization than the other 3 LC germlines when combined with any of the HCs. As a result, the Tm for pairs H1-69:L1-39 and H3-23:L1-39 is 12-13° higher than for pairs H3-53:L3-20, H3-53:L4-1, H5-51:L3-20 and H5-51:L4-1. 0.9944316 evidence cleaner0 2023-06-29T08:42:40Z DUMMY: Melting temperatures 0.9929166 evidence cleaner0 2023-06-29T08:42:43Z DUMMY: Tm 0.22407825 structure_element cleaner0 2023-06-28T15:58:47Z SO: Fabs 0.9954069 experimental_method cleaner0 2023-06-29T09:08:34Z MESH: differential scanning calorimetry 0.93906766 structure_element cleaner0 2023-06-28T16:24:55Z SO: LC 0.17053662 structure_element cleaner0 2023-06-28T15:58:47Z SO: Fabs mutant MESH: cleaner0 2023-06-28T21:03:20Z H1-69 0.49335834 mutant cleaner0 2023-06-28T21:04:18Z MESH: H3-23 0.74506783 protein_state cleaner0 2023-06-29T09:33:43Z DUMMY: stable mutant MESH: cleaner0 2023-06-28T21:08:33Z H3-53 mutant MESH: cleaner0 2023-06-28T21:05:06Z H5-51 0.8035386 mutant cleaner0 2023-06-28T21:05:50Z MESH: L1-39 0.69415265 structure_element cleaner0 2023-06-28T16:24:55Z SO: LC 0.99619627 structure_element cleaner0 2023-06-28T16:11:33Z SO: HCs 0.9950289 evidence cleaner0 2023-06-29T08:42:56Z DUMMY: Tm complex_assembly GO: cleaner0 2023-06-29T08:43:14Z H1-69:L1-39 complex_assembly GO: cleaner0 2023-06-28T21:15:28Z H3-23:L1-39 complex_assembly GO: cleaner0 2023-06-28T21:13:47Z H3-53:L3-20 complex_assembly GO: cleaner0 2023-06-28T21:18:21Z H3-53:L4-1 complex_assembly GO: cleaner0 2023-06-28T21:14:53Z H5-51:L3-20 complex_assembly GO: cleaner0 2023-06-29T07:47:40Z H5-51:L4-1 RESULTS paragraph 42838 These findings correlate well with the degree of conformational disorder observed in the crystal structures. Parts of CDR H3 main chain are completely disordered, and were not modeled in Fabs H5-51:L3-20 and H5-51:L3-11 that have the lowest Tms in the set. No electron density is observed for a number of side chains in CDRs H3 and L3 in all Fabs with germline H3-53, which indicates loose packing of the variable domains. All those molecules are relatively unstable, as is reflected in their low Tms. 0.9975747 evidence cleaner0 2023-06-28T19:16:53Z DUMMY: crystal structures 0.997758 structure_element cleaner0 2023-06-28T16:25:23Z SO: CDR 0.84807676 structure_element cleaner0 2023-06-28T19:05:17Z SO: H3 0.68790114 protein_state cleaner0 2023-06-29T09:33:49Z DUMMY: disordered structure_element SO: cleaner0 2023-06-28T15:58:47Z Fabs complex_assembly GO: cleaner0 2023-06-28T21:14:53Z H5-51:L3-20 complex_assembly GO: cleaner0 2023-06-28T21:14:32Z H5-51:L3-11 0.6941904 evidence cleaner0 2023-06-29T08:43:41Z DUMMY: Tms 0.9930948 evidence cleaner0 2023-06-29T08:43:46Z DUMMY: electron density 0.9978542 structure_element cleaner0 2023-06-28T19:04:38Z SO: CDRs 0.9923321 structure_element cleaner0 2023-06-28T19:05:17Z SO: H3 0.99722135 structure_element cleaner0 2023-06-29T09:03:45Z SO: L3 0.55399996 structure_element cleaner0 2023-06-28T15:58:47Z SO: Fabs mutant MESH: cleaner0 2023-06-28T21:08:33Z H3-53 0.6801788 structure_element cleaner0 2023-06-29T09:04:01Z SO: variable domains 0.5376354 evidence cleaner0 2023-06-29T07:48:27Z DUMMY: Tms DISCUSS title_1 43340 Discussion DISCUSS paragraph 43351 This is the first report of a systematic structural investigation of a phage germline library. The 16 Fab structures offer a unique look at all pairings of 4 different HCs (H1-69, H3-23, H3-53, and H5-51) and 4 different LCs (L1-39, L3-11, L3-20 and L4-1), all with the same CDR H3. The structural data set taken as a whole provides insight into how the backbone conformations of the CDRs of a specific heavy or light chain vary when it is paired with 4 different light or heavy chains, respectively. A large variability in the CDR conformations for the sets of HCs and LCs is observed. In some cases the CDR conformations for all members of a set are virtually identical, for others subtle changes occur in a few members of a set, and in some cases larger deviations are observed within a set. The five variants that crystallized with 2 copies of the Fab in the asymmetric unit serve somewhat as controls for the influence of crystal packing on the conformations of the CDRs. In four of the 5 structures the CDR conformations are consistent. In only one case, that of H1-69:L3-20 (the lowest resolution structure), do we see differences in the conformations of the 2 copies of CDRs H1 and L1. This variability is likely a result of 2 factors, crystal packing interactions and internal instability of the variable domain. experimental_method MESH: cleaner0 2023-06-29T09:14:19Z systematic structural investigation 0.9177982 experimental_method cleaner0 2023-06-29T09:09:11Z MESH: phage germline library 0.16469127 structure_element cleaner0 2023-06-28T15:59:05Z SO: Fab 0.9961118 evidence cleaner0 2023-06-29T08:43:56Z DUMMY: structures 0.99849904 structure_element cleaner0 2023-06-28T16:11:33Z SO: HCs 0.8344044 mutant cleaner0 2023-06-28T21:03:20Z MESH: H1-69 0.90730447 mutant cleaner0 2023-06-28T21:04:18Z MESH: H3-23 0.9297971 mutant cleaner0 2023-06-28T21:08:33Z MESH: H3-53 0.9016702 mutant cleaner0 2023-06-28T21:05:06Z MESH: H5-51 0.9983071 structure_element cleaner0 2023-06-28T16:11:39Z SO: LCs 0.64202046 mutant cleaner0 2023-06-28T21:05:50Z MESH: L1-39 0.7273175 mutant cleaner0 2023-06-28T21:06:35Z MESH: L3-11 0.7565879 mutant cleaner0 2023-06-28T21:07:16Z MESH: L3-20 mutant MESH: cleaner0 2023-06-28T21:08:01Z L4-1 0.99818146 structure_element cleaner0 2023-06-28T16:25:23Z SO: CDR 0.96377325 structure_element cleaner0 2023-06-28T19:05:17Z SO: H3 0.9447263 evidence cleaner0 2023-06-29T08:44:01Z DUMMY: structural data 0.9982551 structure_element cleaner0 2023-06-28T19:04:38Z SO: CDRs structure_element SO: cleaner0 2023-06-28T16:13:49Z light chain structure_element SO: cleaner0 2023-06-28T15:56:24Z heavy chains 0.9916883 structure_element cleaner0 2023-06-28T16:25:23Z SO: CDR 0.9959287 structure_element cleaner0 2023-06-28T16:11:33Z SO: HCs 0.9971118 structure_element cleaner0 2023-06-28T16:11:39Z SO: LCs 0.9891389 structure_element cleaner0 2023-06-28T16:25:23Z SO: CDR 0.98784024 experimental_method cleaner0 2023-06-29T09:09:15Z MESH: crystallized 0.1982733 structure_element cleaner0 2023-06-28T15:59:05Z SO: Fab 0.9961863 structure_element cleaner0 2023-06-28T19:04:38Z SO: CDRs 0.99503726 evidence cleaner0 2023-06-29T08:44:06Z DUMMY: structures 0.96922016 structure_element cleaner0 2023-06-28T16:25:23Z SO: CDR complex_assembly GO: cleaner0 2023-06-28T21:20:21Z H1-69:L3-20 0.9952447 evidence cleaner0 2023-06-29T08:44:10Z DUMMY: structure 0.99505025 structure_element cleaner0 2023-06-28T19:04:38Z SO: CDRs 0.9711269 structure_element cleaner0 2023-06-28T19:04:12Z SO: H1 0.9512453 structure_element cleaner0 2023-06-28T16:26:32Z SO: L1 0.9851179 structure_element cleaner0 2023-06-29T09:03:48Z SO: variable domain DISCUSS paragraph 44673 For the CDRs with canonical structures, the largest changes in conformation occur for CDR H1 of H1-69 and H3-53. The other 2 HCs, H3-23 and H5-51, have canonical structures that are remarkably well conserved (Fig. 1). Of the 4 HCs, H1-69 has the greatest number of canonical structure assignments (Table 2). H1-69 is unique in having a pair of glycine residues at positions 26 and 27, which provide more conformational freedom in CDR H1. Besides IGHV1-69, only the germlines of the VH4 family possess double glycines in CDR H1, and it will be interesting to see if they are also conformationally unstable. 0.99440986 structure_element cleaner0 2023-06-28T19:04:38Z SO: CDRs 0.99743253 structure_element cleaner0 2023-06-28T16:25:23Z SO: CDR 0.6280479 structure_element cleaner0 2023-06-28T19:04:12Z SO: H1 0.89499897 mutant cleaner0 2023-06-28T21:03:20Z MESH: H1-69 0.92543626 mutant cleaner0 2023-06-28T21:08:33Z MESH: H3-53 0.9889471 structure_element cleaner0 2023-06-28T16:11:33Z SO: HCs 0.8808372 mutant cleaner0 2023-06-28T21:04:18Z MESH: H3-23 0.90260917 mutant cleaner0 2023-06-28T21:05:06Z MESH: H5-51 0.9224551 protein_state cleaner0 2023-06-29T09:34:13Z DUMMY: remarkably well conserved 0.95445126 structure_element cleaner0 2023-06-28T16:11:33Z SO: HCs 0.803112 mutant cleaner0 2023-06-28T21:03:20Z MESH: H1-69 0.8641219 mutant cleaner0 2023-06-28T21:03:20Z MESH: H1-69 0.98897785 residue_name cleaner0 2023-06-29T09:12:53Z SO: glycine 0.9578594 residue_number cleaner0 2023-06-29T09:20:55Z DUMMY: 26 0.91396666 residue_number cleaner0 2023-06-29T09:20:57Z DUMMY: 27 protein_state DUMMY: cleaner0 2023-06-29T09:34:53Z conformational freedom 0.99736977 structure_element cleaner0 2023-06-28T16:25:23Z SO: CDR 0.67056143 structure_element cleaner0 2023-06-28T19:04:12Z SO: H1 0.9806967 mutant cleaner0 2023-06-28T21:02:50Z MESH: IGHV1-69 0.61210406 structure_element cleaner0 2023-06-29T08:14:53Z SO: VH4 0.9653481 residue_name cleaner0 2023-06-29T09:12:56Z SO: glycines 0.99733585 structure_element cleaner0 2023-06-28T16:25:23Z SO: CDR 0.5672671 structure_element cleaner0 2023-06-28T19:04:12Z SO: H1 0.8510997 protein_state cleaner0 2023-06-29T09:34:57Z DUMMY: conformationally unstable DISCUSS paragraph 45281 Having all 16 VH:VL pairs with the same CDR H3 provides some insights into why molecular modeling efforts of CDR H3 have proven so difficult. As mentioned in the Results section, this data set is composed of 21 Fabs, since 5 of the 16 variants have 2 Fab copies in the asymmetric unit. For the 18 Fabs with complete backbone atoms for CDR H3, 10 have conformations similar to that of the parent, while the others have significantly different conformations (Fig. 6). Thus, it is likely that the CDR H3 conformation is dependent upon 2 dominating factors: 1) amino acid sequence; and 2) VH and VL context. More than half of the variants retain the conformation of the parent despite having differences in the VH:VL pairing. This subset includes 2 structures with 2 copies of the Fab in the asymmetric unit, all of which are nearly identical in conformation. This provides an internal control showing a consistency in the conformations. The remaining 8 structures exhibit “non-parental” conformations, indicating that the VH and VL context can also be a dominating factor influencing CDR H3. Importantly, there are 5 distinctive conformations in this subset. This subset also has 2 structures with 2 Fab copies in the asymmetric unit. Each pair has nearly identical conformations providing an internal check on the consistency of the conformations. Interestingly, as described earlier, these 2 pairs differ in the stem regions with the H1-69:L3-20 pair in the ‘extended’ conformation and H5-51:L4-1 pair in the ‘kinked’ conformation. The conformations are different from each other, as well as from the parent. 0.901212 complex_assembly cleaner0 2023-06-29T09:24:05Z GO: VH:VL structure_element SO: cleaner0 2023-06-28T16:25:23Z CDR structure_element SO: cleaner0 2023-06-28T19:05:17Z H3 structure_element SO: cleaner0 2023-06-28T16:25:23Z CDR structure_element SO: cleaner0 2023-06-28T19:05:17Z H3 0.19667532 structure_element cleaner0 2023-06-28T15:58:47Z SO: Fabs 0.2617504 structure_element cleaner0 2023-06-28T15:59:05Z SO: Fab 0.36789358 structure_element cleaner0 2023-06-28T15:58:47Z SO: Fabs structure_element SO: cleaner0 2023-06-28T16:25:23Z CDR structure_element SO: cleaner0 2023-06-28T19:05:17Z H3 structure_element SO: cleaner0 2023-06-28T16:25:23Z CDR structure_element SO: cleaner0 2023-06-28T19:05:17Z H3 structure_element SO: cleaner0 2023-06-29T07:50:58Z VH structure_element SO: cleaner0 2023-06-28T19:10:07Z VL complex_assembly GO: cleaner0 2023-06-29T07:50:34Z VH:VL 0.98431927 evidence cleaner0 2023-06-29T08:44:18Z DUMMY: structures 0.18366018 structure_element cleaner0 2023-06-28T15:59:05Z SO: Fab 0.91228855 evidence cleaner0 2023-06-29T08:44:24Z DUMMY: structures structure_element SO: cleaner0 2023-06-29T07:50:49Z VH structure_element SO: cleaner0 2023-06-28T19:10:07Z VL structure_element SO: cleaner0 2023-06-28T16:25:23Z CDR structure_element SO: cleaner0 2023-06-28T19:05:17Z H3 0.96874285 evidence cleaner0 2023-06-29T08:44:29Z DUMMY: structures 0.16393337 structure_element cleaner0 2023-06-28T15:59:05Z SO: Fab 0.99679464 structure_element cleaner0 2023-06-29T09:04:12Z SO: stem regions complex_assembly GO: cleaner0 2023-06-28T21:20:21Z H1-69:L3-20 0.9944728 protein_state cleaner0 2023-06-29T07:41:57Z DUMMY: extended complex_assembly GO: cleaner0 2023-06-29T07:51:40Z H5-51:L4-1 0.9884319 protein_state cleaner0 2023-06-29T07:42:05Z DUMMY: kinked DISCUSS paragraph 46902 The CDR H3 conformational analysis shows that, for each set of variants of one HC paired with the 4 different LCs, both “parental” and “non-parental” conformations are observed. The same variability is observed for the sets of variants composed of one LC paired with each of the 4 HCs. Thus, no patterns of conformational preference for a particular HC or LC emerge to shed any direct light on what drives the conformational differences. This finding supports the hypothesis of Weitzner et al. that the H3 conformation is controlled both by its sequence and its environment. structure_element SO: cleaner0 2023-06-28T16:25:23Z CDR structure_element SO: cleaner0 2023-06-28T19:05:17Z H3 0.7433255 experimental_method cleaner0 2023-06-29T09:09:20Z MESH: conformational analysis 0.9436985 structure_element cleaner0 2023-06-29T09:04:34Z SO: HC 0.93943304 structure_element cleaner0 2023-06-28T16:11:39Z SO: LCs 0.93057585 structure_element cleaner0 2023-06-28T16:24:55Z SO: LC 0.9718633 structure_element cleaner0 2023-06-28T16:11:33Z SO: HCs 0.8819633 structure_element cleaner0 2023-06-29T09:04:20Z SO: HC 0.8892341 structure_element cleaner0 2023-06-28T16:24:55Z SO: LC 0.9856926 structure_element cleaner0 2023-06-28T19:05:17Z SO: H3 DISCUSS paragraph 47486 In looking at a possible correlation between the tilt angle and the conformation of CDR H3, no clear trends are observed. Two variants, H1-69:L3-20 and H3-23:L3-20, have the largest differences in the tilt angles compared to other variants as seen in Table 3. The absolute VH:VL orientation parameters for the 2 Fabs (Table S2) show significant deviation in HL, LC1 and HC2 values (2-3 standard deviations from the mean). One of the variants, H3-23:L3-20, has the CDR H3 conformation similar to the parent, but the other, H1-69:L3-20, is different. 0.9763776 evidence cleaner0 2023-06-29T08:44:51Z DUMMY: tilt angle structure_element SO: cleaner0 2023-06-28T16:25:24Z CDR structure_element SO: cleaner0 2023-06-28T19:05:17Z H3 0.9966311 complex_assembly cleaner0 2023-06-28T21:20:21Z GO: H1-69:L3-20 0.9964395 complex_assembly cleaner0 2023-06-29T07:52:58Z GO: H3-23:L3-20 complex_assembly GO: cleaner0 2023-06-29T07:53:33Z VH:VL 0.9644147 evidence cleaner0 2023-06-29T08:47:57Z DUMMY: orientation parameters structure_element SO: cleaner0 2023-06-28T15:58:47Z Fabs evidence DUMMY: cleaner0 2023-06-29T08:47:49Z deviation 0.9223454 structure_element cleaner0 2023-06-29T08:47:12Z SO: HL 0.9130852 structure_element cleaner0 2023-06-29T08:47:20Z SO: LC1 0.92378676 structure_element cleaner0 2023-06-29T08:47:31Z SO: HC2 0.996636 complex_assembly cleaner0 2023-06-29T07:53:07Z GO: H3-23:L3-20 structure_element SO: cleaner0 2023-06-28T16:25:24Z CDR structure_element SO: cleaner0 2023-06-28T19:05:17Z H3 0.99652 complex_assembly cleaner0 2023-06-28T21:20:21Z GO: H1-69:L3-20 DISCUSS paragraph 48037 As noted in the Results section, the 2 variants, H1-69:L3-20 and H3-23:L3-20, are outliers in terms of the tilt angle; at the same time, both have the smallest VH:VL interface. These smaller interfaces may perhaps translate to a significant deviation in how VH is oriented relative to VL than the other variants. These deviations from the other variants can also be seen to some extent in VH:VL orientation parameters in Table S2, as well as in the smaller number of residues involved in the VH:VL interfaces of these 2 variants (Fig. S5). These differences undoubtedly influence the conformation of the CDRs, in particular CDR H1 (Fig. 1A) and CDR L1 (Fig. 3C), especially with the tandem glycines and multiple serines present, respectively. complex_assembly GO: cleaner0 2023-06-28T21:20:21Z H1-69:L3-20 complex_assembly GO: cleaner0 2023-06-29T07:53:56Z H3-23:L3-20 0.65877026 evidence cleaner0 2023-06-29T08:48:01Z DUMMY: tilt angle 0.9951705 site cleaner0 2023-06-28T20:18:37Z SO: VH:VL interface 0.92253155 site cleaner0 2023-06-29T09:11:30Z SO: interfaces 0.9880365 structure_element cleaner0 2023-06-29T09:04:46Z SO: VH 0.9885372 structure_element cleaner0 2023-06-28T19:10:08Z SO: VL complex_assembly GO: cleaner0 2023-06-29T07:54:20Z VH:VL 0.99509436 site cleaner0 2023-06-29T09:11:34Z SO: VH:VL interfaces 0.9969213 structure_element cleaner0 2023-06-28T19:04:38Z SO: CDRs 0.9970937 structure_element cleaner0 2023-06-28T16:25:24Z SO: CDR 0.9948553 structure_element cleaner0 2023-06-28T19:04:12Z SO: H1 0.9974147 structure_element cleaner0 2023-06-28T16:25:24Z SO: CDR 0.9947161 structure_element cleaner0 2023-06-28T16:26:32Z SO: L1 0.9838372 residue_name cleaner0 2023-06-29T09:13:01Z SO: glycines 0.986471 residue_name cleaner0 2023-06-29T09:13:04Z SO: serines DISCUSS paragraph 48784 Pairing of different germlines yields antibodies with various degrees of stability. As indicated by the melting temperatures, germlines H1-69 and H3-23 for HC and germline L1-39 for LC produce more stable Fabs compared to the other germlines in the experimental set. Structural determinants of the differential stability are not always easy to decipher. One possible explanation of the clear preference of LC germline L1-39 is that CDR L3 has smaller residues at positions 91 and 94, allowing for more room to accommodate CDR H3. Other germlines have bulky residues, Tyr, Arg and Trp, at these positions, whereas L1-39 has Ser and Thr. Various combinations of germline sequences for VL and VH impose certain constraints on CDR H3, which has to adapt to the environment. A more compact CDR L3 may be beneficial in this situation. protein_type MESH: cleaner0 2023-06-28T16:03:38Z antibodies 0.99466765 evidence cleaner0 2023-06-29T08:48:10Z DUMMY: melting temperatures 0.75309616 mutant cleaner0 2023-06-28T21:03:21Z MESH: H1-69 0.8418204 mutant cleaner0 2023-06-28T21:04:18Z MESH: H3-23 0.9949491 structure_element cleaner0 2023-06-29T09:05:01Z SO: HC 0.4990733 mutant cleaner0 2023-06-28T21:05:51Z MESH: L1-39 0.9483518 structure_element cleaner0 2023-06-28T16:24:55Z SO: LC 0.48471507 protein_state cleaner0 2023-06-29T09:35:47Z DUMMY: stable 0.24393126 structure_element cleaner0 2023-06-28T15:58:47Z SO: Fabs 0.9337159 structure_element cleaner0 2023-06-28T16:24:55Z SO: LC mutant MESH: cleaner0 2023-06-28T21:05:51Z L1-39 structure_element SO: cleaner0 2023-06-28T16:25:24Z CDR structure_element SO: cleaner0 2023-06-29T07:55:30Z L3 0.907399 residue_number cleaner0 2023-06-29T09:21:03Z DUMMY: 91 0.9088576 residue_number cleaner0 2023-06-29T09:21:06Z DUMMY: 94 structure_element SO: cleaner0 2023-06-28T16:25:24Z CDR structure_element SO: cleaner0 2023-06-28T19:05:17Z H3 0.99063313 residue_name cleaner0 2023-06-29T09:13:07Z SO: Tyr 0.9902063 residue_name cleaner0 2023-06-29T09:13:09Z SO: Arg 0.9905239 residue_name cleaner0 2023-06-29T09:13:11Z SO: Trp mutant MESH: cleaner0 2023-06-28T21:05:51Z L1-39 0.9903556 residue_name cleaner0 2023-06-29T09:13:14Z SO: Ser 0.99004596 residue_name cleaner0 2023-06-29T09:13:16Z SO: Thr 0.8680984 structure_element cleaner0 2023-06-28T19:10:08Z SO: VL 0.82958955 structure_element cleaner0 2023-06-29T09:05:03Z SO: VH structure_element SO: cleaner0 2023-06-28T16:25:24Z CDR structure_element SO: cleaner0 2023-06-28T19:05:17Z H3 0.93768626 protein_state cleaner0 2023-06-29T09:35:55Z DUMMY: compact structure_element SO: cleaner0 2023-06-28T16:25:24Z CDR structure_element SO: cleaner0 2023-06-29T07:55:42Z L3 DISCUSS paragraph 49613 At the other end of the stability range is LC germline L3-20, which yields antibodies with the lowest Tms. While pairings with H3-53 and H5-51 may be safely called a mismatch, those with H1-69 and H3-23 have Tms about 5-6° higher. Curiously, the 2 Fabs, H1-69:L3-20 and H3-23:L3-20, deviate markedly in their tilt angles from the rest of the panel. It is possible that by adopting extreme tilt angles the structure modulates CDR H3 and its environment, which apparently cannot be achieved solely by conformational rearrangement of the CDR. Note that most of the VH:VL interface residues are invariant; therefore, significant change of the tilt angle must come with a penalty in free energy. Yet, for the 2 antibodies, the total gain in stability merits the domain repacking. structure_element SO: cleaner0 2023-06-28T16:24:55Z LC 0.9399285 mutant cleaner0 2023-06-28T21:07:17Z MESH: L3-20 protein_type MESH: cleaner0 2023-06-28T16:03:38Z antibodies 0.826334 evidence cleaner0 2023-06-29T08:48:15Z DUMMY: Tms 0.85578394 mutant cleaner0 2023-06-28T21:08:33Z MESH: H3-53 0.909995 mutant cleaner0 2023-06-28T21:05:06Z MESH: H5-51 mutant MESH: cleaner0 2023-06-28T21:03:21Z H1-69 0.83195966 mutant cleaner0 2023-06-28T21:04:18Z MESH: H3-23 0.72107553 evidence cleaner0 2023-06-29T08:48:19Z DUMMY: Tms 0.25456816 structure_element cleaner0 2023-06-28T15:58:47Z SO: Fabs complex_assembly GO: cleaner0 2023-06-28T21:20:21Z H1-69:L3-20 complex_assembly GO: cleaner0 2023-06-29T07:57:01Z H3-23:L3-20 0.7603384 evidence cleaner0 2023-06-28T16:02:51Z DUMMY: tilt angles evidence DUMMY: cleaner0 2023-06-28T16:02:51Z tilt angles 0.9946995 evidence cleaner0 2023-06-29T08:48:28Z DUMMY: structure structure_element SO: cleaner0 2023-06-28T16:25:24Z CDR structure_element SO: cleaner0 2023-06-28T19:05:17Z H3 0.99783033 structure_element cleaner0 2023-06-28T16:25:24Z SO: CDR 0.9948602 site cleaner0 2023-06-28T20:18:37Z SO: VH:VL interface protein_type MESH: cleaner0 2023-06-28T16:03:38Z antibodies DISCUSS paragraph 50389 Overall, the stability of the Fab, as measured by Tm, is a result of the mutual adjustment of the HC and LC variable domains and adjustment of CDR H3 to the VH:VL cleft. The final conformation represents an energetic minimum; however, in most cases it is very shallow, so that a single mutation can cause a dramatic rearrangement of the structure. 0.21189184 structure_element cleaner0 2023-06-28T15:59:05Z SO: Fab 0.99219584 evidence cleaner0 2023-06-29T08:48:36Z DUMMY: Tm 0.99844164 structure_element cleaner0 2023-06-29T09:05:09Z SO: HC 0.99835795 structure_element cleaner0 2023-06-28T16:24:55Z SO: LC 0.97715676 structure_element cleaner0 2023-06-29T09:05:17Z SO: variable domains structure_element SO: cleaner0 2023-06-28T16:25:24Z CDR structure_element SO: cleaner0 2023-06-28T19:05:17Z H3 0.9936478 site cleaner0 2023-06-29T09:11:40Z SO: VH:VL cleft 0.99620557 evidence cleaner0 2023-06-29T08:48:39Z DUMMY: structure DISCUSS paragraph 50737 In summary, the analysis of this structural library of germline variants composed of all pairs of 4 HCs and 4LCs, all with the same CDR H3, offers some unique insights into antibody structure and how pairing and sequence may influence, or not, the canonical structures of the L1, L2, L3, H1 and H2 CDRs. Comparison of the CDR H3s reveals a large set of variants with conformations similar to the parent, while a second set has significant conformational variability, indicating that both the sequence and the structural context define the CDR H3 conformation. Quite unexpectedly, 2 of the variants, H1-69:L3-20 and H3-53:L4-1, have the ‘extended’ stem region differing from the other 14 that have a ‘kinked’ stem region. Why this is the case is unclear at present. These data reveal the difficulty of modeling CDR H3 accurately, as shown again in Antibody Modeling Assessment II. Furthermore, antibody CDRs, H3 in particular, may go through conformational changes upon binding their targets, making structural prediction for docking purposes an even more difficult task. Fortunately, for most applications of antibody modeling, such as engineering affinity and biophysical properties, an accurate CDR H3 structure is not always necessary. For those applications where accurate CDR structures are essential, such as docking, the results in this work demonstrate the importance of experimental structures. With the recent advances in expression and crystallization methods, Fab structures can be obtained rapidly. 0.8765336 experimental_method cleaner0 2023-06-29T09:09:28Z MESH: structural library 0.934844 structure_element cleaner0 2023-06-28T16:11:33Z SO: HCs structure_element SO: cleaner0 2023-06-29T07:57:39Z LCs structure_element SO: cleaner0 2023-06-28T16:25:24Z CDR structure_element SO: cleaner0 2023-06-28T19:05:17Z H3 protein_type MESH: cleaner0 2023-06-28T15:45:48Z antibody 0.8813323 evidence cleaner0 2023-06-29T08:48:42Z DUMMY: structure 0.9966403 structure_element cleaner0 2023-06-28T16:26:32Z SO: L1 0.99470454 structure_element cleaner0 2023-06-28T20:09:54Z SO: L2 0.9959739 structure_element cleaner0 2023-06-29T09:05:21Z SO: L3 0.99525684 structure_element cleaner0 2023-06-28T19:04:13Z SO: H1 0.9918994 structure_element cleaner0 2023-06-28T16:26:22Z SO: H2 0.9839631 structure_element cleaner0 2023-06-28T19:04:38Z SO: CDRs structure_element SO: cleaner0 2023-06-28T16:25:24Z CDR structure_element SO: cleaner0 2023-06-29T07:58:01Z H3s structure_element SO: cleaner0 2023-06-28T16:25:24Z CDR structure_element SO: cleaner0 2023-06-28T19:05:17Z H3 complex_assembly GO: cleaner0 2023-06-28T21:20:21Z H1-69:L3-20 complex_assembly GO: cleaner0 2023-06-28T21:18:21Z H3-53:L4-1 0.87856656 protein_state cleaner0 2023-06-29T07:41:57Z DUMMY: extended 0.9895041 structure_element cleaner0 2023-06-29T09:05:30Z SO: stem region 0.5306472 protein_state cleaner0 2023-06-29T07:42:05Z DUMMY: kinked 0.98894227 structure_element cleaner0 2023-06-29T09:05:32Z SO: stem region structure_element SO: cleaner0 2023-06-28T16:25:24Z CDR structure_element SO: cleaner0 2023-06-28T19:05:17Z H3 protein_type MESH: cleaner0 2023-06-28T15:45:48Z antibody 0.9935402 structure_element cleaner0 2023-06-28T19:04:38Z SO: CDRs 0.9950309 structure_element cleaner0 2023-06-28T19:05:17Z SO: H3 protein_type MESH: cleaner0 2023-06-28T15:45:48Z antibody structure_element SO: cleaner0 2023-06-28T16:25:24Z CDR structure_element SO: cleaner0 2023-06-28T19:05:17Z H3 0.98669493 evidence cleaner0 2023-06-29T08:48:51Z DUMMY: structure 0.991574 structure_element cleaner0 2023-06-28T16:25:24Z SO: CDR 0.70661396 evidence cleaner0 2023-06-29T08:48:54Z DUMMY: structures 0.9209164 evidence cleaner0 2023-06-29T08:48:57Z DUMMY: structures 0.95461094 experimental_method cleaner0 2023-06-29T09:09:54Z MESH: expression and crystallization methods 0.17987959 structure_element cleaner0 2023-06-28T15:59:05Z SO: Fab 0.9961416 evidence cleaner0 2023-06-29T08:49:00Z DUMMY: structures DISCUSS paragraph 52257 The set of 16 germline Fab structures offers a unique dataset to facilitate software development for antibody modeling. The results essentially support the underlying idea of canonical structures, indicating that most CDRs with germline sequences tend to adopt predefined conformations. From this point of view, a novel approach to design combinatorial antibody libraries would be to cover the range of CDR conformations that may not necessarily coincide with the germline usage in the human repertoire. This would insure more structural diversity, leading to a more diverse panel of antibodies that would bind to a broad spectrum of targets. 0.23744409 structure_element cleaner0 2023-06-28T15:59:05Z SO: Fab 0.99531835 evidence cleaner0 2023-06-29T08:49:04Z DUMMY: structures protein_type MESH: cleaner0 2023-06-28T15:45:48Z antibody 0.9604034 evidence cleaner0 2023-06-29T08:49:07Z DUMMY: structures 0.99709547 structure_element cleaner0 2023-06-28T19:04:38Z SO: CDRs protein_type MESH: cleaner0 2023-06-28T15:45:48Z antibody 0.993736 structure_element cleaner0 2023-06-28T16:25:24Z SO: CDR 0.99389875 species cleaner0 2023-06-28T16:04:00Z MESH: human protein_type MESH: cleaner0 2023-06-28T16:03:38Z antibodies METHODS title_1 52900 Materials and methods METHODS title_2 52922 Fab production, purification and crystallization METHODS paragraph 52971 The production, purification and crystallization of the Fabs reported in this article were described previously. Briefly, the 16 Fabs were produced by combining 4 different HC and 4 different LC germline constructs. The human HC germlines were IGHV1-69 (H1-69), IGHV3-23 (H3-23), IGHV3-53 (H3-53) and IGHV5-51 (H5-51) in the IMGT nomenclature. The human LC germlines were IGKV1-39 (L1-39), IGKV3-11 (L3-11), IGKV3-20 (L3-20) and IGKV4-1 (L4-1) corresponding to O12, L6, A27 and B3 in the V-BASE nomenclature. CDR H3 of the anti-CCL2 antibody CNTO 888 with the amino acid sequence ARYDGIYGELDF was used in all Fab constructs. The J region genes were IGHJ1 for the HC and IGKJ1 for the LC for all Fabs. Human IgG1 and κ constant regions were used in all Fab constructs. A 6xHis tag was added to the C-terminus of the HC to facilitate purification. METHODS paragraph 53822 The Fabs were expressed in HEK 293E cells and purified by affinity and size-exclusion chromatography. For crystallization, the Fabs were dialyzed into 20 mM Tris buffer, pH 7.4, with 50 mM NaCl and concentrated to 12-18 mg/mL. Automated crystallization screening was carried out using the vapor diffusion method at 20°C with an Oryx4 (Douglas Instruments) or a Mosquito (TTP Labtech) crystallization robot in a sitting drop format using Corning 3550 plates. Initial screening was carried out with an in-house 192-well screen optimized for Fab crystallization and the Hampton 96-well Crystal Screen HT (Hampton Research). For the majority of the Fabs, the crystallization protocol employed microseed matrix screening using self-seeding or cross-seeding approaches. A summary of the final crystallization conditions for each of the Fabs is presented in Table 1. METHODS title_2 54687 X-ray data collection METHODS paragraph 54709 For 13 of the Fab crystals, X-ray data collection was carried out at Janssen Research and Development, LLC using a Rigaku MicroMax™-007HF microfocus X-ray generator equipped with a Saturn 944 CCD detector and an X-stream™ 2000 cryocooling system (Rigaku), and for the remaining 3, X-ray data collection was carried out at the Advanced Photon Source (APS) synchrotron at Argonne National Laboratory using the IMCA 17-ID beamline with a Pilatus 6M detector. For X-ray data collection, the Fab crystals were soaked for a few seconds in a cryo-protectant solution containing the corresponding mother liquor supplemented with 17-25% glycerol (Table S1). The crystals for which data were collected in-house were flash cooled in the stream of nitrogen at 100 K. Crystals sent to the APS were flash cooled in liquid nitrogen prior to shipping them to the synchrotron. Diffraction data for all variants were processed with the program XDS. X-ray data statistics are given in Table 1. METHODS title_2 55691 Structure determination METHODS paragraph 55715 A summary of the methods used in the structure solution and refinement of the 16 Fabs is presented in Table S1. Twelve of the structures were solved by molecular replacement with Phaser using different combinations of search models for the VH, VL and constant domains. Four of the structures, H3-53:L1-39, H3-53:L3-11, H5-51:L1-39 and H5-51:L3-11, were solved by direct replacement followed by rigid body refinement with REFMAC. All structures were refined using REFMAC. Model adjustments were carried out using the program Coot. The refinement statistics are given in Table 1. Other crystallographic calculations were performed with the CCP4 suite of programs. The structural figures were prepared using the PyMOL Molecular Graphics System, Version 1.0 (Schrödinger, LLC). METHODS title_2 56492 Structural analysis METHODS paragraph 56512 The canonical structure assignments (Table 2) were made using PyIgClassify, an online canonical structure classification tool (http://dunbrack2.fccc.edu/pyigclassify/) that uses the rules set forth by Dunbrack and coworkers. METHODS paragraph 56738 The conformational variability within the CDRs was assessed by calculating the root-mean-square deviation (rmsd) from the average structure that was generated after superposition of all structures of the set using the main-chain atoms of the CDR in question. The rmsd was calculated for all main-chain atoms (N, CA, C, O) of the CDR. METHODS paragraph 57072 The contact surface areas of the VH and VL domains at the VH:VL inteface were computed with the CCP4 program PISA. The surface complementarity of the VH and VL domains was computed using the CCP4 program SC. METHODS title_2 57280 VH:VL tilt angles METHODS paragraph 57298 The orientation of the VH domain with respect to the VL domain was assessed using 2 different approaches. The first approach calculates the 6 VH:VL orientation parameters that describe the VH:VL relationship according to Dunbar and co-workers using a script downloaded from the website (http://opig.stats.ox.ac.uk/webapps/abangle). The six parameters include 5 angles, HL, H1, H2, L1 and L2, and a distance, dc. These parameters are derived by first defining 2 planes, one for each domain, based on core residues in the domains. The distance between the planes, dc, is determined along a vector between the planes that is used to establish a consistent coordinate system. The torsion angle between the domains, HL, is much like the VH:VL packing angle defined by Abhinandan and Martin. The tilt of one domain relative to the other is defined by the HC1 and LC1 angles, and the twist of one domain relative to the other is defined by the HC2 and LC2 angles. METHODS paragraph 58255 The second approach calculates the difference in the tilt angle between pairs of Fvs, which reflects the relative orientation between the VH and VL domains. The difference with respect to the reference structure is calculated by sequential root-mean-square superposition of the VL and VH domains using β-sheet core Cα positions (Chothia numbering scheme): 3–13, 18–25, 33–38, 43–49, 61–67, 70–76, 85–90, 97–103 for VL; 3–7, 18–24, 34–40, 44–51, 56–59, 67–72, 77–82a, 87–94, 102–110 for VH. The κ angle in the spherical polar angular system (ω, ϕ, κ) of the latter transformation is the difference in the tilt angle. METHODS title_2 58911 Differential scanning calorimetry METHODS paragraph 58945 DSC experiments were performed on a VP-capillary DSC system (MicroCal Inc., Northampton, MA) in which temperature differences between the reference and sample cell are continuously measured and calibrated to power units. Samples were heated from 10°C to 95°C at a heating rate of 60°C/hour. The pre-scan time was 15 minutes and the filtering period was 10 seconds. The concentration used in the DSC experiments was about 0.4 mg/mL in phosphate-buffered saline. Analysis of the resulting thermograms was performed using MicroCal Origin 7 software. Melting temperature of proteins was determined by deconvolution of the DSC scans using non-2 state model in the MicroCal Origin 7 software. Scans were deconvoluted using a non-2 state model with either 1-step transition or 2-step transition depending on the number of resolved peaks observed in a scan. METHODS title_2 59799 Accession numbers METHODS paragraph 59817 Atomic coordinates and structure factors have been deposited in the Protein Data Bank with accession numbers 4KMT, 5I15, 5I16, 5I17, 5I18, 5I19, 5I1A, 5I1C, 5I1D, 5I1E, 5I1G, 5I1H, 5I1I, 5I1J, 5I1K and 5I1L. SUPPL title_1 60025 Supplementary Material COMP_INT title_1 60048 Disclosure of potential conflicts of interest COMP_INT paragraph 60094 No potential conflicts of interest were disclosed. 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