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0 9 Structure evidence Structure of the GAT domain of the endosomal adapter protein Tom1 TITLE |
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17 20 GAT structure_element Structure of the GAT domain of the endosomal adapter protein Tom1 TITLE |
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45 60 adapter protein protein_type Structure of the GAT domain of the endosomal adapter protein Tom1 TITLE |
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61 65 Tom1 protein Structure of the GAT domain of the endosomal adapter protein Tom1 TITLE |
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50 71 cell-surface receptor protein_type Cellular homeostasis requires correct delivery of cell-surface receptor proteins (cargo) to their target subcellular compartments. ABSTRACT |
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4 20 adapter proteins protein_type The adapter proteins Tom1 and Tollip are involved in sorting of ubiquitinated cargo in endosomal compartments. ABSTRACT |
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21 25 Tom1 protein The adapter proteins Tom1 and Tollip are involved in sorting of ubiquitinated cargo in endosomal compartments. ABSTRACT |
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30 36 Tollip protein The adapter proteins Tom1 and Tollip are involved in sorting of ubiquitinated cargo in endosomal compartments. ABSTRACT |
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64 77 ubiquitinated ptm The adapter proteins Tom1 and Tollip are involved in sorting of ubiquitinated cargo in endosomal compartments. ABSTRACT |
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15 19 Tom1 protein Recruitment of Tom1 to the endosomal compartments is mediated by its GAT domain’s association to Tollip’s Tom1-binding domain (TBD). ABSTRACT |
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69 72 GAT structure_element Recruitment of Tom1 to the endosomal compartments is mediated by its GAT domain’s association to Tollip’s Tom1-binding domain (TBD). ABSTRACT |
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97 103 Tollip protein Recruitment of Tom1 to the endosomal compartments is mediated by its GAT domain’s association to Tollip’s Tom1-binding domain (TBD). ABSTRACT |
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106 125 Tom1-binding domain structure_element Recruitment of Tom1 to the endosomal compartments is mediated by its GAT domain’s association to Tollip’s Tom1-binding domain (TBD). ABSTRACT |
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127 130 TBD structure_element Recruitment of Tom1 to the endosomal compartments is mediated by its GAT domain’s association to Tollip’s Tom1-binding domain (TBD). ABSTRACT |
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36 48 solution NMR experimental_method In this data article, we report the solution NMR-derived structure of the Tom1 GAT domain. ABSTRACT |
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57 66 structure evidence In this data article, we report the solution NMR-derived structure of the Tom1 GAT domain. ABSTRACT |
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74 78 Tom1 protein In this data article, we report the solution NMR-derived structure of the Tom1 GAT domain. ABSTRACT |
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79 82 GAT structure_element In this data article, we report the solution NMR-derived structure of the Tom1 GAT domain. ABSTRACT |
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22 31 structure evidence The estimated protein structure exhibits a bundle of three helical elements. ABSTRACT |
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3 10 compare experimental_method We compare the Tom1 GAT structure with those structures corresponding to the Tollip TBD- and ubiquitin-bound states. ABSTRACT |
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15 19 Tom1 protein We compare the Tom1 GAT structure with those structures corresponding to the Tollip TBD- and ubiquitin-bound states. ABSTRACT |
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20 23 GAT structure_element We compare the Tom1 GAT structure with those structures corresponding to the Tollip TBD- and ubiquitin-bound states. ABSTRACT |
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24 33 structure evidence We compare the Tom1 GAT structure with those structures corresponding to the Tollip TBD- and ubiquitin-bound states. ABSTRACT |
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45 55 structures evidence We compare the Tom1 GAT structure with those structures corresponding to the Tollip TBD- and ubiquitin-bound states. ABSTRACT |
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77 83 Tollip protein We compare the Tom1 GAT structure with those structures corresponding to the Tollip TBD- and ubiquitin-bound states. ABSTRACT |
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84 88 TBD- protein_state We compare the Tom1 GAT structure with those structures corresponding to the Tollip TBD- and ubiquitin-bound states. ABSTRACT |
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93 108 ubiquitin-bound protein_state We compare the Tom1 GAT structure with those structures corresponding to the Tollip TBD- and ubiquitin-bound states. ABSTRACT |
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141 159 Circular dichroism experimental_method "Subject area Biology More specific subject area Structural biology Type of data Table, text file, graph, figures How data was acquired Circular dichroism and NMR." TABLE |
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164 167 NMR experimental_method "Subject area Biology More specific subject area Structural biology Type of data Table, text file, graph, figures How data was acquired Circular dichroism and NMR." TABLE |
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0 3 NMR experimental_method "NMR data was recorded using a Bruker 800 MHz Data format PDB format text file." TABLE |
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12 22 CS-Rosetta experimental_method "Analyzed by CS-Rosetta, Protein Structure Validation Server (PSVS), NMRPipe, NMRDraw, and PyMol Experimental factors Recombinant human Tom1 GAT domain was purified to homogeneity before use Experimental features Solution structure of Tom1 GAT was determined from NMR chemical shift data Data source location Virginia and Colorado, United States." TABLE |
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24 59 Protein Structure Validation Server experimental_method "Analyzed by CS-Rosetta, Protein Structure Validation Server (PSVS), NMRPipe, NMRDraw, and PyMol Experimental factors Recombinant human Tom1 GAT domain was purified to homogeneity before use Experimental features Solution structure of Tom1 GAT was determined from NMR chemical shift data Data source location Virginia and Colorado, United States." TABLE |
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61 65 PSVS experimental_method "Analyzed by CS-Rosetta, Protein Structure Validation Server (PSVS), NMRPipe, NMRDraw, and PyMol Experimental factors Recombinant human Tom1 GAT domain was purified to homogeneity before use Experimental features Solution structure of Tom1 GAT was determined from NMR chemical shift data Data source location Virginia and Colorado, United States." TABLE |
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68 75 NMRPipe experimental_method "Analyzed by CS-Rosetta, Protein Structure Validation Server (PSVS), NMRPipe, NMRDraw, and PyMol Experimental factors Recombinant human Tom1 GAT domain was purified to homogeneity before use Experimental features Solution structure of Tom1 GAT was determined from NMR chemical shift data Data source location Virginia and Colorado, United States." TABLE |
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77 84 NMRDraw experimental_method "Analyzed by CS-Rosetta, Protein Structure Validation Server (PSVS), NMRPipe, NMRDraw, and PyMol Experimental factors Recombinant human Tom1 GAT domain was purified to homogeneity before use Experimental features Solution structure of Tom1 GAT was determined from NMR chemical shift data Data source location Virginia and Colorado, United States." TABLE |
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131 136 human species "Analyzed by CS-Rosetta, Protein Structure Validation Server (PSVS), NMRPipe, NMRDraw, and PyMol Experimental factors Recombinant human Tom1 GAT domain was purified to homogeneity before use Experimental features Solution structure of Tom1 GAT was determined from NMR chemical shift data Data source location Virginia and Colorado, United States." TABLE |
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137 141 Tom1 protein "Analyzed by CS-Rosetta, Protein Structure Validation Server (PSVS), NMRPipe, NMRDraw, and PyMol Experimental factors Recombinant human Tom1 GAT domain was purified to homogeneity before use Experimental features Solution structure of Tom1 GAT was determined from NMR chemical shift data Data source location Virginia and Colorado, United States." TABLE |
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142 145 GAT structure_element "Analyzed by CS-Rosetta, Protein Structure Validation Server (PSVS), NMRPipe, NMRDraw, and PyMol Experimental factors Recombinant human Tom1 GAT domain was purified to homogeneity before use Experimental features Solution structure of Tom1 GAT was determined from NMR chemical shift data Data source location Virginia and Colorado, United States." TABLE |
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216 234 Solution structure evidence "Analyzed by CS-Rosetta, Protein Structure Validation Server (PSVS), NMRPipe, NMRDraw, and PyMol Experimental factors Recombinant human Tom1 GAT domain was purified to homogeneity before use Experimental features Solution structure of Tom1 GAT was determined from NMR chemical shift data Data source location Virginia and Colorado, United States." TABLE |
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238 242 Tom1 protein "Analyzed by CS-Rosetta, Protein Structure Validation Server (PSVS), NMRPipe, NMRDraw, and PyMol Experimental factors Recombinant human Tom1 GAT domain was purified to homogeneity before use Experimental features Solution structure of Tom1 GAT was determined from NMR chemical shift data Data source location Virginia and Colorado, United States." TABLE |
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243 246 GAT structure_element "Analyzed by CS-Rosetta, Protein Structure Validation Server (PSVS), NMRPipe, NMRDraw, and PyMol Experimental factors Recombinant human Tom1 GAT domain was purified to homogeneity before use Experimental features Solution structure of Tom1 GAT was determined from NMR chemical shift data Data source location Virginia and Colorado, United States." TABLE |
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267 270 NMR experimental_method "Analyzed by CS-Rosetta, Protein Structure Validation Server (PSVS), NMRPipe, NMRDraw, and PyMol Experimental factors Recombinant human Tom1 GAT domain was purified to homogeneity before use Experimental features Solution structure of Tom1 GAT was determined from NMR chemical shift data Data source location Virginia and Colorado, United States." TABLE |
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271 285 chemical shift evidence "Analyzed by CS-Rosetta, Protein Structure Validation Server (PSVS), NMRPipe, NMRDraw, and PyMol Experimental factors Recombinant human Tom1 GAT domain was purified to homogeneity before use Experimental features Solution structure of Tom1 GAT was determined from NMR chemical shift data Data source location Virginia and Colorado, United States." TABLE |
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5 8 GAT structure_element "Tom1 GAT structural data is publicly available in the RCSB Protein Data Bank (http: |
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4 8 Tom1 protein The Tom1 GAT domain solution structure will provide additional tools for modulating its biological function. TABLE |
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9 12 GAT structure_element The Tom1 GAT domain solution structure will provide additional tools for modulating its biological function. TABLE |
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20 38 solution structure evidence The Tom1 GAT domain solution structure will provide additional tools for modulating its biological function. TABLE |
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0 4 Tom1 protein Tom1 GAT can adopt distinct conformations upon ligand binding. TABLE |
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5 8 GAT structure_element Tom1 GAT can adopt distinct conformations upon ligand binding. TABLE |
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33 37 Tom1 protein A conformational response of the Tom1 GAT domain upon Tollip TBD binding can serve as an example to explain mutually exclusive ligand binding events. TABLE |
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38 41 GAT structure_element A conformational response of the Tom1 GAT domain upon Tollip TBD binding can serve as an example to explain mutually exclusive ligand binding events. TABLE |
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54 60 Tollip protein A conformational response of the Tom1 GAT domain upon Tollip TBD binding can serve as an example to explain mutually exclusive ligand binding events. TABLE |
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61 64 TBD structure_element A conformational response of the Tom1 GAT domain upon Tollip TBD binding can serve as an example to explain mutually exclusive ligand binding events. TABLE |
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16 41 far-UV circular dichroism experimental_method Analysis of the far-UV circular dichroism (CD) spectrum of the Tom 1 GAT domain (Fig. 1) predicts 58.7% α-helix, 3% β-strand, 15.5% turn, and 22.8% disordered regions. TABLE |
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43 45 CD experimental_method Analysis of the far-UV circular dichroism (CD) spectrum of the Tom 1 GAT domain (Fig. 1) predicts 58.7% α-helix, 3% β-strand, 15.5% turn, and 22.8% disordered regions. TABLE |
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47 55 spectrum evidence Analysis of the far-UV circular dichroism (CD) spectrum of the Tom 1 GAT domain (Fig. 1) predicts 58.7% α-helix, 3% β-strand, 15.5% turn, and 22.8% disordered regions. TABLE |
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63 68 Tom 1 protein Analysis of the far-UV circular dichroism (CD) spectrum of the Tom 1 GAT domain (Fig. 1) predicts 58.7% α-helix, 3% β-strand, 15.5% turn, and 22.8% disordered regions. TABLE |
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69 72 GAT structure_element Analysis of the far-UV circular dichroism (CD) spectrum of the Tom 1 GAT domain (Fig. 1) predicts 58.7% α-helix, 3% β-strand, 15.5% turn, and 22.8% disordered regions. TABLE |
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104 111 α-helix structure_element Analysis of the far-UV circular dichroism (CD) spectrum of the Tom 1 GAT domain (Fig. 1) predicts 58.7% α-helix, 3% β-strand, 15.5% turn, and 22.8% disordered regions. TABLE |
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116 124 β-strand structure_element Analysis of the far-UV circular dichroism (CD) spectrum of the Tom 1 GAT domain (Fig. 1) predicts 58.7% α-helix, 3% β-strand, 15.5% turn, and 22.8% disordered regions. TABLE |
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4 8 Tom1 protein The Tom1 GAT structural restraints yielded ten helical structures (Fig. 2A,B) with a root mean square deviation (RMSD) of 0.9 Å for backbone and 1.3 Å for all heavy atoms (Table 1) and estimated the presence of three helices spanning residues Q216-E240 (α-helix 1), P248-Q274 (α-helix 2), and E278-T306 (α-helix 3). TABLE |
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9 12 GAT structure_element The Tom1 GAT structural restraints yielded ten helical structures (Fig. 2A,B) with a root mean square deviation (RMSD) of 0.9 Å for backbone and 1.3 Å for all heavy atoms (Table 1) and estimated the presence of three helices spanning residues Q216-E240 (α-helix 1), P248-Q274 (α-helix 2), and E278-T306 (α-helix 3). TABLE |
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13 34 structural restraints evidence The Tom1 GAT structural restraints yielded ten helical structures (Fig. 2A,B) with a root mean square deviation (RMSD) of 0.9 Å for backbone and 1.3 Å for all heavy atoms (Table 1) and estimated the presence of three helices spanning residues Q216-E240 (α-helix 1), P248-Q274 (α-helix 2), and E278-T306 (α-helix 3). TABLE |
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55 65 structures evidence The Tom1 GAT structural restraints yielded ten helical structures (Fig. 2A,B) with a root mean square deviation (RMSD) of 0.9 Å for backbone and 1.3 Å for all heavy atoms (Table 1) and estimated the presence of three helices spanning residues Q216-E240 (α-helix 1), P248-Q274 (α-helix 2), and E278-T306 (α-helix 3). TABLE |
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85 111 root mean square deviation evidence The Tom1 GAT structural restraints yielded ten helical structures (Fig. 2A,B) with a root mean square deviation (RMSD) of 0.9 Å for backbone and 1.3 Å for all heavy atoms (Table 1) and estimated the presence of three helices spanning residues Q216-E240 (α-helix 1), P248-Q274 (α-helix 2), and E278-T306 (α-helix 3). TABLE |
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113 117 RMSD evidence The Tom1 GAT structural restraints yielded ten helical structures (Fig. 2A,B) with a root mean square deviation (RMSD) of 0.9 Å for backbone and 1.3 Å for all heavy atoms (Table 1) and estimated the presence of three helices spanning residues Q216-E240 (α-helix 1), P248-Q274 (α-helix 2), and E278-T306 (α-helix 3). TABLE |
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243 252 Q216-E240 residue_range The Tom1 GAT structural restraints yielded ten helical structures (Fig. 2A,B) with a root mean square deviation (RMSD) of 0.9 Å for backbone and 1.3 Å for all heavy atoms (Table 1) and estimated the presence of three helices spanning residues Q216-E240 (α-helix 1), P248-Q274 (α-helix 2), and E278-T306 (α-helix 3). TABLE |
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254 263 α-helix 1 structure_element The Tom1 GAT structural restraints yielded ten helical structures (Fig. 2A,B) with a root mean square deviation (RMSD) of 0.9 Å for backbone and 1.3 Å for all heavy atoms (Table 1) and estimated the presence of three helices spanning residues Q216-E240 (α-helix 1), P248-Q274 (α-helix 2), and E278-T306 (α-helix 3). TABLE |
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266 275 P248-Q274 residue_range The Tom1 GAT structural restraints yielded ten helical structures (Fig. 2A,B) with a root mean square deviation (RMSD) of 0.9 Å for backbone and 1.3 Å for all heavy atoms (Table 1) and estimated the presence of three helices spanning residues Q216-E240 (α-helix 1), P248-Q274 (α-helix 2), and E278-T306 (α-helix 3). TABLE |
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277 286 α-helix 2 structure_element The Tom1 GAT structural restraints yielded ten helical structures (Fig. 2A,B) with a root mean square deviation (RMSD) of 0.9 Å for backbone and 1.3 Å for all heavy atoms (Table 1) and estimated the presence of three helices spanning residues Q216-E240 (α-helix 1), P248-Q274 (α-helix 2), and E278-T306 (α-helix 3). TABLE |
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293 302 E278-T306 residue_range The Tom1 GAT structural restraints yielded ten helical structures (Fig. 2A,B) with a root mean square deviation (RMSD) of 0.9 Å for backbone and 1.3 Å for all heavy atoms (Table 1) and estimated the presence of three helices spanning residues Q216-E240 (α-helix 1), P248-Q274 (α-helix 2), and E278-T306 (α-helix 3). TABLE |
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304 313 α-helix 3 structure_element The Tom1 GAT structural restraints yielded ten helical structures (Fig. 2A,B) with a root mean square deviation (RMSD) of 0.9 Å for backbone and 1.3 Å for all heavy atoms (Table 1) and estimated the presence of three helices spanning residues Q216-E240 (α-helix 1), P248-Q274 (α-helix 2), and E278-T306 (α-helix 3). TABLE |
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7 16 ubiquitin chemical Unlike ubiquitin binding, data suggest that conformational changes of the Tom1 GAT α-helices 1 and 2 occur upon Tollip TBD binding (Fig. 3A,B). TABLE |
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74 78 Tom1 protein Unlike ubiquitin binding, data suggest that conformational changes of the Tom1 GAT α-helices 1 and 2 occur upon Tollip TBD binding (Fig. 3A,B). TABLE |
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79 82 GAT structure_element Unlike ubiquitin binding, data suggest that conformational changes of the Tom1 GAT α-helices 1 and 2 occur upon Tollip TBD binding (Fig. 3A,B). TABLE |
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83 100 α-helices 1 and 2 structure_element Unlike ubiquitin binding, data suggest that conformational changes of the Tom1 GAT α-helices 1 and 2 occur upon Tollip TBD binding (Fig. 3A,B). TABLE |
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112 118 Tollip protein Unlike ubiquitin binding, data suggest that conformational changes of the Tom1 GAT α-helices 1 and 2 occur upon Tollip TBD binding (Fig. 3A,B). TABLE |
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119 122 TBD structure_element Unlike ubiquitin binding, data suggest that conformational changes of the Tom1 GAT α-helices 1 and 2 occur upon Tollip TBD binding (Fig. 3A,B). TABLE |
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15 24 far-UV CD experimental_method Representative far-UV CD spectrum of the His-Tom1 GAT domain. FIG |
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25 33 spectrum evidence Representative far-UV CD spectrum of the His-Tom1 GAT domain. FIG |
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41 45 His- experimental_method Representative far-UV CD spectrum of the His-Tom1 GAT domain. FIG |
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45 49 Tom1 protein Representative far-UV CD spectrum of the His-Tom1 GAT domain. FIG |
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50 53 GAT structure_element Representative far-UV CD spectrum of the His-Tom1 GAT domain. FIG |
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40 62 backbone superposition experimental_method (A) Stereo view displaying the best-fit backbone superposition of the refined structures for the Tom1 GAT domain. FIG |
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78 88 structures evidence (A) Stereo view displaying the best-fit backbone superposition of the refined structures for the Tom1 GAT domain. FIG |
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97 101 Tom1 protein (A) Stereo view displaying the best-fit backbone superposition of the refined structures for the Tom1 GAT domain. FIG |
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102 105 GAT structure_element (A) Stereo view displaying the best-fit backbone superposition of the refined structures for the Tom1 GAT domain. FIG |
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96 100 Tom1 protein Helices are shown in orange, whereas loops are colored in green. (B) Ribbon illustration of the Tom1 GAT domain. FIG |
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101 104 GAT structure_element Helices are shown in orange, whereas loops are colored in green. (B) Ribbon illustration of the Tom1 GAT domain. FIG |
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21 44 superimposed structures experimental_method (A) Two views of the superimposed structures of the Tom1 GAT domain in the free state (gray) with that in the Tollip TBD-bound state (red). (B) Two views of the superimposed structures of the Tom1 GAT domain (gray) with that in the Ub-bound state (green). FIG |
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52 56 Tom1 protein (A) Two views of the superimposed structures of the Tom1 GAT domain in the free state (gray) with that in the Tollip TBD-bound state (red). (B) Two views of the superimposed structures of the Tom1 GAT domain (gray) with that in the Ub-bound state (green). FIG |
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57 60 GAT structure_element (A) Two views of the superimposed structures of the Tom1 GAT domain in the free state (gray) with that in the Tollip TBD-bound state (red). (B) Two views of the superimposed structures of the Tom1 GAT domain (gray) with that in the Ub-bound state (green). FIG |
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75 79 free protein_state (A) Two views of the superimposed structures of the Tom1 GAT domain in the free state (gray) with that in the Tollip TBD-bound state (red). (B) Two views of the superimposed structures of the Tom1 GAT domain (gray) with that in the Ub-bound state (green). FIG |
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110 116 Tollip protein (A) Two views of the superimposed structures of the Tom1 GAT domain in the free state (gray) with that in the Tollip TBD-bound state (red). (B) Two views of the superimposed structures of the Tom1 GAT domain (gray) with that in the Ub-bound state (green). FIG |
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117 126 TBD-bound protein_state (A) Two views of the superimposed structures of the Tom1 GAT domain in the free state (gray) with that in the Tollip TBD-bound state (red). (B) Two views of the superimposed structures of the Tom1 GAT domain (gray) with that in the Ub-bound state (green). FIG |
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161 184 superimposed structures experimental_method (A) Two views of the superimposed structures of the Tom1 GAT domain in the free state (gray) with that in the Tollip TBD-bound state (red). (B) Two views of the superimposed structures of the Tom1 GAT domain (gray) with that in the Ub-bound state (green). FIG |
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192 196 Tom1 protein (A) Two views of the superimposed structures of the Tom1 GAT domain in the free state (gray) with that in the Tollip TBD-bound state (red). (B) Two views of the superimposed structures of the Tom1 GAT domain (gray) with that in the Ub-bound state (green). FIG |
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197 200 GAT structure_element (A) Two views of the superimposed structures of the Tom1 GAT domain in the free state (gray) with that in the Tollip TBD-bound state (red). (B) Two views of the superimposed structures of the Tom1 GAT domain (gray) with that in the Ub-bound state (green). FIG |
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232 240 Ub-bound protein_state (A) Two views of the superimposed structures of the Tom1 GAT domain in the free state (gray) with that in the Tollip TBD-bound state (red). (B) Two views of the superimposed structures of the Tom1 GAT domain (gray) with that in the Ub-bound state (green). FIG |
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0 3 NMR experimental_method NMR and refinement statistics for the Tom1 GAT domain. TABLE |
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8 29 refinement statistics evidence NMR and refinement statistics for the Tom1 GAT domain. TABLE |
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38 42 Tom1 protein NMR and refinement statistics for the Tom1 GAT domain. TABLE |
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43 46 GAT structure_element NMR and refinement statistics for the Tom1 GAT domain. TABLE |
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0 3 NMR experimental_method NMR structural statistics for lowest energy conformers of Tom1 GAT using PSVS. TABLE |
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4 25 structural statistics evidence NMR structural statistics for lowest energy conformers of Tom1 GAT using PSVS. TABLE |
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58 62 Tom1 protein NMR structural statistics for lowest energy conformers of Tom1 GAT using PSVS. TABLE |
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63 66 GAT structure_element NMR structural statistics for lowest energy conformers of Tom1 GAT using PSVS. TABLE |
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73 77 PSVS experimental_method NMR structural statistics for lowest energy conformers of Tom1 GAT using PSVS. TABLE |
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28 41 superimposing experimental_method deviations were obtained by superimposing residues 215–309 of Tom1 GAT among 10 lowest energy refined structures. TABLE |
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51 58 215–309 residue_range deviations were obtained by superimposing residues 215–309 of Tom1 GAT among 10 lowest energy refined structures. TABLE |
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62 66 Tom1 protein deviations were obtained by superimposing residues 215–309 of Tom1 GAT among 10 lowest energy refined structures. TABLE |
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67 70 GAT structure_element deviations were obtained by superimposing residues 215–309 of Tom1 GAT among 10 lowest energy refined structures. TABLE |
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102 112 structures evidence deviations were obtained by superimposing residues 215–309 of Tom1 GAT among 10 lowest energy refined structures. TABLE |
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