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	---
	license: mit
	language:
	- en
	tags:
	- biology
	- protein structure
	- token classification
	widget:
	- text: "N-terminal acetylation (Nt-acetylation), carried out by N-terminal acetyltransferases (NATs), is a conserved and primary modification of nascent peptide chains. Naa60 (also named NatF) is a recently identified NAT found only in multicellular eukaryotes. This protein was shown to locate on the Golgi apparatus and mainly catalyze the Nt-acetylation of transmembrane proteins, and it also harbors lysine Nε-acetyltransferase (KAT) activity to catalyze the acetylation of lysine ε-amine. Here, we report the crystal structures of human Naa60 (hNaa60) in complex with Acetyl-Coenzyme A (Ac-CoA) or Coenzyme A (CoA). The hNaa60 protein contains an amphipathic helix following its GNAT domain that may contribute to Golgi localization of hNaa60, and the β7-β8 hairpin adopted different conformations in the hNaa60(1-242) and hNaa60(1-199) crystal structures. Remarkably, we found that the side-chain of Phe 34 can influence the position of the coenzyme, indicating a new regulatory mechanism involving enzyme, co-factor and substrates interactions. Moreover, structural comparison and biochemical studies indicated that Tyr 97 and His 138 are key residues for catalytic reaction and that a non-conserved β3-β4 long loop participates in the regulation of hNaa60 activity."
	model-index:
	- name: Bioformer8L-ProteinStructure-NER-v0.1_quantized
	results:
	- task:
	name: NER
	type: token-classification
	metrics:
	- name: NER Precision
	type: precision
	value: 0.90
	- name: NER Recall
	type: recall
	value: 0.92
	- name: NER F Score
	type: f_score
	value: 0.91
	---


	\| Feature \| Description \|
	\| --- \| --- \|
	\| Name \| `Bioformer8L-ProteinStructure-NER-v0.1_quantized` \|
	\| Default Pipeline \| `transformer`, `ner` \|
	\| Components \| `transformer`, `ner` \|
	\| Vectors \| 0 keys, 0 unique vectors (0 dimensions) \|
	\| Sources \| n/a \|
	\| License \| n/a \|
	\| Author \| [Melanie Vollmar]() \|

	### Label Scheme

	<details>

	<summary>View label scheme (20 labels for 1 components)</summary>

	\| Component \| Labels \|
	\| --- \| --- \|
	\| `ner` \| "bond_interaction", "chemical", "complex_assembly", "evidence", "experimental_method", "gene", "mutant", "oligomeric_state", "protein", "protein_state", "protein_type", "ptm", "residue_name", "residue_name_number", "residue_number", "residue_range", "site", "species", "structure_element", "taxonomy_domain" \|

	</details>

	### Scores for entity types
	\| entity type \| precision \| recall \| F1 \| sample number\|
	\| --- \| --- \| --- \| --- \| --- \|
	\| "bond_interaction" \| 0.94 \| 0.89 \| 0.91 \| 40 \|
	\| "chemical" \| 0.85 \| 0.91 \| 0.88 \| 597 \|
	\| "complex_assembly" \| 0.86 \| 0.89 \| 0.87 \| 183 \|
	\| "evidence" \| 0.82 \| 0.89 \| 0.85 \| 400 \|
	\| "experimental_method" \| 0.86 \| 0.84 \| 0.85 \| 307 \|
	\| "gene" \| 0.73 \| 0.86 \| 0.79 \| 26 \|
	\| "mutant" \| 0.88 \| 0.93 \| 0.90 \| 215 \|
	\| "oligomeric_state" \| 0.91 \| 0.96 \| 0.94 \| 117 \|
	\| "protein" \| 0.90 \| 0.94 \| 0.92 \| 758 \|
	\| "protein_state" \| 0.81 \| 0.86 \| 0.83 \| 543 \|
	\| "protein_type" \| 0.85 \| 0.85 \| 0.85 \| 277 \|
	\| "ptm" \| 0.66 \| 0.70 \| 0.68 \| 34 \|
	\| "residue_name" \| 0.93 \| 0.92\| 0.92\| 70 \|
	\| "residue_name_number" \| 0.95 \| 0.95\| 0.95 \| 257 \|
	\| "residue_number" \| 0.64 \| 0.88 \| 0.74 \| 44 \|
	\| "residue_range" \| 0.84 \| 0.76 \| 0.80 \| 31 \|
	\| "site" \| 0.86 \| 0.89 \| 0.88 \| 247 \|
	\| "species" \| 0.95 \| 0.97 \| 0.96 \| 76 \|
	\| "structure_element" \| 0.90 \| 0.92 \| 0.91 \| 749 \|
	\| "taxonomy_domain" \| 0.99 \| 0.98 \| 0.98 \| 82 \|

	---
	license: mit
	language:
	- en
	tags:
	- biology
	- protein structure
	- token classification
	widget:
	- text: "N-terminal acetylation (Nt-acetylation), carried out by N-terminal acetyltransferases (NATs), is a conserved and primary modification of nascent peptide chains. Naa60 (also named NatF) is a recently identified NAT found only in multicellular eukaryotes. This protein was shown to locate on the Golgi apparatus and mainly catalyze the Nt-acetylation of transmembrane proteins, and it also harbors lysine Nε-acetyltransferase (KAT) activity to catalyze the acetylation of lysine ε-amine. Here, we report the crystal structures of human Naa60 (hNaa60) in complex with Acetyl-Coenzyme A (Ac-CoA) or Coenzyme A (CoA). The hNaa60 protein contains an amphipathic helix following its GNAT domain that may contribute to Golgi localization of hNaa60, and the β7-β8 hairpin adopted different conformations in the hNaa60(1-242) and hNaa60(1-199) crystal structures. Remarkably, we found that the side-chain of Phe 34 can influence the position of the coenzyme, indicating a new regulatory mechanism involving enzyme, co-factor and substrates interactions. Moreover, structural comparison and biochemical studies indicated that Tyr 97 and His 138 are key residues for catalytic reaction and that a non-conserved β3-β4 long loop participates in the regulation of hNaa60 activity."
	model-index:
	- name: Bioformer8L-ProteinStructure-NER-v0.1_quantized
	results:
	- task:
	name: NER
	type: token-classification
	metrics:
	- name: NER Precision
	type: precision
	value: 0.90
	- name: NER Recall
	type: recall
	value: 0.92
	- name: NER F Score
	type: f_score
	value: 0.91
	---


	\| Feature \| Description \|
	\| --- \| --- \|
	\| Name \| `Bioformer8L-ProteinStructure-NER-v0.1_quantized` \|
	\| Default Pipeline \| `transformer`, `ner` \|
	\| Components \| `transformer`, `ner` \|
	\| Vectors \| 0 keys, 0 unique vectors (0 dimensions) \|
	\| Sources \| n/a \|
	\| License \| n/a \|
	\| Author \| [Melanie Vollmar]() \|

	### Label Scheme

	<details>

	<summary>View label scheme (20 labels for 1 components)</summary>

	\| Component \| Labels \|
	\| --- \| --- \|
	\| `ner` \| "bond_interaction", "chemical", "complex_assembly", "evidence", "experimental_method", "gene", "mutant", "oligomeric_state", "protein", "protein_state", "protein_type", "ptm", "residue_name", "residue_name_number", "residue_number", "residue_range", "site", "species", "structure_element", "taxonomy_domain" \|

	</details>

	### Scores for entity types
	\| entity type \| precision \| recall \| F1 \| sample number\|
	\| --- \| --- \| --- \| --- \| --- \|
	\| "bond_interaction" \| 0.94 \| 0.89 \| 0.91 \| 40 \|
	\| "chemical" \| 0.85 \| 0.91 \| 0.88 \| 597 \|
	\| "complex_assembly" \| 0.86 \| 0.89 \| 0.87 \| 183 \|
	\| "evidence" \| 0.82 \| 0.89 \| 0.85 \| 400 \|
	\| "experimental_method" \| 0.86 \| 0.84 \| 0.85 \| 307 \|
	\| "gene" \| 0.73 \| 0.86 \| 0.79 \| 26 \|
	\| "mutant" \| 0.88 \| 0.93 \| 0.90 \| 215 \|
	\| "oligomeric_state" \| 0.91 \| 0.96 \| 0.94 \| 117 \|
	\| "protein" \| 0.90 \| 0.94 \| 0.92 \| 758 \|
	\| "protein_state" \| 0.81 \| 0.86 \| 0.83 \| 543 \|
	\| "protein_type" \| 0.85 \| 0.85 \| 0.85 \| 277 \|
	\| "ptm" \| 0.66 \| 0.70 \| 0.68 \| 34 \|
	\| "residue_name" \| 0.93 \| 0.92\| 0.92\| 70 \|
	\| "residue_name_number" \| 0.95 \| 0.95\| 0.95 \| 257 \|
	\| "residue_number" \| 0.64 \| 0.88 \| 0.74 \| 44 \|
	\| "residue_range" \| 0.84 \| 0.76 \| 0.80 \| 31 \|
	\| "site" \| 0.86 \| 0.89 \| 0.88 \| 247 \|
	\| "species" \| 0.95 \| 0.97 \| 0.96 \| 76 \|
	\| "structure_element" \| 0.90 \| 0.92 \| 0.91 \| 749 \|
	\| "taxonomy_domain" \| 0.99 \| 0.98 \| 0.98 \| 82 \|