Snapshots of PLP‐substrate and PLP‐product external aldimines as intermediates in two types of cysteine desulfurase enzymes

Snapshots of PLP‐substrate and PLP‐product external aldimines as intermediates in two types of cysteine desulfurase enzymes

Cysteine desulfurase enzymes catalyze sulfur mobilization from l‐cysteine to sulfur‐containing biomolecules such as iron‐sulfur (Fe‐S) clusters and thio‐tRNAs. The enzymes utilize the cofactor pyridoxal‐5'‐phosphate (PLP), which forms the external substrate‐ and product‐aldimines and ketimines...

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Veröffentlicht in:The FEBS journal 2020-03, Vol.287 (6), p.1138-1154
Hauptverfasser: Nakamura, Ryosuke, Hikita, Masahide, Ogawa, Shoko, Takahashi, Yasuhiro, Fujishiro, Takashi
Format: Artikel
Sprache:eng
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Bacillus subtilis - enzymology
Biocatalysis
Biochemistry & Molecular Biology
Biomolecules
Biosynthesis
Carbon-Sulfur Lyases - chemistry
Carbon-Sulfur Lyases - metabolism
Catalysis
Crystallography
Crystallography, X-Ray
Cysteine
cysteine desulfurase
Data bases
enzyme catalysis
Enzymes
Helicobacter pylori - enzymology
Histidine
Imines
Imines - chemistry
Imines - metabolism
Intermediates
Iron
Life Sciences & Biomedicine
Models, Molecular
Pyridoxal Phosphate - chemistry
Pyridoxal Phosphate - metabolism
reaction intermediates
Science & Technology
Substrates
Sulfur
X‐ray crystallography
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container_issue 6
container_start_page 1138
container_title The FEBS journal
container_volume 287
creator Nakamura, Ryosuke
Hikita, Masahide
Ogawa, Shoko
Takahashi, Yasuhiro
Fujishiro, Takashi
description Cysteine desulfurase enzymes catalyze sulfur mobilization from l‐cysteine to sulfur‐containing biomolecules such as iron‐sulfur (Fe‐S) clusters and thio‐tRNAs. The enzymes utilize the cofactor pyridoxal‐5'‐phosphate (PLP), which forms the external substrate‐ and product‐aldimines and ketimines during catalysis and are grouped into two types (I and II) based on their different catalytic loops. To clarify the structure‐based catalytic mechanisms for each group, we determined the structures of the external substrate‐ and product‐aldimines as catalytic intermediates of NifS (type I) and SufS (type II) that are involved in Fe‐S cluster biosynthesis using X‐ray crystallographic snapshot analysis. As a common intermediate structure, the thiol group of the PLP‐l‐cysteine external aldimine is stabilized by the conserved histidine adjacent to PLP through a polar interaction. This interaction makes the thiol group orientated for subsequent nucleophilic attack by a conserved cysteine residue on the catalytic loop in the state of PLP‐l‐cysteine ketimine, which is formed from the PLP‐l‐cysteine aldimine. Unlike the intermediates, structural changes of the loops were different between the type I and II enzymes. In the type I enzyme, conformational and topological change of the loop is necessary for nucleophilic attack by the cysteine. In contrast, the loop in type II cysteine desulfurase enzymes showed no large conformational change; rather, it might possibly orient the thiol group of the catalytic cysteine for nucleophilic attack toward PLP‐l‐cysteine. The present structures allow a revision of the catalytic mechanism and may provide a clue for consideration of enzyme function, structural diversity, and evolution of cysteine desulfurase enzymes. Database Structural data are available in PDB database under the accession numbers 5WT2, 5WT4, 5ZSP, 5ZST, 5ZS9, 5ZSK, 5ZSO, 6KFZ, 6KG0, and 6KG1. Catalytic reaction intermediates of two distinct types of PLP‐dependent cysteine desulfurase enzymes, NifS (type I) and SufS (type II), involved in iron‐sulfur cluster biosynthesis were structurally captured by X‐ray crystallographic snapshot analysis. The present data confirmed that NifS and SufS utilized the common PLP‐external aldimine intermediates. Also, it was demonstrated that they used their characteristic catalytic loops in different ways during NifS and SufS catalysis.
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Unlike the intermediates, structural changes of the loops were different between the type I and II enzymes. In the type I enzyme, conformational and topological change of the loop is necessary for nucleophilic attack by the cysteine. In contrast, the loop in type II cysteine desulfurase enzymes showed no large conformational change; rather, it might possibly orient the thiol group of the catalytic cysteine for nucleophilic attack toward PLP‐l‐cysteine. The present structures allow a revision of the catalytic mechanism and may provide a clue for consideration of enzyme function, structural diversity, and evolution of cysteine desulfurase enzymes. Database Structural data are available in PDB database under the accession numbers 5WT2, 5WT4, 5ZSP, 5ZST, 5ZS9, 5ZSK, 5ZSO, 6KFZ, 6KG0, and 6KG1. 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The enzymes utilize the cofactor pyridoxal‐5'‐phosphate (PLP), which forms the external substrate‐ and product‐aldimines and ketimines during catalysis and are grouped into two types (I and II) based on their different catalytic loops. To clarify the structure‐based catalytic mechanisms for each group, we determined the structures of the external substrate‐ and product‐aldimines as catalytic intermediates of NifS (type I) and SufS (type II) that are involved in Fe‐S cluster biosynthesis using X‐ray crystallographic snapshot analysis. As a common intermediate structure, the thiol group of the PLP‐l‐cysteine external aldimine is stabilized by the conserved histidine adjacent to PLP through a polar interaction. This interaction makes the thiol group orientated for subsequent nucleophilic attack by a conserved cysteine residue on the catalytic loop in the state of PLP‐l‐cysteine ketimine, which is formed from the PLP‐l‐cysteine aldimine. Unlike the intermediates, structural changes of the loops were different between the type I and II enzymes. In the type I enzyme, conformational and topological change of the loop is necessary for nucleophilic attack by the cysteine. In contrast, the loop in type II cysteine desulfurase enzymes showed no large conformational change; rather, it might possibly orient the thiol group of the catalytic cysteine for nucleophilic attack toward PLP‐l‐cysteine. The present structures allow a revision of the catalytic mechanism and may provide a clue for consideration of enzyme function, structural diversity, and evolution of cysteine desulfurase enzymes. Database Structural data are available in PDB database under the accession numbers 5WT2, 5WT4, 5ZSP, 5ZST, 5ZS9, 5ZSK, 5ZSO, 6KFZ, 6KG0, and 6KG1. Catalytic reaction intermediates of two distinct types of PLP‐dependent cysteine desulfurase enzymes, NifS (type I) and SufS (type II), involved in iron‐sulfur cluster biosynthesis were structurally captured by X‐ray crystallographic snapshot analysis. The present data confirmed that NifS and SufS utilized the common PLP‐external aldimine intermediates. 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The enzymes utilize the cofactor pyridoxal‐5'‐phosphate (PLP), which forms the external substrate‐ and product‐aldimines and ketimines during catalysis and are grouped into two types (I and II) based on their different catalytic loops. To clarify the structure‐based catalytic mechanisms for each group, we determined the structures of the external substrate‐ and product‐aldimines as catalytic intermediates of NifS (type I) and SufS (type II) that are involved in Fe‐S cluster biosynthesis using X‐ray crystallographic snapshot analysis. As a common intermediate structure, the thiol group of the PLP‐l‐cysteine external aldimine is stabilized by the conserved histidine adjacent to PLP through a polar interaction. This interaction makes the thiol group orientated for subsequent nucleophilic attack by a conserved cysteine residue on the catalytic loop in the state of PLP‐l‐cysteine ketimine, which is formed from the PLP‐l‐cysteine aldimine. Unlike the intermediates, structural changes of the loops were different between the type I and II enzymes. In the type I enzyme, conformational and topological change of the loop is necessary for nucleophilic attack by the cysteine. In contrast, the loop in type II cysteine desulfurase enzymes showed no large conformational change; rather, it might possibly orient the thiol group of the catalytic cysteine for nucleophilic attack toward PLP‐l‐cysteine. The present structures allow a revision of the catalytic mechanism and may provide a clue for consideration of enzyme function, structural diversity, and evolution of cysteine desulfurase enzymes. Database Structural data are available in PDB database under the accession numbers 5WT2, 5WT4, 5ZSP, 5ZST, 5ZS9, 5ZSK, 5ZSO, 6KFZ, 6KG0, and 6KG1. Catalytic reaction intermediates of two distinct types of PLP‐dependent cysteine desulfurase enzymes, NifS (type I) and SufS (type II), involved in iron‐sulfur cluster biosynthesis were structurally captured by X‐ray crystallographic snapshot analysis. The present data confirmed that NifS and SufS utilized the common PLP‐external aldimine intermediates. Also, it was demonstrated that they used their characteristic catalytic loops in different ways during NifS and SufS catalysis.</abstract><cop>HOBOKEN</cop><pub>Wiley</pub><pmid>31587510</pmid><doi>10.1111/febs.15081</doi><tpages>17</tpages><orcidid>https://orcid.org/0000-0001-7967-8380</orcidid><orcidid>https://orcid.org/0000-0002-1409-3784</orcidid><orcidid>https://orcid.org/0000-0002-1797-2223</orcidid><oa>free_for_read</oa></addata></record>
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subjects Bacillus subtilis - enzymology
Biocatalysis
Biochemistry & Molecular Biology
Biomolecules
Biosynthesis
Carbon-Sulfur Lyases - chemistry
Carbon-Sulfur Lyases - metabolism
Catalysis
Crystallography
Crystallography, X-Ray
Cysteine
cysteine desulfurase
Data bases
enzyme catalysis
Enzymes
Helicobacter pylori - enzymology
Histidine
Imines
Imines - chemistry
Imines - metabolism
Intermediates
Iron
Life Sciences & Biomedicine
Models, Molecular
Pyridoxal Phosphate - chemistry
Pyridoxal Phosphate - metabolism
reaction intermediates
Science & Technology
Substrates
Sulfur
X‐ray crystallography
title Snapshots of PLP‐substrate and PLP‐product external aldimines as intermediates in two types of cysteine desulfurase enzymes
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