1n31 Citations

Snapshots of the cystine lyase C-DES during catalysis. Studies in solution and in the crystalline state.

Kaiser JT, Bruno S, Clausen T, Huber R, Schiaretti F, Mozzarelli A, Kessler D
J Biol Chem 278 357-65 (2003)
Cited: 18 times
EuropePMC logo PMID: 12386155

Abstract

The cystine lyase (C-DES) of Synechocystis is a pyridoxal-5'-phosphate-dependent enzyme distantly related to the family of NifS-like proteins. The crystal structure of an N-terminal modified variant has recently been determined. Herein, the reactivity of this enzyme variant was investigated spectroscopically in solution and in the crystalline state to follow the course of the reaction and to determine the catalytic mechanism on a molecular level. Using the stopped-flow technique, the reaction with the preferred substrate cystine was found to follow biphasic kinetics leading to the formation of absorbing species at 338 and 470 nm, attributed to the external aldimine and the alpha-aminoacrylate; the reaction with cysteine also exhibited biphasic behavior but only the external aldimine accumulated. The same reaction intermediates were formed in crystals as seen by polarized absorption microspectrophotometry, thus indicating that C-DES is catalytically competent in the crystalline state. The three-dimensional structure of the catalytically inactive mutant C-DES(K223A) in the presence of cystine showed the formation of an external aldimine species, in which two alternate conformations of the substrate were observed. The combined results allow a catalytic mechanism to be proposed involving interactions between cystine and the active site residues Arg-360, Arg-369, and Trp-251*; these residues reorient during the beta-elimination reaction, leading to the formation of a hydrophobic pocket that stabilizes the enolimine tautomer of the aminoacrylate and the cysteine persulfide product.

Articles - 1n31 mentioned but not cited (1)

  1. 1.2 Å resolution crystal structure of the periplasmic aminotransferase PvdN from Pseudomonas aeruginosa. Drake EJ, Gulick AM. Acta Crystallogr F Struct Biol Commun 72 403-408 (2016)


Reviews citing this publication (5)

  1. Structure, function, and formation of biological iron-sulfur clusters. Johnson DC, Dean DR, Smith AD, Johnson MK. Annu Rev Biochem 74 247-281 (2005)
  2. Enzymatic activation of sulfur for incorporation into biomolecules in prokaryotes. Kessler D. FEMS Microbiol Rev 30 825-840 (2006)
  3. Structural biology of enzymes of the thiamin biosynthesis pathway. Settembre E, Begley TP, Ealick SE. Curr Opin Struct Biol 13 739-747 (2003)
  4. Iron-sulfur cluster biosynthesis in photosynthetic organisms. Kessler D, Papenbrock J. Photosynth Res 86 391-407 (2005)
  5. The Energy Landscape of Human Serine Racemase. Raboni S, Marchetti M, Faggiano S, Campanini B, Bruno S, Marchesani F, Margiotta M, Mozzarelli A. Front Mol Biosci 5 112 (2018)

Articles citing this publication (12)

  1. Genomic and experimental evidence for multiple metabolic functions in the RidA/YjgF/YER057c/UK114 (Rid) protein family. Niehaus TD, Gerdes S, Hodge-Hanson K, Zhukov A, Cooper AJ, ElBadawi-Sidhu M, Fiehn O, Downs DM, Hanson AD. BMC Genomics 16 382 (2015)
  2. Exploring the pyridoxal 5'-phosphate-dependent enzymes. Mozzarelli A, Bettati S. Chem Rec 6 275-287 (2006)
  3. Fine tuning of the active site modulates specificity in the interaction of O-acetylserine sulfhydrylase isozymes with serine acetyltransferase. Spyrakis F, Felici P, Bayden AS, Salsi E, Miggiano R, Kellogg GE, Cozzini P, Cook PF, Mozzarelli A, Campanini B. Biochim Biophys Acta 1834 169-181 (2013)
  4. Targeting cystalysin, a virulence factor of treponema denticola-supported periodontitis. Spyrakis F, Cellini B, Bruno S, Benedetti P, Carosati E, Cruciani G, Micheli F, Felici A, Cozzini P, Kellogg GE, Voltattorni CB, Mozzarelli A. ChemMedChem 9 1501-1511 (2014)
  5. Biochemical and computational approaches to improve the clinical treatment of dopa decarboxylase-related diseases: an overview. Cellini B, Montioli R, Oppici E, Voltattorni CB. Open Biochem J 6 131-138 (2012)
  6. Direct observation of intermediates in the SufS cysteine desulfurase reaction reveals functional roles of conserved active-site residues. Blahut M, Wise CE, Bruno MR, Dong G, Makris TM, Frantom PA, Dunkle JA, Outten FW. J Biol Chem 294 12444-12458 (2019)
  7. Regulation of human serine racemase activity and dynamics by halides, ATP and malonate. Marchetti M, Bruno S, Campanini B, Bettati S, Peracchi A, Mozzarelli A. Amino Acids 47 163-173 (2015)
  8. Role of active-site residues Tyr55 and Tyr114 in catalysis and substrate specificity of Corynebacterium diphtheriae C-S lyase. Astegno A, Allegrini A, Piccoli S, Giorgetti A, Dominici P. Proteins 83 78-90 (2015)
  9. Slr0077 of Synechocystis has cysteine desulfurase as well as cystine lyase activity. Kessler D. Biochem Biophys Res Commun 320 571-577 (2004)
  10. Biochemical discrimination between selenium and sulfur 2: mechanistic investigation of the selenium specificity of human selenocysteine lyase. Johansson AL, Collins R, Arnér ES, Brzezinski P, Högbom M. PLoS One 7 e30528 (2012)
  11. Structural insights into catalysis by βC-S lyase from Streptococcus anginosus. Kezuka Y, Yoshida Y, Nonaka T. Proteins 80 2447-2458 (2012)
  12. The ABCB7-Like Transporter PexA in Rhodobacter capsulatus Is Involved in the Translocation of Reactive Sulfur Species. Riedel S, Siemiatkowska B, Watanabe M, Müller CS, Schünemann V, Hoefgen R, Leimkühler S. Front Microbiol 10 406 (2019)


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