2hu5 Citations

The acylaminoacyl peptidase from Aeropyrum pernix K1 thought to be an exopeptidase displays endopeptidase activity.

Kiss AL, Hornung B, Rádi K, Gengeliczki Z, Sztáray B, Juhász T, Szeltner Z, Harmat V, Polgár L
J Mol Biol 368 509-20 (2007)
Related entries: 1ve6, 1ve7, 2hu7, 2hu8

Cited: 21 times
EuropePMC logo PMID: 17350041

Abstract

Mammalian acylaminoacyl peptidase, a member of the prolyl oligopeptidase family of serine peptidases, is an exopeptidase, which removes acylated amino acid residues from the N terminus of oligopeptides. We have investigated the kinetics and inhibitor binding of the orthologous acylaminoacyl peptidase from the thermophile Aeropyrum pernix K1 (ApAAP). Complex pH-rate profiles were found with charged substrates, indicating a strong electrostatic effect in the surroundings of the active site. Unexpectedly, we have found that oligopeptides can be hydrolysed beyond the N-terminal peptide bond, demonstrating that ApAAP exhibits endopeptidase activity. It was thought that the enzyme is specific for hydrophobic amino acids, in particular phenylalanine, in accord with the non-polar S1 subsite of ApAAP. However, cleavage after an Ala residue contradicted this notion and demonstrated that P1 residues of different nature may bind to the S1 subsite depending on the remaining peptide residues. The crystal structures of the complexes formed between the enzyme and product-like inhibitors identified the oxyanion-binding site unambiguously and demonstrated that the phenylalanine ring of the P1 peptide residue assumes a position different from that established in a previous study, using 4-nitrophenylphosphate. We have found that the substrate-binding site extends beyond the S2 subsite, being capable of binding peptides with a longer N terminus. The S2 subsite displays a non-polar character, which is unique among the enzymes of this family. The S3 site was identified as a hydrophobic region that does not form hydrogen bonds with the inhibitor P3 residue. The enzyme-inhibitor complexes revealed that, upon ligand-binding, the S1 subsite undergoes significant conformational changes, demonstrating the plasticity of the specificity site.

Articles - 2hu5 mentioned but not cited (5)

  1. Structure and catalysis of acylaminoacyl peptidase: closed and open subunits of a dimer oligopeptidase. Harmat V, Domokos K, Menyhárd DK, Palló A, Szeltner Z, Szamosi I, Beke-Somfai T, Náray-Szabó G, Polgár L. J Biol Chem 286 1987-1998 (2011)
  2. Predicting binding sites from unbound versus bound protein structures. Clark JJ, Orban ZJ, Carlson HA. Sci Rep 10 15856 (2020)
  3. Enhancing subtilisin thermostability through a modified normalized B-factor analysis and loop-grafting strategy. Tang H, Shi K, Shi C, Aihara H, Zhang J, Du G. J Biol Chem 294 18398-18407 (2019)
  4. Prolyl endopeptidase-like is a (thio)esterase involved in mitochondrial respiratory chain function. Rosier K, McDevitt MT, Smet J, Floyd BJ, Verschoore M, Marcaida MJ, Bingman CA, Lemmens I, Dal Peraro M, Tavernier J, Cravatt BF, Gounko NV, Vints K, Monnens Y, Bhalla K, Aerts L, Rashan EH, Vanlander AV, Van Coster R, Régal L, Pagliarini DJ, Creemers JWM. iScience 24 103460 (2021)
  5. Structural characterization of a prolyl aminodipeptidase (PepX) from Lactobacillus helveticus. Ojennus DD, Bratt NJ, Jones KL, Juers DH. Acta Crystallogr F Struct Biol Commun 75 625-633 (2019)


Reviews citing this publication (1)

  1. Dipeptidyl-peptidases: Key enzymes producing entry forms of extracellular proteins in asaccharolytic periodontopathic bacterium Porphyromonas gingivalis. Nemoto TK, Ohara Nemoto Y. Mol Oral Microbiol 36 145-156 (2021)

Articles citing this publication (15)

  1. A novel class of bifunctional acylpeptide hydrolases--potential role in the antioxidant defense systems of the Antarctic fish Trematomus bernacchii. Gogliettino M, Riccio A, Balestrieri M, Cocca E, Facchiano A, D'Arco TM, Tesoro C, Rossi M, Palmieri G. FEBS J 281 401-415 (2014)
  2. Alpha/beta-hydrolases: A unique structural motif coordinates catalytic acid residue in 40 protein fold families. Dimitriou PS, Denesyuk A, Takahashi S, Yamashita S, Johnson MS, Nakayama T, Denessiouk K. Proteins 85 1845-1855 (2017)
  3. A self-compartmentalizing hexamer serine protease from Pyrococcus horikoshii: substrate selection achieved through multimerization. Menyhárd DK, Kiss-Szemán A, Tichy-Rács É, Hornung B, Rádi K, Szeltner Z, Domokos K, Szamosi I, Náray-Szabó G, Polgár L, Harmat V. J Biol Chem 288 17884-17894 (2013)
  4. Structural and kinetic contributions of the oxyanion binding site to the catalytic activity of acylaminoacyl peptidase. Kiss AL, Palló A, Náray-Szabó G, Harmat V, Polgár L. J Struct Biol 162 312-323 (2008)
  5. A Porphyromonas gingivalis Periplasmic Novel Exopeptidase, Acylpeptidyl Oligopeptidase, Releases N-Acylated Di- and Tripeptides from Oligopeptides. Nemoto TK, Ohara-Nemoto Y, Bezerra GA, Shimoyama Y, Kimura S. J Biol Chem 291 5913-5925 (2016)
  6. A novel class of protease targets of phosphatidylethanolamine-binding proteins (PEBP): a study of the acylpeptide hydrolase and the PEBP inhibitor from the archaeon Sulfolobus solfataricus. Palmieri G, Langella E, Gogliettino M, Saviano M, Pocsfalvi G, Rossi M. Mol Biosyst 6 2498-2507 (2010)
  7. Catalytically distinct states captured in a crystal lattice: the substrate-bound and scavenger states of acylaminoacyl peptidase and their implications for functionality. Menyhárd DK, Orgován Z, Szeltner Z, Szamosi I, Harmat V. Acta Crystallogr D Biol Crystallogr 71 461-472 (2015)
  8. Identification and characterisation of a novel acylpeptide hydrolase from Sulfolobus solfataricus: structural and functional insights. Gogliettino M, Balestrieri M, Cocca E, Mucerino S, Rossi M, Petrillo M, Mazzella E, Palmieri G. PLoS One 7 e37921 (2012)
  9. Proteolytic systems of archaea: slicing, dicing, and mincing in the extreme. Maupin-Furlow JA. Emerg Top Life Sci 2 561-580 (2018)
  10. EstDZ3: A New Esterolytic Enzyme Exhibiting Remarkable Thermostability. Zarafeta D, Szabo Z, Moschidi D, Phan H, Chrysina ED, Peng X, Ingham CJ, Kolisis FN, Skretas G. Front Microbiol 7 1779 (2016)
  11. Selective inhibition of acylpeptide hydrolase in SAOS-2 osteosarcoma cells: is this enzyme a viable anticancer target? Gogliettino M, Cocca E, Sandomenico A, Gratino L, Iaccarino E, Calvanese L, Rossi M, Palmieri G. Mol Biol Rep 48 1505-1519 (2021)
  12. Computational study of the competitive binding of valproic acid glucuronide and carbapenem antibiotics to acylpeptide hydrolase. Ishikawa T, Otaki H, Mizuta S, Kuriyama M, Onomura O, Higuchi N, Nakashima MN, Nakashima M, Ohyama K. Drug Metab Pharmacokinet 32 201-207 (2017)
  13. Cryo-EM structure of acylpeptide hydrolase reveals substrate selection by multimerization and a multi-state serine-protease triad. Kiss-Szemán AJ, Stráner P, Jákli I, Hosogi N, Harmat V, Menyhárd DK, Perczel A. Chem Sci 13 7132-7142 (2022)
  14. A deeply conserved protease, acylamino acid-releasing enzyme (AARE), acts in ageing in Physcomitrella and Arabidopsis. Hoernstein SNW, Özdemir B, van Gessel N, Miniera AA, Rogalla von Bieberstein B, Nilges L, Schweikert Farinha J, Komoll R, Glauz S, Weckerle T, Scherzinger F, Rodriguez-Franco M, Müller-Schüssele SJ, Reski R. Commun Biol 6 61 (2023)
  15. A strategy to recover a poor-quality ligase product. Del Prete S, Gogliettino M, Palmieri G, Cocca E. J Biol Methods 10 jbm-10-e99010007 (2023)


Related citations provided by authors (1)

  1. Crystal structure of an acylpeptide hydrolase/esterase from Aeropyrum pernix K1.. Bartlam M, Wang G, Yang H, Gao R, Zhao X, Xie G, Cao S, Feng Y, Rao Z Structure 12 1481-8 (2004)

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