2x95 Citations

High-resolution crystal structures of Drosophila melanogaster angiotensin-converting enzyme in complex with novel inhibitors and antihypertensive drugs.

Akif M, Georgiadis D, Mahajan A, Dive V, Sturrock ED, Isaac RE, Acharya KR
J Mol Biol 400 502-17 (2010)
Related entries: 2x8y, 2x8z, 2x90, 2x91, 2x92, 2x93, 2x94, 2x96, 2x97

Cited: 33 times
EuropePMC logo PMID: 20488190

Abstract

Angiotensin I-converting enzyme (ACE), one of the central components of the renin-angiotensin system, is a key therapeutic target for the treatment of hypertension and cardiovascular disorders. Human somatic ACE (sACE) has two homologous domains (N and C). The N- and C-domain catalytic sites have different activities toward various substrates. Moreover, some of the undesirable side effects of the currently available and widely used ACE inhibitors may arise from their targeting both domains leading to defects in other pathways. In addition, structural studies have shown that although both these domains have much in common at the inhibitor binding site, there are significant differences and these are greater at the peptide binding sites than regions distal to the active site. As a model system, we have used an ACE homologue from Drosophila melanogaster (AnCE, a single domain protein with ACE activity) to study ACE inhibitor binding. In an extensive study, we present high-resolution structures for native AnCE and in complex with six known antihypertensive drugs, a novel C-domain sACE specific inhibitor, lisW-S, and two sACE domain-specific phosphinic peptidyl inhibitors, RXPA380 and RXP407 (i.e., nine structures). These structures show detailed binding features of the inhibitors and highlight subtle changes in the orientation of side chains at different binding pockets in the active site in comparison with the active site of N- and C-domains of sACE. This study provides information about the structure-activity relationships that could be utilized for designing new inhibitors with improved domain selectivity for sACE.

Reviews citing this publication (7)

  1. How to design a potent, specific, and stable angiotensin-converting enzyme inhibitor. Regulska K, Stanisz B, Regulski M, Murias M. Drug Discov. Today 19 1731-1743 (2014)
  2. Control of aging by the renin-angiotensin system: a review of C. elegans, Drosophila, and mammals. Egan BM, Scharf A, Pohl F, Kornfeld K. Front Pharmacol 13 938650 (2022)
  3. Small molecule angiotensin converting enzyme inhibitors: A medicinal chemistry perspective. Zheng W, Tian E, Liu Z, Zhou C, Yang P, Tian K, Liao W, Li J, Ren C. Front Pharmacol 13 968104 (2022)
  4. ACE and ACE2: insights from Drosophila and implications for COVID-19. Herrera P, Cauchi RJ. Heliyon 7 e08555 (2021)
  5. ACE2 and ACE: structure-based insights into mechanism, regulation and receptor recognition by SARS-CoV. Lubbe L, Cozier GE, Oosthuizen D, Acharya KR, Sturrock ED. Clin Sci (Lond) 134 2851-2871 (2020)
  6. Biochemical exploration of β-lactamase inhibitors. Arer V, Kar D. Front Genet 13 1060736 (2022)
  7. Phosphinic Peptides as Tool Compounds for the Study of Pharmacologically Relevant Zn-Metalloproteases. Georgiadis D, Skoulikas N, Papakyriakou A, Stratikos E. ACS Pharmacol Transl Sci 5 1228-1253 (2022)

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  1. Remarkable potential of the α-aminophosphonate/phosphinate structural motif in medicinal chemistry. Mucha A, Kafarski P, Berlicki Ł. J. Med. Chem. 54 5955-5980 (2011)
  2. The N domain of human angiotensin-I-converting enzyme: the role of N-glycosylation and the crystal structure in complex with an N domain-specific phosphinic inhibitor, RXP407. Anthony CS, Corradi HR, Schwager SL, Redelinghuys P, Georgiadis D, Dive V, Acharya KR, Sturrock ED. J. Biol. Chem. 285 35685-35693 (2010)
  3. Inhibition mechanism and model of an angiotensin I-converting enzyme (ACE)-inhibitory hexapeptide from yeast (Saccharomyces cerevisiae). Ni H, Li L, Liu G, Hu SQ. PLoS ONE 7 e37077 (2012)
  4. Venom peptide analysis of Vipera ammodytes meridionalis (Viperinae) and Bothrops jararacussu (Crotalinae) demonstrates subfamily-specificity of the peptidome in the family Viperidae. Munawar A, Trusch M, Georgieva D, Spencer P, Frochaux V, Harder S, Arni RK, Duhalov D, Genov N, Schlüter H, Betzel C. Mol Biosyst 7 3298-3307 (2011)
  5. The potential role of procyanidin as a therapeutic agent against SARS-CoV-2: a text mining, molecular docking and molecular dynamics simulation approach. Maroli N, Bhasuran B, Natarajan J, Kolandaivel P. J Biomol Struct Dyn 40 1230-1245 (2022)
  6. Development of flexible electrochemical impedance spectroscopy-based biosensing platform for rapid screening of SARS-CoV-2 inhibitors. Kiew LV, Chang CY, Huang SY, Wang PW, Heh CH, Liu CT, Cheng CH, Lu YX, Chen YC, Huang YX, Chang SY, Tsai HY, Kung YA, Huang PN, Hsu MH, Leo BF, Foo YY, Su CH, Hsu KC, Huang PH, Ng CJ, Kamarulzaman A, Yuan CJ, Shieh DB, Shih SR, Chung LY, Chang CC. Biosens Bioelectron 183 113213 (2021)
  7. Inhibitor and substrate binding by angiotensin-converting enzyme: quantum mechanical/molecular mechanical molecular dynamics studies. Wang X, Wu S, Xu D, Xie D, Guo H. J Chem Inf Model 51 1074-1082 (2011)
  8. A new QSAR model, for angiotensin I-converting enzyme inhibitory oligopeptides. Sagardia I, Roa-Ureta RH, Bald C. Food Chem 136 1370-1376 (2013)
  9. ACE for all - a molecular perspective. Harrison C, Acharya KR. J Cell Commun Signal 8 195-210 (2014)
  10. Crystal structures of highly specific phosphinic tripeptide enantiomers in complex with the angiotensin-I converting enzyme. Masuyer G, Akif M, Czarny B, Beau F, Schwager SL, Sturrock ED, Isaac RE, Dive V, Acharya KR. FEBS J. 281 943-956 (2014)
  11. A Proline-Based Tectons and Supramolecular Synthons for Drug Design 2.0: A Case Study of ACEI. Bojarska J, Remko M, Breza M, Madura I, Fruziński A, Wolf WM. Pharmaceuticals (Basel) 13 E338 (2020)
  12. Elapid snake venom analyses show the specificity of the peptide composition at the level of genera Naja and Notechis. Munawar A, Trusch M, Georgieva D, Hildebrand D, Kwiatkowski M, Behnken H, Harder S, Arni R, Spencer P, Schlüter H, Betzel C. Toxins (Basel) 6 850-868 (2014)
  13. Structural characterization of angiotensin I-converting enzyme in complex with a selenium analogue of captopril. Akif M, Masuyer G, Schwager SL, Bhuyan BJ, Mugesh G, Isaac RE, Sturrock ED, Acharya KR. FEBS J. 278 3644-3650 (2011)
  14. Antioxidant activity of peptide-based angiotensin converting enzyme inhibitors. Bhuyan BJ, Mugesh G. Org. Biomol. Chem. 10 2237-2247 (2012)
  15. Absence of cell surface expression of human ACE leads to perinatal death. Michaud A, Acharya KR, Masuyer G, Quenech'du N, Gribouval O, Morinière V, Gubler MC, Corvol P. Hum. Mol. Genet. 23 1479-1491 (2014)
  16. Effect of peptide-based captopril analogues on angiotensin converting enzyme activity and peroxynitrite-mediated tyrosine nitration. Bhuyan BJ, Mugesh G. Org. Biomol. Chem. 9 5185-5192 (2011)
  17. Structural basis of peptide recognition by the angiotensin-1 converting enzyme homologue AnCE from Drosophila melanogaster. Akif M, Masuyer G, Bingham RJ, Sturrock ED, Isaac RE, Acharya KR. FEBS J. 279 4525-4534 (2012)
  18. Losartan as an ACE inhibitor: a description of the mechanism of action through quantum biochemistry. Bezerra EM, de Alvarenga ÉC, Dos Santos RP, de Sousa JS, Fulco UL, Freire VN, Albuquerque EL, da Costa RF. RSC Adv 12 28395-28404 (2022)
  19. Site-specific indolation of proline-based peptides via copper(II)-catalyzed oxidative coupling of tertiary amine N-oxides. Wu X, Zhang D, Zhou S, Gao F, Liu H. Chem. Commun. (Camb.) 51 12571-12573 (2015)
  20. A UPLC-DAD-Based Bio-Screening Assay for the Evaluation of the Angiotensin Converting Enzyme Inhibitory Potential of Plant Extracts and Compounds: Pyrroquinazoline Alkaloids from Adhatoda vasica as a Case Study. Tehreem S, Rahman S, Bhatti MS, Uddin R, Khan MN, Tauseef S, El-Seedi HR, Bin Muhsinah A, Uddin J, Musharraf SG. Molecules 26 6971 (2021)
  21. A new high-resolution crystal structure of the Drosophila melanogaster angiotensin converting enzyme homologue, AnCE. Harrison C, Acharya KR. FEBS Open Bio 5 661-667 (2015)
  22. Angiotensin-converting enzyme Ance is cooperatively regulated by Mad and Pannier in Drosophila imaginal discs. Kim AR, Choi EB, Kim MY, Choi KW. Sci Rep 7 13174 (2017)
  23. Design and synthesis of novel anti-urease imidazothiazole derivatives with promising antibacterial activity against Helicobacter pylori. Shahin AI, Zaib S, Zaraei SO, Kedia RA, Anbar HS, Younas MT, Al-Tel TH, Khoder G, El-Gamal MI. PLoS One 18 e0286684 (2023)
  24. Genome-Wide Analysis in Drosophila Reveals the Genetic Basis of Variation in Age-Specific Physical Performance and Response to ACE Inhibition. Gabrawy MM, Khosravian N, Morcos GS, Morozova TV, Jezek M, Walston JD, Huang W, Abadir PM, Leips J. Genes (Basel) 13 143 (2022)
  25. Lisinopril Preserves Physical Resilience and Extends Life Span in a Genotype-Specific Manner in Drosophila melanogaster. Gabrawy MM, Campbell S, Carbone MA, Morozova TV, Arya GH, Turlapati LB, Walston JD, Starz-Gaiano M, Everett L, Mackay TFC, Leips J, Abadir PM. J Gerontol A Biol Sci Med Sci 74 1844-1852 (2019)
  26. Memory of Chirality as a Prominent Pathway for the Synthesis of Natural Products through Chiral Intermediates. Hardwick T, Ahmed N. ChemistryOpen 7 484-487 (2018)


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