Browsing by Author "Natesh, Ramanathan"

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    Structural details on the binding of antihypertensive drugs captopril and enalaprilat to human testicular angiotensin I-converting enzyme
    (American Chemical Society, 2004) Natesh, Ramanathan; Schwager, Sylva L U; Evans, Hazel R; Sturrock, Edward D; Acharya, K Ravi
    Angiotensin converting enzyme (ACE) plays a critical role in the circulating or endocrine renin−angiotensin system (RAS) as well as the local regulation that exists in tissues such as the myocardium and skeletal muscle. Here we report the high-resolution crystal structures of testis ACE (tACE) in complex with the first successfully designed ACE inhibitor captopril and enalaprilat, the Phe-Ala-Pro analogue. We have compared these structures with the recently reported structure of a tACE−lisinopril complex [Natesh et al. (2003) Nature 421, 551−554]. The analyses reveal that all three inhibitors make direct interactions with the catalytic Zn2+ ion at the active site of the enzyme:  the thiol group of captopril and the carboxylate group of enalaprilat and lisinopril. Subtle differences are also observed at other regions of the binding pocket. These are compared with N-domain models and discussed with reference to published biochemical data. The chloride coordination geometries of the three structures are discussed and compared with other ACE analogues. It is anticipated that the molecular details provided by these structures will be used to improve the binding and/or the design of new, more potent domain-specific inhibitors of ACE that could serve as new generation antihypertensive drugs.
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    Structure of testis ACE glycosylation mutants and evidence for conserved domain movement
    (American Chemical Society, 2006) Watermeyer, Jean M; Sewell, Trevor B; Schwager, Sylva L; Natesh, Ramanathan; Corradi, Hazel R; Acharya, Ravi K; Sturrock, Edward D
    Human angiotensin-converting enzyme is an important drug target for which little structural information has been available until recent years. The slow progress in obtaining a crystal structure was due to the problem of surface glycosylation, a difficulty that has thus far been overcome by the use of a glucosidase-1 inhibitor in the tissue culture medium. However, the prohibitive cost of these inhibitors and incomplete glucosidase inhibition makes alternative routes to minimizing the N-glycan heterogeneity desirable. Here, glycosylation in the testis isoform (tACE) has been reduced by Asn-Gln point mutations at N-glycosylation sites, and the crystal structures of mutants having two and four intact sites have been solved to 2.0 Å and 2.8 Å, respectively. Both mutants show close structural identity with the wild-type. A hinge mechanism is proposed for substrate entry into the active cleft, based on homology to human ACE2 at the levels of sequence and flexibility. This is supported by normal-mode analysis that reveals intrinsic flexibility about the active site of tACE. Subdomain II, containing bound chloride and zinc ions, is found to have greater stability than subdomain I in the structures of three ACE homologues. Crystallizable glycosylation mutants open up new possibilities for cocrystallization studies to aid the design of novel ACE inhibitors.