1. The structure of testis angiotensin-converting enzyme in complex with the C domain-specific inhibitor RXPA380
Hazel R Corradi, Itai Chitapi, B Trevor Sewell, Dimitris Georgiadis, Vincent Dive, Edward D Sturrock, K Ravi Acharya Biochemistry. 2007 May 8;46(18):5473-8. doi: 10.1021/bi700275e. Epub 2007 Apr 18.
Angiotensin I-converting enzyme (ACE) is central to the regulation of the renin-angiotensin system and is a key therapeutic target for combating hypertension and related cardiovascular diseases. Currently available drugs bind both active sites of its two homologous domains, although it is now understood that these domains function differently in vivo. The recently solved crystal structures of both domains (N and C) open the door to new domain-specific inhibitor design, taking advantage of the differences between these two large active sites. Here we present the first crystal structure at a resolution of 2.25 A of testis ACE (identical to the C domain of somatic ACE) with the highly C-domain-specific phosphinic inhibitor, RXPA380. Testis ACE retains the same conformation as seen in previously determined inhibitor complexes, but the RXPA380 central backbone conformation is more similar to that seen for the inhibitor captopril than enalaprilat. The RXPA380 molecule occupies more subsites of the testis ACE active site than the previously determined inhibitors and possesses bulky moieties that extend into the S2' and S2 subsites. Thus the high affinity of RXPA380 for the testis ACE/somatic ACE C domain is explained by the interaction of these bulky moieties with residues unique to these domains, specifically Phe 391, Val 379, and Val 380, that are not found in the N domain. The characterization of the extended active site and the binding of a potent C-domain-selective inhibitor provide the first structural data for the design of truly domain-specific pharmacophores.
2. Combined use of selective inhibitors and fluorogenic substrates to study the specificity of somatic wild-type angiotensin-converting enzyme
Nicolas D Jullien, Philippe Cuniasse, Dimitris Georgiadis, Athanasios Yiotakis, Vincent Dive FEBS J. 2006 Apr;273(8):1772-81. doi: 10.1111/j.1742-4658.2006.05196.x.
Somatic angiotensin-converting enzyme (ACE) contains two homologous domains, each bearing a functional active site. Studies on the selectivity of these ACE domains towards either substrates or inhibitors have mostly relied on the use of mutants or isolated domains of ACE. To determine directly the selectivity properties of each ACE domain, working with wild-type enzyme, we developed an approach based on the combined use of N-domain-selective and C-domain-selective ACE inhibitors and fluorogenic substrates. With this approach, marked differences in substrate selectivity were revealed between rat, mouse and human somatic ACE. In particular, the fluorogenic substrate Mca-Ala-Ser-Asp-Lys-DpaOH was shown to be a strict N-domain-selective substrate of mouse ACE, whereas with rat ACE it displayed marked C-domain selectivity. Similar differences in selectivity between these ACE species were also observed with a new fluorogenic substrate of ACE, Mca-Arg-Pro-Pro-Gly-Phe-Ser-Pro-DpaOH. In support of these results, changes in amino-acid composition in the binding site of these three ACE species were pinpointed. Together these data demonstrate that the substrate selectivity of the N-domain and C-domain depends on the ACE species. These results raise concerns about the interpretation of functional studies performed in animals using N-domain and C-domain substrate selectivity data derived only from human ACE.
3. Investigating the domain specificity of phosphinic inhibitors RXPA380 and RXP407 in angiotensin-converting enzyme
Wendy L Kröger, Ross G Douglas, Hester G O'Neill, Vincent Dive, Edward D Sturrock Biochemistry. 2009 Sep 8;48(35):8405-12. doi: 10.1021/bi9011226.
Human somatic angiotensin-converting enzyme (ACE) is a membrane-bound dipeptidyl carboxypeptidase that contains two extracellular domains (N and C). Although highly homologous, they exhibit different substrate and inhibition profiles. The phosphinic inhibitors RXPA380 and RXP407 are highly selective for the C- and N-domains, respectively. A number of residues, implicated by structural data, are likely to contribute to this selectivity. However, the extent to which these different interactions are responsible for domain selectivity is unclear. In this study, a series of C- and N-domain mutants containing conversions to corresponding domain residues were used to scrutinize the contribution of these residues to selective inhibitor binding. Enzyme kinetic analyses of the purified mutants indicated that the RXPA380 C-selectivity is particularly reliant on the interaction between the P2 substituent and Phe 391 (testis ACE numbering). Moreover, a C-domain mutant in which Phe 391 has been changed to a Tyr residue, in addition to containing an N-domain S2' pocket (S2'F/Y), displayed the greatest shift toward a more N-domain-like Ki. None of the single mutations within the N-domain caused a large shift in RXP407's affinity for these enzymes. However, the double mutant containing the Tyr 369 to Phe change as well as Arg 381 to Glu displayed a 100-fold decrease in binding affinity, confirming that the S2 pocket plays a major role in RXP407 selectivity. Taken together, these data advance our understanding regarding the molecular basis for the remarkable ACE domain selectivity exhibited by these inhibitors.
