The palladacycle, AJ-5, exhibits anti-tumour and anti-cancer stem cell activity in breast cancer cells.

Breast cancer is the most common malignancy amongst women worldwide but despite enormous efforts to address this problem, there is still limited success with most of the current therapeutic strategies. The current study describes the anti-cancer activity of a binuclear palladacycle complex (AJ-5) in oestrogen receptor positive (MCF7) and oestrogen receptor negative (MDA-MB-231) breast cancer cells as well as human breast cancer stem cells. AJ-5 is shown to induce DNA double strand breaks leading to intrinsic and extrinsic apoptosis and autophagy cell death pathways which are mediated by the p38 MAP kinase. This study provides evidence that AJ-5 is potentially an effective compound in the treatment of breast cancer.

Pharmacokinetic evaluation of lisinopril-tryptophan, a novel C-domain ACE inhibitor.

Angiotensin-converting enzyme (ACE, EC 3.4.15.1) is a metallopeptidase comprised of two homologous catalytic domains (N- and C-domains). The C-domain cleaves the vasoactive angiotensin II precursor, angiotensin I, more efficiently than the N-domain. Thus, C-domain-selective ACE inhibitors have been designed to investigate the pharmacological effects of blocking the C-terminal catalytic site of the enzyme and improve the side effect profile of current ACE inhibitors. Lisinopril-tryptophan (LisW-S), an analogue of the ACE inhibitor lisinopril, is highly selective for the C-domain. In this study, we have analysed the ex vivo domain selectivity and pharmacokinetic profile of LisW-S. The IC50 value of LisW-S was 38.5 nM in rat plasma using the fluorogenic substrate Abz-FRKP(Dnp)P-OH. For the pharmacokinetics analysis of LisW-S, a sensitive and selective LC-MS/MS method was developed and validated to determine the concentration of LisW-S in rat plasma. LisW-S was administered to Wistar rats at a dose of 1 mg/kg bodyweight intravenously, 5 mg/kg bodyweight orally. The Cmax obtained following oral administration of the drug was 0.082 µM and LisW-S had an apparent terminal elimination half-life of around 3.1 h. The pharmacokinetic data indicate that the oral bioavailability of LisW-S was approximately 5.4%. These data provide a basis for better understanding the absorption mechanism of LisW-S and evaluating its clinical application.

Characterization of domain-selective inhibitor binding in angiotensin-converting enzyme using a novel derivative of lisinopril.

Human ACE (angiotensin-converting enzyme) (EC 3.4.15.1) is an important drug target because of its role in the regulation of blood pressure via the renin-angiotensin-aldosterone system. Somatic ACE comprises two homologous domains, the differing substrate preferences of which present a new avenue for domain-selective inhibitor design. We have co-crystallized lisW-S, a C-domain-selective derivative of the drug lisinopril, with human testis ACE and determined a structure using X-ray crystallography to a resolution of 2.30 A (1 A=0.1 nm). In this structure, lisW-S is seen to have a similar binding mode to its parent compound lisinopril, but the P2' tryptophan moiety takes a different conformation to that seen in other inhibitors having a tryptophan residue in this position. We have examined further the domain-specific interactions of this inhibitor by mutating C-domain-specific active-site residues to their N domain equivalents, then assessing the effect of the mutation on inhibition by lisW-S using a fluorescence-based assay. Kinetics analysis shows a 258-fold domain-selectivity that is largely due to the co-operative effect of C-domain-specific residues in the S2' subsite. The high affinity and selectivity of this inhibitor make it a good lead candidate for cardiovascular drug development.

Investigating the domain specificity of phosphinic inhibitors RXPA380 and RXP407 in angiotensin-converting enzyme.

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.

Probing the basis of domain-dependent inhibition using novel ketone inhibitors of Angiotensin-converting enzyme.

Human angiotensin-converting enzyme (ACE) has two homologous domains, the N and C domains, with differing substrate preferences. X-ray crystal structures of the C and N domains complexed with various inhibitors have allowed identification of active site residues that might be important for the molecular basis of this selectivity. However, it is unclear to what extent the different residues contribute to substrate domain selectivity. Here, cocrystal structures of human testis ACE, equivalent to the C domain, have been determined with two novel C domain-selective ketomethylene inhibitors, (5 S)-5-[( N-benzoyl)amino]-4-oxo-6-phenylhexanoyl- l-tryptophan (kAW) and (5 S)-5-[( N-benzoyl)amino]-4-oxo-6-phenylhexanoyl- l-phenylalanine (kAF). The ketone groups of both inhibitors bind to the zinc ion as a hydrated geminal diolate, demonstrating the ability of the active site to catalyze the formation of the transition state. Moreover, active site residues involved in inhibitor binding have been mutated to their N domain counterparts, and the effect of the mutations on inhibitor binding has been determined. The C domain selectivity of these inhibitors was found to result from interactions between bulky hydrophobic side chain moieties and C domain-specific residues F391, V518, E376, and V380 (numbering of testis ACE). Mutation of these residues decreased the affinity for the inhibitors 4-20-fold. T282, V379, E403, D453, and S516 did not contribute individually to C domain-selective inhibitor binding. Further domain-selective inhibitor design should focus on increasing both the affinity and selectivity of the side chain moieties.