Abstract
Dimeric calpains constitute a promising therapeutic target for many diseases such as cardiovascular, neurodegenerative and ischaemic disease. The discovery of selective calpain inhibitors, however, has been extremely challenging. Previously, allosteric inhibitors of calpains, such as PD150606, which included a specific α-mercaptoacrylic acid sub-structure, were reported to bind to the penta-EF hand calcium binding domain, PEF(S) of calpain. Although these are selective to calpains over other cysteine proteases, their mode of action has remained elusive due to their ability to inhibit the active site domain with and without the presence of PEF(S), with similar potency. These findings have led to the question of whether the inhibitory response can be attributed to an allosteric mode of action or alternatively to inhibition at the active site. In order to address this problem, we report a structure-based virtual screening protocol as a novel approach for the discovery of PEF(S) binders that populate a novel chemical space. We have identified compound 1, Vidupiprant, which is shown to bind to the PEF(S) domain by the TNS displacement method, and it exhibited specificity in its allosteric mode of inhibition. Compound 1 inhibited the full-length calpain-1 complex with a higher potency (IC50 = 7.5 μM) than the selective, cell-permeable non-peptide calpain inhibitor, PD150606 (IC50 = 19.3 μM), where the latter also inhibited the active site domain in the absence of PEF(S) (IC50 = 17.8 μM). Hence the method presented here has identified known compounds with a novel allosteric mechanism for the inhibition of calpain-1. We show for the first time that the inhibition of enzyme activity can be attributed to an allosteric mode of action, which may offer improved selectivity and a reduced side-effects profile.
Highlights
Calpains are proteins that belong to the family of calcium-dependent, non-lysosomal cysteine proteases expressed ubiquitously in mammals and other organisms.[1]
The small subunit consists of two domains, namely the penta-EF hand calcium binding PEF(S) and glycine rich (GR) domains, which are essential for stabilizing calpain-1 and calpain-2.4 High sequence similarity of 62% is exhibited by the large subunits of calpain-1 and -2 in humans.[4]
They consist of four different domains, an N-terminal anchor helix, the active site domain (CysPc), a domain that resembles the C2 membrane binding domains of phosphokinases, known as the C2L domain, and a second penta-EF hand calcium binding domain known as PEF(L)
Summary
Calpains are proteins that belong to the family of calcium-dependent, non-lysosomal cysteine proteases expressed ubiquitously in mammals and other organisms.[1] the physiological roles of calpains are still poorly understood, they have been shown to be involved in many processes such as cell motility, long-term potentiation in neurons and cell fusion in myoblasts.[2] In particular, conventional dimeric calpains have been reported to be involved in the cell degeneration processes that characterize numerous disease conditions.[3]. The PEF(L) domain is the determinant of the calcium concentration that is required for protease activation, which differentiates between the two isoforms: calpain-1 requires micromolar concentrations of Ca2+, whereas calpain-2 requires millimolar concentrations for activation.[5]
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