Structural and Functional Analysis of Caspase Active Sites

Abstract

Amino acid sequences of caspases 1, 3, 7, and 8 were aligned with their published three-dimensional (3D) structures. The resultant alignment was used as a template to compare the primary structures of caspases 2, 4−6, and 9−11 to build 3D homology models. The structural models were subsequently refined and validated using structure−activity relationship data obtained from an array of substrate-like inhibitors. All caspases were shown to have identical S1 and catalytic dyad architecture but diverse S2−S4 structures. S2 pockets of these 11 caspases can be briefly categorized into two groups: Csp3, -6, and -7 as one and Csp1, -2, -4, -5, -8, -9, -10, and -11 as the other. S2 pockets of Csp3, -6, and -7 are smaller than those of the other eight caspases, and are limited to binding small P2 residues such as Ala and Val. At the S3 site, the presence of a conserved Arg in all caspases suggests that Glu would be a universally preferred P3 residue. Csp8 and Csp9 have an additional Arg in this pocket that can further enhance the binding of a P3 Glu, whereas Csp2 has a Glu adjacent to the conserved Arg. As such, Csp2 is the only caspase that can accommodate both positively and negatively charged P3. At S4, Csp1, -4, -5, and -11 are closely related with respect to their structures and binder preferences; all have a large hydrophobic pocket and prefer large hydrophobic residues such as Trp. S4 of Csp2, -3, and -7 represents an opposite group with a conformation that is highly specific in binding an Asp. The S4 structures of Csp6, -8, -9, and -10 appear to be hybrids of the two extremes, and have little specificity for any P4. Information revealed from this work provides a guide for designing potent caspase inhibitors with desirable specificity.