Abstract
Baculovirus P35 is a universal substrate-inhibitor of the death caspases. Stoichiometric inhibition by P35 is correlated with cleavage of its reactive site loop (RSL) and formation of a stable P35.caspase complex through a novel but undefined mechanism. The P35 crystal structure predicts that the RSL associates with the beta-sheet core of P35 positioning the caspase cleavage site at the loop's apex. Here we demonstrate that proper interaction between the RSL and the beta-sheet core is critical for caspase inhibition, but not cleavage. Disruption of RSL interaction with the beta-sheet by substituting hydrophobic residues of the RSL's transverse helix alpha1 with destabilizing charged residues caused loss of caspase inhibition, without affecting P35 cleavage. Restabilization of the helix/sheet interaction by charge compensation from within the beta-sheet partially restored anti-caspase potency. Mutational effects on P35 helix/sheet interactions were confirmed by measuring intermolecular helix/sheet association with the yeast two-hybrid system. Moreover, the identification of P35 oligomers in baculovirus-infected cells suggested that similar P35 interactions occur in vivo. These findings indicate that P35's anti-caspase potency depends on a distinct conformation of the RSL which is required for events that promote stable, post-cleavage interactions and inhibition of the target caspase.
Highlights
Baculovirus P35 is a potent inhibitor of the death proteases known as caspases
Proper association of the reactive site loop (RSL) with the main core of P35 is required for caspase inhibition
Disruption of RSL Interactions Causes Loss of P35 Function—Stoichiometric inhibition of caspases by P35 includes cleavage of the RSL at Asp87, the P1 residue located at the apex of the loop
Summary
Baculovirus P35 is a potent inhibitor of the death proteases known as caspases. These aspartate-specific cysteinyl proteases are critical components of the cell death machinery and are targets in anti-apoptotic strategies (for reviews, see Refs. 1– 4). To determine the contribution of the RSL to anti-caspase activity and thereby define the molecular mechanism of P35, we investigated the functional significance of predicted interactions between the RSL and the -sheet core. To investigate the significance of the interaction between ␣1 and the -sheet, we tested the effect of site-specific mutations within these domains on P35 anti-caspase activity.
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