Autographa californica M nucleopolyhedrovirus ProV-CATH is activated during infected cell death.

V-CATH, a cathepsin L-like cysteine protease encoded by the baculovirus Autographa californica M nucleopolyhedrovirus, has been shown to play an essential role in host liquefaction. Similar to cellular cathepsin L, V-CATH is synthesized as an inactive proenzyme and is activated by cleavage of the propeptide. Previous studies indicated that removal of the propeptide was rapid, occurring as soon as the protein could be detected by Western blot, 22 h postinfection. We found, however, that these results reflected artifactual processing of the proenzyme. When the protease inhibitor E-64 was used to prevent this aberration, we found that proV-CATH accumulated in infected cells and activation did not begin until the onset of cell death, at approximately 80 h postinfection. Western blot analysis of fractions of live and dead cells isolated by fluorescence-activated cell sorting revealed that mature V-CATH was found only in dead cells. The regulation of activation of proV-CATH, therefore, was quite different from that of cellular cathepsins. Acridine orange staining revealed that lysosome integrity was lost in dead cells, an occurrence that could lead to the activation of proV-CATH by lysosomal proteases.

Autographa californica M nucleopolyhedrovirus chiA is required for processing of V-CATH.

Infection of permissive insect hosts by the baculovirus Autographa californica M nucleopolyhedrovirus results in liquefaction, a pathogenic effect that enhances the dispersal of progeny virions. Two viral gene products-a protease, V-CATH, and a chitinase, chiA-have been shown to be required for liquefaction to occur. It has been generally accepted that the primary functions of these proteins is to degrade the proteinaceous and chitinous components of the host cadaver, respectively. We have generated suggestive evidence, however, that chiA may also serve as a molecular chaperone for proV-CATH, the precursor of V-CATH. When cells were infected with virus lacking a functional chiA gene, proV-CATH failed to undergo processing in vivo and in vitro and formed insoluble aggregates in the endoplasmic reticulum of infected cells. Thus, expression of chiA may be required for the proper folding of the nascent V-CATH polypeptide in the endoplasmic reticulum. Identical results were obtained when tunicamycin was used to block N-linked glycosylation in cells infected with wildtype virus, suggesting that the putative chiA/V-CATH interaction is mediated by N-linked oligosaccharides.

Urease activity in the crystalline state.

Crystalline Klebsiella aerogenes urease was found to have less than 0.05% of the activity observed for the soluble enzyme under standard assay conditions. Li2SO4, present in the crystal storage buffer at 2 M concentration, was shown to inhibit soluble urease by a mixed inhibition mechanism (Ki's of 0.38 +/- 0.05 M for the free enzyme and 0.13 +/- 0.02 M for the enzyme-urea complex). However, the activity of crystals was less than 0.5% of the expected value, suggesting that salt inhibition does not account for the near absence of crystalline activity. Dissolution of crystals resulted in approximately 43% recovery of the soluble enzyme activity, demonstrating that protein denaturation during crystal growth does not cause the dramatic diminishment in the catalytic rate. Finally, crushed crystals exhibited only a three-fold increase in activity over that of intact crystals, indicating that the rate of substrate diffusion into the crystals does not significantly limit the enzyme activity. We conclude that urease is effectively inactive in this crystal form, possibly due to conformational restrictions associated with a lid covering the active site, and propose that the small amounts of activity observed arise from limited enzyme activity at the crystal surfaces or trace levels of enzyme dissolution into the crystal storage buffer.