Identification of a protease inhibitor from rat peritoneal macrophages as poly(ADP-ribose)

Rat peritoneal macrophages contain a chymotrypsin-like protease and its specific inhibitor, both being associated with chromatin of the cells. The inhibitor was separated from the protease by gel filtration through a Sephadex G-75 column, further treated with trypsin, DNase and RNase, and then purified successively on Sephadex G-75, Sephadex G-25, and dihydroxyboryl Bio-Gel P-60 columns. The purified inhibitor had a molecular weight in the range from 2,000 to 3,500 and an absorption maximum at 260 nm at pH 7.0. When the inhibitor was digested by snake venom phosphodiesterase, the inhibitory potency was lost, yielding 5'-AMP and 2'-(5'-phosphoribosyl)-5'-AMP as the digestion products which were identified by high pressure liquid chromatography. The inhibitory potency was neutralized specifically by anti-poly(ADP-ribose) antiserum. The profile of inhibition by the isolated inhibitor was nearly identical with that produced by authentic poly(ADP-ribose). It was therefore concluded that the inhibitor isolated was identical with poly(ADP-ribose), whose chain length ranged from 4 to 7 ADP-ribosyl units. This is the first demonstration that a intracellular protease inhibitor can be endogenous poly(ADP-ribose).     

Construction and characterization of an infectious DNA clone and of mutants of simian immunodeficiency virus isolated from the African green monkey.

We constructed a full-length molecular clone of simian immunodeficiency virus from an African green monkey. Upon transfection, this clone directed the production of virus particles cytopathic and infectious to human CD4+ leukemia cell lines. Mutations were introduced by recombinant DNA techniques into eight open reading frames of simian immunodeficiency virus from the African green monkey thus far identified. The phenotypes of mutant viruses, i.e., infectivity, cytopathogenicity, transactivation of gene expression controlled by a long terminal repeat, and viral RNA and protein syntheses, were examined by transfection and infection experiments. Three structural (gag, pol, and env) and two regulatory (tat and rev) gene mutants were not infectious, whereas vif, vpx, and nef were dispensable for infectivity and mutant viruses were highly cytopathic. In transient transfection assays, a rev mutant produced mainly small mRNA species and no detectable virus protein and particles. The transactivation potential of a tat mutant was about 10-fold less than that of wild-type DNA, generating small amounts of virus.     

Involvement of the C-terminal region of yeast proteinase B inhibitor 2 in its inhibitory action

Yeast proteinase B inhibitor 2 (YIB2), which is composed of 74 amino acid residues, is an unusual serine protease inhibitor, since it lacks disulfide bonds. To identify its reactive site for proteases, we constructed an expression system for a synthetic YIB2 gene and then attempted to change the inhibitory properties of YIB2 by amino acid replacements. The purified wild-type YIB2 inhibited the activity of subtilisin BPN', a protein homologous to yeast proteinase B, although its binding ability was not strong, and a time-dependent decrease in its inhibitory activity was observed, demonstrating that wild-type YIB2 behaves as a temporary inhibitor when subtilisin BPN' is the target protease. Since YIB2 exhibits sequence homology to the propeptide of subtilisin, which inhibits a cognate protease using its C-terminal region, we replaced the six C-termi nal residues of YIB2 with those of the propeptide of subtilisin BPN' to make the mutant YIB2m1. This mutant exhibited markedly increased inhibitory activity toward subtilisin BPN' without a time-dependent decrease in its inhibitory activity. Replacement of only the C-terminal Asn of YIB2 by Tyr, or deletion of the C-terminal Tyr of YIB2m1, inhibited subtilisin, but the ability of these mutants to bind subtilisin and their resistance to proteolytic attack were weaker than those of YIB2m1, indicating that the C-terminal residue contributes to the interaction with the protease to a greater extent than the preceding five residues and that the resistance of YIB2 to proteolyic attack is closely related to its ability to bind a protease. These results demonstrate that YIB2 is a unique protease inhibitor that involves its C-terminal region in the interaction with the protease.