The proteinase inhibitor pepstatin A inhibits formation of reverse transcriptase in H9 cells infected with human immunodeficiency virus 1

Localization of pepstatin's inhibitory action during Fc-mediated antibody internalization: possible implications for antibody-mediated viral transmission

Antibody internalization via Fc receptors is an important cellular mechanism, possibly facilitating the entry of antigenic peptides or viral particles into cells when specific antibodies are present at the periphery. Using an experimental model of trophoblast cells, we have shown that anti-p21(ras) monoclonal antibodies can use IFN-gamma-induced surface Fcgamma receptors to enter the cell. This entry of anti-p21(ras) antibodies ultimately inhibits IFN-gamma-mediated class II antigen induction. Since there may be obvious and inevitable harmful aspects of this mechanism, during which Fc-mediated viral particle or autoantigen transport may occur, we concentrated efforts on defining a potent inhibitor able to eliminate such uptake. The results presented here show that the protease inhibitor pepstatin A efficiently inhibits Fcgamma receptor induction by IFN-gamma and also blocks the endocytic pathway followed by an antibody when it enters the cell at the level of early endosomal compartments. We thus postulate that the use of pepstatin A, because of its inhibition of autoantigen presentation or viral transmission, including that of HIV, may find important applications in therapeutic protocols.

Mutations in the central polypurine tract of HIV-1 result in delayed replication

The reverse transcription of HIV-1 generates a linear genomic DNA with a single-stranded gap. The gap is believed to be the result of plus-strand priming from a second, centrally located, polypurine tract (PPT). A mutant containing four amino-acid-neutral purine-to-pyrimidine changes within the central PPT did not replicate as fast as wild-type virus. Another mutant with the entire 15-bp PPT deleted was replication-deficient. The results indicate that plus-strand priming at the central PPT is important for viral replication, possibly by ensuring efficient DNA synthesis.

Polymerizing properties of pepstatin A

Pepstatin A, a pentapeptide aspartyl protease inhibitor, can spontaneously polymerize into filaments having a helical substructure and, after negative staining, characteristic diameters ranging from 6 to 12 nm. Optical diffraction analysis demonstrated that these filaments consist of a 6-nm-wide strand helically wound with a periodic pitch of 25 nm. Selected images suggest that these filaments may actually be composed of two, intertwined 6-nm-wide strands, an hypothesis not at variance with the diffraction data. These filaments may extend over several micrometers. At low ionic strength and neutral pH, the critical concentration for pepstatin A filament assembly is 0.1 mM. At higher pepstatin A concentrations or in physiological salt solutions, a variety of higher order structures were observed, including ribbons, sheets, and cylinders with both regular and twisted or irregular geometries. Pepstatin A polymerized into these higher order structures loses its ability to inhibit the aspartyl protease of the human immunodeficiency virus type 1. These results have implications not only for model studies on the polymerization of small peptides into higher order structures, but also for the practical development of soluble protease inhibitors.

Modified oligopeptides designed to interact with the HIV-1 proteinase inhibit viral replication

The human immunodeficiency virus 1 (HIV-1) codes for a proteinase that cuts viral proteins at specific sites. We have tested 13 modified oligopeptides related to these cleavage sites to see if they inhibit viral replication. To indicate whether a decrease in replication could be due to a general inhibition of cell metabolism, we also measured the effect of the peptides on cellular protein synthesis. Three of the peptides tested (Ac-Gln-Asn-Sta-Val-NH2, Ac-Gln-Asn-Sta-Val-Val-NH2, and Ac-Glu-Asn-Sta-Ile-NH2) inhibited HIV-1 replication at concentrations that did not inhibit protein synthesis. Ac-Gln-Asn-Sta-Val-NH2 was the most potent, causing an approximately 40% decrease in viral replication, measured as the synthesis of HIV-1 antigens and the formation of infectious particles.