Yeast cells as a tool for analysis of HIV-1 protease susceptibility to protease inhibitors, a comparative study.

HIV develops drug resistance at a high rate under drug selection pressure. Resistance tests are recommended to help physicians optimize antiretroviral drug therapies. For this purpose, genotypic and phenotypic tests have been developed.

HIV-2 Protease resistance defined in yeast cells.

Background: Inhibitors of the HIV-1 Protease currently used in therapeutic protocols, have been found to inhibit, although at higher concentrations, the HIV-2 encoded enzyme homologue. Similar to observations in HIV-1 infected individuals, therapeutic failure has also been observed for some patients infected with HIV-2 as a consequence of the emergence of viral strains resistant to the anti-retroviral molecules. In order to be able to define the specific mutations in the Protease that confer loss of susceptibility to Protease Inhibitors, we set up an experimental model system based in the expression of the viral protein in yeast.

Involvement of a small GTP binding protein in HIV-1 release.

Background: There is evidence suggesting that actin binding to HIV-1 encoded proteins, or even actin dynamics themselves, might play a key role in virus budding and/or release from the infected cell. A crucial step in the reorganisation of the actin cytoskeleton is the engagement of various different GTP binding proteins. We have thus studied the involvement of GTP-binding proteins in the final steps of the HIV-1 viral replication cycle.

HIV-1 gag polyprotein rescues HLA-DR intracellular transport in a human CD4+ cell line.

Major histocompatibility complex class II HLA-DR molecules are plasma-membrane integral heterodimers, constitutively expressed in antigen-presenting cells. Their expression is known to be upregulated in peripheral T lymphocytes upon cell activation and to be constitutive in T cell lines. In H78-C10.

Viral and cellular specificities of caprine arthritis encephalitis virus Vif protein.

The caprine arthritis encephalitis virus (CAEV) Vif protein is necessary for a productive infection of susceptible goat cells. The vif gene is conserved among all primate and most nonprimate lentiviruses. However, previous reports demonstrated that, in their respective host cells, primate Vif deleted lentiviruses could not be complemented by nonprimate Vif proteins, suggesting that species-specific restrictions between Vif and the virus-producing cells may modulate the Vif function on viral infectivity.

Production of HIV-1 by resting memory T lymphocytes.

Background: The persistence of HIV-1 within resting memory CD4 T cells constitutes a major obstacle in the control of HIV-1 infection.

Objective: To examine the expression of HIV-1 in resting memory CD4 T cells, using an in-vitro model.

Design And Methods: Phytohaemagglutinin-activated peripheral blood mononuclear cells were challenged with T cell-tropic and macrophage-tropic HIV-1 clones, and with a replication-incompetent and non-cytotoxic HIV-1-derived vector (HDV) pseudotyped by the vesicular stomatitis virus glycoprotein G.

Caprine arthritis encephalitis virus: evidence for a B/D-type assembly pathway in a C-type lentivirus replication.

Lentiviruses, among which is caprine arthritis encephalitis virus (CAEV), are known to concomitantly assemble and bud at the plasma membrane of infected cells, in a C-type defined pathway. Electron microscopy analysis of CAEV-infected cells demonstrated viral particles budding at the plasma membrane and into intracellular membrane-surrounded vesicles. Furthermore, nonenveloped immature virus-like particles, resembling intracytoplasmic type-A particles (ICAPs), accumulated within the cytoplasm of those cells.

Tryptophan 95, an amino acid residue of the Caprine arthritis encephalitis virus vif protein which is essential for virus replication.

The Caprine arthritis encephalitis virus (CAEV) vif gene was demonstrated to be essential for efficient virus replication. CAEV Vif deletion mutants demonstrated an attenuated replication phenotype in primary goat cell cultures and resulted in abortive infection when inoculated into goats. In this study, we determined the in vitro replication phenotype of five CAEV Vif point mutant infectious molecular clones and the ability of the corresponding in vitro translated Vif proteins to interact with the CAEV Pr55(gag) in the glutathione S--transferase (GST) binding assay.

Cell membrane vesicles are a major contaminant of gradient-enriched human immunodeficiency virus type-1 preparations.

During preliminary experiments to establish the proportion of virus-coded p24 protein to virus membrane-associated HLA-DR in gradient-enriched HIV-1 preparations, we became aware of a large variability between experiments. In order to determine whether HLA-DR-containing cellular material was contaminating the virus preparations, we carried out enrichment by gradient centrifugation of clarified supernatants from noninfected cells and tested this material for HLA-DR content. We found that, independently of the cell type used, gradient enrichment resulted in the isolation of large quantities of HLA-DR-containing material which banded at a density overlapping that of infectious HIV.

A C-terminal domain conserved in precursor processing proteases is required for intramolecular N-terminal maturation of pro-Kex2 protease.

The Kex2 protease of the yeast Saccharomyces cerevisiae is the prototype of a family of eukaryotic subtilisin homologs thought to process prohormones and other precursors in the secretory pathway. Deletion analysis of Kex2 protease shows that a sequence of 154-159 residues carboxyl to the subtilisin domain is essential for the formation of active enzyme. Disruption of this region, termed the 'P-domain', blocks the normally rapid intra-molecular cleavage of the N-terminal pro-segment of pro-Kex2 protease in the endoplasmic reticulum (ER).

Relationship between endo- and exopeptidases in a processing enzyme system: activation of an endoprotease by the aminopeptidase B-like activity in somatostatin-28 convertase.

The somatostatin-28 convertase activity involved in vitro in the processing of somatostatin-28 into the neuropeptides somatostatin-28-(1-12) and somatostatin-14 is composed of an endoprotease and a basic aminopeptidase. We report herein on the purification to apparent homogeneity of these two constituents and on their functional interrelationship. In particular we observed that after various physicochemical treatments, the 90-kDa endoprotease activity was recovered both at this molecular mass and as a 45-kDa entity.

Role of peptide substrate structure in the selective processing of peptide prohormones at basic amino acid pairs by endoproteases.

Three putative processing enzymes, each with defined action in a prohormone system, a 'pro-ocytocin-neurophysin convertase' from bovine neurohypophysis secretory granules, a 'Leu-enkephalin Arg6 generating enzyme' from human CSF and the endoprotease from the 'S-28 convertase' complex of rat brain cortex, were tested for their ability to hydrolyze peptides deriving from pro-ocytocin, pro-enkephalin B and pro-somatostatin, respectively at pairs of basic amino acids. The observations suggest that structural parameters specified by the peptide region around the dibasic moieties govern recognition by the enzyme and define which peptide bond is hydrolyzed.

Somatostatin-28 and pro-ocytocin/neurophysin convertases: basic pair selective endoproteases involved in pro-hormone processing in the rat brain cortex and bovine corpus luteum.

Two neuropeptide precursor processing enzyme systems were characterized in the rat brain cortex and bovine neurohypophysis and corpus luteum. The first one combines the action of a 90 kDa endoprotease which cleaves somatostatin-28 before the Arg-Lys doublet and that of an aminopeptidase B-like enzyme. The second system associates the action of a 58 kDa endoprotease cleaving pro-ocytocin/neurophysin (1-20) after the Lys-Arg dibasic moiety and a carboxypeptidase B-like activity.

Proteolytic enzymes in the post-translational processing of polypeptide hormone precursors.

Selective and limited proteolysis is a key step in the post-translational modification of peptide hormone precursors. This process appears to involve a proteolytic machinery including highly specific endoproteases. Some of the enzyme systems possibly involved in the processing of pro-neuropeptides will be described and their mechanism of action discussed.

Enzymes that process somatostatin precursors. A novel endoprotease that cleaves before the arginine-lysine doublet is involved in somatostatin-28 convertase activity of rat brain cortex.

The selective processing activity which generates both the NH2- and COOH-terminal fragments of the octacosapeptide somatostatin-28 (S-28) was investigated. Separation into two distinct proteolytic activities was achieved by ion-exchange chromatography. An endoprotease cleaving either the substrate Pro-Arg-Glu-Arg-Lys-Ala-Gly-Ala-Lys-Asn-Tyr-NH2, i.

[Proteolytic events in the maturation of pro-neuropeptides. The somatostatin model].

The post-translational processing (maturation) of the precursors was studied on the model of the prosomatostatin. We have shown the presence of a single and common precursor to both somatostatin -28 and -14 in mouse hypothalamus, in contrast with the situation in the Teleostean fish, Lophius piscatorius. The search for a maturation activity was carried out using a synthetic undecapeptide substrate including in its sequence the cleavage site for somatostatin-14 release.

The somatostatin-28 convertase of rat brain cortex is associated with secretory granule membranes.

An Arg-Lys esteropeptidase that converts somatostatin-28 in vitro into somatostatin-14 was previously characterized in extracts of rat cerebral cortex. Both the octacosapeptide somatostatin-28 and a synthetic undecapeptide containing the sequence around the Arg-Lys site, i.e.

The somatostatin-28 convertase of rat brain cortex generates both somatostatin-14 and somatostatin-28.

The products generated after addition of the ARG-LYS esteropeptidase activity purified from rat brain to synthetic somatostatin-28 were analyzed using radioimmunoassay, HPLC and amino acid analysis. In addition to somatostatin-14, both free arginine and free Lysine were identified together with somatostatin-28. The dipeptide ARG-LYS was not present, which indicates that three peptide bonds were hydrolyzed in order to achieve excision of the doublet.

Proteolytic events in the post-translational processing of somatostatin precursors from rat brain cortex and anglerfish pancreatic islets.

An Arg-Lys esteropeptidase which converts somatostatin-28 (S-28) into somatostatin-14 (S-14) was detected in rat brain cortical extracts using a synthetic undecapeptide substrate mimicking the octacosapeptide sequence at the restriction site. This enzyme system was unable to release either the octacosapeptide or S-14 from the 15,000 mol wt (15K) rat hypothalamic precursor. This argues in favor of sequential degradation of the precursor into S-14 via S-28 as an obligatory intermediate.

Characterization of a somatostatin-28 containing the (Tyr-7, Gly-10) derivative of somatostatin-14: a terminal active product of prosomatostatin II processing in anglerfish pancreatic islets.

Anglerfish (Lophius piscatorius) Brockmann organs contain a form of somatostatin-14, identical to the hypothalamic tetradecapeptide, and two distinct forms of somatostatin-28, which can be separated by reversed-phase high-pressure liquid chromatography (HPLC). Analysis of the NH2-terminal amino acid sequence and comparison of the ability to incorporate 125I indicate that one of these forms corresponds to an octacosapeptide including in its sequence the (Tyr-7, Gly-10) derivative of somatostatin-14 (somatostatin II). Exposure of this somatostatin-28 species to an endopeptidase activity from the rat brain cortex generates a peptide immunologically related to somatostatin and undistinguishable from synthetic (Tyr-7, Gly-10) somatostatin-14 II by HPLC.

Enzymes processing somatostatin precursors: an Arg-Lys esteropeptidase from the rat brain cortex converting somatostatin-28 into somatostatin-14.

The post-translational proteolytic conversion of somatostatin-14 precursors was studied to characterize the enzyme system responsible for the production of the tetradecapeptide either from its 15-kDa precursor protein or from its COOH-terminal fragment, somatostatin-28. A synthetic undecapeptide Pro-Arg-Glu-Arg-Lys-Ala-Gly-Ala-Lys-Asn-Tyr(NH2), homologous to the amino acid sequence of the octacosapeptide at the putative Arg-Lys cleavage locus, was used as substrate, after 125I labeling on the COOH-terminal tyrosine residue. A 90-kDa proteolytic activity was detected in rat brain cortex extracts after molecular sieve fractionation followed by ion exchange chromatography.