Effect of p15-associated protease from an avian RNA tumor virus on avian virus-specific polyprotein precursors.

A proteolytic activity is associated with structural protein p15 in avian RNA tumor viruses. Its effect on the known intracellular viral polyprotein precursors obtained by immunoprecipitation was investigated. Cleavage of Pr76gag resulted in the sequential appearance of p15, p27, and p19. The intracellular precursor Pr180gag-pol was also cleaved by p15, whereas the intracellular glycoprotein precursors of avian RNA tumor viruses, Pr92env, remained unaffected by p15 under all conditions tested. The specificities of the antibodies used to precipitate the precursors influenced the pattern of intermediates and cleavage products obtained by p15 treatment. If virus harvested from the the Prague strain of Rous sarcoma virus, subgroup C-transformed cells at 15-min intervals was incubated at 37 degrees C for further maturation, RNA-dependent DNA polymerase activity showed an optimum of DNA synthesis with 70S viral RNA or synthetic template-primers after short incubation periods. The presence of additional p15 during incubation resulted in a shift of the enzyme activity peak toward earlier time points. Virus harvested at 3-h intervals contained significant amounts of Pr180gag-pol and Pr76gag. The addition of p15 resulted in the cleavage of Pr180gag-pol and Pr76gag, but only a few distinct low-molecular-weight polypeptides appeared. Treatment of purified RNA-dependent DNA polymerase with p15 in vitro resulted in a disappearance of the beta subunit and an enrichment of the alpha subunit. In addition, a polypeptide of 32 x 10(3) molecular weight was generated. The cleavage pattern observed differed from the one obtained by trypsin treatment.     

Determination of the proteolytic processing sites in the polyprotein encoded by the bottom-component RNA of cowpea mosaic virus

We have purified two low-molecular-weight polypeptides from the Prague C strain of Rous sarcoma virus and have identified these as products of the gag precursor Pr76 by protein sequencing and by amino acid analysis. Both polypeptides are derived from a stretch of 22 amino acids within Pr76 that separates p19 and p10. We refer to this region as p2. Together the two cleavage products form the entire p2 region. The junctions of p19 with the amino-terminal fragment of p2 and of p10 with the carboxy-terminal fragment of p2 define two new processing sites within the gag precursor, Tyr-155-His-156 and Gly-177-Ser-178. Both polypeptides are major cleavage products of Pr76 that occur in Prague C Rous sarcoma virus at an estimated 1,000 copies per virion. They also are prominent components of avian myeloblastosis virus. The combination of gel filtration and reverse-phase high-pressure liquid chromatography, which was used for the isolation of the two fragments of p2, resolved over a dozen other low-molecular-weight polypeptides from avian sarcoma and leukemia viruses that previously were undetected. This technique thus should serve as a useful procedure for further characterization of viral components.     

Effects of nucleocapsid mutations on human immunodeficiency virus assembly and RNA encapsidation.

The human immunodeficiency virus (HIV) Pr55Gag precursor proteins direct virus particle assembly. While Gag-Gag protein interactions which affect HIV assembly occur in the capsid (CA) domain of Pr55Gag, the nucleocapsid (NC) domain, which functions in viral RNA encapsidation, also appears to participate in virus assembly. In order to dissect the roles of the NC domain and the p6 domain, the C-terminal Gag protein domain, we examined the effects of NC and p6 mutations on virus assembly and RNA encapsidation. In our experimental system, the p6 domain did not appear to affect virus release efficiency but p6 deletions and truncations reduced the specificity of genomic HIV-1 RNA encapsidation. Mutations in the nucleocapsid region reduced particle release, especially when the p2 interdomain peptide or the amino-terminal portion of the NC region was mutated, and NC mutations also reduced both the specificity and the efficiency of HIV-1 RNA encapsidation. These results implicated a linkage between RNA encapsidation and virus particle assembly or release. However, we found that the mutant ApoMTRB, in which the nucleocapsid and p6 domains of HIV-1 Pr55Gag were replaced with the Bacillus subtilis MtrB protein domain, released particles efficiently but packaged no detectable RNA. These results suggest that, for the purposes of virus-like particle assembly and release, NC can be replaced by a protein that does not appear to encapsidate RNA.     

Identification of a key target sequence to block human immunodeficiency virus type 1 replication within the gag-pol transframe domain

Although the full sequence of the human immunodeficiency virus type 1 (HIV-1) genome has been known for more than a decade, effective genetic antivirals have yet to be developed. Here we show that, of 22 regions examined, one highly conserved sequence (ACTCTTTGGCAACGA) near the 3' end of the HIV-1 gag-pol transframe region, encoding viral protease residues 4 to 8 and a C-terminal Vpr-binding motif of p6(Gag) protein in two different reading frames, can be successfully targeted by an antisense peptide nucleic acid oligomer named PNA(PR2). A disrupted translation of gag-pol mRNA induced at the PNA(PR2)-annealing site resulted in a decreased synthesis of Pr160(Gag-Pol) polyprotein, hence the viral protease, a predominant expression of Pr55(Gag) devoid of a fully functional p6(Gag) protein, and the excessive intracellular cleavage of Gag precursor proteins, hindering the processes of virion assembly. Treatment with PNA(PR2) abolished virion production by up to 99% in chronically HIV-1-infected H9 cells and in peripheral blood mononuclear cells infected with clinical HIV-1 isolates with the multidrug-resistant phenotype. This particular segment of the gag-pol transframe gene appears to offer a distinctive advantage over other regions in invading viral structural genes and restraining HIV-1 replication in infected cells and may potentially be exploited as a novel antiviral genetic target.     

Vaccinia Virus Structural Polypeptide Derived from a High-Molecular-Weight Precursor: Formation and Integration into Virus Particles

Polypeptide 4a, a major vaccinia structural polypeptide which was previously shown to form from a high-molecular-weight precursor is made after the period of viral deoxyribonucleic acid (DNA) synthesis. Pulse-chase experiments demonstrated that a period of 1 to 2 hr is required for a 50% conversion of precursor to product. The rates of incorporation of polypeptides into virus particles were examined. The kinetics of incorporation of labeled 4a and other major structural polypeptides into virus particles were similar, despite the additional time required for the formation of 4a from its precursor. Furthermore, 4a was present exclusively in a particulate form at all times examined. Both observations suggested that cleavage of the precursor occurs after, or immediately prior to, association with developing virus particles. Polypeptide P4a was previously identified as the probable precursor of 4a and is not ordinarily found in detectable amounts in virus particles. Under conditions in which breakdown of P4a was inhibited by adding rifampin or amino acid analogues after the period of viral DNA synthesis, isolated virus particles contained significant amounts of this polypeptide. Further analysis showed that P4a was localized within the virus core, which is also the site of 4a. Synchronization of virus assembly after the removal of rifampin was shown to be useful for studying the integration of polypeptides into a particulate fraction of the cytoplasm.     

Quantitative separation of murine leukemia virus proteins by reversed-phase high-pressure liquid chromatography reveals newly described gag and env cleavage products.

The structural proteins of murine type C retroviruses are proteolytic cleavage products of two different precursor polyproteins coded by the viral gag and env genes. To further investigate the nature and number of proteolytic cleavages involved in virus maturation, we quantitatively isolated the structural proteins of the Rauscher and Moloney strains of type C murine leukemia virus (R-MuLV and M-MuLV, respectively) by reversed-phase high-pressure liquid chromatography. Proteins and polypeptides isolated from R-MuLV included p10, p12, p15, p30, p15(E), gp69, and gp71 and three previously undescribed virus components designated here as p10', p2(E), and p2(E). Homologous proteins and polypeptides were isolated from M-MuLV. Complete or partial amino acid sequences of all the proteins listed above were either determined in this study or were available in previous reports from this laboratory. These data were compared with those from the translation of the M-MuLV proviral DNA sequence (Shinnick et al., Nature [London] 293:543-548, 1981) to determine the exact nature of proteolytic cleavages for all the structural proteins described above and to determine the origin of p10' and p2(E)s. The results showed that, during proteolytic processing of gp80env from M-MuLV (M-gp 80env), a single Arg residue was excised between gp70 and p15(E) and a single peptide bond was cleaved between p15(E) and p2(E). The structure of M-gPr80env is gp70-(Arg)-p15(E)-p2(E). The data suggest that proteolytic cleavage sites in R-gp85env are identical to corresponding cleavage sites in M-gp80env. The p2(E)s are shown to be different genetic variants of p2(E) present in the uncloned-virus preparations. The data for R- and M-p10's shows that they are cleavage products of the gag precursor with the structure p10-Thr-Leu-Asp-Asp-OH. The complete structure of Pr65gag is p15-p12-p30-p10'. Stoichiometries of the gag and env cleavage products in mature R- and M-MuLV were determined. In each virus, gag cleavage products (p15, p12, p30, and p10 plus p10') were found in equimolar amounts and p15(E)s were equimolar with p2(E)s. The stoichiometry of gag to env cleavage products was 4:1. These data are consistent with the proposal that proteolytic processing of precursor polyproteins occurs after virus assembly and that the C-terminal portion of Pr15(E) [i.e., p15(E)-p2(E)] is located on the inner side of the lipid bilayer of the virus.     

Intracellular production of virus particles and viral components in NIH/3T3 cells chronically infected with Moloney murine leukemia virus: effect of interferon.

The effect of interferon on the biochemical properties and the maturation process of intracellular viral particles isolated from the cytoplasmic fraction of NIH/3T3 cells chronically infected with Moloney murine leukemia virus was investigated. By labeling these virions with either [35S]methionine or [3H]glucosamine, we demonstrated that they contain the same viral proteins and glycoproteins found in extracellular virions. Interferon treatment was found to reduce the rate of intracellular virus assembly. This effect was not a consequence of an interferon inhibition of viral RNA synthesis or its translation or a consequence of an interference with the posttranslational cleavage processing of viral precursor proteins, since all of these steps were not affected by interferon. However, the reduced rate of virus assembly could be attributed to the inhibition of viral protein glycosylation observed in interferon-treated cells. Nevertheless, despite this reduced rate, virus particles accumulated in interferon-treated cells. This accumulation was probably due to the strong inhibition of their final release from such cells.     

Requirements for incorporation of Pr160gag-pol from human immunodeficiency virus type 1 into virus-like particles.

The roles of the human immunodeficiency virus precursor polyproteins Pr55gag and Pr160gag-pol in viral core assembly were studied in CMT3-COS cells. To do this, the precursors were expressed separately by using a simian virus 40 late replacement vector system described previously. Consistent with previously published data, our results show that the Pr55gag precursor, when expressed alone, was able to form particles which had an immature morphology and that particle formation required the presence of a myristate addition signal at the amino terminus of the precursor. In contrast, the Pr160gag-pol precursor was not able to form particles when expressed alone, although it still underwent proteolytic processing. Coexpression of the two precursor polyproteins from separate vectors in the same cell resulted in processing of the Pr55gag in trans by the protease embedded in Pr160gag-pol and the formation of virus-like particles containing the products of both precursors. Proteolytic processing occurred independently of the presence of a functional myristate addition signal on either precursor. On the other hand, removal of myristate from one or the other precursor had nonreciprocal effects on virus particle formation. Cells expressing Pr55gag lacking myristate and Pr160gag-pol containing it did not produce particles. Cells expressing a myristylated Pr55gag and unmyristylated Pr160gag-pol still produced virus-like particles which contained nearly normal amounts of Pr160gag-pol. The results suggest that the incorporation of Pr160gag-pol into particles is largely determined by intermolecular protein-protein interactions between the two precursor polypeptides.     

Polyprotein Precursors to Mouse Mammary Tumor Virus Proteins

Mouse mammary tumor virus (MMTV) derived from the culture medium of GR cells contained seven proteins, identified as gp55, gp33, p25, pp20, p16, p12, and p10. The major viral phosphoprotein was the 20,000-molecular-weight protein, pp20. Immunoprecipitation of cytoplasmic extracts from pulse-labeled GR cells identified three MMTV gag-specific proteins, termed Pr78(gag), Pr110(gag), and Pr180(gag+). These intracellular polyproteins were precipitable from cytoplasmic extracts by antisera to virions p25 and p12 but not by antisera to gp55. The major intracellular gag-specific precursor polyprotein, Pr78(gag), contained antigenic determinants and tryptic peptides characteristic of p25, p12, p10, and presumably pp20. This precursor is presumably derived from nascent chain cleavage or rapid posttranslational cleavage of the larger intracellular precursor-like protein, designated Pr110(gag). Pr110(gag) contained all but one of the leucine-containing tryptic peptides of Pr78(gag), plus several additional peptides. In addition to Pr78(gag) and Pr110(gag), monospecific antisera to virion p12 and p25 were also capable of precipitating from pulse-labeled cells a small amount of a 180,000-molecular-weight precursor-like protein, designated Pr180(gag+). This large polyprotein contained nearly all of the leucine-containing tryptic peptides of Pr78(gag) and Pr110(gag) plus several additional peptides. By analogy to type C viral systems, Pr180(gag+) is presumed to represent a gag-pol common precursor which is the major pathway for synthesis of MMTV polymerase. Immunoprecipitation of cytoplasmic extracts from pulse-labeled cells with antisera to gp55 identified two env-specific proteins, designated gPr76(env) and gP79(env). The major env precursor, gPr76(env), could be labeled with radioactive glucosamine and was shown to contain antigenic determinants and tryptic peptides characteristic of gp55 and gp33. A minor glycoprotein, gP79(env), contained both fucose and glucosamine and was precipitable from cytoplasmic extracts with monospecific serum to gp55. It is suggested that gP79(env) represents fucosylated gPr76(env) which is transiently synthesized and cleaved rapidly into gp55 and gp33.     

Intracellular ribonucleoprotein complexes of visna virus are infectious.

Sheep choroid plexus cells infected with visna virus produce intracytoplasmic viral ribonucleoprotein complexes with sedimentation values of 120S to 200S and buoyant densities of 1.29 to 1.32 g/cm3. These ribonucleoprotein complexes display an endogenous RNA-directed DNA polymerase activity and contain all of the species of RNA associated with polysomes. An analysis of the polypeptides present in the ribonucleoproteins allowed us to identify the mature internal virion core proteins and their precursor, Pr55gag, as well as the glycosylated envelope precursor gPr150env and small amounts of mature glycoprotein gp135. Ultracentrifugation-purified ribonucleoproteins could infect sheep choroid plexus cells and led to a normal lytic cycle with virus production. Our results suggest that visna virus can propagate by means of intracellular infectious particles.     

Impaired Maturation of Mouse Mammary Tumor Virus Precursor Polypeptides in Lymphoid Leukemia Cells, Producing Intracytoplasmic A Particles and No Extracellular B-Type Virions

Processing of polypeptides of the mouse mammary tumor virus, a type B retrovirus, was investigated in a transplanted thymic lymphoma cell line of the GR strain (GRSL). This cell line was maintained in vivo in ascites form and in vitro as a suspension culture. GRSL cells produce clusters of intracytoplasmic A particles and are virtually deficient in the production of mature extracellular B-type particles. As control, a mammary tumor cell line of the same mouse strain capable of complete virion synthesis was used. The kinetics of viral polypeptide synthesis were studied by pulse labeling with various isotopes (including (35)S and (32)P), followed by immunoprecipitation of cell lysates with monospecific antisera to the major mouse mammary tumor virus gag and env proteins, p27 and gp52, respectively. Both the primary gag and env precursor polypeptides were synthesized in the GRSL cells, but their conversion into viral proteins was impaired. The major gag precursor, Pr73(gag), was stable over a period of 8 h, and mature viral core polypeptides could not be detected. Also, the highly phosphorylated intermediates in the proteolytic processing of Pr73(gag) in virus-producing cells were absent in GRSL cells. By immunoprecipitation, Pr73(gag) was detected in a GRSL particle fraction with the density of intracytoplasmic A particles. The precursor for envelope proteins, Pr73(env), was turned over without the generation of mature viral envelope components gp52 and gp36. The in vivo-transplanted ascites GRSL cells, however, were shown to express gp52 on the cell surface together with a 73,000-dalton polypeptide, as indicated by cell surface iodination and immunoprecipitation.     

Further studies on the glycosylated gag gene products of Rauscher murine leukemia virus: identification of an N-terminal 45,000-dalton cleavage product

A glycosylated 45,000-Mr protein containing Rauscher murine leukemia virus p15 and p12 antigenic sites and tryptic peptides was identified in Rauscher murine leukemia virus-infected cells. This glycoprotein, termed gP45gag, was also shown to contain a single tryptic peptide also present in gPr80gag and its unglycosylated apoprotein precursor Pr75gag, but lacking in Pr65gag or Pr40gag. The presence of this peptide only in viral precursor proteins containing the so-called leader (L) sequence strongly suggests that gPr45gag is an N-terminal fragment of larger glycosylated gag polyproteins, composed of L sequences in addition to p15 and p12. The kinetics of appearance of radiolabeled gPr45gag and its disappearance during chase-incubation is suggestive of a precursor-like role for this intermediate gene product. An observed 27,000-Mr glycosylated polypeptide, termed gP27gag and containing p15 but not p12, p30, or p10 antigenic determinants, is a candidate cleavage product derived from gPr45gag. These observations suggest that gPr45gag and its putative cleavage product gP27gag represent an authentic pathway for intracellular processing of glycosylated core proteins.     

Translation of bovine leukemia virus virion RNAs in heterologous protein-synthesizing systems.

Bovine leukemia virus 60 to 70S RNA was heat denatured, the polyadenylic acid-containing species were separated by velocity sedimentation, and several size classes were translated in a micrococcal nuclease-treated cell-free system from rabbit reticulocytes. The major RNA species sedimented at 38S and migrated as a single component of molecular weight 2.95 x 10(6) when analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The predominant polypeptides of the in vitro translation of bovine leukemia virus 38S RNA were products with molecular weights of 70,000 and 45,000; minor components with molecular weights of 145,000 and 18,000 were also observed. Two lines of evidence indicate that the 70,000- and 45,000-molecular weight polypeptides represent translation products of the gag gene of the bovine leukemia virus genome (Pr70gag and Pr45gag). First, they are specifically precipitated by a monospecific antiserum to the major internal protein, p24, and second, they are synthesized and correctly processed into virion proteins p24, p15, and p10 in Xenopus laevis oocytes microinjected with bovine leukemia virus 38S RNA. The 145,000-molecular weight polypeptide was immunoprecipitated by the anti-p24 serum and not by an antiserum to the major envelope glycoprotein, gp60. It contained all the tryptic peptides of Pr70gag and additional peptides unique to it, and thus represents in elongation product of Pr70gag in an adjacent gene, presumably the pol gene. The 18,000-molecular weight product was antigenically unrelated to p24 and gp60 and shared no peptides in common with Pr70gag, Pr45gag, or the 145,000-molecular weight polypeptide. It was maximally synthesized on a polyadenylic acid-containing virion 16 to 18S RNA, and we present evidence that this RNA is a 3' end-derived subgenomic fragment of the bovine leukemia virus genome rather than a contaminating cellular RNA.     

Four Moloney murine leukemia virus-infected rat cell clones producing replication-defective particles: protein and nucleic acid analyses.

Four cloned rat cell lines (NX-1 to -4) infected with Moloney murine leukemia virus and defective in virus replication were found to be all different by viral protein and nucleic acid analyses. All four clones produced noninfectious particles and, except for NX-2, at about the same level as wild type. Compared with wild-type virions these defective particles contained larger amounts of gag precursor proteins and very little or no p30 or p15. Analysis of intracellular precursor proteins revealed that NX-2 to -4 synthesized normal Pr65gag, whereas NX-1 produced a slightly smaller precursor. Both NX-1 and NX-4 synthesized an intracellular polyprotein with a size similar to that of wild-type Pr180 gag-pol. Restriction endonuclease analysis of NX-1 to -4 cellular DNA showed that each clone contained a single integrated provirus which possessed large terminal repeat sequences at both the 5' and 3' ends. The proviruses of NX-1 to -3 appeared normal by restriction endonuclease analysis, but NX-4 provirus had a deletion of 1,700 base pairs comprising part of the polymerase region. The noninfectious particles produced by all four clones packaged Moloney viral RNAs and rat RNAs of two different sizes.     

Processing of Proteinase Precursors and Their Effect on Hepatitis A Virus Particle Formation

Proteolytic processing of the picornaviral polyprotein mediated by the differential action of virus-encoded proteinase(s) is pivotal to both RNA genome replication and capsid formation. Possibly to enlarge the array of viral proteins, picornaviral polyprotein processing results in intermediate and mature products which apparently have distinct functions within the viral life cycle. For hepatitis A virus (HAV), we report here on the autoproteolysis of precursor polypeptides comprising the only viral proteinase, 3C^pro, and on their role in viral particle formation. Following transient expression of a nested set of 3C^pro-containing proteins (P3, 3ABC, 3BCD, 3CD, 3BC, and 3C) in eukaryotic cells, the extent of processing was determined by analyzing the cleavage products. The 3C/3D site was more efficiently cleaved than those at the 3A/3B and 3B/3C sites, leading to the accumulation of the intermediate product 3ABC. In the absence of 3A from the precursor, cleavage at the 3B/3C site was further reduced and a switch to an alternative 3C/3D site was observed. Coexpression of various parts of P3 with the precursor of the viral structural proteins P1-2A showed that all 3C-containing intermediates cleaved P1-2A with almost equal efficiency; however, viral particles carrying the neutralizing epitope form much more readily in the presence of the complete P3 domain than with parts of it. These data support the notion that efficient liberation of structural proteins from P1-2A is necessary but not sufficient for productive HAV capsid formation and suggest that the polypeptides flanking 3C^pro promote the assembly of viral particles.