Analysis of three late varicella-zoster virus proteins, a 125,000-molecular-weight protein and gp1 and gp3

Two monoclonal antibodies were prepared against varicella-zoster virus proteins. One of the monoclonal antibodies (10.2) reacted only with the nuclei of infected cells and immunoprecipitated one nonglycosylated late viral protein (125,000 molecular weight). The other monoclonal antibody (19.1) with neutralizing activity, reacted with membrane antigens of infected cells and with the varicella-zoster virus envelope and immunoprecipitated two late major viral glycoproteins (gp1 and gp3). Synthesis of the 125,000-molecular-weight protein, gp1, and gp3 began at 20 to 22 h postinfection, 2 h after the peak of viral DNA synthesis, and continued until 29 h postinfection, when the first progeny virus appeared in infected cells. Pulse-chase experiments showed that during pulse-labeling, only gp1 was detected, whereas during the chase period, gp1 as well as gp3 was detected in infected cells. Under nonreducing conditions, gp3 migrated in sodium dodecyl sulfate-polyacrylamide gel electrophoresis as a 130,000-molecular-weight protein as compared with the 62,000-molecular-weight species obtained when gels were resolved under reducing conditions. This finding indicates that gp3 is a dimer that is disulfide linked.     

Primate retroviruses: intracistronic mapping of type D viral gag gene by use of nonconditional replication mutants.

Nonconditional replication mutants of squirrel monkey retrovirus (SMRV), an endogenous type D virus of primates, are shown to be defective in post-translational processing of nonglycosylated virus-coded structural proteins. Utilizing such mutants, in combination with sensitive radioimmunological assays, we demonstrate the existence of a 72,000-molecular-weight precursor polyprotein (Pr72gag) encoded by a region of the SMRV genome designated gag. Post-translational cleavage of this precursor polyprotein gives rise to virion structural proteins of 35,000 (p35), 16,000 (p16), 12,000 (p12), and 9,000 (p9) molecular weight. Three of these viral proteins, p35, p16, and p9, are shown to be phosphorylated. Analysis of viral antigen expression in cell lines nonproductively infected with either of two replication-defective SMRV mutants or mink cells productively infected with wild-type SMRV resulted in the detection of several SMRV Pr72gag intermediate cleavage products. Adjacent proteins within such intermediates are identified by use of specific competition immunoassays, and the intracistropic order of individual structural proteins with SMRV Pr72gag was tentatively deduced as NH2-p16-p12-p35-p9-COOH.     

Human Anti-Varicella-Zoster Virus (VZV) Recombinant Monoclonal Antibody Produced after Zostavax Immunization Recognizes the gH/gL Complex and Neutralizes VZV Infection

Varicella-zoster virus (VZV) is a ubiquitous, highly cell-associated, and exclusively human neurotropic alphaherpesvirus. VZV infection is initiated by membrane fusion, an event dependent in part on VZV glycoproteins gH and gL. Consistent with its location on the virus envelope, the gH/gL complex is a target of neutralizing antibodies produced after virus infection. One week after immunizing a 59-year-old VZV-seropositive man with Zostavax, we sorted his circulating blood plasma blasts and amplified expressed immunoglobulin variable domain sequences by single-cell PCR. Sequence analysis identified two plasma blast clones, one of which was used to construct a recombinant monoclonal antibody (rec-RC IgG). The rec-RC IgG colocalized with VZV gE on the membranes of VZV-infected cells and neutralized VZV infection in tissue culture. Mass spectrometric analysis of proteins immunoprecipitated by rec-RC IgG identified both VZV gH and gL. Transfection experiments showed that rec-RC IgG recognized a VZV gH/gL protein complex but not individual gH or gL proteins. Overall, our recombinant monoclonal anti-VZV antibody effectively neutralizes VZV and recognizes a conformational epitope within the VZV gH/L protein complex. An unlimited supply of this antibody provides the opportunity to analyze membrane fusion events that follow virus attachment and to identify multiple epitopes on VZV-specific proteins.     

A Raf-1-related p110 polypeptide associates with the CD4-p56lck complex in T cells.

The CD4 and CD8 antigens on T cells have been shown to associate with the Src family member p56lck and a GTP-binding protein, p32. The identification of receptor interactions with intracellular mediators is essential in the elucidation of downstream signals mediated by engagement of these receptor complexes. In this study, we report the detection of an additional 110-kDa polypeptide (p110) associated with the CD4-p56lck complex in human peripheral blood T lymphocytes and leukemic T-cell lines. p110 bound preferentially to CD4-p56lck as an assembled complex and poorly, if at all, to the individual components. p110 was recognized directly by an antiserum to the C-terminal region of the serine/threonine kinase Raf-1 and is related to a p110 polypeptide detected in anti-Raf-1 immunoprecipitates. Despite its association with the CD4-p56lck complex, p110 was found to be phosphorylated predominantly on serine residues. Furthermore, phorbol ester treatment of cells resulted in a transient increase in the detection of p110 associated with CD4-p56lck, concomitant with the modulation of CD4-p56lck from the cell surface. This Raf-1-related p110 is therefore likely to play a role in signals generated from the CD4-p56lck complex. p110 may serve as a bridge between the CD4-p56lck complex and the serine/threonine kinase pathways of T-cell activation.     

Shared antigenic determinants between two distinct classes of proteins in cells infected with herpes simplex virus

Guinea pig antisera and mouse monoclonal antibodies against a 40,000-molecular-weight nucleocapsid protein (p40) of herpes simplex virus types 1 and 2 immunoprecipitated 40,000- and 80,000-molecular-weight classes of soluble proteins from infected cell extracts. The soluble 40,000-molecular-weight protein class (intracellular p40) appeared as a cluster of three to four closely spaced bands of proteins having molecular weights ranging between 39,000 and 45,000, whereas the soluble 80,000-molecular-weight protein class (intracellular p80) appeared as a doublet of bands. The peptide map of intracellular p40 closely resembled the maps of the p40 and p45 proteins of nucleocapsids, but it showed both differences and similarities when compared with the peptide map of intracellular p80. Pulse-chase experiments suggested that intracellular p80 was not a precursor of intracellular p40. We conclude that the intracellular p40 and p80 protein classes share common antigenic determinants, presumably reflecting similar amino acid sequences, although they have distinct differences in protein structure.     

The ribosomal L5 protein is associated with mdm-2 and mdm-2-p53 complexes.

Throughout the purification of the mdm-2 or mdm-2-p53 protein complexes, a protein with a molecular weight of 34,000 was observed to copurify with these proteins. Several monoclonal antibodies directed against distinct epitopes in the mdm-2 or p53 protein coimmunoprecipitated this 34,000-molecular-weight protein, which did not react to p53 or mdm-2 polyclonal antisera in a Western immunoblot. The N-terminal amino acid sequence of this 34,000-molecular-weight protein demonstrated that the first 40 amino acids were identical to the ribosomal L5 protein, found in the large rRNA subunit and bound to 5S RNA. Partial peptide maps of the authentic L5 protein and the 34,000-molecular-weight protein were identical. mdm-2-L5 and mdm-2-L5-p53 complexes were shown to bind 5S RNA specifically, presumably through the known specificity of L5 protein for 5S RNA. In 5S RNA-L5-mdm-2-p53 ribonucleoprotein complexes, it was also possible to detect the 5.8S RNA which has been suggested to be covalently linked to a percentage of the p53 protein in a cell. These experiments have identified a unique ribonucleoprotein complex composed of 5S RNA, L5 protein, mdm-2 proteins, p53 protein, and possibly the 5.8S RNA. While the function of such a ribonucleoprotein complex is not yet clear, the identity of its component parts suggests a role for these proteins and RNA species in ribosomal biogenesis, ribosomal transport from the nucleus to the cytoplasm, or translational regulation in the cell.     

Identification and Characterization of a Herpes Simplex Virus Gene Product Required for Encapsidation of Virus DNA

A mutant of herpes simplex virus type 1, 17tsVP1201, has a temperature-sensitive processing defect in a late virus polypeptide. Immunoprecipitation studies with monoclonal antibodies showed that the aberrant polypeptide in mutant virus-infected cells was the nucleocapsid polypeptide known as p40. Since a revertant, TS(+) for growth, processed the polypeptide normally under conditions restrictive for the mutant, the processing event must be essential for virus replication. Electron microscopic analysis of mutant virus-infected cells grown at the nonpermissive temperature revealed that the nuclei contained large aggregations of empty nucleocapsids possessing some internal structure. Therefore, although the mutant synthesized virus DNA at the nonpermissive temperature, the DNA was not packaged into nucleocapsids. When mutant virus-infected cells were shifted from 39 to 31 degrees C in the presence of cycloheximide, the polypeptide p40 was processed to lower-molecular-weight forms, and full nucleocapsids were detected in the cell nuclei. The aberrant polypeptide of the mutant, however, was not processed in cells mixedly infected with 17tsVP1201 and a revertant at the nonpermissive temperature, suggesting that the defect of the mutant was in the gene encoding p40 rather than in a gene of a processing enzyme.     

Identification with monoclonal antibodies of virus-specific DNA-binding proteins in the nuclei of cells infected with three serotypes of Marek''s disease virus-related viruses.

Two groups of virus-specific polypeptides were identified in the nuclei of infected cells by cross-reacting monoclonal antibodies with three serotypes of Marek's disease virus. Of these, a 135,000-molecular-weight polypeptide common to all three serotypes was found to bind to both double-stranded and single-stranded DNAs.     

Coronavirus JHM: Cell-Free Synthesis of Structural Protein p60

Sac(-) cells infected with murine coronavirus strain JHM shut off host cell protein synthesis and synthesized polypeptides with molecular weights of 150,000, 60,000, and 23,000. The 60,000- and 23,000-molecular-weight polypeptides comigrated with virion structural proteins p60 and p23, and the 60,000-molecular-weight protein was identified as p60 by tryptic peptide fingerprinting. Polyadenylate-containing RNA [poly(A) RNA] extracted from the cytoplasm of infected cells directed the synthesis of both 60,000- and 23,000-molecular-weight polypeptides in messenger-dependent cell-free systems derived from mouse L-cells and rabbit reticulocytes. The reticulocyte system also synthesized a 120,000-molecular-weight polypeptide that was specifically immunoprecipitated by antiserum raised against JHM virions. The identity of the 60,000- and 23,000-molecular-weight in vitro products was established by comigration with virion proteins, immunoprecipitation, and in the case of p60, tryptic peptide fingerprinting. The cytoplasmic poly(A) RNAs which encoded p60 and p23 sedimented in sucroseformamide gradients at 17S and 19S, respectively, and were clearly separable. These RNAs were among the major poly(A) RNA species synthesized in the cytoplasm of actinomycin D-treated cells late in infection, and the in vitro translation of size-fractionated RNA released from polysomes confirmed that they represent physiological mRNA's. These results suggest that the expression of the coronavirus JHM genome involves more than one subgenomic mRNA.     

Purification of measles virus and characterization of subviral components.

Purified measles virus was obtained from [35S]methionine-labeled cells infected at 33 degrees C and maintained in the absence of fetal calf serum. The pellet that was produced by a single high-speed ultracentrifuge spin of culture medium contained virus of purity sufficient for structural analysis. Purified virions contain seven polypeptides with estimated molecular weights of: L, 200,000; G, 80,000; P2, 70,000; NP, 60,000; A, 43,000; F1, 41,000; and M, 37,000, as determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis under reducing conditions. Treatment of virions with 0.25% trypsin resulted in a less dense particle which lacked polypeptides G and F1. Solubilization of the viral membrane with the detergent Triton X-100 in low-salt buffer resulted in the loss of the G polypeptide, whereas in the presence of 1 M KCl, Triton X-100 also removed most of the M polypeptide. The nucleocapsids (p = 1.3) obtained from virions treated with Triton X-100 and 1 M KCl contained the L, P2, NP, and M polypeptides. Nucleocapsids isolated from the cytoplasm of infected cells were predominantly composed of the NP polypeptide with smaller amounts of either polypeptide P2 or novel polypeptides, related to NP, with estimated molecular weights of 56,000 to 58,000 and 45,000 to 46,000. A significant amount of polypeptide L was always found in association with nucleocapsids isolated either from virions or from the cytoplasm of infected cells. A membrane component containing the viral membrane polypeptides G, F1, and M was also isolated from infected cells. The data presented here thus suggest that L is an integral part of the nucleocapsid complex. In addition, 37,000-molecular-weight polypeptide (M) appears to have the function described for the matrix proteins of other paramyxoviruses.     

Monoclonal antibody to the amino-terminal L sequence of murine leukemia virus glycosylated gag polyproteins demonstrates their unusual orientation in the cell membrane.

To analyze cell surface murine leukemia virus gag protein expression, we have prepared monoclonal antibodies against the spontaneous AKR T lymphoma KKT-2. One of these antibodies, 43-13, detects an AKR-specific viral p12 determinant. A second monoclonal antibody, 43-17, detects a novel murine leukemia virus-related antigen found on glycosylated gag polyproteins (gp95gag, gp85gag, and gp55gag) on the surface of cells infected with and producing ecotropic endogenous viruses, but does not detect antigens within these virions. The 43-17 antibody immunoprecipitates the precursor of the cell surface gag protein whether in its glycosylated or unglycosylated state, but does not detect the cytoplasmic precursor of the virion gag proteins (Pr65gag). Based on these findings, we have localized the 43-17 determinant to the unique amino-terminal part of the glycosylated gag polyprotein (the L domain). We have determined that gp95gag contains L-p15-p12-p30-p10 determinants, whereas gp85gag lacks the carboxyterminal p10 determinant, and gp55gag lacks both p30 and p10 carboxy terminal determinants. Analysis of cell surface gag expression with the 43-17 antibody leads us to propose that the L domain plays a crucial role in (i) the insertion and orientation of murine leukemia virus gag polyproteins in the cell membrane and (ii) the relative abundance of expression of AKR leukemia virus versus Moloney murine leukemia virus glycosylated gag polyproteins in infected cells.     

Immunity to varicella-zoster viral glycoproteins, gp I (gp 90/58) and gp III (gp 118), and to a nonglycosylated protein, p 170

Humoral and cellular immunity against two major glycoproteins (gp) of varicella-zoster virus (VZV), gp I (gp 90/58) and gp III (gp 118), and against a nonglycosylated phosphoprotein (p 170) was demonstrated in human subjects. Primary VZV infection was accompanied by the development of IgG to gp I (mean titer 1:200), gp III (mean titer 1:132), and p 170 (mean titer 1:331). Increased IgG antibody production to each of the VZV proteins occurred during recurrent VZV infection with mean titers to gp I of 1:29512, to gp III of 1:15848, and to p 170 of 1:15848. Persistent high titers to gp III (mean titer 1:891) and to p 170 (mean titer 1:2238) were observed in 75% and 88% of VZV-immune subjects, respectively. T lymphocytes which proliferated on stimulation with gp I, gp III, and p 170 developed with primary VZV infection. VZV-immune subjects had mean transformation indices of 4.2 +/- 0.70 SE to gp I, 4.7 +/- 1 SE to gp III, and 3 +/- 0.39 SE to p 170. Among individual subjects, humoral and cellular immunity was not always detected to all three of the VZV proteins. Resolution of primary VZV infection and maintenance of VZV latency did not require a host response to each of these major viral proteins.     

Feline leukemia virus: biochemical and immunological characterization of gag gene-coded structural proteins.

The major non-glycosylated structural proteins of feline leukemia virus have been isolated, and competition immunoassays have been developed for each. These proteins include the 27,000- to 30,000-molecular-weight major internal antigen designated p30, a 15,000-molecular-weight protein (p15), an acidic protein of 12,000 molecular weight (p12), and a highly basic 10,000-molecular-weight protein (p10). Immunologically and biochemically corresponding proteins of feline and murine leukemia viruses have been identified. and, on the basis of analogy to the known sequence of a prototype type C virus of mouse origin, the map order of the gag region of the feline type C viral genome has been tentatively deduced as NH2-p15-p12-p10-COOH. The demonstration of two feline leukemia virus gag gene-coded proteins, p15 and p12, expressed in the form of an uncleaved precursor in a mink cell line nonproductively transformed by feline sarcoma virus provides indirect support for the proposed sequence.     

Characterization of a major protein with a molecular weight of 160,000 associated with the viral capsid of Epstein-Barr virus.

A monoclonal antibody designated V3 was produced against a late protein associated with the Epstein-Barr virus-induced viral capsid antigen complex. The antibody reacted with discrete patches in the nuclei of infected cells as well as with virus particles, as shown by immunofluorescence and ultrastructural immunoperoxidase staining. The molecular weight of the protein precipitated by this monoclonal antibody was ca. 160,000. All anti-viral capsid antigen antibody-positive sera tested in an enzyme-linked immunosorbent assay reacted with this purified protein. The synthesis of the antigen was inhibited by phosphonoacetic acid but was not affected by tunicamycin, indicating that this was a late nonglycosylated viral protein. No differences were noted between the protein isolated from the P3HR-1 and B-95-8 cell lines as determined by immunoprecipitation and peptide mapping. By isoelectric focusing, this protein had a pI on the basic side ranging from 7.5 to 9.0.     

Immune reactive measles virus polypeptides on the cell's surface: turnover and relationship of the glycoproteins to each other and to HLA determinants

To better understand the mechanism(s) whereby antibody and complement and cytotoxic lymphocytes lyse infected cells, we studied the structure, interrelationship and turnover of measles virus polypeptides expressed on the cell's surface. Of the 6 major viral structural polypeptides, L, HA, P, NC, F, and M, found in purified virions or infected cells, only 2, the HA and F, resided on the surface of infected cells. The HA was present primarily in the form of a 160k dimer, and F was identified as a 64k polypeptide migrating distinct from other viral polypeptides. With reduction, the HA migrated as a 80k monomer, and F0, after cleavage, was found to be composed of a 42k nonglycosylated polypeptide, F1, and a 24k glycosylated protein, F2. The relationship between F0 and F1 and between the HA dimer and monomer was verified by tryptic peptide mapping. The turnover of HA and F from the cell's surface was 10 and 9 hr, respectively. However, in the presence of specific antibody after a marked loss of viral antigen from the surface, the turnover for HA and F was 15 and 12 hr, respectively. Despite being independent molecules, HA and F were closely linked, as they moved together (co-capped) over the plasma membrane when incubated with monospecific or monoclonal antibody. In contrast, neither HA nor F co-capped with the major histocompatibility antigens or with other host cell proteins, which indicates a separation between these host cell proteins and measles viral glycoproteins on the cell's surface.     

Three major glycoprotein genes of varicella-zoster virus whose products have neutralization epitopes

Varicella-zoster virus (VZV) codes for approximately eight glycosylated polypeptides in infected cell cultures and in virions. To determine the number of serologically distinct glycoprotein gene products encoded by VZV, we have developed murine monoclonal antibodies to purified virions. Of 10 monoclonal antibodies which can immunoprecipitate intracellular VZV antigens and virion glycoproteins, 1 (termed gA) reacted with gp105, 1 (termed gB) reacted with gp115 (intracellular only), gp62, and gp57, and 8 (termed gC) reacted with gp92, gp83, gp52, and gp45. The anti-gA monoclonal antibody neutralized VZV infectivity in the absence of complement. All eight anti-gC monoclonal antibodies neutralized only in the presence of complement. An anti-gB monoclonal antibody obtained from another laboratory also neutralizes in the absence of complement. Since the above reactivities account for all major detectable VZV glycoprotein species, the data strongly suggest that VZV has three major glycoprotein genes which encode glycosylated polypeptides with neutralization epitopes.     

The 1,629-nucleotide open reading frame located downstream of the Autographa californica nuclear polyhedrosis virus polyhedrin gene encodes a nucleocapsid-associated phosphoprotein.

A 78-kDa protein was produced in bacteria from a clone of the 1,629-nucleotide open reading frame located immediately downstream from the polyhedrin gene of Autographa californica nuclear polyhedrosis virus. The identity of this protein was confirmed by its reactivity with peptide antiserum and amino terminal peptide sequencing after purification from transformed bacteria. The polypeptide was used to produce polyclonal antisera in rabbits. Immunoblot analysis of insect cells infected with the baculovirus indicated that two related proteins with molecular masses of 78 and 83 kDa were synthesized late in infection. Biochemical fractionation studies indicated that both of these proteins were present in purified nucleocapsids from budded and occluded virus preparations. Immunoprecipitation of 32P-labeled proteins and treatment of purified nucleocapsids with alkaline phosphatase demonstrated that the 83-kDa protein was a phosphorylated derivative of the 78-kDa protein. Furthermore, immunoelectron microscopy revealed that the proteins were localized to regions of nucleocapsid assembly within the infected cell and appeared to be associated with the end structures of mature nucleocapsids.     

The cytoplasmic domain of alphavirus E2 glycoprotein contains a short linear recognition signal required for viral budding.

Intracellular alphavirus nucleocapsids express a binding site for the cytoplasmic domain of the viral E2 spike glycoprotein. This binding site is recognized by the anti-idiotype monoclonal antibody, F13. The monoclonal anti-anti-idiotype antibody, raised against F13 and designated 3G10, recognizes the carboxy-terminal eight residues of the E2 cytoplasmic domain in Semliki Forest virus (SFV), identifying this as the signal for nucleocapsid interaction. F13 binding to cells infected with SFV or a second alphavirus, Sindbis virus, is inhibited by a synthetic peptide corresponding to the entire 31 residue cytoplasmic domain (E2c), and also by a synthetic peptide corresponding to the eight residue epitope recognized by 3G10. Both E2c and the eight residue peptide inhibited viral budding in microinjection experiments and when conjugated to colloidal gold are bound specifically to nucleocapsids in infected cells. These results identify a short linear signal in the E2 cytoplasmic domain required for the interaction with nucleocapsids which leads to budding of at least two alphaviruses from infected cells.