Expression of the Major Viral Glycoprotein of Avian Tumor Virus in Cells of chf(+) Chicken Embryos

The expression of gp85, the major viral glycoprotein of avian tumor virus, by certain chicken embryonic cells was studied by the use of sera directed to antigenic determinants of subgroup E viral gp85. As analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis of immune precipitates prepared with lysates of cells that had been labeled with [³H]glucosamine, chf(+) chicken embryo cells synthesize molecules of gp85 which possess type and probably also group antigenic specificities. Under similar conditions of analysis, no gp85 or antigenically related components could be detected in lysates of chf(−) cells.     

Subcellular localization of the env-related glycoproteins in Friend erythroleukemia cells.

A scheme was developed for the subcellular fractionation of murine erythroleukemia cells transformed by Friend leukemia virus. The subcellular localization of the env-related glycoproteins was determined by immune precipitation with antiserum against gp70, the envelope glycoprotein of the helper virus, followed by gel electrophoresis. In cells labeled for 2 h with [35S]methionine, the glycoprotein encoded by the defective spleen focus-forming virus, gp55SFFV, was found primarily in the nuclear fraction and in fractions containing dense cytoplasmic membranes such as endoplasmic reticulum. A similar distribution was noted for gp85env, the precursor to gp70. The concentration of viral glycoproteins in the nuclear fraction could not be accounted for by contamination with endoplasmic reticulum. In pulse-chase experiments, neither glycoprotein underwent major redistribution. However, labeled gp85env disappeared from intracellular membranes with a half-time of 30 min to 1 h, whereas labeled gp55SFFV was stable during a 2-h chase. In plasma membrane preparations with very low levels of contamination with endoplasmic reticulum, gp70 was the major viral env-related glycoprotein detected; a minor amount of gp55SFFV and no gp85env could be detected. The unexpected result of these experiments is the amount of viral glycoproteins found in the nuclear fraction. Presence of viral proteins in the nucleus could be relevant to the mechanism of viral leukemogenesis.     

Extracellular cleavage of the glycoprotein precursor of Rous sarcoma virus.

The kinetics of cleavage of pr92gp, the precursor of the two glycoproteins of Rous sarcoma virus gp85 and gp35, were followed. Viral glycoproteins were detected by immunoprecipitation with anti-gp85 and anti-gp35 serum. It could be shown in pulse-chase experiments that little or no intracellular cleavage of the precursor took place during the time in which the majority of newly synthesized viral glycoprotein was exported from the cells. Soon after its synthesis, however, pr92gp underwent some modification that made it migrate slightly faster on sodium dodecyl sulfate-polyacrylamide gels. Under steady state conditions the precursor was shown to be the predominant form of intracellular viral glycoprotein. Virus which was harvested every 2 min from infected cells prelabeled for 90 min with [3H]mannose contained mostly uncleaved and only a little mature glycoprotein. By incubation of this freshly released virus in serum-free buffer, the majority of the glycoprotein precursor could be cleaved into mature gp85 and gp35. Virus harvested every 10 min contained only mature glycoproteins.     

Biosynthesis of an unglycosylated envelope glycoprotein of Rous sarcoma virus in the presence of tunicamycin.

Cells stably infected with Rous sarcoma virus were treated with tunicamycin to prevent the glycosylation of the precursor (pr92gp) to the two viral envelope glycoproteins gp85 and gp35. Pretreatment of the cells for 4 h with the antibiotic resulted in a 90% reduction in [3H]mannose incorporation into total cellular glycoproteins, intracellular viral glycoproteins, and released virus particles. Protein synthesis and virus particle formation were not significantly affected by the treatment. A new polypeptide made in the presence of the drug was identified by immunoprecipitation of pulse-labeled cell lysates with monospecific anti-gp85 and anti-gp35 sera. This polypeptide, migrating on sodium dodecyl sulfate-polyacrylamide gels as a molecule of 62,000 daltons (pr62), contained no [3H]mannose, was labeled with [S35]methionine and [3H]arginine, could not be chased into the higher-molecular-weight glycosylated form, and contained the same [3H]arginine tryptic peptides as pr92gp. The unglycosylated pr62 was still detectable 2 h after the pulse labeling of the cells. The lack of glycosylation of pr62 did not seem to reduce its stability. No clear evidence for the incorporation of this molecule or its cleavage products into viral particles could be obtained. To code for an envelope polypeptide of 62,000 daltons, only about 1,500 nucleotides or 15% of the total coding capacity of the virus are needed.     

Sites of synthesis of viral proteins in avian sarcoma virus-infected chicken cells.

We determined the sites of synthesis of avian sarcoma virus-specific proteins in infected chicken cells by immunoprecipitation of the products synthesized in vitro by free and membrane-bound polyribosomes; 85% of Pr76, the precursor of the viral internal structural proteins (group-specific antigens), was synthesized on free polyribosomes, and 15% was synthesized on membrane-bound polyribosomes. Pr92, the lycosylated precursor of the viral glycoproteins (gp85 and gp35), was synthesized exclusively on membrane-bound polyribomes, which is consistent with its role as a membrane protein. When we investigated the site of synthesis of pp60src, the product of the avian sarcoma virus src gene, we found that 90% was synthesized on free polyribosomes, whereas 10% was detected on membrane-bound polyribosomes. The implications of these results with respect to the subcellular location of pp60src are discussed.     

Identification of a precursor protein to the major glycoproteins of mouse mammary tumor virus.

Mouse mammary tumor virus-producing cultures of mouse mammary tumor cells synthesize a viral-related polypeptide of molecular weight of 73,000 (gp 73) which is rapidly labeled during a short pulse but disappears during the chase concomitantly with the appearance of label in the virion glycoproteins gp 49 and gp 37.5/33.5. The addition of the protein synthesis-inhibitor cycloheximide to the chase medium has little effect on this conversion. Treatment of the proposed precursor with alpha-chymotrypsin leads to the formation of a polypeptide of molecular weight 49,000, similar to the major virion glycoprotein. A comparison of tryptic digest maps of the glycoproteins involved supports the hypothesis that both the viral glycoproteins gp 49 and gp 37.5/33.5 are derived from gp 73.     

Identification of a Precursor Protein to the Major Glycoproteins of Mouse Mammary Tumor Virus

Mouse mammary tumor virus-producing cultures of mouse mammary tumor cells synthesize a viral-related polypeptide of molecular weight of 73,000 (gp 73) which is rapidly labeled during a short pulse but disappears during the chase concomitantly with the appearance of label in the virion glycoproteins gp 49 and gp 37.5/33.5. The addition of the protein synthesis-inhibitor cycloheximide to the chase medium has little effect on this conversion. Treatment of the proposed precursor with α-chymotrypsin leads to the formation of a polypeptide of molecular weight 49,000, similar to the major virion glycoprotein. A comparison of tryptic digest maps of the glycoproteins involved supports the hypothesis that both the viral glycoproteins gp 49 and gp 37.5/33.5 are derived from gp 73.     

Inhibition of Rous sarcoma virus replication by 2-deoxyglucose and tunicamycin: identification of an unglycosylated env gene product.

Two inhibitors of glycosylation, 2-deoxyglucose and tunicamycin, depressed the synthesis of infectious Rous sarcoma virus greater than 100-fold. Under the same conditions only a two- to threefold decrease in the production of virus particles was observed. The noninfectious particles had a lower density (1.145 g/ml) in isopycnic sucrose gradients and lacked the two virion glycoproteins, gp85 and gp37, found on infectious virions. The four internal structural proteins of the virus, p27, p19, p15, and p12, appeared to be assembled normally into the noninfectious virus. Polypeptides related to the Rous sarcoma virus glycoproteins were immunoprecipitated from pulse-labeled Rous sarcoma virus (Prague strain, subgroup B)-transformed cells. pr95gp, the polyprotein precursor to gp85 and gp37, was the major protein precipitated from untreated cells. PR95GP, THE POLYPROTEIN PRECURSOR TO GP85 AND GP37, WAS THE MAJOR PROTEIN PRECIPITATED FROM UNTREATED CELLS. This was absent in both tunicamycin- and 2-deoxyglucose-treatec ells, and a new polypeptide of molecular weight 57,000 to 58,000 was the major species precipitated. In tunicamycin-treated cells this product was unstable and was degraded during a 2-h chase; in 2-deoxyglucose-treated cells, on the other hand, the polypeptide appeared to be more stable and underwent partial glycosylation. The synthesis and processing of pr76, the polyprotein precursor to the internal structural proteins of the virion, occurred normally in both treated and untreated cells. It is concluded that the unglycosylated env gene product is a polypeptide of molecular weight 57,000 to 58,000.     

Type-Common CP-1 Antigen of Herpes Simplex Virus Is Associated with a 59,000-Molecular-Weight Envelope Glycoprotein

The CP-1 antigen of herpes simplex virus type 1 (HSV-1) is a glycoprotein found in the soluble portion of infected cells, in detergent extracts of infected cell membranes, and in the envelope of purified virus. Antisera were prepared against a further purified form of CP-1 prepared from HSV soluble antigen mix; a glycoprotein, gp52, isolated from detergent-treated infected cells; and detergent extracts of purified virus. Each of the antisera reacted with CP-1 to give a single immunoprecipitin band of identity, and each antiserum neutralized the infectivity of HSV-1 and HSV-2. Our results suggested that the type-common determinants involved in the stimulation of neutralizing antibody resided on a 52,000-molecular-weight (52K) glycoprotein. The envelope of HSV contains several glycoproteins: one component at 59K and a complex of two or three components at 130K, none of which corresponds in molecular weight to gp52. Using the antisera as immunological probes, we performed pulse-chase experiments with [(35)S]methionine-labeled HSV-1-infected cells and followed the disposition of the glycoproteins during the infectious cycle. Each antiserum immunoprecipitated a (35)S-labeled 52K protein from lysates of cells pulse-labeled at 5 h after infection. By 10 h, the label was chased into a 59K protein also precipitable by each of the three antisera. The results suggest that gp52 is a precursor of gp59 and that the latter corresponds in molecular weight to one of the major glycoproteins of the virion envelope.     

Complete sequence of the Rous sarcoma virus env gene: identification of structural and functional regions of its product.

The amino-terminal amino acid sequences of gp85 and gp37, the envelope glycoproteins of Rous sarcoma virus (RSV), were determined. Alignment of these sequences with the amino acid sequence predicted from the complete nucleotide sequence of the Prague strain of RSV, subgroup C (PR-C), has allowed us to delineate the env gene-coding region of this virus. The coding sequences for gp85 and gp37 have been placed in an open reading frame that extends from nucleotide 5045 to nucleotide 6862 and predict sizes of 341 amino acids (36,962 molecular weight) for gp85 and 198 amino acids (21,566 molecular weight) for gp37. Carbohydrate makes a significant contribution to the observed molecular weights of these polypeptides--the amino acid sequence contains 14 potential glycosylation sites (Asn-X-Ser/Thr) in gp85 and two in gp37. Experiments aimed at estimating the number of carbohydrate side chains yielded results consistent with most or all of these sites being occupied. Although an initiation codon is located early (codon 4) in the open reading frame, it is likely that splicing yields an mRNA on which translation initiates at the same AUG as that of the gag gene to produce a nascent polypeptide in which gp85 is preceded by a 62-amino-acid-long leader peptide. This leader contains the hydrophobic sequence (signal sequence) necessary for translocation across the endoplasmic reticulum and is completely removed from the env gene product during translation. The polyprotein precursor, Pr95env, is cleaved to gp85 and gp37 at the carboxyl side of the basic sequence:-Arg-Arg-Lys-Arg-. gp85 is attached through a disulphide linkage to gp37, and although the positions of the cysteines involved in this linkage are not known, the presence of a 27-amino-acid-long hydrophobic region at the carboxy-terminus of gp37 is consistent with its role as a membrane anchor for the viral glycoprotein complex. The location of host range variable regions with respect to the possible tertiary structure of the complex is discussed.     

Viral proteins expressed on the surface of murine leukemia cells.

Leukemic cells of AKR mice contain as constituents of their membranes the murine leukemia virus envelope protein gp70 and the precursor polyprotein of the viral internal (core) structural proteins. Both gp70 and the core polyprotein are represented on the cell surface as glycoproteins, as evidenced by incorporation of [3H]glucosamine into their structure and the binding of these proteins to lectins. The glycosylated core polyprotein exists in at least two serologically distinguishable forms: the 95,000-dalton polyprotein reacts with antisera prepared against the viral proteins p30, p12, and p10, whereas the 85,000-dalton polyprotein reacts with antisera prepared against the viral proteins p30 and p12, but not p10. Additional heterogeneity in these cell surface polyproteins has been observed wtih leukemias induced by exogenous leukemia viruses. Spontaneous leukemia cells of AKR mice invariably express gp70 and the core polyprotein on their cell surface; normal thymocytes of young AKR mice express gp70, but not the core polyprotein on their surface.     

Characterization of herpesvirus sylvilagus glycoproteins released into the culture medium of infected cells: antisera to gp13 and gp32 neutralize viral infectivity in vitro and identify antigens on plasma membranes of infected cells.

Polypeptides released into the culture medium of herpesvirus sylvilagus-infected cells were identified by sodium dodecyl sulfate-polyacrylamide gel electrophoresis of extracellular fluid from [35S]methionine- and [3H]glucosamine-labeled cell cultures. Virus-induced glycoproteins 31, 32, and 33 (molecular weights of 62,000, 59,000, and 54,000, respectively) were the most abundant species and appeared predominantly in the culture medium. This observation, together with the known cell-associated nature of herpesvirus sylvilagus, suggested that virus-induced glycoproteins 31, 32, and 33 were specifically released. Immunization of rabbits with virus-induced glycoproteins 13 (molecular weight of 130,000) and 32 resulted in the production of antibodies that neutralized viral infectivity in vitro. Both antiserum to gp13 and antiserum to gp32 immunoprecipitated gp13, gp26, gp33a, gp45, and virus-induced polypeptide 39 (molecular weights of 130,000, 77,000, 49,000, 27,000, and 36,000, respectively) from [35S]methionine-labeled cell extracts as well as virus-induced glycoproteins 31, 32, and 33 from the culture medium. In addition, membrane immunofluorescence assays indicate that an antigen(s) reactive with anti-gp13/32 serum was located on the plasma membrane of infected cells.     

Bovine viral diarrhea virus proteins: relatedness of p175 with p80 and p125 and evidence of glycoprotein processing.

Three monoclonal antibodies, which recognized two nonoverlapping antigenic domains and were reactive to the bovine viral diarrhea virus (BVDV) p80 protein, were found to cross react with the p125 protein of both cytopathic and noncytopathic BVDVs and a molecular weight 175,000 BVDV protein (p175). Results from limited proteolysis and chemical cleavage experiments confirmed the relatedness of these three proteins. In pulse-chase experiments it was apparent that p175 was a transient protein, as it was diminished during the chase, with a half-life of about 30 min. However, both p125 and p80 were also observed in short-pulsed lysates. Furthermore, during the chase, radiolabel was not found to accumulate into p125 or p80. Rather, these two proteins were stable with half-lives greater than 2 h. A fourth nonglycosylated protein, p37, increased during the chase. Processing of several glycoproteins was evident in these experiments. A glycoprotein of molecular weight 75,000 (gp75) diminished during the chase period, while glycoproteins gp62, gp48, and gp25 appeared or increased during the chase period. In contrast, the glycoprotein gp53 was a major protein in pulse-labeled cell lysates and remained constant throughout the chase period. In further experiments two stable forms of p80 differing in intramolecular disulphide bonding were observed.     

Synthesis and glycosylation of polyprotein precursors to the internal core proteins of Friend murine leukemia virus

Synthesis and post-translational processing of murine leukemia virus proteins were analyzed in a murine cell line (Eveline) that produces large amounts of Friend lymphatic leukemia virus. Immunoprecipitation of l-[(35)S]methionine-labeled cell extracts demonstrated that several different virus-specific proteins antigenically related to the virion core (gag) proteins p12 and p30 become radioactive within 1 min of labeling and exhibit labeling kinetics characteristic of primary translation products. The most abundant of these were proteins with molecular weights of 75,000 and 65,000. There were, in addition, two large glycosylated polyproteins with apparent molecular weights of 220,000 and 230,000, which were precipitated by antisera to p30 or p12 but not by antiserum to the major envelope glycoproteins gp69/71. Several lines of evidence, including labeling with d-[(3)H]glucosamine and binding to insolubilized lectins, suggested that the 75,000-dalton internal core polyprotein is slowly processed to form a glycoprotein with an apparent molecular weight of 93,000. On the contrary, the 65,000-dalton protein appeared to be an immediate precursor to the virion core proteins. Its processing can involve intermediates containing p30 and p12 antigens with molecular weights of 50,000 and 40,000; however, the latter did not appear to be obligatory intermediates. The detection of the 40,000-dalton protein suggested that the genes for p30 and p12 are adjacent on the viral genome. These results indicated that there are several pathways of synthesis and post-translational processing of polyprotein precursors to the gag proteins and that several of these polyproteins are glycosylated. A comparison of gag precursor processing in rapidly growing, slowly growing, and stationary cells indicated that different pathways are favored under different conditions of cell growth. Our analysis of envelope glycoprotein synthesis has confirmed the existence of two rapidly labeled 90,000-dalton glycoproteins, which appear to be precursors to the envelope glycoproteins gp69/71.     

Synthesis and secretion of mucous glycoprotein by the gill of Mytilus edulis. I. Histochemical and chromatographic analysis of [14C]glucosamine bioincorporation

The ability of the isolated gill epithelium of Mytilus edulis to incorporate [14C]glucosamine as a precursor in the biosynthesis and secretion of mucous glycoproteins was investigated. Localization of mucous cells in the gill filament was achieved using histochemical staining techniques. Mucus cells containing neutral and acidic mucins were found in the lateral region, whereas mucus cells containing primarily neutral or sulfated mucins were found in the abfrontal region. Autoradiographic results showed that in both regions, the mucous cells were rich in content of the incorporated radiolabel. The secreted glycoproteins containing the incorporated radiolabel were analyzed by column chromatography using Bio-Gel P-2 and P-6. Two populations of the glycoproteins differing in molecular size were isolated. Upon alkaline reductive borohydride cleavage of the O-glycosidic linkages of the high molecular weight protein, about 70% of the radiolabel and 85% of the carbohydrate content were removed from the protein. The alkaline borohydride cleavage resulted in the formation of at least six oligosaccharide chains of various lengths of sugar units. Gas chromatographic analysis of the carbohydrate composition shows that the glycoproteins contain N-acetylglucosamine, N-acetylgalactosamine, and galactose, fucose, and mannose as the neutral monosaccharides. The above results indicate that the isolated gill epithelium of M. edulis is capable of incorporating [14C]glucosamine in the synthesis of secretable mucin-type glycoproteins.     

Lectin analysis of common glycoproteins detected on the surface of continuous microvascular endothelium in situ and in culture: identification of sialoglycoproteins

For many years, molecular interactions with vascular endothelium have been studied in vitro on cultured endothelial cells. Yet, it is clear that the different environmental conditions in vivo vs. in vitro may cause phenotypic drift and altered expression of cell surface molecules. In this study, we identify several endothelial surface proteins of similar apparent molecular mass by radioiodination of cultured microvascular cells and by intravascular radioiodination of rat heart endothelium in situ. The radioiodinated surface polypeptides detected by sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE) (followed by autoradiography) were subjected to lectin affinity chromatography in order to provide an additional screen for identifying common surface glycoproteins and a means for partial characterization of their glycans. With a battery of 18 lectins, seven major (gp140, gp120, gp100, gp85, gp75, gp60, gp47) and 6 minor (gp330, gp300, gp180, gp160, gp150, gp42) glycoproteins were identified on the cultured cells each with a different lectin binding profile. The lectin binding profiles of many endothelial glycoproteins in situ were similar to those of their counterparts in culture. A common set of seven major glycoproteins with the same apparent molecular masses was found in situ as well as in vitro. These common glycoproteins were characterized further using both sialidase digestion and sequential lectin affinity chromatography of cell lysates. Most of the glycoproteins appear to have both complex-type N-linked and O-linked glycans except for gp60 with only O-linked glycans, gp47 with only complex N-linked sugars, and gp42 with only simple N-linked sugars. A subset of sialoglycoproteins (gp140, gp120, gp100, gp60, gp47) was identified. One of them, gp120, is podocalyxin based on immunoprecipitation with specific antiserum and another one, gp60, is a recently identified albumin binding protein on the surface of cultured microvascular endothelial cells. This study shows that gp60 is indeed present on the surface of endothelium in situ and that it is a sialoglycoprotein with typical O-linked glycans. It is apparent that the continuous type of microvascular endothelium can indeed express in culture and in situ a common set of major glycoproteins.     

Molecular characterization of fetal antigens on red blood cells of chickens,Japanese quail,and quail-chicken hybrids

The molecular nature of chicken fetal antigen (CFA) and quail fetal antigen (QFA) was studied on embryonic red blood cells (RBCs) of the chicken, the Japanese quail, and the quail-chicken hybrid. Specific immunoprecipitation of radiolabeled membrane proteins followed by electrophoretic separation and autoradiography were used to identify the protein molecules carrying these fetal antigens. CFA was found on molecules of 24, 50, 88, 99, 130, 170, and 220 kd (kilodaltons) in the chicken and hybrid and on molecules of 24, 50, 99, and 170 kd in the Japanese quail. Similarly, quail fetal antigen was associated with 24-, 50-, 99-, and 170-kd molecules in the quail and hybrid and was not detected in the chicken. Partial proteolytic digestion of the 50- and 170-kd molecules isolated from RBCs of all sources showed remarkably similar peptide patterns. Likewise, two-dimensional separation of the CFA-positive and QFA-positive 50-kd molecules from quail RBCs revealed a similar pattern of at least nine isomorphic variants. Sequential depletions of quail embryonic RBC extracts with either anti-CFA or anti-QFA followed by immune precipitation with the reciprocal antiserum suggested that most of the cell surface proteins carrying QFA also have CFA on the same molecules. It is suggested that specific glycosylations of a variety of distinct molecular weight proteins determines the antigenic phenotype characterized as "fetal antigens."     

Synthesis and processing of viral glycoproteins in two nonconditional mutants of Rous sarcoma virus.

We have studied the pattern of glycoprotein synthesis in two nonconditional mutants of Rous sarcoma virus. One mutant, SE33, produces no viral particles but synthesizes Pr92env, which is cleaved intracellularly to mature glycoproteins. The second mutant, SE521, encodes a gPr92env which is not cleaved to gp85 or gp37 and therefore produces virions with the phenotype of Bryan RSV(-) or NY8. Neither of these mutants have detectable genomic deletions. The study of these mutants has led to the following conclusions. (i) In the absence of particle production or p15 synthesis, gPr92env can be cleaved to the mature glycoprotein which is found on the cell surface. (ii) Noncleaved gPr92env is not packaged into virions but is found on the cell surface. (iii) gPr92env alone can account for subgroup specific viral interference. (iv) gPr92env is probably transported to the cell surface before additional glycosylation or cleavage to mature virion glycoprotein. The nonprocessed precursor of SE521 appears to be glycosylated normally, and thus far we have been unable to determine the basis for the defect in this mutant.     

Posttranslational modifications distinguish the envelope glycoprotein of the immunodeficiency disease-inducing feline leukemia virus retrovirus.

The envelope glycoprotein (gp70) of a molecularly cloned, replication-defective feline leukemia virus (FeLV-FAIDS clone 61C) carries determinants for induction of fatal immunodeficiency disease, whereas the gp70 of its companion replication-competent, probably parent virus (clone 61E) does not. Immunoprecipitation analysis of the extracellular glycoproteins of 61E and EECC, a replication-competent viral construct composed of the 61C env and 3' long terminal repeat fused to the 61E gag-pol genes, demonstrated that the gp70 of EECC could be distinguished from that of 61E by both feline immune serum and a murine monoclonal antibody. Molecular weights of both the envelope precursor polyprotein (gp80) and the mature extracellular glycoprotein (gp70) of 61E were smaller than the corresponding proteins from the pathogenic EECC. Both the molecular weight disparity and monoclonal antibody discrimination of the two gp80s were abolished by inhibition of envelope protein glycosylation with tunicamycin, whereas the apparent gp70 size differences were resolved by enzymatic removal of N-linked oligosaccharides. Pulse-chase studies in EECC-infected cells demonstrated that processing of gp80 to gp70 was delayed and that this retardation of envelope glycoprotein processing could be simulated in 61E-infected cells by treatment with the glucosidase inhibitor N-methyldeoxynojirimycin, a compound that causes retention of oligosaccharides in the high-mannose form. The resultant 61E gp70 then could be recognized by sera from EECC-immunized cats. The presence of a higher content of sialic acid on the apathogenic 61E gp70 indicated that oligosaccharides of 61E and EECC gp70 were processed differently. These data suggested that the unique biochemical properties which distinguish the envelope glycoproteins of the FeLV-FAIDS variant from its companion apathogenic parent virus were responsible for T-cell cytopathicity and induction of immunodeficiency disease. Further biochemical characterization of these glycoproteins should be useful in understanding the pathogenic mechanisms of immunodeficiency disease induced by retroviruses.     

Proteins specified by herpes simplex virus. XIII. Glycosylation of viral polypeptides.

In the course of herpes simplex virus 1 (HSV-1) replication in human epidermoid carcinoma no. 2 cells, the synthesis and glycosylation of host cell proteins ceases and is replaced by the synthesis and glycosylation of virus-specified polypeptides. Analyses of the synthesis of viral glycoproteins show that the glycosylation of viral polypeptides occurs late in the virus growth cycle and that certain of the precursors to major vital glycoproteins are members of the gamma group of polypeptides, i.e., polypeptides synthesized at increasing rates until 12 to 15 h postinfection. Viral glycoproteins are formed by stepwise additions of heterosaccharide chains to completed precursor polypeptides. The precursor and the highly glycosylated product are separable by gel electrophoresis and are localized in different fractions of infected cells. Within 15 min of their synthesis, precursor polypeptides acquire heterosaccharide chains of about 2,000 molecular weight, which contain glucosamine but little or nor fucose or sialic acid. Both precursor and product of this first stage of glycosylation are absent or present in low concentrations in the surface membranes of the infected cell and in the virion. The partially glycosylated product is then conjugated further in a slow, discontinuous process to form the mature glycoprotein of the virion and plasma membrane. These mature products bear large heterosaccharide units with molecular weights greater than 4,000 to 5,000; these contain fucose and sialic acid as well as glucosamine. Heterosaccharide chains from infected and uninfected cells are distributed among discrete size classes and the smallest chains consist of multiple saccharide residues.