The product of the avian erythroblastosis virus erbB locus is a glycoprotein

Avian erythroblastosis virus (AEV) induces both erythroblastosis and fibrosarcomas in susceptible birds. A locus, v-erbB, within the viral genome has been implicated in AEV-mediated oncogenesis. We report here the detection and partial characterization of the protein product of the v-erbB oncogene in AEV-transformed cells. We obtained the antisera necessary for our analysis by expressing a portion of the molecularly cloned v-erbB locus in Escherichia coli and immunizing rabbits with the resulting bacterial erbB polypeptide. Antisera directed against the bacterial polypeptide reacted with v-erbB proteins obtained from virus-infected avian cells. By three criteria—tunicamycin inhibition, lectin binding and metabolic labeling with radioactive sugar precursors—the product of the v-erbB gene appears to be a glycoprotein.     

The erbB gene of avian erythroblastosis virus is a member of the src gene family

The erbB gene of an avian erythroblastosis virus, AEV-H, was determined to be 1812 nucleotides long and was predicted to code for a protein of 67,638 daltons. Unexpectedly, a sequence of 285 amino acids in the middle of the protein showed a significant homology (38%) with the sequence in the carboxy terminus of p60^src. The nucleotide sequence of a mutant of AEV-H, td-130, which induces sarcomas but not erythroblastosis in chicken, was also analyzed. A deletion of 169 nucleotides was identified in the 3′ half of the erbB gene, indicating that the gene codes for a truncated protein with the predicted molecular weight of 46,667. These findings suggest that the homologous domain of erbB protein with its N-terminal portion is sufficient for the transformation of fibroblasts and that one-third of the carboxy-terminal domain has a key role for the transformation of erythroid cells.     

Phosphorylation of the erbB gene product from an avian erythroblastosis virus-transformed chick fibroblast cell line

Polyclonal antiserum prepared against the human epidermal growth factor receptor immunoprecipitated four proteins of Mr = 66,000, 68,000, 74,000, and 82,000 from avian erythroblastosis virus-transformed chick embryo fibroblasts (cell line AEV-C23) which seemed to be related to the erbB gene product. The Mr = 66,000 and 68,000 proteins chased into the Mr = 74,000 and 82,000 proteins in pulse-chase experiments. The Mr = 68,000 and 82,000 proteins were found to be phosphorylated primarily on serine and threonine residues and contained minor amounts of phosphotyrosine. Tryptic peptide analysis of these phosphoproteins revealed several major peptides, and treatment of cells with the tumor promoter 12-O-tetradecanoyl-phorbol-13-acetate resulted in the appearance of an additional phosphopeptide. 12-O-Tetradecanoyl-phorbol-13-acetate also inhibited growth of AEV-C23 cells in soft agar and in monolayer culture. In vitro phosphorylation of Mr = 68,000 and 74,000 proteins in immunoprecipitates occurred on tyrosine with lesser amounts of phosphoserine and phosphothreonine detected.     

Temperature-sensitive mutants of avian erythroblastosis virus: surface expression of the erbB product correlates with transformation

The v-erbB gene of avian erythroblastosis virus (AEV) codes for an integral plasma membrane glycoprotein, gp74erbB. Expression of gp74erbB and its intracellular precursors, gp66erbB and gp68erbB, has been studied in cells transformed by two temperature-sensitive mutants of AEV. After shift to 42 degrees C, the processing of gp68erbB is blocked in tsAEV-transformed, but not in wtAEV-transformed, erythroblasts and fibroblasts. In addition, gp74erbB disappears from the surface of tsAEV cells within 12 hr after shift. Thus tsAEV mutants probably bear a lesion in v-erbB that affects the maturation and subcellular localization of gp74erbB. The tsAEV erythroblasts, when "committed" to differentiation by a pulse-shift to 42 degrees C, reexpress gp74erbB during terminal differentiation at 36 degrees C. This suggests that tsAEV erythroblasts become insensitive to the transforming functions of gp74erbB at a certain stage of differentiation.     

Molecular cloning and characterization of the chicken DNA locus related to the oncogene erbB of avian erythroblastosis virus.

Chicken cell DNA contains sequences which are homologous to the avian erythroblastosis virus oncogene v-erb. These cellular sequences (c-erb) have been isolated from a library of chicken cell DNA fragments generated by partial digestion with AluI and HaeIII and shown to be shared by at least two loci in the chicken DNA. One of them, denoted c-erbB, contains approximately 1.8 kilobase pairs of chicken DNA homologous to the 3' part of the v-erb oncogene (v-erbB). Restriction mapping studies show that the c-erbB DNA sequences homologous to v-erbB are distributed among six EcoRI fragments located in a single genomic region. Heteroduplexes between v-erbB in viral RNA and cloned c-erbB DNA show that the chicken DNA sequences homologous to v-erbB are interrupted by 11 DNA sequences not present in the v-erb oncogene. We conclude from our data that the c-erbB locus might represent the cellular progenitor for the v-erbB domain of the v-erb oncogene.     

Transforming capacities of avian erythroblastosis virus mutants deleted in the erbA or erbB oncogenes

Mutants of avian erythroblastosis virus (AEV) were constructed by deleting large nucleotide segments in each of the viral oncogenes termed v-erbA and v-erbB. Mutants in erbA (erbA ^?B⁺) retained the ability to transform fibroblasts in vitro, and these cells exhibited most of the transformation characteristics that typify wild-type AEV-transformed fibroblasts. In addition, the mutants induced small erythroid colonies upon infection of bone marrow cells in culture. Chickens inoculated with erbA ^?B⁺ virus or with erbA ^?B⁺-transformed cells developed sarcomas or atypical erythroid leukemias. The erythroid cells transformed in vivo or in vitro by the erbA ^?B⁺ viruses appeared not to be as tightly blocked in differentiation as wild-type transformed cells. In contrast, fibroblasts infected with the erbA ⁺B^? mutant resembled normal cells in all transformation parameters tested, and no bone marrow cell transformation was observed with the mutant. The results indicate that the main transforming properties of AEV are encoded in erbB and that its effects are enhanced by erbA.     

Mutation of a protein kinase C phosphorylation site in the erbB protein of avian erythroblastosis virus.

Tumor promoter-stimulated phosphorylation of threonine 98 of the erbB protein of avian erythroblastosis virus (AEV) correlates with inhibition of erbB-dependent mitogenesis. To more clearly define the role of phosphorylation of this residue in regulation of the activity of the erbB protein, we have constructed erbB mutations which encode alanine (Ala-98), tyrosine (Tyr-98), or serine (Ser-98) at position 98. The biosynthesis and stability of the three mutant proteins were similar to those of the wild-type erbB protein, and all three retained the ability to transform chicken embryo fibroblasts. Treatment of transformed CEF with 12-tetradecanoylphorbol-13-acetate (TPA) stimulated incorporation of 32Pi into wild-type and mutant erbB proteins and resulted in a slight decrease in the electrophoretic mobilities of all the erbB proteins. Tryptic maps of erbB phosphopeptides showed no endogenous or TPA-stimulated phosphorylation of alanine 98 or tyrosine 98 in cells transformed by the Ala-98 and Tyr-98 mutants. Analysis of tryptic phosphopeptides by high-pressure liquid chromatography revealed that TPA treatment of cells stimulated phosphorylation of other sites of the erbB protein in addition to threonine 98. A high endogenous level of phosphorylation of serine 98 of the Ser-98 mutant protein was found, and TPA treatment of cells did not result in further phosphorylation of this residue. Cells transformed by wild-type and mutant AEV were equally sensitive to TPA-dependent inhibition of growth in soft agar and TPA-dependent inhibition of [3H]thymidine incorporation. TPA treatment inhibited tyrosine phosphorylation to a similar extent in cells transformed by wild-type or Ala-98 AEV. These data indicate that phosphorylation of threonine 98 of the erbB protein is not responsible for TPA-dependent inhibition of growth of AEV-transformed cells or TPA-induced inhibition of erbB-dependent tyrosine phosphorylation. TPA-stimulated phosphorylation of the erbB protein at other sites may mediate these effects. The data also show that subtle changes in a phosphorylation site (i.e., changing threonine to serine) can drastically alter recognition by protein kinases.     

Induction of high-grade anti-tumor immunity by use of a recombinant H-2Kb/avian erythroblastosis virus erbB gene transfectant

Summary The recombinant H-2K^b-erbB gene, encoding for a part of the H-2 class I antigen and the kinase domain of the V-erbB peptide, was successfully introduced into murine mastocytoma P815 variant P1.HTR cells, which resulted in low but significant cell-surface expression of the hybrid gene product. When the chimeric gene transfectant was inoculated into the CDF₁ mice, it soon grew but regressed thereafter. The tumorigenicity of this transfectant was lower than the H-2K^b gene transfectant that expressed the H-2K^b antigen at a comparable level. These CDF₁ mice that had received the chimeric gene transfectant obtained a high-grade anti-tumor immunity against the challenge of a high dose of parental tumor. Corresponding to these observations, anti-tumor cytotoxic T lymphocytes, which lyse parental P1.HTR cells but not syngeneic L1210 or NS-1 tumor cells, were developed in the peritoneal cavity of mice that had been inoculated with the transfectant and parental tumor. Definite antibody activity binding to parental P1.HTR tumor cells was also demonstrated in the sera of these mice, precipitating 40-kDa, 74-kDa and 98-kDa molecules from the surface of the radiolabeled P1-HTR tumor cells. The results suggested that the chimeric H-2-erbB gene transfectant efficiently triggers both cellular and humoral anti-tumor immune responses.     

Isolation and characterization of multiple human genes homologous to the oncogenes of avian erythroblastosis virus

Human DNA sequences complementary to the oncogenes v-erbA and v-erbB of avian erythroblastosis virus have been isolated from a genomic DNA library. Two clones, lambda he-A1 and lambda he-A2, were related to the erbA gene and one to the erbB gene (lambda he-B). The two erbA genes were only distantly related to each other as judged from hybridization analysis. Furthermore, human chromosomal DNA appears to contain one or two additional genes analogous to the lambda he-A2 sequence, whereas the mouse genome contained only two genes complementary to lambda he-A1 and lambda he-A2, respectively. Polyadenylated RNA species, 5.0 kb in size, were found in the human HeLa and the human hematopoietic K562 cell lines, suggesting that at least some of the erb-related genes are active and do not represent pseudogenes. Taken together, the data demonstrate that two distantly related classes of erbA genes exist in human and mouse DNA, and that multiple copies of genes belonging to one of these two classes exist in the human genome.     

Identification and characterization of pseudorabies virus glycoprotein gM as a nonessential virion component.

Sequence analysis within BamHI fragment 3 of the pseudorabies virus (PrV) genome revealed an open reading frame homologous to the UL10 gene of herpes simplex virus. A rabbit antiserum directed against a synthetic oligopeptide representing the carboxy-terminal 18 amino acids of the predicted UL10 product recognized a major 45-kDa protein in lysates of purified Pr virions. In addition, a second protein of 90 kDa which could represent a dimeric form was observed. Enzymatic deglycosylation showed that the PrV UL10 protein is N glycosylated. Therefore, it was designated PrV gM according to its homolog in herpes simplex virus. A PrV mutant lacking ca. 60% of UL10 coding sequences was able to productively replicate on noncomplementing cells, demonstrating that PrV gM is not required for viral replication in cell culture. However, infectivity of the mutant virus was reduced and penetration was delayed, indicating a modulatory role of PrV gM in the initiation of infection.     

Cell-free translation of avian erythroblastosis virus RNA

Avian erythroblastosis virus (AEV) RNA rescued from nonproducer cells by superinfection with a helper virus is translated into three polypeptides in the messenger-dependent rabbit reticulocyte lysate. A 75,000 molecular weight polypeptide (P75AEV) is synthesized from 28S RNA and is encoded by the 5' section of the AEV RNA, including gag-related and AEV-specific sequences. The P75AEV synthesized in infected cells and the P75AEV synthesized in the cell-free system are electrophoretically identical. A 44,000 molecular weight polypeptide (P44AEV) is synthesized from 20-24S RNA, apparently from the 3' section of the AEV-specific RNA sequence. A minor 37,000 molecular weight polypeptide (P37AEV) is synthesized from 20S AEV RNA. A comparison is drawn between the cell-free products of MC29 and AEV RNAs.     

Structural domains of the avian erythroblastosis virus erbB protein required for fibroblast transformation: dissection by in-frame insertional mutagenesis.

Avian erythroblastosis virus (AEV) induces erythroblastosis and fibrosarcomas. The viral erbB protein is required for AEV-mediated oncogenesis. To explore the structural aspects of the v-erbB polypeptide necessary for its oncogenic function, we created a series of small in-frame insertions in different domains of the v-erbB oncogene. AEV genomes bearing lesions within the v-erbB kinase domain demonstrated a drastically decreased ability to transform avian fibroblasts, establishing a functional role for this structurally conserved oncogene domain. In contrast, mutations in the extracellular domain, between the transmembrane region and the kinase domain, or at the extreme C terminus of the v-erbB protein had no effect on AEV-mediated fibroblast transformation. One lesion within the v-erbB kinase domain, a 10-amino acid insertion, produced a temperature-sensitive mutant capable of fibroblast transformation at 36 degrees C but not at 41 degrees C, suggesting that small in-frame insertions have general utility for the in vitro creation of conditional mutants.     

Isolation and characterization of chicken DNA homologous to the two putative oncogenes of avian erythroblastosis virus

The genome of avian erythroblastosis virus contains two independently expressed genetic loci (v-erbA and v-erbB) whose activities are probably responsible for oncogenesis by the virus. Both loci are closely related to nucleotide sequences found in the DNA and RNA of chickens and other vertebrates. We have isolated and characterized chicken DNA homologous to v-erbA and v-erbB. The two viral genes are represented by separate domains within chicken DNA (c-erbA and c-erbB), which are separated by a minimum of 12 kilobases (kb) of DNA and may not be linked at all. The nucleotide sequences shared by the viral and cellular erb loci are colinear, but the cellular loci are interrupted by multiple intervening sequences of various lengths. Polyribosomes prepared from normal chicken embryos contain two polyadenylated RNAs transcribed from c-erbA and two transcribed from c-erbB. The evident coding regions of these RNAs represent an unusually small fraction of the lengths of the RNAs, as if the 3′ untranslated domains of the RNAs might be exceptionally large (3–11 kb). These findings indicate that the c-erb loci are normal vertebrate genes rather than genes of cryptic endogenous retroviruses, and that they may have a role in the metabolism of normal cells. It appears that the viral erb genes, like most other retrovirus oncogenes, have been copied from cellular genes. In the viral genome, the two genes are devoid of introns, but they remain independently expressed loci, and they remain colinear with the coding domains of their cellular progenitors.     

Transfection by DNAs of avian erythroblastosis virus and avian myelocytomatosis virus strain MC29.

Chicken embryo fibroblasts and NIH 3T3 mouse cells were transformable by DNAs of chicken cells infected with avian myelocytomatosis virus strain MC29 or with avian erythroblastosis virus. Transfection of chicken cells appeared to require replication of MC29 or avian erythroblastosis virus in the presence of a nontransforming helper virus. In contrast, NIH 3T3 cells transformed by MC29 or avian erythroblastosis virus DNA contained only replication-defective transforming virus genomes.     

Purification and chemical characterization of the major glycoprotein of avian myeloblastosis virus.

The major glycoprotein of avian myeloblastosis virus (AMV) has been purified to an apparent state of homogeneity by gel filtration on a Sepharose 4B column in the presence of 6 m guanidine hydrochloride followed by dialysis against distilled water and then extraction with chloroform-methanol. The AMV glycoprotein remains soluble in the aqueous phase whereas contaminating proteins precipitate, either upon dialysis against distilled water or after treatment with chloroform-methanol.Carbohydrate, represented by glucosamine, mannose, galactose, fucose, and sialic acid, constitutes 40% of the weight of AMV glycoprotein. Glucosamine is the major carbohydrate component whereas fucose and sialic acid are present in relatively low amount. Amino acid analysis indicates a relatively high content of aspartic and glutamic acid, serine, threonine, and glycine. Based on SDS-polyacrylamide gel electrophoresis, a molecular weight value of 77,500 ± 500 was determined for AMV glycoprotein.     

Identification and characterization of pseudorabies virus glycoprotein H.

On the basis of DNA sequence analysis, it has recently been shown that the pseudorabies virus (PrV) genome encodes a protein homologous to glycoprotein H (gH) of other herpesviruses (B. Klupp and T.C. Mettenleiter, Virology 182:732-741, 1991). To obtain antibodies specific for gH(PrV), rabbits were immunized with synthetic peptides representing two potential epitopes on gH(PrV) as predicted by computer analysis. The antipeptide sera recognized the gH precursor polypeptide pgH translated in vitro from an in vitro-transcribed mRNA. Western blot (immunoblot) analyses of purified pseudorabies virions using these antisera revealed specific reactivity with a protein with an apparent molecular mass of 95 kDa. Specificity of the reaction could be demonstrated by competition experiments with respective peptides. Analysis of PrV deletion mutants defective in genes encoding known glycoproteins proved that gH(PrV) constitutes a novel PrV glycoprotein not previously found. Treatment of purified virion preparations with endoglycosidase H reduced the apparent molecular mass of gH(PrV) to 90 kDa, indicating the presence of N-linked high-mannose (or hybrid) carbohydrates in mature virions. Removal of all N-linked carbohydrates by N-glycosidase F resulted in a product of 76 kDa. In summary, our results demonstrate the existence of gH in PrV as a structural component of the virion.     

Identification and characterization of the UL56 gene product of herpes simplex virus type 2

The UL56 gene product of herpes simplex virus (HSV) has been shown to play an important role in viral pathogenicity. However, the properties and functions of the UL56 protein are little understood. We raised rabbit polyclonal antisera specific for the UL56 protein of HSV type 2 (HSV-2) and examined its expression and properties. The gene product was identified as three polypeptides with apparent molecular masses ranging from 32 to 35 kDa in HSV-2-infected cells, and at least one species was phosphorylated. Studies of their origins showed that the UL56 protein of HSV-2 is also translated from the upstream in-frame methionine codon that is not present in the HSV-1 genome. Synthesis was first detected at 6 h postinfection and was not abolished by the viral DNA synthesis inhibitor phosphonoacetic acid. Indirect immunofluorescence studies revealed that the UL56 protein localized to both the Golgi apparatus and cytoplasmic vesicles in HSV-2-infected and single UL56-expressing cells. Deletion mutant analysis showed that the C-terminal hydrophobic region of the protein was required for association with the cytoplasmic membrane and that the N-terminal proline-rich region was important for its translocation to the Golgi apparatus and cytoplasmic vesicles. Moreover, the results of protease digestion assays and sucrose gradient fractionation strongly suggested that UL56 is a tail-anchored type II membrane protein associated with lipid rafts. We thus hypothesized that the UL56 protein, as a tail-anchored type II membrane protein, may be involved in vesicular trafficking in HSV-2-infected cells.