Sendai virus envelope glycoproteins become laterally mobile on the surface of human erythrocytes following fusion

Fluorescence photobleaching recovery has been employed to study the lateral mobility of the Sendai virus envelope glycoproteins (HN, neuraminidase/hemagglutinin protein (HN) fusion protein (F) on the surface of human erythrocytes. Our results indicate that the two viral glycoproteins are laterally immobile on the cell surface prior to fusion, and become mobile during the fusion process. The two fused glycoproteins are mobilized to the same extent (diffusion coefficients of 3.1-3.3 X 10(-10) cm2/sec with mobile fractions of 0.53-0.57 for both HN and F). Their mobilization is blocked under conditions that allow virus adsorption and hemagglutination, but not virus-cell or cell-cell fusion. These findings suggest a possible role for the lateral diffusion of the viral glycoproteins in the mechanism of cell-cell fusion, enabling them to perturb the membranes of adjacent cells and lead to cell-cell fusion.     

Dissecting the activating mutations in v-erbB of avian erythroblastosis virus strain R.

The v-erbB oncogene isolated from the R (or ES4) strain of avian erythroblastosis virus is capable of inducing erythroleukemia and fibrosarcomas. This oncogene differs from the proto-oncogene c-erbB, the avian homolog of the epidermal growth factor receptor, by its lack of an intact ligand-binding domain as well as additional alterations in its cytoplasmic coding sequences. By contrast, the insertionally activated c-erbB, a variant oncogene, which encodes a product that also lacks the ligand-binding domain but is otherwise unaltered in its cytoplasmic coding sequences, is capable of inducing leukemia but cannot induce sarcomas. In this report, we show that the critical changes for activating the sarcomagenic potential displayed by v-erbB R are two point mutations within the tyrosine kinase domain and an internal deletion of 21 amino acids in the carboxyl-terminal regulatory domain. The removal of the carboxyl-terminal autophosphorylation sites is not obligatory. These activating mutations (Arg-263 to His, Ile-384 to Ser, and the deletion of residues 494 to 514), when introduced singly into the insertionally activated c-erbB, all dramatically increase fibroblast-transforming potential. Arg-263 resides near the highly conserved HRD motif of the kinase domain, and its mutation to His increases the autophosphorylation activity. The other two mutations do not alter the intrinsic kinase activity and presumably affect other aspects of the receptor involved in growth signaling. Therefore, the high transforming potential of v-erbB R is a consequence of synergism among multiple activating mutations.     

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.     

Alterations in the developmental patterns of enzymes in chicken embryos infected with West Nile virus.

Infection of chicken embryos with West Nile (WN) virus, a group B togavirus containing structural lipids, caused a rapidly developing hypertriglyceridemia. Changes in the activity of several hepatic regulatory enzymes in glycolytic and lipogenic pathways occurred during infection. Compared to control values in embryos of the same age (16 days), an 8.8-fold increase in the specific activity of ATP-citrate lyase and a 5.6-fold increase in that of hexokinase were observed on the third day of WN virus infection. Hexose monophosphate shunt dehydrogenase specific activities were elevated twofold in virus-infected livers. Activities of malic enzyme and phosphofructokinase were also elevated in WN virus-infected livers. Malate dehydrogenase and NADP-linked isocitrate dehydrogenase levels showed little or no change during infection. The levels of pyruvate kinase and lactate dehydrogenase were decreased in virus-infected livers. Hepatic acetyl-CoA carboxylase activity was at least twofold higher in virus-infected embryos; however, following removal of low-molecular-weight compounds, the specific activities of this enzyme from infected and control embryos were virtually identical. The results of mixing experiments suggest that the low levels of carboxylase activity in control embryos may be due to the presence of enzyme inhibitor(s) which can be removed by gel filtration.The incorporation of radiolabeled precursors into cellular lipids by liver minces from virus-infected and uninfected embryos was measured. There was a twofold increase in carbohydrate incorporation in virus-infected liver as compared to uninfected liver; [¹⁴C]pyruvic acid was incorporated into lipids to the greatest extent. [1-¹⁴C]acetic acid, [U-¹⁴C]alanine, and [U-¹⁴C]leucine were incorporated very poorly in both infected and control livers. Twice as much [1-¹⁴C]oleic acid or [1-¹⁴C oleic]triolein was incorporated in WN-infected livers as in control. The relative distribution of neutral and polar lipids formed from each precursor was generally similar in infected and uninfected livers as determined by thin-layer chromatography of radiolabeled lipids. Except for a threefold increase in oxidation of [¹⁴C]glucose by virus-infected livers, the oxidations of carbohydrates and fatty acids were similar in infected and uninfected livers. The pentose phosphate pathway appears to be the major pathway utilized in glucose oxidation for both control and virus-infected livers. The results indicate that enhanced flux of metabolites into lipids reflects a virus-induced alteration in embryonic development: The enzyme patterns of infected embryos are more characteristic of older embryos or even newly hatched chicks.     

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.     

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.     

Substitution of 5' helper virus sequences into non-rel portion of reticuloendotheliosis virus strain T suppresses transformation of chicken spleen cells

The genome of the highly oncogenic avian retrovirus reticuloendotheliosis virus strain T (REV-T) differs from that of the helper virus reticuloendotheliosis virus strain A by a substitution (rel and a large deletion. Further deletions, constructed in vitro, within the helper-virus-related sequences of REV-T have little effect on the ability of the virus to transform chicken spleen cells in vitro. However, deletions that extend into rel abolish transformation. Substitution of helper-virus-related sequences for the deleted region in the non-rel portion of REV-T also abolishes transformation. Viruses with revertant phenotype were obtained both spontaneously and by construction in vitro from these substituted recombinants. The revertant viruses have various mutations, including deletions and insertions, in the helper-virus-related sequences. Thus the additional helper-virus-related sequences suppress expression of transformation in cis, and the deletion in REV-T seems necessary for expression of the transforming properties of the virus.     

Cell surface expression of v-fms-coded glycoproteins is required for transformation.

The viral oncogene v-fms encodes a transforming glycoprotein with in vitro tyrosine-specific protein kinase activity. Although most v-fms-coded molecules remain internally sequestered in transformed cells, a minor population of molecules is transported to the cell surface. An engineered deletion mutant lacking 348 base pairs of the 3.0-kilobase-pair v-fms gene encoded a polypeptide that was 15 kilodaltons smaller than the wild-type v-fms gene product. The in-frame deletion of 116 amino acids was adjacent to the transmembrane anchor peptide located near the middle of the predicted protein sequence and 432 amino acids from the carboxyl terminus. The mutant polypeptide acquired N-linked oligosaccharide chains, was proteolytically processed in a manner similar to the wild-type glycoprotein, and exhibited an associated tyrosine-specific protein kinase activity in vitro. However, the N-linked oligosaccharides of the mutant glycoprotein were not processed to complex carbohydrate chains, and the glycoprotein was not detected at the cell surface. Cells expressing high levels of the mutant glycoprotein did not undergo morphological transformation and did not form colonies in semisolid medium. The transforming activity of the v-fms gene product therefore appears to be mediated through target molecules on the plasma membrane.     

Identification of herpes simplex virus type 1 glycoproteins interacting with the cell surface.

To investigate the interaction of herpes simplex virus type 1 (HSV-1) with the cell surface, we studied the formation of complexes by HSV-1 virion proteins with biotinylated cell membrane components. HSV-1 virion proteins reactive with surface components of HEp-2 and other cells were identified as gC, gB, and gD. Results from competition experiments suggested that binding of gC, gB, and gD occurred in a noncooperative way. The observed complex formation could be specifically blocked by monospecific rabbit antisera against gB and gD. The interaction of gD with the cell surface was also inhibited by monoclonal antibody IV3.4., whereas other gD-specific monoclonal antibodies, despite their high neutralizing activity, were not able to inhibit this interaction. Taken together, these data provide direct evidence that at least three of the seven known HSV-1 glycoproteins are able to form complexes with cellular surface structures.     

Hormone-dependent terminal differentiation in vitro of chicken erythroleukemia cells transformed by ts mutants of avian erythroblastosis virus

Chicken erythroblast cell strains and a cell line transformed by ts mutants of avian erythroblastosis virus (AEV) terminally differentiate when shifted to the nonpermissive temperature (42°C). The differentiated cells resemble mature erythrocytes with respect to morphology and ultrastructure, expression of differentiation-specific cell-surface antigens, pattern of protein synthesis and hemoglobin content. Terminal differentiation is dependent on conditions favoring the differentiation of normal erythroid progenitor cells, including an erythropoietin-like factor. Colonies of ts AEV cells grown at 42°C in semisolid medium resemble erythrocyte colonies derived from normal erythroid progenitor cells. The colonies obtained were comparable in size or slightly larger than the late erythroid precursor (CFU-E) colonies. These results suggest that AEV-transformed cells are blocked at a stage of differentiation that is more advanced than that of the uninfected target cells. ts AEV cells are irreversibly committed to terminal differentiation within 20 to 30 hr after shift to 42°C.