Characterization of the 55K adenovirus type 5 E1B product and related proteins.

In addition to major proteins of 19K and 55K (176 and 496 residues, 176R and 496R, respectively), early region 1B (E1B) of human adenovirus type 5 (Ad5) is predicted to encode at least three other polypeptides of 156R, 93R and 84R that share 79 amino-terminal residues with 496R. We have used a series of specific antipeptide sera to identify and partially characterize these proteins. 84R was produced in large amounts, 156R somewhat less, and 93R at very low levels. Synthesis of 176R, 496R, as well as the E2A 72K DNA-binding protein commenced shortly after that of E1A proteins in Ad5-infected KB cells. Production of 156R, 93R and 84R began somewhat later, but prior to the synthesis of the late structural protein IX and hexon. 156R, which is composed of the 79 amino-terminal and 77 carboxy-terminal amino acids of 496R, migrated on SDS-PAGE as two species which appeared to differ by their degree of phosphorylation. 156R and 496R yielded identical tryptic phosphopeptides that contained both phosphoserine and phosphothreonine, and one of these was immunoprecipitated by a serum specific for the carboxy terminus. These results suggested that Ser-490 and/or Ser-491 as well as Thr-495 are major sites of phosphorylation in these proteins.

Phosphorylation at the carboxy terminus of the 55-kilodalton adenovirus type 5 E1B protein regulates transforming activity.

The 55-kDa product of early region 1B (E1B) of human adenoviruses is required for viral replication and participates in cell transformation through complex formation with and inactivation of the cellular tumor suppressor p53. We have used both biochemical and genetic approaches to show that this 496-residue (496R) protein of adenovirus type 5 is phosphorylated at serine and threonine residues near the carboxy terminus within sequences characteristic of substrates of casein kinase II. Mutations which converted serines 490 and 491 to alanine residues decreased viral replication and greatly reduced the efficiency of transformation of primary baby rat kidney cells. Such mutant 496R proteins interacted with p53 at efficiencies similar to those of wild-type 496R but only partially inhibited p53 transactivation activity. These results indicated that phosphorylation at these carboxy-terminal sites either regulates the inhibition of p53 or regulates some other 496R function required for cell transformation.

Individual adenovirus E1B proteins induce transformation independently but by additive pathways.

The specific contributions of human adenovirus type 5 early region 1B (E1B) proteins were examined using mutants which synthesize these products individually. In cooperation with E1A, transformation of primary baby rat kidney cells was achieved with either the 176R protein or 496R protein alone, albeit at an efficiency considerably less than that observed when both were present. These results indicate that transformation mediated by either E1B product can proceed independently, but that the processes involved are additive.

Persistence of vesicular stomatitis virus in cloned interleukin-2-dependent natural killer cell lines.

We have investigated virus-lymphocyte interactions by using cloned subpopulations of interleukin-2-dependent effector lymphocytes maintained in vitro. Cloned lines of H-2-restricted hapten- or virus-specific cytotoxic T lymphocytes (CTL) and alloantigen-specific CTL were resistant to productive infection by vesicular stomatitis virus (VSV). In contrast, cloned lines of natural killer (NK) cells were readily and persistently infected by VSV, a virus which is normally highly cytolytic. VSV-infected NK cells continued to proliferate, express viral surface antigen, and produce infectious virus. Furthermore, persistently infected NK cells showed no marked alteration of normal cellular morphology and continued to lyse NK-sensitive target cells albeit at a slightly but significantly reduced level. The persistence of VSV in NK cells did not appear to be caused by the generation of temperature-sensitive viral mutants, defective interfering particles, or interferon. Consequently, studies comparing the intracellular synthesis and maturation of VSV proteins in infected NK and mouse L cells were conducted. In contrast to L cells, in which host cell protein synthesis was essentially totally inhibited by infection, the infection of NK cells caused no marked diminution in the synthesis of host cell proteins. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis of immunoprecipitates of viral proteins from infected cells showed that the maturation rate and size of VSV surface G glycoprotein were comparable in L cells and NK cells. Nucleocapsid (N) protein synthesis also appeared to be unaffected in NK cells. In contrast, the viral proteins NS and M appeared to be selectively degraded in NK cell extracts. Mixing experiments suggested that a protease in NK cells was responsible for the selective breakdown of VSV NS protein. Finally, VSV-infected NK cells were resistant to lysis by virus-specific CTL, suggesting that persistently infected NK cells may harbor virus and avoid cell-mediated immune destruction in an immunocompetent host.

Protein kinase activity associated with immunoprecipitates of the vesicular stomatitis virus phosphoprotein NS.

Monospecific antisera prepared to denatured N and NS proteins of the Indiana serotype of VSV were used to investigate the protein associations in extracts of virus-infected cells. Complexes precipitated from the cytoplasm of infected cells with either anti-N or anti-NS serum both contained N and NS proteins but could be differentiated by the absence of any trace of M protein in the complexes precipitated with anti-NS serum. Immunoprecipitation with anti-NS serum of NS protein from the soluble cytoplasmic protein pool always resulted in coprecipitation of N protein suggesting a possible functional association of these proteins in the soluble fraction. The association of protein kinase activity with complexes containing NS protein was demonstrated by the phosphorylation of NS serine residues when immunoprecipitates containing NS protein were incubated with [32P]ATP in vitro. In protein aggregates precipitated with antibody after high salt dissociation of viral proteins it was also possible to demonstrate the presence of a c-src-like protein kinase activity as previously shown by G.M. Clinton, N.G. Guerina, H. Guo, and H.S. Huang (J. Biol. Chem. 257, 3313-3319 (1982) ).

Heterotypic exclusion between vesicular stomatitis viruses of the New Jersey and Indiana serotypes.

Co-infection of cells with vesicular stomatitis viruses of the Indiana and New Jersey serotypes results in interference. Using specifically-labelled immunofluorescent antibodies, it was demonstrated that within any one co-infected cell, one virus serotype replicated to the relative exclusion of the other serotype. This result was further substantiated by an examination of the virus serotypes released by infectious centres co-infected with both viruses. Dominance of one serotype over the other was shown to be a function of the relative multiplicity of the two viruses. Superinfection by the second serotype at a higher multiplicity resulted in dominance by the second virus during the early period (up to 1-5 h) post-infection. After this time, the minority virus was able to overcome this dominance. Dominance of the majority virus was also abolished by u.v; inactivation. Cell protein synthesis appeared to be less affected in cells infected with both serotypes than when infection was with a single serotype.