Class of {varphi}X174 Mutants Relatively Deficient in Synthesis of Viral RNA

Nonpermissive cells infected with {varphi}X174 gene D amber mutants synthesized some sixfold less viral RNA than permissive cells. The decrease was unaffected by increasing the multiplicity of infection and was a consequence of an overall decrease in all viral RNA species. It is suggested that the gene D product may function in replicative form DNA unwinding to expose the template for transcription

Protein kinase CK2 phosphorylation regulates the interaction of Kaposi's sarcoma-associated herpesvirus regulatory protein ORF57 with its multifunctional partner hnRNP K

ORF57 protein of Kaposi's sarcoma-associated herpesvirus has a counterpart in all herpesvirus of mammals and birds and regulates gene expression at transcriptional and post-transcriptional levels. ORF57 was capable of self-interaction and bound a rapidly migrating form of heterogeneous nuclear ribonucleoprotein K (hnRNP K), a multifunctional cellular protein involved in gene expression. In virus infected cell extracts, ORF57 was present in a complex with hnRNP K that had protein kinase CK2 activity, and was phosphorylated by CK2. Different regions of ORF57 bound both catalytic α/α′ and regulatory β subunits of CK2. CK2 modification enhanced the ORF57–hnRNP K interaction, and may regulate the presence and activities of components in the complex. We suggest that ORF57 and hnRNP K interaction may modulate ORF57-mediated regulation of viral gene expression. Herpesviral ORF57 (Rhadinovirus) and ICP27 (Simplexvirus) proteins both interact with hnRNP K and CK2 implying that adaptation of the ancestral hnRNP K and CK2 to associate with viral regulatory ancestor protein likely pre-dates divergence of these Herpesviridae genera that occurred 200 million years ago

The Herpes Simplex Virus Type 1 US11 Protein Binds the Coterminal UL12, UL13, and UL14 RNAs and Regulates UL13 Expression In Vivo

The US11 protein of herpes simplex virus type 1 (HSV-1) is a small, highly basic phosphoprotein expressed at late times during infection. US11 localizes to the nucleolus in infected cells, can associate with ribosomes, and has been shown to bind RNA. The RNA substrates of US11 identified thus far have no apparent role in the virus lytic cycle, so we set out to identify a novel, biologically relevant RNA substrate(s) for this protein in HSV-1-infected cells. We designed a reverse transcriptase PCR-based protocol that allowed specific selection of a 600-bp RNA binding partner for US11. This RNA sequence, designated 12/14, is present in the coterminal HSV-1 mRNAs UL12, UL13, and UL14. We show that the binding of US11 to 12/14 is sequence-specific and mediated by the C-terminal domain of the protein. To elucidate the role of US11 in the virus life cycle, we infected cells with wild-type virus, a cosmid-reconstructed US11 HSV-1 null mutant, and a cosmid-reconstructed wild-type virus and analyzed expression of UL12, -13, and -14 during a time course of infection. These experiments revealed that this interaction has biological activity; at early times of infection, US11 down-regulates UL13 protein kinase mRNA and protein

Formation of Nuclear Foci of the Herpes Simplex Virus Type 1 Regulatory Protein ICP4 at Early Times of Infection: Localization, Dynamics, Recruitment of ICP27, and Evidence for the De Novo Induction of ND10-Like Complexes

Herpes simplex virus type 1 (HSV-1) has an intricate association with cellular nuclear structures known as ND10 or promyelocytic leukemia protein (PML) nuclear bodies. Parental viral genomes initially become juxtaposed to ND10, and then viral replication compartments develop from the ND10-associated genomes. Viral immediate-early (IE) regulatory protein ICP0 colocalizes with ND10 and then induces the degradation of critical ND10 component protein PML and therefore the release and dispersal of other ND10 proteins. The IE transcriptional regulatory protein ICP4 also forms foci at early times of infection, many of which are juxtaposed to ND10 and later develop into replication compartments, indicating that at least some of the initial ICP4 foci contain parental viral genomes. Here we report that the ICP4 foci also contain ICP27 and that their formation occurs extremely rapidly at locations just inside the nuclear envelope. By examining developing plaques or thinly seeded cells infected at high multiplicity, we found evidence to suggest that at least some of the ND10-viral nucleoprotein complex association could be attributed to de novo formation of ND10-like structures in response to incoming viral genomes. The ICP4 complexes associated efficiently with ND10 in cells infected with an ICP0-null mutant virus at high but not at low multiplicity, and the degree of association was reduced by the proteasome inhibitor MG132. Therefore, the interaction between viral nucleoprotein complexes and ND10 is in part due to a dynamic response by the cell. This response is modulated by functional ICP0, and cells that are productively or nonproductively infected in the absence of functional ICP0 can be distinguished by the relative locations of ICP4 foci and ND10 proteins

CK2 Protein Kinase Is Stimulated and Redistributed by Functional Herpes Simplex Virus ICP27 Protein

It has been shown previously (S. Wadd, H. Bryant, O. Filhol, J. E. Scott, T.-T. Hsieh, R. D. Everett, and J. B. Clements, J. Biol. Chem. 274:28991-28998, 2000) that ICP27, an essential and multifunctional herpes simplex virus type 1 (HSV-1) protein, interacts with CK2 and with heterogeneous ribonucleoprotein K (hnRNP K). CK2 is a pleiotropic and ubiquitous protein kinase, and the tetrameric holoenzyme consists of two catalytic α or α′ subunits and two regulatory β subunits. We show here that HSV-1 infection stimulates CK2 activity. CK2 stimulation occurs at early times after infection and correlates with redistribution of the holoenzyme from the nucleus to the cytoplasm. Both CK2 stimulation and redistribution require expression and cytoplasmic accumulation of ICP27. In HSV-1-infected cells, CK2 phosphorylates ICP27 and affects its cytoplasmic accumulation while it also phosphorylates hnRNP K, which is not ordinarily phosphorylated by this kinase, suggesting an alteration of hnRNP K activities. This is the first example of CK2 stimulation by a viral protein in vivo, and we propose that it might facilitate the HSV-1 lytic cycle by, for example, regulating trafficking of ICP27 protein and/or viral RNAs