The simian-virus-40 large-tumor antigen in replicating viral chromatin. A salt-resistant protein-DNA interaction

Association of herpes simplex virus type 1 ICP8 and ICP27 proteins with cellular RNA polymerase II holoenzyme

Herpes simplex virus 1 (HSV-1) infection causes the shutoff of host gene transcription and the induction of a transcriptional program of viral gene expression. Cellular RNA polymerase II is responsible for transcription of all the viral genes, but several viral proteins stimulate viral gene transcription. ICP4 is required for all delayed-early and late gene transcription, ICP0 stimulates transcription of viral genes, and ICP27 stimulates expression of some early genes and transcription of at least some late viral genes. The early DNA-binding protein, ICP8, also stimulates late gene transcription. We therefore investigated which HSV proteins interact with RNA polymerase II. Using immunoprecipitation and Western blotting methods, we observed the coprecipitation of ICP27 and ICP8 with RNA polymerase II holoenzyme. The association of ICP27 with RNA polymerase II was detectable as early as 3 h postinfection, while ICP8 association became evident by 5 h postinfection, and the association of both was independent of viral DNA synthesis. Infections with ICP27 gene mutant viruses revealed that ICP27 is required for the association of ICP8 with RNA polymerase II, while studies with ICP8 gene deletion mutants showed no apparent role for ICP8 in the association of ICP27 with RNA polymerase II. The association of ICP27 and ICP8 with RNA polymerase II holoenzyme appeared to be independent of nucleic acids. We hypothesize that the interaction of ICP27 with RNA polymerase II holoenzyme reflects its role in stimulating early and late gene expression and/or its role in inhibiting host transcription and that the interaction of ICP8 with RNA polymerase II holoenzyme reflects its role in stimulating late gene transcription.

Simian virus 40 T-antigen DNA helicase is a hexamer which forms a binary complex during bidirectional unwinding from the viral origin of DNA replication

The role of simian virus 40 (SV40) large tumor antigen (T antigen) as a DNA helicase at the replication fork was studied. We found that a T-antigen hexamer complex acts during the unidirectional unwinding of appropriate DNA substrates and is localized directly in the center of the fork, contacting the adjacent double strand as well as the emerging single strands. When bidirectional DNA unwinding, initiated at the viral origin of DNA replication, was analyzed, a larger T-antigen complex that is simultaneously active at both branch points of an unwinding bubble was observed. The size and shape of this helicase complex imply that the T-antigen dodecamer complex, assembled at the origin and active in the localized melting of duplex DNA, is subsequently also used to continue DNA unwinding bidirectionally. Then, however, the dodecamer complex does not split into two hexamer subunits that track along the DNA; rather, the DNA is threaded through the intact complex, with the concomitant extrusion of single-stranded loops.

T-antigen is not bound to the replication origin of the simian virus 40 late transcription complex

Simian virus 40 tumor antigen (T-antigen) plays a central role in determining which gene is transcribed from viral DNA late in infection. Results from several studies have led to a model in which the binding of T-antigen to the viral origin of replication results in repression of transcription from the stronger early gene promoter and stimulation of transcription from the late gene promoter. We have tested this model by determining directly the occupancy of the T-antigen binding site in the origin of replication of the late transcription complex. Thus, viral transcription complexes were digested with BglI, a restriction enzyme that cuts in the viral replication origin. The enzyme cleaved 78(+/- 12)% of the late transcription complexes. Control experiments demonstrated that cleavage is blocked when T-antigen is bound to the origin site, that exogenously added T-antigen can bind to the site in the transcription complex, and that T-antigen is not released during isolation of the complex. These results indicate that most of the late transcription complexes do not have T-antigen bound to the origin site, and are therefore inconsistent with models that require this site to be occupied by T-antigen to maintain proper regulation of gene transcription late in infection.

Sequence independent duplex DNA opening reaction catalysed by SV40 large tumor antigen

Simian virus 40 (SV40) large tumor antigen (T antigen) is mainly localized in the nucleus where it exhibits two biochemical properties: DNA binding and helicase activity. Both activities are necessary for viral DNA replication and may also enable T antigen to modulate cellular growth. Here we present biochemical and electron microscopic evidence that the helicase activity can start at internal sites of fully double-stranded DNA molecules not containing the SV40 origin or replication. Using T antigen specific monoclonal antibodies, this unwinding reaction can be biochemically divided in an initiation (duplex opening) and a propagation step. The duplex opening reaction (as well as the propagation step) does not depend on a specific DNA sequence or secondary structure. In addition, we have found that T antigen forms an ATP dependent nucleoprotein complex at double-stranded DNA, which may be an essential step for the sequence independent duplex DNA opening reaction.

Occurrence of bovine herpesvirus-1 DNA in nucleosomes and chromatin of bovine herpesvirus-1-infected cells: identification of a virion-associated protein in chromatin of infected cells

During virus replication a fraction of the intranuclear DNA of bovine herpesvirus-1 (BHV-1) was present in the nucleosomal structure of infected eukaryotic cells, and virion proteins were associated with the chromatin of virus infected cells. Synthesis of BHV-1 DNA in bovine embryonic lung (BEL) cells was found to begin four to six hours post-infection (p.i.) and to continue until at least 24 hours p.i. Chromatin isolated from infected cell nuclei at ten hours p.i. contained both BHV-1 viral and cell DNA. No BHV-1 DNA was found in mock-infected cell chromatin. Micrococcal nuclease cleavage products of both mock-infected and BHV-1-infected BEL cell nuclei produced monomers and multimers of unit fragment size which were indistinguishable from each other and displayed a typical nucleosome pattern on agarose gels. Southern analyses of micrococcal nuclease digests of infected cell nuclei indicated that some of the intranuclear BHV-1 DNA was present in a nucleosomal form. Three new proteins (with approximate molecular weights: 125,000, 42,000, and 17,000) were identified in chromatin isolated from BHV-1-infected BEL cells at ten hours p.i. These proteins were not present in mock-infected BEL cell chromatin. The 17,000 molecular weight protein was recognized by BHV-1 virion specific antisera. Neither of the two larger proteins appear to bind DNA from BHV-1. The smallest protein co-migrates with cellular histones, but no DNA binding proteins with the same molecular weight were found in the virion.

Monoclonal antibodies as probes for a function of large T antigen during the elongation process of simian virus 40 DNA replication

Various monoclonal antibodies specific for simian virus 40 large tumor antigen (T antigen) inhibit the elongation process of viral DNA replication in an in vitro system. The results provide strong evidence for a function intrinsic to T antigen during ongoing replicative-chain elongation. The antibody inhibition studies were further used to establish a correlation between the known biochemical activities of T antigen and its function during the elongation phase. The data demonstrate that, in addition to DNA binding and ATPase, a third function of T antigen is required for replicative chain elongation. This function is most probably related to the recently described DNA helicase activity of T antigen. This conclusion is based on the following results: aphidicolin treatment of actively replicating simian virus 40 minichromosomes causes a partial uncoupling of parental DNA strand separation and DNA synthesis; the strand separation reaction is blocked by the same monoclonal antibodies which strongly inhibit the elongation process. DNA helicase activity of isolated T antigen is equally well inhibited by the same set of monoclonal antibodies that affect minichromosome replication in vitro.

An immunoaffinity purification procedure for SV40 large T antigen

A rapid purification procedure for SV40 large T antigen has been developed which combines the use of an adenovirus-SV40 hybrid virus which overproduces large T antigen, and immunoaffinity chromatography on an anti-large T monoclonal antibody coupled to protein A Sepharose. The protein exhibits the p53-binding, ATPase, and sequence-specific DNA-binding activities of T antigen. The purification procedure can be completed in 1 day and allows the isolation of milligram amounts of large T in excellent yield. The pure protein is extremely antigenic and is tolerant of iodination to high specific activity, permitting the development of a competition radioimmunoassay for large T that reliably detects nanogram amounts of the protein.

A large-tumor-antigen-specific monoclonal antibody inhibits DNA replication of simian virus 40 minichromosomes in an in vitro elongation system

In productively infected cells, a fraction of large-tumor antigen (T antigen) is tightly bound to replicating simian virus 40 (SV40) minichromosomes and does not dissociate at salt concentrations of greater than 1 M NaCl. We present electronmicrograms demonstrating the presence of T antigen on the replicated sections of replicating SV40 minichromosomes. We also show that the fraction of tightly bound T antigen is recognized by antibodies from mouse tumor serum and, more specifically, by a particular T-antigen-specific monoclonal antibody, PAb 1630. A second T-antigen-specific monoclonal antibody, PAb 101, does not react with the T-antigen fraction remaining on replicating SV40 chromatin at high salt concentrations. We used an in vitro replication system which allows, via semiconservative DNA replication, the completion of in vivo-initiated replicative intermediate DNA molecules. We show that monoclonal antibody PAb 1630, but not monoclonal antibody PAb 101, inhibits viral DNA replication. We discuss the possibility that SV40 T antigen may play a role in chain elongation during SV40 chromatin replication.

Chromatin structure and DNA replication

The structure of (3H) thymidine pulse labeled, replicating chromatin differs from that of non replicating chromatin by several operational criteria which are related to the higher nuclease sensitivity of replicating chromatin. We summarize the structural changes that we observe using replicating chromatin as substrate for micrococcal nuclease. The data suggest a more extended configuration of replicating compared to non replicating chromatin. We use these data to discuss a model of the chromatin structure in the vicinity of replication forks. Finally, we present data to show that the reversion of structural changes in replicative chromatin depends on continued DNA replication.