Sequences flanking the pentanucleotide T-antigen binding sites in the polyomavirus core origin help determine selectivity of DNA replication.

Replication of the genomes of the polyomaviruses requires two virus-specified elements, the cis-acting origin of DNA replication, with its auxiliary DNA elements, and the trans-acting viral large tumor antigen (T antigen). Appropriate interactions between them initiate the assembly of a replication complex which, together with cellular proteins, is responsible for primer synthesis and DNA chain elongation. The organization of cis-acting elements within the origins of the polyomaviruses which replicate in mammalian cells is conserved; however, these origins are sufficiently distinct that the T antigen of one virus may function inefficiently or not at all to initiate replication at the origin of another virus. We have studied the basis for such replication selectivity between the murine polyomavirus T antigen and the primate lymphotropic polyomavirus origin. The murine polyomavirus T antigen is capable of carrying out the early steps of the assembly of an initiation complex at the lymphotropic papovavirus origin, including binding to and deformation of origin sequences in vitro. However, the T antigen inefficiently unwinds the origin, and unwinding is influenced by sequences flanking the T antigen pentanucleotide binding sites on the late side of the viral core origin. These same sequences contribute to the replication selectivity observed in vivo and in vitro, suggesting that the inefficient unwinding is the cause of the replication defect. These observations suggest a mechanism by which origins of DNA replication can evolve replication selectivity and by which the function of diverse cellular origins might be temporally activated during the S phase of the eukaryotic cell cycle.     

Requirements for species-specific papovavirus DNA replication.

Replication of papovavirus DNA requires a functional replication origin, a virus-encoded protein, large T antigen, and species-specific permissive factors. How these components interact to initiate and sustain viral DNA replication is not known. Toward that end, we have attempted to identify the viral target(s) of permissive factors. The functionally defined replication origins of polyomavirus and simian virus 40, two papovaviruses that replicate in different species (mice and monkeys, respectively), are composed of two functionally distinct domains: a core domain and an auxiliary domain. The origin cores of the two viruses are remarkably similar in primary structure and have common binding sites for large T antigen. By contrast, their auxiliary domains share few sequences and serve as binding sites for cellular proteins. It seemed plausible, therefore, that if cellular permissive factors interacted with the replication origin, their targets were likely to be in the auxiliary domain. To test this hypothesis we constructed hybrid origins for DNA replication that were composed of the auxiliary domain of one virus and the origin core of the other and assessed their capacity to replicate in a number of mouse and monkey cell lines, which express the large T antigen of one or the other virus. The results of this analysis showed that the auxiliary domains of the viral replication origins could substitute for one another in DNA replication, provided that the viral origin core and its cognate large T antigen were present in a permissive cellular milieu. Surprisingly, the large T antigens of the viruses could not substitute for one another, regardless of the species of origin of the host cell, even though the two large T antigens bind to the same sequence motif in vitro. These results suggest that species-specific permissive factors do not interact with the origin-auxiliary domains but, rather, with either the origin core or the large T antigen or with both components to effect DNA replication.     

Association of a cellular heat shock protein with simian virus 40 large T antigen in transformed cells.

The viral oncoprotein of simian virus 40, large T antigen (T-ag), is essential for viral replication and cellular transformation. To understand the mechanisms by which T-ag mediates its multifunctional properties, it is important to identify the cellular targets with which it interacts. A cellular protein of 73 kilodaltons (p73) which specifically associates with T-ag in simian virus 40-transformed BALB/c 3T3E cells has been identified. The binding of p73 to T-ag was demonstrated by coimmunoprecipitation analyses using polyclonal and monoclonal antibodies specific for T-ag. The interaction of p73 with T-ag was independent of T-ag complex formation with the cellular protein p53. Partial V8 protease cleavage maps for p73 and the cellular heat shock protein hsp70 were identical. Immunoblot analyses indicated that p73 complexed to T-ag was antigenically related to hsp70. T-ag deletion mutants were constructed that remove internal, amino-terminal, and carboxy-terminal sequences. These mutants mapped the p73 binding domain to the amino terminus of T-ag. The specific dissociation of p73 from the p73/T-ag complex was mediated by ATP; GTP, CTP, and UTP were also utilized as substrates. These characteristics suggest that p73 may be a member of the hsp70 family of heat shock proteins. The biologic significance of p73/T-ag complex formation has yet to be determined.     

Polyomavirus Large T Antigen Binds Cooperatively to Its Multiple Binding Sites in the Viral Origin of DNA Replication

Polyomavirus large T antigen binds to multiple 5′-G(A/G)GGC-3′ pentanucleotide sequences in sites 1/2, A, B, and C within and adjacent to the origin of viral DNA replication on the polyomavirus genome. We asked whether the binding of large T antigen to one of these sites could influence binding to other sites. We discovered that binding to origin DNA is substantially stronger at pH 6 to 7 than at pH 7.4 to 7.8, a range often used in DNA binding assays. Large T antigen-DNA complexes formed at pH 6 to 7 were stable, but a fraction of these complexes dissociated at pH 7.6 and above upon dilution or during electrophoresis. Increased binding at low pH is therefore due at least in part to increased stability of protein-DNA complexes, and binding at higher pH values is reversible. Binding to fragments of origin DNA in which one or more sites were deleted or inactivated by point mutations was measured by nitrocellulose filter binding and DNase I footprinting. The results showed that large T antigen binds cooperatively to its four binding sites in viral DNA, suggesting that the binding of this protein to one of these sites stabilizes its binding to other sites via protein-protein contacts. Sites A, B, and C may therefore augment DNA replication by facilitating the binding of large T antigen to site 1/2 at the replication origin. ATP stabilized large T antigen-DNA complexes against dissociation in the presence, but not the absence, of site 1/2, and ATP specifically enhanced protection against DNase I digestion in the central 10 to 12 bp of site 1/2, at which hexamers are believed to form and begin unwinding DNA. We propose that large T antigen molecules bound to these multiple sites on origin DNA interact with each other to form a compact protein-DNA complex and, furthermore, that ATP stimulates their assembly into hexamers at site 1/2 by a “handover” mechanism mediated by these protein-protein contacts.     

In vivo and in vitro association of hsc70 with polyomavirus capsid proteins.

Members of the 70-kDa family of cellular stress proteins assit in protein folding by preventing inappropriate intra- and intermolecular interactions during normal protein synthesis and transport and when cells are exposed to a variety of environmental stresses. During infection of A31 mouse fibroblasts with polyomavirus, the constitutive form of hsp70, hsc70, coimmunoprecipitated with all three viral capsid proteins (VP1, VP2, and VP3). In addition, the subcellular location of hsc70 changed from cytoplasmic to nuclear late in polyomavirus infection, coincident with the nuclear localization of the viral capsid proteins. VP1 and VP2 expressed in Sf9 insect cells with recombinant baculovirus vectors also coimmunoprecipitated with an hsp70-like protein, and VP1 expressed in Escherichia coli coimmunoprecipitated with the hsp70 homolog DnaK. Capsid proteins expressed by in vitro translation coimmunoprecipitated with the hsc70 protein present in the reticulocyte translation extract. Therefore, the polyomavirus capsid proteins associate with hsc70 during virus infection as well as in recombinant protein expression systems. This association may play a role in preventing the premature assembly of capsids in the cytosol and/or in facilitating the nuclear transport of capsid protein complexes.