Genetic analysis of the enhancer requirements for polyomavirus DNA replication in mice.

In this report, we describe the first systematic analysis of the genetic requirements for polyomavirus (Py) enhancer-activated viral DNA replication during the acute phase of infection in mice. Four mutants were made which substituted XhoI sites for conserved enhancer consensus sequences (adenovirus type 5 E1A, c-fos, simian virus 40, and a glucocorticoidlike consensus sequence). Viral DNA replication in infected mouse organs was measured by DNA blot analysis. Only the loss of the glucocorticoidlike consensus sequence element significantly reduced Py DNA replication in the kidneys, the primary target organ for viral replication. The loss of the c-fos, adenovirus type 5 E1A, or simian virus 40 consensus sequences, however, expanded organ-specific viral DNA replication, relative to wild-type Py, by allowing high-level replication in the pancreas or heart or both. Analysis of Py variants selected for replication in undifferentiated embryonal carcinoma cell lines (PyF441, PyF111) showed that there was little change in levels of viral DNA replication in kidneys and other organs as compared with those in the wild-type virus. If the entire B enhancer is deleted, only low overall levels of viral replication are observed. Wild-type levels of replication in the kidneys can be reconstituted by addition of a single domain from within the A enhancer (nucleotides 5094 to 5132) to the B enhancer deletion virus, suggesting that a single domain from the A enhancer can functionally substitute for the entire B enhancer. This also indicates that the determinants for kidney-specific replication are not found in the B enhancer.     

The replication functions of polyomavirus large tumor antigen are regulated by phosphorylation.

Polyomavirus (Py) large T antigen (T Ag) contains two clusters of phosphorylation sites within the amino-terminal half of the protein. To characterize possible regulatory effects of phosphorylation on viral DNA replication, Py T Ag was treated with calf intestinal alkaline phosphatase (CIAP). Incubation of the protein with a range of phosphatase concentrations caused progressive loss of phosphate without affecting its stability. Treatment with smaller quantities of CIAP stimulated the ability of the viral protein to mediate replication of constructs containing the viral replication origin, while higher concentrations of CIAP caused a marked diminution of this replication function. Several biochemical activities of Py T Ag were examined after CIAP treatment. Py T Ag DNA unwinding and nonspecific DNA binding were only slightly affected by dephosphorylation. However, as determined by DNase I footprinting experiments, treatment with smaller amounts of CIAP stimulated specific binding to the Py replication origin by Py T Ag, while treatment with larger amounts of CIAP caused marked inhibition of origin-specific binding by the viral protein. Phosphotryptic maps of Py T Ag before or after treatment with CIAP revealed changes in individual phosphopeptides that were uniquely associated with either the stimulation or the inhibition of replication. Our data therefore suggest that Py T Ag is regulated by both repressing and activating phosphates.     

Amplification and excision of integrated polyoma DNA sequences require a functional origin of replication

Cells transformed by Polyoma virus (Py) can undergo a high rate of excision or amplification of integrated viral DNA sequences, and these phenomena require the presence of homology (i.e., repeats) within the viral insertion as well as a functional viral large T antigen (T-Ag). To determine whether the main role of large T-Ag in excision and amplification was replicative or recombination-promoting, we studied transformed rat cell lines containing tandem insertions of a ts-a Py molecule (encoding a thermolabile large T-Ag) with a deletion of the origin of viral DNA replication. Culturing of these cells at the temperature permissive for large T-Ag function did not result in any detectable excision or amplification of integrated Py sequences. We then introduced into origin-defective lines a recombinant plasmid containing the viral origin of replication and the gene coding for resistance to the antibiotic G418. All G418-resistant clones analyzed readily amplified the integrated plasmid molecules when grown under conditions permissive for large T-Ag function, showing that these cells produced viral large T-Ag capable of promoting amplification in trans of DNA sequences containing the Py origin. These observations strongly suggest that Polyoma large T antigen promotes excision or amplification of viral DNA by initiating replication at the integrated origin, providing a favorable substrate for subsequent recombination.     

A unique subpopulation of murine DNA polymerase alpha/primase specifically interacts with polyomavirus T antigen and stimulates DNA replication.

Murine cells or cell extracts support the replication of plasmids containing the replication origin (ori-DNA) of polyomavirus (Py) but not that of simian virus 40 (SV40), whereas human cells or cell extracts support the replication of SV40 ori-DNA but not that of Py ori-DNA. It was shown previously that fractions containing DNA polymerase alpha/primase from permissive cells allow viral ori-DNA replication to proceed in extracts of nonpermissive cells. To extend these observations, the binding of Py T antigen to both the permissive and nonpermissive DNA polymerase alpha/primase was examined. Py T antigen was retained by a murine DNA polymerase alpha/primase but not by a human DNA polymerase alpha/primase affinity column. Likewise, a Py T antigen affinity column retained DNA polymerase alpha/primase activity from murine cells but not from human cells. The murine fraction which bound to the Py T antigen column was able to stimulate Py ori-DNA replication in the nonpermissive extract. However, the DNA polymerase alpha/primase activity in this murine fraction constituted only a relatively small proportion (approximately 20 to 40%) of the total murine DNA polymerase alpha/primase that had been applied to the column. The DNA polymerase alpha/primase purified from the nonbound murine fraction, although far more replete in this activity, was incapable of supporting Py DNA replication. The two forms of murine DNA polymerase alpha/primase also differed in their interactions with Py T antigen. Our data thus demonstrate that there are two distinct populations of DNA polymerase alpha/primase in murine cells and that species-specific interactions between T antigen and DNA polymerases can be identified. They may also provide the basis for initiating a novel means of characterizing unique subpopulations of DNA polymerase alpha/primase.     

DNA sequence requirements for replication of polyomavirus DNA in vivo and in vitro.

Cell extracts of FM3A mouse cells replicate polyomavirus (Py) DNA in the presence of immunoaffinity-purified Py large T antigen, deoxynucleoside triphosphates, ATP, and an ATP-generating system. This system was used to examine the effects of mutations within or adjacent to the Py core origin (ori) region in vitro. The analysis of plasmid DNAs containing deletions within the early-gene side of the Py core ori indicated that sequences between nucleotides 41 and 57 define the early boundary of Py DNA replication in vitro. This is consistent with previously published studies on the early-region sequence requirements for Py replication in vivo. Deleting portions of the T-antigen high-affinity binding sites A and B (between nucleotides 57 and 146) on the early-gene side of the core ori led to increased levels of replication in vitro and to normal levels of replication in vivo. Point mutations within the core ori region that abolish Py DNA replication in vivo also reduced replication in vitro. A mutant with a reversed orientation of the Py core ori region replicated in vitro, but to a lesser extent that wild-type Py DNA. Plasmids with deletions on the late-gene side of the core ori, within the enhancer region, that either greatly reduced or virtually abolished Py DNA replication in vivo replicated to levels similar to those of wild-type Py DNA plasmids in vitro. Thus, as has been observed with simian virus 40, DNA sequences needed for Py replication in vivo are different from and more stringent than those required in vitro.     

Mutations that decrease DNA binding of the processivity factor of the herpes simplex virus DNA polymerase reduce viral yield, alter the kinetics of viral DNA replication, and decrease the fidelity of DNA replication

The processivity subunit of the herpes simplex virus DNA polymerase, UL42, is essential for viral replication and possesses both Pol- and DNA-binding activities. Previous studies demonstrated that the substitution of alanine for each of four arginine residues, which reside on the positively charged surface of UL42, resulted in decreased DNA binding affinity and a decreased ability to synthesize long-chain DNA by the polymerase. In this study, the effects of each substitution on the production of viral progeny, viral DNA replication, and DNA replication fidelity were examined. Each substitution mutant was able to complement the replication of a UL42 null mutant in transient complementation assays and to support the replication of plasmid DNA containing herpes simplex virus type 1 (HSV-1) origin sequences in transient DNA replication assays. Mutant viruses containing each substitution and a lacZ insertion in a nonessential region of the genome were constructed and characterized. In single-cycle growth assays, the mutants produced significantly less progeny virus than the control virus containing wild-type UL42. Real-time PCR assays revealed that these UL42 mutants synthesized less viral DNA during the early phase of infection. Interestingly, during the late phase of infection, the mutant viruses synthesized larger amounts of viral DNA than the control virus. The frequencies of mutations of the virus-borne lacZ gene increased significantly in the substitution mutants compared to those observed for the control virus. These results demonstrate that the reduced DNA binding of UL42 is associated with significant effects on virus yields, viral DNA replication, and replication fidelity. Thus, a processivity factor can influence replication fidelity in mammalian cells.     

Regulatory mutants of polyoma virus defective in DNA replication and the synthesis of early proteins

In polyoma virus the origin of replication, the 5′ ends of early mRNAs, and the initiation codon for early protein synthesis map within an approximately 200 bp region of the genome. We have previously reported the isolation and partial characterization of viable mutants of polyoma virus with deletions in this important regulatory region of the genome. Three of the mutants with large deletions, one of which had significantly altered growth properties, have been further characterized with respect to their nucleotide sequence alterations and their levels of viral DNA replication and of early protein synthesis. The nearly coincident deletions in mutants 17 and 2–19 reduce the capacity of these viruses to replicate, even in the presence of a coinfecting virus; thus they help define one boundary of the origin of DNA replication. The deletion in mutant 75 appears to remove sequences that are essential for efficient expression of early genes, but has little or no effect upon DNA replication. Its defect is complemented in trans by wild-type virus. All three mutants eliminate sequences which are candidates for RNA polymerase and ribosome binding sites near the initiation codon for early proteins.     

Polyoma Viral DNA Replicated as a Nucleoprotein Complex in Close Association with the Host Cell Chromatin

Polyoma viral DNA is shown to be replicated in close association with the mouse cell chromatin. Two virus-specific nucleoprotein complexes, designated complex A and B, can be dissociated from the isolated chromatin by gentle homogenization in 0.5 M NaCl. Complex A contains only replicating polyoma (Py) DNA whereas complex B contains only mature Py DNA I. The results show, furthermore, that complex A, containing viral DNA in different stages of replication, and complex B are both nucleoproteins with the same buoyant density. The data presently available suggest that newly synthesized stretches of Py DNA are immediately complexed with mouse cell histones and that complex B becomes the "core" of progeny Py virions. These results suggested that Py-induced replication of the mouse cell chromatin may be necessary to provide replicating Py DNA with histones.     

DNA sequences essential for replication of the B genome component of tomato golden mosaic virus.

The genome of the geminivirus tomato golden mosaic virus (TGMV) is divided between two DNA components, designated A and B, which differ in sequence except for a 230-nucleotide common region. The A genome component is known to encode viral functions necessary for viral DNA replication, while the B genome component specifies functions necessary for spread of the virus through the infected plant. To identify cis-acting sequences required for viral DNA replication, several mutants were constructed by the introduction of small insertions into TGMV B at selected sites within and just outside the common region. Other mutants had the common region inverted or deleted. All of the mutants were tested for their effects on infectivity and DNA replication in whole plants and leaf discs. Our results indicate that the common region in its correct orientation is required for infectivity and for replication of TGMV B. Furthermore, the conserved hairpin loop sequence located within the TGMV common region and found in all geminiviruses is necessary for DNA replication, and may be part of the viral replication origin.     

Timing of ultraviolet light induced mutagenesis in simian virus 40 relative to viral DNA replication in monkey cells

Summary Simian virus 40 (SV40) was used to probe ultraviolet light (UV) — induced mutation in mammalian cells. Viral mutations were scored as reversions of early and late temperature-sensitive (ts) mutants to the wild-type (WT) phenotype. When virus was exposed to moderate or high UV doses, WT revertants were obtained at a frequency related to the square of the dose from two early (tsA) and one late (tsBC) mutant grown at the restrictive temperature. The reversions generated in the progeny of UV-irradiated early mutants presumably arose before the onset of viral DNA replication because, at the non-permissive temperature, tsA mutants are unable to express the functions responsible for the initiation of viral DNA synthesis. Moreover, the early mutant tsA209 underwent similar levels of induced reversion at the permissive and restrictive temperatures, suggesting that the pre-replicative mutational pathway might predominate for moderately and heavily irradiated virus, even under conditions where DNA synthesis can be initiated. The analysis of bursts from revertant plaques produced at the restrictive temperature was consistent with this interpretation. Although the mechanism of pre-replicative mutagenesis is not known, it is likely to be mediated by cellular activities owing to the low genetic complexity of the virus.     

Viral DNA Synthesis in Cells Infected by Temperature-Sensitive Mutants of Simian Virus 40

Temperature-sensitive mutants of simian virus 40 (SV40) have been classified as those that are blocked prior to viral DNA synthesis at the restrictive temperature, "early" mutants, and those harboring a defect later in the replication cycle, "late" mutants. Mutants of the A and D complementation groups are early, those of the B, C, and BC groups are late. Our results confirm earlier reports that A mutants are defective in a function required for the initiation of each round of viral DNA synthesis. D mutants, on the other hand, continue viral DNA replication at the restrictive temperature after preincubation at the permissive temperature. The length of time required for D function to be expressed at the permissive temperature-after which infection proceeds unabated on shifting of the cultures to the restrictive temperature-is 10 to 20 h. The viral DNA synthesized in D mutants under these conditions progresses in normal fashion through replicative intermediate molecules to mature component I and II DNA molecules.     

Polyomavirus DNA replication in the pancreas and in a transformed pancreas cell line has distinct enhancer requirements.

The regulatory DNA (enhancer) of polyomavirus (Py) is a major determinant of tissue-specific DNA replication during acute infection of newborn mice. Previously, we reported that the combination of one of the two Py enhancers (A enhancer) and the repeated Moloney murine leukemia virus (Mo-MuLV) enhancer gave a chimeric Py genome (Py-MuLV) that replicates predominantly in the acinar cells of the pancreas, a tissue not permissive for wild-type PyA2 replication (R. Rochford, B. A. Campbell, and L. P. Villareal. Proc. Nat. Acad. Sci. USA 84:449-453,1987). In this report, we further examine the combined enhancer requirements for acinar cell-specific Py replication. We also compare enhancer requirements for Py replication in the acinar cells of the pancreas with those of a transformed acinar cell line (266-6 cells). The deletion of sequences within the A enhancer of Py-MuLV (nucleotides 5098 to 5132) results in a virus with 10-fold-reduced levels of pancreas-specific replication. The deletion, however, of one of the 72-bp repeated Mo-MuLV enhancer sequences from Py-MuLV results in a complete loss of pancreas-specific DNA replication. Thus, the Py A enhancer is required for efficient replication of Py in the pancreas without otherwise altering organ specificity, but both of the repeated copies of the Mo-MuLV enhancer are essential for pancreas-specific Py replication. In contrast to the enhancer requirements for in vivo pancreas replication, in transformed acinar cells (266-6), PyA2 wild-type replicated efficiently and the Py-MuLV recombinant replicated inefficiently. These data suggest that the cell-specific control of DNA replication is different between normal pancreas cells and their transformed cell line counterparts and that this difference is apparent in the enhancer requirement of cell-specific Py DNA replication.