Interaction of a nuclear factor-1-like protein with the regulatory region of the human polyomavirus JC virus

We have initiated a study to identify host proteins which interact with the regulatory region of the human polyomavirus JC (JCV), which is associated with the demyelinating disease, progressive multifocal leukoencephalopathy. We examined the interaction of nuclear proteins prepared from different cell lines with the JCV regulatory region by DNA binding gel retardation assays. Binding was detected with nuclear extracts prepared from human fetal glial cells, glioma cells, and HeLa cells. Little or no binding was detected with nuclear extracts prepared from human embryonic kidney cells. Competitive binding assays suggest that the nuclear factor(s) which interacted with the JCV regulatory region was different from those which interacted with the regulatory region of the closely related polyomavirus SV40. We found three areas in the JCV regulatory region protected from DNase I digestion: site A, located just upstream from the TATA sequence in the first 98-base pair (bp) repeat; site B, located upstream from the TATA sequence in the second 98-bp repeat; and site C, located just following the second 98-bp repeat. There were some differences in the ability of the nuclear factor(s) from the two brain cell lines and HeLa cells to completely protect the nucleotides within the footprint region. The results from the DNase I protective studies and competitive DNA binding studies with specific oligonucleotides, suggest that nuclear factor-1 or a nuclear factor-1-like factor is interacting with all three sites in the JCV regulatory region. In addition, the results suggest that the nuclear factor which interacts with the JCV regulatory region from human brain cell lines is different from the factor found in HeLa cells.     

Polyomavirus mutation that confers a cell-specific cis advantage for viral DNA replication.

The structural and biological properties of a polyomavirus mutant selected in Friend erythroleukemic cells were investigated. The growth efficiency of this mutant (PyFL78) was compared with that of the parental PyA2 strain by a growth competition assay in Friend erythroleukemic and 3T3 (or 3T6) cell lines. The results reveal that PyFL78 displays a cis-acting growth advantage over the PyA2 parental strain in Friend erythroleukemic cells but not in 3T3 or 3T6 cells. This cell-specific cis advantage is shown to be due to modifications within the polyomavirus noncoding regulatory region.     

Viral genomes maintained extrachromosomally in hamster polyomavirus-induced lymphomas display a cell-specific replication in vitro.

Hamster polyomavirus causes lymphomas when injected into newborn Syrian hamsters. Large amounts of extrachromosomal viral genomes are accumulated in the lymphoma cells. These genomes are characterized by deletions affecting the late coding region as well as a specific part of the noncoding regulatory region. By contrast with wild-type genomes, lymphoma-associated genomes replicate in a lymphoblastoid cell line but not in a fibroblastic cell line. The deletion acts in a cis-dominant manner and is the primary determinant of this host-range effect on replication. The boundaries of the regulatory region necessary for viral DNA replication in the two cell contexts have been defined. The regulatory region can be functionally divided in two domains: one domain (distal from the origin of replication) is necessary for viral genome replication in fibroblasts, whereas the other domain (proximal to the origin of replication) is functional only in the lymphoblastoid cell context and contains the sequence specifically conserved in the lymphoma-associated genomes. This sequence harbors a motif recognized by a lymphoblastoid cell-specific trans-acting factor.     

A cell regulatory agent, CeReS-18, inhibits mouse 3T6 cell proliferation but not polyomavirus replication

We have purified a cell regulatory sialoglycopeptide, CeReS-18, from intact bovine cerebral cortex cells. This is an 18-kDa molecule that reversibly inhibits cellular DNA synthesis and the proliferation of a wide array of target cells. In the present study, the effect of CeReS-18 on mouse 3T6 host cell proliferation and polyomavirus replication was investigated. The results showed that CeReS-18 was able to inhibit 3T6 cell cycling in a concentration-dependent, calcium-sensitive, and reversible manner. Despite the inhibition of cell proliferation, CeReS-18 did not influence polyomavirus infection of 3T6 cells. Indirect immunofluorescent assays revealed that CeReS-18-treated, and cell cycle-arrested, 3T6 cells remained permissive to polyomavirus replication. Electron microscopy and immunogold labeling showed that new viral particles were assembled inside the nuclei of infected cells in the presence of CeReS-18 and during cell cycle arrest. The cellular requirements for the replication of polyomavirus DNA and the synthesis of viral proteins, as well as for the assembly of viral particles, therefore, remained available in CeReS-18-inhibited 3T6 cells. In addition, although polyomavirus infection can be mitogenic, infection of CeReS-18-treated 3T6 cells did not reverse the cell cycle arrest mediated by this cell cycle inhibitor.     

Novel polyomavirus detected in the feces of a chimpanzee by nested broad-spectrum PCR

In order to screen for new polyomaviruses in samples derived from various animal species, degenerated PCR primer pairs were constructed. By using a nested PCR protocol, the sensitive detection of nine different polyomavirus genomes was demonstrated. The screening of field samples revealed the presence of a new polyomavirus, tentatively designated chimpanzee polyomavirus (ChPyV), in the feces of a juvenile chimpanzee (Pan troglodytes). Analysis of the region encoding the major capsid protein VP1 revealed a unique insertion in the EF loop of the protein and showed that ChPyV is a distinct virus related to the monkey polyomavirus B-lymphotropic polyomavirus and the human polyomavirus JC polyomavirus.     

n-Butyrate, a cell cycle blocker, inhibits the replication of polyomaviruses and papillomaviruses but not that of adenoviruses and herpesviruses.

Small DNA viruses are dependent on the interaction of early proteins (such as large T antigen) with host p53 and Rb to bring about the G1-to-S cell cycle transition. The large DNA viruses are less dependent on host regulatory genes since additional early viral proteins (such as viral DNA polymerase, DNA metabolic enzymes, and other replication proteins) are involved in DNA synthesis. A highly conserved domain of large T antigen (similar to the p53-binding region) exclusively identifies papovavirus, parvovirus, and papillomaviruses from all other larger DNA viruses and implies a conserved interaction with host regulatory genes. In this report, we show that 3 to 6 mM butyrate, a general cell cycle blocker implicated in inhibition of the G1-to-S transition, inhibits DNA replication of polyomavirus and human papillomavirus type 11 but not the replication of larger DNA viruses such as adenovirus types 2 and 5, herpes simplex virus type 1, Epstein-Barr virus, and cytomegalovirus, which all bypass the butyrate-mediated cell cycle block. This butyrate effect on polyomavirus replication is not cell type specific, nor does it depend on the p53 or Rb gene, as inhibition was seen in fibroblasts with intact or homozygous deleted p53 or Rb, 3T6 cells, keratinocytes, C2C12 myoblasts, and 3T3-L1 adipocytes. In addition, butyrate did not inhibit expression of polyomavirus T antigen. The antiviral effect of butyrate involves a form of imprinted state, since pretreatment of cells with 3 mM butyrate inhibits human papillomavirus type 11 DNA replication for at least 96 h after its removal. Butyrate, therefore, serves as a molecular tool in dissecting the life cycle of smaller DNA viruses from that of the larger DNA viruses in relation to the cell cycle.     

Selection of mouse neuroblastoma cell-specific polyoma virus mutants with stage differentiative advantages of replication.

Two mouse neuroblastoma cell lines were analyzed for their permissivity for polyoma virus growth. One (N18) is fully permissive for polyoma replication, the other (41A3) shows limited permissivity and the viral genome persists, without noticeable cell death. Virus persistence does not seem to alter the cells' ability to differentiate in vitro and leads to selection of viral mutants altered in the untranscribed regulatory region of the genome. The mutant types obtained appear to be related to the degree of host cell differentiation. Nucleotide sequence analysis of the restriction fragment covering the regulatory region shows that duplications are present in all mutants, while deletions in the non-duplicated segment are only present in mutants selected from less differentiated cells. These alterations involve both domains of the regulatory region that are considered to be essential for DNA replication and for enhancer activity. Mixed infections with polyoma wild type show that the selected mutants have cis-advantage in replication in neuroblastoma cells and not in 3T6 cells. Mutants carrying the deletion in the non-duplicated segment of the enhancer show a selective advantage in replication over the undeleted one in mixed infection. This advantage is much stronger in neuroblastoma cells in suspension (less-differentiated stage) than in monolayer cells (more-differentiated stage). An interpretation of the overall structure of the regulatory enhancer region, based on the observed differences between the mutants selected at different stages of differentiation in neuroblastoma and previously described mutants selected in undifferentiated cells, is discussed.     

Small tumor antigen of polyomaviruses: role in viral life cycle and cell transformation

The regulatory proteins of polyomaviruses, including small and large T antigens, play important roles, not only in the viral life cycle but also in virus-induced cell transformation. Unlike many other tumor viruses, the transforming proteins of polyomaviruses have no cellular homologs but rather exert their effects mostly by interacting with cellular proteins that control fundamental processes in the regulation of cell proliferation and the cell cycle. Thus, they have proven to be valuable tools to identify specific signaling pathways involved in tumor progression. Elucidation of these pathways using polyomavirus transforming proteins as tools is critically important in understanding fundamental regulatory mechanisms and hence to develop effective therapeutic strategies against cancer. In this short review, we will focus on the structural and functional features of one polyomavirus transforming protein, that is, the small t-antigen of the human neurotropic JC virus (JCV) and the simian virus, SV40.     

Regulatory DNA sequence conserved in the course of BK virus evolution

Summary Within the genome of human polyomavirus BK (BKV), there exists a noncoding regulatory region toward the late region side of the origin of DNA replication. In most BKV strains isolated by viral culture, this regulatory region contains tandem repeats varying in size. Recently. however, several laboratories isolated new BKV strains (designated as archetypal strains) lacking such repeat sequences. To examine the genetic relationship between archetypal strains, a phylogenetic tree was constructed for seven BKV strains, including three archetypal strains, from DNA sequence data on the late genes, those for leader protein (agnoprotein), and those for structural proteins (VP1, VP2, and VP3). For three strains data previously reported were used, whereas for the others sequences were determined in this study. From total numbers of nucleotide substitutions in each pair of strains, a phylogenetic tree was constructed by the unweighted pair-group method. The phylogenetic tree obtained reveals that BKV strains containing the archetypal regulatory region do not constitute a cluster of closely related strains and that these strains, together with those carrying the major part of the archetypal regulatory region, are widespread in the BKV population. This finding suggests that the basic structure of the archetypal regulatory region has been conserved in the course of BKV evolution.     

Characterization of a Novel Polyomavirus Isolated from a Fibroma on the Trunk of an African Elephant (Loxodonta africana)

Viruses of the family Polyomaviridae infect a wide variety of avian and mammalian hosts with a broad spectrum of outcomes including asymptomatic infection, acute systemic disease, and tumor induction. In this study a novel polyomavirus, the African elephant polyomavirus 1 (AelPyV-1) found in a protruding hyperplastic fibrous lesion on the trunk of an African elephant (Loxodonta africana) was characterized. The AelPyV-1 genome is 5722 bp in size and is one of the largest polyomaviruses characterized to date. Analysis of the AelPyV-1 genome reveals five putative open-reading frames coding for the classic small and large T antigens in the early region, and the VP1, VP2 and VP3 capsid proteins in the late region. In the area preceding the VP2 start codon three putative open-reading frames, possibly coding for an agnoprotein, could be localized. A regulatory, non-coding region separates the 2 coding regions. Unique for polyomaviruses is the presence of a second 854 bp long non-coding region between the end of the early region and the end of the late region. Based on maximum likelihood phylogenetic analyses of the large T antigen of the AelPyV-1 and 61 other polyomavirus sequences, AelPyV-1 clusters within a heterogeneous group of polyomaviruses that have been isolated from bats, new world primates and rodents.