Complete nucleotide sequence of polyomavirus SA12

The Polyomaviridae have small icosahedral virions that contain a genome of approximately 5,000 bp of circular double-stranded DNA. Polyomaviruses infect hosts ranging from humans to birds, and some members of this family induce tumors in test animals or in their natural hosts. We report the complete nucleotide sequence of simian agent 12 (SA12), whose natural host is thought to be Papio ursinus, the chacma baboon. The 5,230-bp genome has a genetic organization typical of polyomaviruses. Sequences encoding large T antigen, small t antigen, agnoprotein, and the viral capsid proteins VP1, VP2, and VP3 are present in the expected locations. We show that, like its close relative simian virus 40 (SV40), SA12 expresses microRNAs that are encoded by the late DNA strand overlapping the 3' end of large T antigen coding sequences. Based on sequence comparisons, SA12 is most closely related to BK virus (BKV), a human polyomavirus. We have developed a real-time PCR test that distinguishes SA12 from BKV and the other closely related polyomaviruses JC virus and SV40. The close relationship between SA12 and BKV raises the possibility that these viruses circulate between human and baboon hosts.     

Nucleotide sequence of the DNA replication origin for human papovavirus BKV: sequence and structural homology with SV40.

DNA and RNA sequencing techniques were used to obtain the sequence surrounding the origin of DNA replication for human papovavirus BKV. The structure is characterized by a true palindrome of 17 residues followed by two sets of symmetrical sequences and a stretch of 20 AT residues. Within the two symmetrical sequences is a segment containing a strong purine bias, 23 of 26 nucleotides. These structures are similar, if not identical, to those found in the region of the SV40 replication, origin. Within the homologous DNA segments, 60-80% of the BKV and SV40 nucleotides are the same. The remarkable similarity of BKV and SV40 sequences containing the origins of DNA replication would appear to confirm our previous suggestion of an evolutionary relationship between the two genomes. In addition, topological similarities between these sequences suggest the possibility of certain structural requirements for bidirectional replication origins in these superhelical DNAs.     

The genome of human papovavirus BKV.

The complete DNA sequence of human papovavirus BKV(Dun), consisting of 5153 nucleotide pairs, is presented. We describe the segments of the genome which correspond to the replication origin, the tandem repeated sequences, the 5' and 3' ends of the mRNAs, the splice sites, the early and late viral proteins and the putative viral polypeptides. These BKV DNA sequences are compared with analogous regions in the SV40 and Py virus genomes in an attempt to localize viral functions for lytic growth and transformation.     

Comparative study of papovavirus DNA: BKV(MM), BKV(WT) and SV40.

Extensive physical mapping revealed that approximately 90% of the genomes of BKV(prototype, WT) and BKV (MM strain) are identical or closely related. Nucleotide sequences of the non-homologous regions and a large portion of the homologous regions have been determined for both genomes. The coding sequence of small t antigen of BKV(MM) is 216 nucleotides shorter than that of BKV(WT), even though no differences in biological function of the t antigen was observed. Both genomes contain three similar sets of 44-61 base-pair repeated sequences. However, the DNA sequence of the tandem repeats is totally different between BKV (human cell as host) and SV40 (monkey cell as host). On the other hand, the region between the N-terminus of the T antigen genes and the origin of replication is dominated by a similar set of palindromic sequences in BKV and SV40 DNA. There is also extensive homology between the regions which code for proteins in BKV and SV40, suggesting a close evolutionary relationship.     

Hybrid genomes of the polyomaviruses JC virus, BK virus, and simian virus 40: identification of sequences important for efficient transformation.

Hybrid viral genomes were used to investigate the influence of specific polyomavirus sequences on the transforming behavior of JC virus (JCV). One set of chimeric DNAs was made by exchanging the regulatory regions between JCV and simian virus 40 (SV40) or JCV and BK virus (BKV). A second set of constructs was produced that expressed hybrid JCV-BKV T proteins under the control of either JCV or BKV regulatory signals. Transformation of Rat 2 cells with the parental and chimeric DNAs indicated that both the JCV regulatory signals and the sequence encoding the amino terminus of T protein contributed to the restricted transforming behavior of this virus. Analysis of the viral proteins in the transformed rat cells indicated that the large T antigens of JCV and BKV were less stable than their SV40 counterpart, that small t protein was produced in JCV transformants, and that the subpopulation of T antigen that forms a stable complex with cellular p53 protein was smaller in JCV-transformed cells than in SV40- or BKV-transformed cells.     

Initiation of JC virus DNA replication in vitro by human and mouse DNA polymerase alpha-primase.

Host species specificity of the polyomaviruses simian virus 40 (SV40) and mouse polyomavirus (PyV) has been shown to be determined by the host DNA polymerase alpha-primase complex involved in the initiation of both viral and host DNA replication. Here we demonstrate that DNA replication of the related human pathogenic polyomavirus JC virus (JCV) can be supported in vitro by DNA polymerase alpha-primase of either human or murine origin indicating that the mechanism of its strict species specificity differs from that of SV40 and PyV. Our results indicate that this may be due to differences in the interaction of JCV and SV40 large T antigens with the DNA replication initiation complex.     

Detection and typing of BKV,JCV, and SV40 by multiplex nested polymerase chain reaction

A multiplex nested polymerase chain reaction (PCR) method was developed for detecting and differentiating simultaneously the DNA of polyomaviruses JC, BK, and SV40 in a single tube. In the first amplification step the same set of primers was used to amplify a conserved DNA region of the large T antigen gene of JCV, BKV, and SV40. The second round was carried out using a set of primers designed to obtain products of different size for each related virus. Subsequently, the sensitivity of the multiplex nested PCR was maximized by optimizing parameters such as primer, magnesium, and dNTP concentrations. The sensitivity of the method ranged between 1 and 10 copies of the polyomavirus genome. The assay was then used for detecting polyomavirus DNA in urine, serum, and biopsy specimens from renal transplant recipients. Based on the results obtained, the multiplex nested PCR developed in our study represents a useful tool for supporting the diagnosis of polyomavirus infection and could be used for epidemiological purposes and to better define the role of polyomaviruses in human pathology.     

Polyomaviruses of Nonhuman Primates: Implications for Research

Polyomaviruses are a family of small nonenveloped DNA viruses that infect birds and mammals. At least 7 nonhuman primate polyomaviruses that occur in macaques, African green monkeys, marmosets baboons, and chimpanzees have been described, as well as 4 polyomaviruses that occur in humans. Simian virus 40 (SV40), which infects macaques, was the first nonhuman primate polyomavirus identified as a contaminant of early polio vaccines. Primate polyomaviruses cause inapparent primary infections but persist in the host and can cause severe disease in situations of immunocompromise. This review describes the primate polyomaviruses, and the diseases associated with the viruses of macaques. In macaques, the greatest current concerns are the potential confounding of study results by polyomavirus infections and the zoonotic potential of SV40.Abbreviations: PML, progressive multifocal leukoencephalopathy; SV40, Simian virus 40Polyomaviruses were previously members of the family Papovaviridae, which included (and derived its name from) rabbit papilloma virus (pa), mouse polyoma virus (po), and simian vacuolating virus (va). Papovaviruses are nonenveloped viruses, with double-stranded circular DNA and an icosahedral capsule. Since the 1980s, studies of Simian virus 40 (SV40) and mouse polyomavirus have demonstrated that these viruses have smaller capsids (45 nm versus 50 nm), smaller genomes (5 kb versus 8 kb), and a different genomic organization than those of papillomaviruses. SV40 and mouse polyomavirus now form an independent family, Polyomaviridae.¹⁸More than 13 members of Polyomaviridae infect mammals and birds. The first polyomavirus was discovered in 1953 in mice²⁸ and was so named because it caused tumors at multiple sites in neonatal mice. Indeed oncogenicity is a common feature of polyomaviruses, particularly tumor production in non-native hosts. Various members of the group transform cell lines and immortalize primary cell cultures as well as induce tumors in susceptible animals. SV40 was identified in 1960 in primary macaque kidney cell cultures, as a contaminant of polio vaccines.⁶⁸ In 1971, the human polyomaviruses BKV²³ and JCV⁵⁴ were identified (both are named after the initials of the patients in which they were first recognized). JCV was discovered in the brain of a patient with progressive multifocal leukoencephalopathy, and BKV was found in the urine of a renal transplant patient. Recently, 2 additional polyomaviruses of the nasopharynx of humans, KIV and WUV, have been identified^2,25 through the use of molecular techniques. KIV was found in nasopharyngeal samples from patients with respiratory disease, and WUV initially was detected in a child with pneumonia. KIV and WUV are closely related genetically and may form a new subfamily of polyomaviruses: their early coding regions (T antigens) are similar to those of other primate polyomaviruses, but their late regions (structural proteins) differ.^7,25 Both KIV and WUV appear to be geographically widespread.The capsids of the polyomaviruses contain 3 structural proteins: VP1, the major capsid protein, and VP2 and VP3, which enclose a single molecule of viral DNA. The viruses also encode regulatory proteins, the T (tumor) antigens. SV40 and other primate polyomaviruses encode 2 T antigens, large T and small t, whereas mouse polyomavirus and some of the other family members have a third, middle T antigen. The T antigens of SV40, BKV, and JCV have about 75% amino-acid homology.⁵⁸ The T antigen of SV40 is essential for initiation of viral DNA replication and promotes transformation and immortalization of host cells, partially through binding to and inhibiting tumor suppressor proteins p53, p107, p130 (pRb2), and pRb (reviewed in reference 10).     

Structure of a defective simian virus 40 genome bearing an operator from bacteriophage lambda.

We examined further the physical structure of the simian virus 40 (SV40) and bacteriophage lambda DNA sequences in an SV40-lambda hybrid that had been propagated in monkey kidney cells. The SV40 vector portion of the hybrid, which was a small fragment isolated from a reiteration mutant of SV40, contained the site for initiation of SV40 DNA replication. Electron microscope heteroduplex and restriction endonuclease analyses revealed a tandem duplication of the SV40 vector segment linked to a 2,300-base pair portion (lambda map units 71 to 76) of the lambda immunity region. The defective hybrid genome thus harbors two origins for SV40 DNA replication in addition to the leftward operator and the N gene of lambda.     

Potential transmission of human polyomaviruses through the gastrointestinal tract after exposure to virions or viral DNA

The mechanism of human-to-human transmission of the polyomaviruses JC virus (JCV) and BK virus (BKV) has not been firmly established with regard to possible human exposure. JCV and BKV have been found in sewage samples from different geographical areas in Europe, Africa, and the United States, with average concentrations of 10(2) to 10(3) JCV particles/ml and 10(1) to 10(2) BKV particles/ml. Selected polyomavirus-positive sewage samples were further characterized. The JCV and BKV present in these samples were identified by sequencing of the intergenic region (the region found between the T antigen and VP coding regions) of JCV and the VP1 region of BKV. The regulatory region of the JCV and BKV strains found in sewage samples presented archetypal or archetype-like genetic structures, as described for urine samples. The stability (the time required for a 90% reduction in the virus concentration) of the viral particles in sewage at 20 degrees C was estimated to be 26.7 days for JCV and 53.6 days for BKV. The presence of JCV in 50% of the shellfish samples analyzed confirmed the stability of these viral particles in the environment. BKV and JCV particles were also found to be stable at pH 5; however, treatment at a pH lower than 3 resulted in the detection of free viral DNA. Since most humans are infected with JCV and BKV, these data indicate that the ingestion of contaminated water or food could represent a possible portal of entrance of these viruses or polyomavirus DNA into the human population.     

Xrep, a plasmid-stimulating X chromosomal sequence bearing similarities to the BK virus replication origin and viral enhancers.

The human X chromosome-linked fragment, "Xrep," was sequenced because it exerts a positive effect on plasmid growth in both E. coli and Saccharomyces cerevisiae. The sequence revealed three features similar to the human BK virus replication origin: Xrep has a true palindrome, CCTCC(T)3CCTCC, which is similar to "true" palindrome-like sequences found at the replication origins of polyoma [CCTC(T/C)10CTCC], BK [CCTC(A/G)8CCTCC] and SV40 [CCTCC(A)6GCCTCC] viruses. Twenty nucleotides away from the true palindrome, Xrep has the sequence GAATCCTATTCACTTTT while BK virus, the human analogue of SV40, has GAAATCCCTATTCTTTT in exactly the same position relative to the true palindrome. These two 17-mers differ only in the positions of two nucleotides comparing Xrep and BK virus. Also similar to the replication origins of DNA viruses, Xrep appears to have a cluster of enhancers adjacent to the origin-like sequences. Potent enhancer-like activity was detected in pSV1 X CAT/Xrep constructs. Xrep may originate from an endogenous virus, or from an X chromosomal replication origin.     

The agnoprotein of polyomaviruses: a multifunctional auxiliary protein

The late region of the three primate polyomaviruses (JCV, BKV, and SV40) encodes a small, highly basic protein known as agnoprotein. While much attention during the last two decades has focused on the transforming proteins encoded by the early region (small and large T-antigens), it has become increasingly evident that agnoprotein has a critical role in the regulation of viral gene expression and replication, and in the modulation of certain important host cell functions including cell cycle progression and DNA repair. The importance of agnoprotein is underscored by its expression during lytic infection of glial cells by JCV that occurs in progressive multifocal leukoencephalopathy (PML), and also in some JCV-associated human neural tumors particularly medulloblastoma. In this review, we will discuss the structure and function of agnoprotein in the viral life cycle during the course of lytic infection and the consequences of agnoprotein expression for the host cell.     

Prevalence of BK virus and human papillomavirus in human prostate cancer

Polyomaviruses such as the BK virus (BKV), JC virus (JCV) and SV40, as well as the human papillomaviruses (HPV) are frequently detected throughout human populations, causing subclinical persistent infections and inducing oncogenesis in human and other cell lines. To test the involvement of these viruses in prostate tumorigenesis, we investigated the prevalence of BKV, JCV and HPV in a series of human prostatic malignancies. Forty-two samples of diagnosed prostatic malignancies were tested using standard polymerase chain reaction (PCR) protocols. Differentiation between BKV and JCV among the polyomavirus-positive samples was achieved after sequencing analysis of the PCR products. Reconstitution of BKV in vitro was performed and indirect immunofluorescence for the large T-antigen of the virus was applied to confirm the production of progeny virus. Detection and typing of HPV was carried out by PCR. The overall prevalence of polyomaviruses was 19% in the prostate cancer cases. Sequencing analysis of the polyomavirus-positive specimens revealed the presence of BKV in all samples. Reconstitution of the BKV from the BKV-positive prostate samples was successfully achieved in cell culture and progeny viral particles were obtained, confirming the presence of the virus in the human biopsies. HPV was detected in 4.8% of the samples, however, no HPV-11, HPV-16, HPV-18 or HPV-33 types were identified. BKV was frequently detected and could play a relevant role in the development and progression of human prostate cancer, whereas HPV does not seem to be implicated in this type of human neoplasia.     

The role of sialic acid in human polyomavirus infections

JC virus (JCV) and BK virus (BKV) are human polyomaviruses that infect approximately 85% of the population worldwide [1,2]. JCV is the underlying cause of the fatal demyelinating disease, progressive multifocal leukoencephalopathy (PML), a condition resulting from JCV induced lytic destruction of myelin producing oligodendrocytes in the brain [3]. BKV infection of kidneys in renal transplant recipients results in a gradual loss of graft function known as polyomavirus associated nephropathy (PVN) [4]. Following the identification of these viruses as the etiological agents of disease, there has been greater interest in understanding the basic biology of these human pathogens [5,6]. Recent advances in the field have shown that viral entry of both JCV and BKV is dependent on the ability to interact with sialic acid. This review focuses on what is known about the human polyomaviruses and the role that sialic acid plays in determining viral tropism.