Requirement for the large T and small T proteins of SV40 in the maintenance of the transformed state

Renal Infections

This review discusses the various gross and histologic findings seen in renal infections due to bacteria, viruses, fungi, and mycobacteria. It is crucially important to separate infectious processes in the kidney from other inflammatory or neoplastic processes, as this will have a major impact on therapy. We describe the diagnostic features of renal infections with a specific focus on the differential diagnosis and other processes that may mimic infection. The topics discussed include acute bacterial pyelonephritis, chronic bacterial pyelonephritis, xanthogranulomatous pyelonephritis, malacoplakia, viral infections in the kidney, fungal pyelonephritis and mycobacterial infection of the kidney.

Transforming Activities of JC Virus Early Proteins

Polyomaviruses, as their name indicates, are viruses capable of inducing a variety of tumors in vivo. Members of this family, including the human JC and BK viruses (JCV, BKV), and the better characterized mouse polyomavirus and simian virus 40 (SV40), are small DNA viruses that commandeer a cell's molecular machinery to reproduce themselves. Studies of these virus-host interactions have greatly enhanced our understanding of a wide range of phenomena from cellular processes (e.g., DNA replication and transcription) to viral oncogenesis. The current chapter will focus upon the five known JCV early proteins and the contributions each makes to the oncogenic process (transformation) when expressed in cultured cells. Where appropriate, gaps in our understanding of JCV protein function will be supplanted with information obtained from the study of SV40 and BKV.

Transrepression of RNA polymerase II promoters by the simian virus 40 small t antigen

Simian virus 40 (SV40) small t antigen (t) can activate transcription from certain RNA polymerase II and III promoters (M. Loeken, I. Bikel, D. M. Livingston, and J. Brady, Cell 55:1171-1177, 1988). Here we report a new function of t, its ability to repress human c-fos promoter and AP-1 transcriptional activity in CV-1P cells. This function is the product of a discrete N-terminal domain of t, because the large T antigen (T)/t-common polypeptide, which contains only the first 82 amino acids common to both T and t of SV40, was, like the intact protein, an active repressor. The data further suggest that the t- and T/t-common-mediated repression of c-fos expression was most likely manifest at the level of transcription. In keeping with the possibility that t affects the expression of the genomic c-fos promoter, it also led to repression of AP-1 formation. Thus, SV40 is both an activator and a repressor of transcription. Its ability to inhibit c-fos expression should be considered in light of the natural history of SV40 in its natural host.

Simian virus 40 small tumor antigen and an amino-terminal domain of large tumor antigen share a common transforming function

The 82-residue amino-terminal sequences of simian virus 40 large tumor antigen (TAg) and small tumor antigen (tAg) are identical. Genetic analysis of TAg lacking amino acids 1-82 revealed that it was transformation-defective, as revealed by the agar growth assay, except when introduced in the presence of tAg. Since the latter, alone, lacks overt transforming activity, it would appear that the function of the sequence common to TAg and tAg is necessary, but not sufficient, for TAg transforming activity and that tAg can provide that function or its equivalent in trans. Thus, tAg may, in part, be viewed as a "portable" copy of a TAg functional domain.

Mutational analysis of simian virus 40 small-t antigen

Several point mutations in the simian virus 40 (SV40) small-t antigen have been analyzed for their effects on protein stability, transformation, transactivation, and binding of two cellular proteins. All mutations which affected cysteine residues in two cysteine clusters produced highly unstable small-t antigens. Four point mutations outside these clusters and one in-frame deletion mutant, dl890, produced stable proteins but reduced transformation efficiency. These were able to transactivate the EII promoter and bind the cellular proteins, suggesting that these activities are not sufficient for small-t-mediated enhancement of transformation.

The large tumor antigen of simian virus 40 encodes at least two distinct transforming functions

The large tumor antigen (T antigen) of simian virus 40 is necessary and sufficient for the neoplastic transformation of a number of established cell lines. Mutational analysis has revealed that a biochemical activity residing within the amino-terminal 121 amino acids of T antigen is sufficient to induce the transformation of some cell lines, such as C3H10T1/2. The same domain of the molecule also encodes the transactivation function of T antigen and the ability to complex with the retinoblastoma susceptibility gene product. However, the transformation of other lines, such as REF52, requires an additional activity that is affected by mutations in other portions of the molecule.

JC virus-simian virus 40 genomes containing heterologous regulatory signals and chimeric early regions: identification of regions restricting transformation by JC virus

The papovavirus JC virus (JCV) is highly oncogenic in experimental animals but, unlike simian virus 40 (SV40), is severely restricted in its ability to transform cells in culture. We exploited the close genetic relatedness of these two viruses to delimit region(s) of the T protein which can restrict transforming activity. Novel chimeric genomes were produced by exchanging various segments of the JCV and SV40 T-protein-coding regions. These DNA constructs specified early proteins with in-frame substitutions of analogous amino acid sequences. A second set of genomes was prepared which, in addition to chimeric early proteins, contained substituted regulatory regions. The transformation efficiencies of these chimeric genomes were intermediate between those of SV40 and JCV, with the source of T protein exerting a greater effect than that of the regulatory region. The ability of certain constructs to induce efficient transformation required the presence of an SV40 regulatory region or specific sequences within the SV40 early coding region. Cloned cell lines prepared from representative transformants were characterized; the ability to form colonies in soft agarose was investigated, and the presence of viral T and cellular p53 proteins was determined. The various T proteins differed in amount, stability, and the ability to form stable complexes with p53.

Requirement for the simian virus 40 small tumor antigen in tumorigenesis in transgenic mice

To examine the role of simian virus 40 (SV40) large T and small t antigens in tumorigenesis in animals, we generated transgenic mice which expressed either both the SV40 large T and small t antigens or the SV40 large T antigen alone under the control of the mouse mammary tumor virus long terminal repeat. The mouse mammary tumor virus long terminal repeat directs the expression of transgenes in ductal epithelial cells of several organs, including the mammary gland, lung, and kidney, and in lymphoid cells. The mice which expressed both the T and t tumor antigens developed lung and kidney adenocarcinomas, while those which expressed large T alone did not. Both types of mice developed malignant lymphomas with similar frequencies and latency periods. Our results show that the SV40 small t antigen cooperates with the large T antigen in inducing tumors in slowly dividing epithelial cells in the lung and kidney.

Purification and functional properties of simian virus 40 large and small T antigens overproduced in insect cells

The insect baculovirus Autographa californica nuclear polyhedrosis virus was used as an expression vector for the simian virus 40 (SV40) small t (t) and large T (T) antigens. Spodoptera frugiperda (SF9) cells infected with recombinant viruses encoding these proteins produced approximately 1 to 2 micrograms of t and up to 30 micrograms of T per 3 X 10(6) cells. The former was highly soluble after Nonidet P-40 extraction of the infected cells, unlike its Escherichia coli-produced counterpart. Both SF9-produced proteins were of authentic size and could be readily immunoprecipitated by specific antibodies. Single-step immunoaffinity chromatography was used to purify the two proteins to near homogeneity, with yields averaging 70% in each case. Experiments to test the biological activity of the baculovirus SV40 proteins showed that SF9 t was capable of associating with two of the cellular proteins reported to bind to t in SV40-infected mammalian cells. Moreover, SF9 T had ATPase activity comparable to that of T produced in monkey cells, exhibited helicase activity and SV40 origin-specific DNA binding, and was active in the SV40 DNA replication assay in vitro. Thus, the SV40 T antigens produced in insect cells can be used in future studies of their biochemical roles in vitro and in vivo.

Requirement for the simian virus 40 small tumor antigen in tumorigenesis in transgenic mice

To examine the role of simian virus 40 (SV40) large T and small t antigens in tumorigenesis in animals, we generated transgenic mice which expressed either both the SV40 large T and small t antigens or the SV40 large T antigen alone under the control of the mouse mammary tumor virus long terminal repeat. The mouse mammary tumor virus long terminal repeat directs the expression of transgenes in ductal epithelial cells of several organs, including the mammary gland, lung, and kidney, and in lymphoid cells. The mice which expressed both the T and t tumor antigens developed lung and kidney adenocarcinomas, while those which expressed large T alone did not. Both types of mice developed malignant lymphomas with similar frequencies and latency periods. Our results show that the SV40 small t antigen cooperates with the large T antigen in inducing tumors in slowly dividing epithelial cells in the lung and kidney.

Failure of simian virus 40 small t antigen to disorganize actin cables in nonpermissive cell lines

Mouse C3H 10T1/2 cell lines expressing the simian virus 40 (SV40) small t antigen were obtained by cotransfection of pSV2neo and plasmids which encode small t. Cell lines derived from two plasmids which encode small t in the absence of stable deletion fragments of the large T antigen were morphologically normal and grew to slightly higher saturation densities in low serum than control cell lines. Unexpectedly, the clones had highly organized actin cables, as did parental 10T1/2 cells infected with wild-type SV40. These observations and comparisons of rat F111 cells infected with either polyomavirus or SV40 suggest that the SV40 small t antigen does not directly affect cytoskeletal organization.

The t-unique coding domain is important to the transformation maintenance function of the simian virus 40 small t antigen

The small t antigen (t) of simian virus 40, a 174-amino-acid-containing protein, when present together with the other early viral protein, large T antigen (T), plays an important role in the maintenance of simian virus 40-induced neoplastic phenotype in certain cells. Indeed, each protein functions in a complementary manner in this process. The t coding unit is composed of two segments, a 5' region of 246 nucleotides which is identical to that of the corresponding 5' region of the T coding unit and a 3' segment of 276 nucleotides which is unique. Two mutant, t-encoding genomes, one bearing a missense and the other a nonsense mutation at the same point in the t-unique coding region were constructed in vitro and found to be defective in their ability to dissolve the actin cytoskeleton of rat fibroblasts and to complement T in the growth of mouse fibroblasts in soft agar. Therefore, the unique segment of the t gene encodes a portion of the t molecule which is essential to its transformation maintenance function.

Isolation of a simian virus 40 T-antigen-positive, transformation-resistant cell line by indirect selection

In an attempt to identify cellular genes that might be involved in simian virus 40 (SV40) transformation, we have set out to isolate cells which express T antigen but are not transformed. SV40 DNA and the herpes simplex virus thymidine kinase gene were cotransfected into tk- 3T3 fibroblasts. Of 72 colonies screened that were resistant to hypoxanthine-aminopterin-thymidine, 57 were T antigen positive as judged by immunofluorescence. One of these lines, A27, had a normal growth phenotype in monolayer overgrowth and soft agar assays. It contained intact SV40 sequences that could be rescued by fusion to permissive cells. This rescued virus was fully capable of transforming nonpermissive cells to the same extent as did wild-type virus. The A27 cells, however, were not transformable by infection with SV40 or by transfection of SV40 DNA. It is likely that these cells were altered in a cellular function required for the establishment of the transformed state.

A recombinant murine retrovirus for simian virus 40 large T cDNA transforms mouse fibroblasts to anchorage-independent growth

A recombinant murine retrovirus containing the intact cDNA sequence for the simian virus 40 (SV40) large T antigen (T) was constructed by using the pZIPNeo SV(X)1 vector. Psi 2 packaging cells were then transfected, and G418-resistant clones were used to generate helper-free viral stocks. NIH 3T3 mouse fibroblasts infected by the recombinant T cDNA retrovirus were selected fro G418 resistance. Such cultures synthesized authentic SV40 T and were transformed to anchorage-independent growth at high efficiency. Therefore, this vector has allowed the study of the transformation properties of T under conditions of neutral drug selection and in the absence of SV40 small t antigen.

Cellular proteins which can specifically associate with simian virus 40 small t antigen

When crude, radiolabeled extracts of various cells were applied to homogeneous simian virus 40 small t antigen-Sepharose adsorbents, three cell proteins (57, 32, and 20 kilodaltons [kDa]) bound specifically. Each also bound to an insoluble, truncated t derivative composed of the COOH-terminal 123 residues of the protein. The binding of these proteins was greatly inhibited after reduction and alkylation of the t ligand. Therefore, some element of native conformation, but not all of the primary structure of t, is necessary for this binding property, which may constitute a discrete, in vitro biochemical function of this protein. Results of cell fractionation experiments suggested that the 57- and 32-kDa proteins are nonnuclear cell constituents, whereas the 20-kDa protein was closely associated with a detergent-washed nuclear fraction. Specific immunoblotting and comparative partial proteolytic digestion analyses indicated that the 57-kDa protein is tubulin, a major component of the cytoskeleton. In this regard, t and tubulin were observed to coimmunoprecipitate from crude cell extracts after incubation with monospecific anti-t antibody. Therefore, it is possible that t and tubulin interact in vivo.

Molecular and biological properties of BK virus-IR, a BK virus variant isolated from a human tumor

We describe the molecular and biological properties of BK virus (BKV)-IR, a new BKV variant isolated from a human tumor of pancreatic islets. BKV-IR bears a 253-base-pair (bp) deletion and an 80-bp insertion in the early region of the genome. The deletion abolishes the expression of small-t antigen. The inserted sequences, grouped in four clusters, produce rearrangements in the first and second enhancer elements. They are bound by 12-bp direct repeats and could form a 217-base stem-loop structure suggestive of an insertion sequence. As compared with wild-type BKV, BKV-IR transformed hamster cells with a reduced efficiency and induced ependymomas in hamsters at a lower frequency and with a longer latency period. Tumors induced by BKV-IR, however, showed features of higher malignancy. The possible role of the insertion sequence-like element in transformation by BKV-IR is discussed.

The t-unique coding domain is important to the transformation maintenance function of the simian virus 40 small t antigen

The small t antigen (t) of simian virus 40, a 174-amino-acid-containing protein, when present together with the other early viral protein, large T antigen (T), plays an important role in the maintenance of simian virus 40-induced neoplastic phenotype in certain cells. Indeed, each protein functions in a complementary manner in this process. The t coding unit is composed of two segments, a 5' region of 246 nucleotides which is identical to that of the corresponding 5' region of the T coding unit and a 3' segment of 276 nucleotides which is unique. Two mutant, t-encoding genomes, one bearing a missense and the other a nonsense mutation at the same point in the t-unique coding region were constructed in vitro and found to be defective in their ability to dissolve the actin cytoskeleton of rat fibroblasts and to complement T in the growth of mouse fibroblasts in soft agar. Therefore, the unique segment of the t gene encodes a portion of the t molecule which is essential to its transformation maintenance function.

Isolation of a simian virus 40 T-antigen-positive, transformation-resistant cell line by indirect selection

In an attempt to identify cellular genes that might be involved in simian virus 40 (SV40) transformation, we have set out to isolate cells which express T antigen but are not transformed. SV40 DNA and the herpes simplex virus thymidine kinase gene were cotransfected into tk- 3T3 fibroblasts. Of 72 colonies screened that were resistant to hypoxanthine-aminopterin-thymidine, 57 were T antigen positive as judged by immunofluorescence. One of these lines, A27, had a normal growth phenotype in monolayer overgrowth and soft agar assays. It contained intact SV40 sequences that could be rescued by fusion to permissive cells. This rescued virus was fully capable of transforming nonpermissive cells to the same extent as did wild-type virus. The A27 cells, however, were not transformable by infection with SV40 or by transfection of SV40 DNA. It is likely that these cells were altered in a cellular function required for the establishment of the transformed state.

Intercellular communication and the control of growth: XII. Alteration of junctional permeability by simian virus 40. Roles of the large and small T antigens

We studied the action of temperature-sensitive mutant simian virus 40--a transformation-inducing DNA virus--on the junctional permeability to mono-, di- and triglutamate in rat embryo-, pancreas islet (epithelial)-, and 10T1/2 cell cultures. Junctional permeability was reduced (reversibly) in the transformed state. To dissect the genetics of this alteration, we used two kinds of mutant virus DNA. One kind had a temperature-sensitive mutation on the A gene, rendering the large T antigen (the gene product) thermolabile (T+ in equilibrium T-). The other had a deletion on the F gene, in addition, abolishing (permanently) the expression of the little t addition (t-). The junctional alteration occurred in the condition T+ t+, but not in the conditions T- t+, T+ t- or T- t-. Both antigens, thus, are necessary for this junctional alteration--a genetic requirement identical to that for decontrol of growth (but distinct from that of the cytoskeletal alteration).

Monoclonal antibody to simian virus 40 small t

A monoclonal antibody, PAb280, was produced that recognizes simian virus 40 (SV40) small t but does not react with SV40 large T. The specificity of the antibody was analyzed by immunoprecipitation of labeled cell extracts, Western blotting, and immunocytochemistry. Small t was found to accumulate late in the SV40 lytic cycle and was localized in both the cytoplasm and the nucleus of cells infected with wild-type SV40. Importantly, antibodies against determinants common to SV40 large T and small t did not appear to be able to recognize the cytoplasmic form of SV40 small t at the immunocytochemical level. The localization of small t within the nucleus appeared to be distinct from that of large T.

Purification of biologically active simian virus 40 small tumor antigen

The simian virus 40 small tumor antigen (t antigen) gene has been cloned downstream from a hybrid Escherichia coli trp-lac promoter and a suitable ribosome binding site. A bacterial clone (865i) transformed by such a plasmid (pTR865) expresses this gene and, under optimal conditions, can produce greater than or equal to 5% of its total protein as t antigen. Soluble extracts of such a clone were relatively depleted in t antigen, which was found in the initial pellet fraction. The protein was recovered from this fraction in a significantly purified form by extraction with urea-containing buffer. After gel filtration of such t antigen-enriched solutions, highly purified protein was obtained. When either this fraction (freed of urea) or NaDodSO4 gel-purified 865i t antigen (rendered free of detergent) was injected into untransformed rat cells, dissolution of intracellular actin cable networks was observed.

Episomal DNA of a BK virus variant in a human insulinoma

BK virus (BKV) DNA was detected by blot hybridization in a human adenoma of pancreatic islets from patient I.R. BKV DNA was free, and no evidence was found of viral sequences integrated into cellular DNA. Virus was rescued by transfection of human embryonic fibroblasts with tumor DNA. The DNA from rescued virus (BKV-IR) was different from wild-type BKV DNA by restriction endonuclease mapping. The genome of BKV-IR is 235 base pairs (bp) shorter than the genome of wild-type BKV. This alteration originates from a deletion of approximately 300 bp involving HindIII fragments B and D, and an insertion of 70 bp in the region of HindIII fragment C. Transformation of hamster kidney cells was induced by total tumor DNA as well as by BKV-IR and BKV-IR DNA. No antibodies to BKV tumor (T) antigen were detected in the patient's serum by immunofluorescence. The significance of episomal BKV DNA in a human tumor is discussed.

Effects of large and small T antigens on DNA synthesis and cell division in simian virus 40-transformed BALB/c 3T3 cells

The roles of the large T and small t antigens of simian virus 40 in cellular DNA synthesis and cell division were analyzed in BALB/c 3T3 mouse cells transformed by wild-type, temperature-sensitive A (tsA), or tsA-deletion (tsA/dl) double mutants. Assessment of DNA replication and cell cycle distribution by radioautography of [3H]thymidine-labeled nuclei and by flow microfluorimetry indicate that tsA transformants do not synthesize DNA or divide at the restrictive temperature to the same extent as they do at the permissive temperature or as wild-type transformants do at the restrictive temperature. This confirms earlier studies suggesting that large T induces DNA synthesis and mitosis in transformed cells. Inhibition of replication in tsA transformants at the restrictive temperature, however, is not complete. Some residual cell division does occur but is in large part offset by cell detachment and death. This failure to revert completely to the parental 3T3 phenotype, as indicated by residual cell cycling at the restrictive temperature, was also observed in cells transformed by tsA/dl double mutants which, in addition to producing a ts large T, make no small t protein. Small t, therefore, does not appear to be responsible for the residual cell cycling and plays no demonstrable role in the induction of DNA synthesis or cell division in stably transformed BALB/c 3T3 cells. Comparison of cell cycling in tsA and tsA/dl transformants, normal 3T3 cells, and a transformation revertant suggests that the failure of tsA transformants to revert completely may be due to leakiness of the tsA mutation as well as to a permanent cellular alteration induced during viral transformation. Finally, analysis of cells transformed by tsA/dl double mutants indicates that small t is not required for full expression of growth properties characteristic of transformed cells.

Mutant of simian virus 40 large T-antigen that is defective for viral DNA synthesis, but competent for transformation of cultured rat cells

A mutant was isolated which demonstrates that the transforming activity of simian virus 40 large T-antigen is separable from its function in viral DNA replication. The mutant, SVR9D, is nonconditionally defective for viral DNA synthesis, but competent at wild-type level for morphological transformation of cultured rat cells. The lytic growth defect in SVR9D is complemented by the simian virus 40 A gene product present in the transformed CV1 cell line, COS1. The lesion in SVR9D DNA was mapped genetically by marker rescue of plaque formation and localized to a 214-base-pair segment of the viral genome bounded by nucleotide numbers 4100 and 4314. DNA sequence analysis showed the mutation to be an adenine-to-guanine transition at nucleotide number 4178. This change predicts a lysine-to-glutamic acid amino acid change at residue number 214 of the mutant large T-antigen polypeptide.

Transforming genes and gene products of polyoma and SV40

The small DNA-containing viruses, SV40 and polyoma, transform cells in vitro and induce tumors in vivo. For both viruses two genes required for transformation have been found. The genes required for transformation are also involved in productive infection. Although the two viruses are similar in their effects on cells, the organization of the transforming genes and gene products is different. The purpose of this review is to compare what is known about the biology and the biochemistry of the early regions of the two viruses. The genetic and biochemical studies defining the sequences important for transformation will be reviewed. Then, the products of the transforming genes, called T antigens, will be discussed in detail. There is a substantial body of descriptive information on those products, and studies on the function of the T antigens have also begun.

Transformation of hamster kidney cells by fragments of BK virus DNA

Hamster kidney cells were transformed, with comparable efficiency, by circular or linear molecules of complete BK virus (BKV) genome and by agarose gel-purified fragments of BKV DNA obtained by single or double digestions with various restriction endonucleases. Only fragments containing the complete early region of BKV DNA displayed transforming activity. Analysis by blot hybridization of the arrangement of viral DNA sequences in a cloned cell line transformed by a 3.8-kilobase fragment, obtained after sequential digestion of BKV DNA with HhaI and BamHI, showed the presence of seven viral integrations into the cellular DNA. Apparently all of the integrated viral molecules contained the entire early region of BKV DNA. Large T antigen, small t antigen, and the 56,000-dalton nonviral Tau antigen were detected in transformed cells by immunoprecipitation. The pattern of integration of viral sequences in transformed cells was constant over many generations. Likewise, large T antigen was always detected in transformed cells at various passage levels. These results may suggest that all of the sequences of the early region coding for large T antigen are required for transformation by BKV. Alternatively, subgenomic segments of the BKV DNA early region may be unable to transform because the appropriate polyadenylation site, necessary to obtain a complete functional transcriptional unit, is removed by the restriction enzyme cleavage.

Instability of integrated viral DNA in mouse cells transformed by simian virus 40

The state and organization of simian virus 40 (SV40) DNA in tsA mutant-transformed mouse clones were examined early after agar selection in an attempt to elucidate the mechanisms that actively generate the diverse integration patterns found in transformed cells. Although recently selected as a cloned population from agar, A21 cells displayed extremely heterogeneous SV40 DNA patterns when analyzed by agarose gel electrophoresis and Southern blot hybridization. Reselection of clones in agar from A21 at 33 degrees C or 39.5 degrees C and DNA analysis by hybridization demonstrated (i) simplification of the number of integration sites in the new clones; (ii) new sites of integrated SV40 DNA in high molecular weight cell DNA fragments generated by digestion with restriction endonuclease Bgl II; (iii) relatedness between clones with respect to integrated viral sequence arrangement; and (iv) persistence of free viral DNA forms. The majority of free viral DNA appeared to be full length, nondefective SV40 DNA, although a subpopulation of defective viral molecules was also detected. No detectable free SV40 DNA could be observed in A21 clonal derivatives isolated by growth in agar at 39.5 degrees C, indicating that the persistence of free viral forms was regulated by the A gene. These results suggest that the heterogeneity in viral sequences in the A21 cells was generated within a cloned population from which new clones can be derived with different transformed phenotypes and integration patterns.

Simian virus 40 gene A regulation of cellular DNA synthesis. II. In nonpermissive cells

The stimulation of host macromolecular synthesis and induction into the cell cycle of serum-deprived G0-G1-arrested mouse embryo fibroblasts were examined after infection of resting cells with wild-type simian virus 40 or with viral mutants affecting T antigen (tsA58) or small t antigen (dl884). At various times after virus infection, cell cultures were analyzed for DNA synthesis by autoradiography and flow microfluorimetry. Whereas mock-infected cultured remained quiescent and displayed either a 2N DNA content (80%) or a 4N DNA content (15%), mouse cells infected with wild-type simian virus 40, tsA58 at 33 degrees C, or dl884 were induced into active cell cycling at approximately 18 h postinfection. Although dl884-infected mouse cells were induced to cycle initially at the same rate as wild type-infected cells, they became arrested earlier after infection and also failed to reach the saturation densities of wild-type simian virus 40-infected cells. Infection with dl884 also failed to induce loss of cytoplasmic actin cables in the majority of the infected cell population. Mouse cells infected with tsA58 and maintained at 39.5 degrees C showed a transient burst of DNA synthesis as reflected by changes in cell DNA content and an increase in the number of labeled nuclei during the first 24 h postinfection; however, after the abortive stimulation of DNA synthesis at 39.5 degrees C shift experiments demonstrated that host DNA replication was regulated by a functional A gene product. It is concluded that both products of the early region of simian virus 40 DNA play a complementary role in recruiting and maintaining simian virus 40-infected cells in the cell cycle.

Transformation of primary hamster brain cells with JC virus and its DNA

We transformed primary hamster brain cells with four isolates of JC virus and JC virus DNA. Several properties of these transformants were characterized and compared to those of simian virus 40 transformants isolated under identical conditions.