Dynamics of the nucleoprotein structure of simian virus 40 regulatory region during viral development

The regulatory region of SV40 is composed of multiple elements, including the origin of replication (ori), the encapsidation signal (ses) and the enhancer. Here, the structure of the chromatin and nucleoprotein complexes in a region encompassing ses and part of the enhancer was investigated in detail by in situ probing with DNase I. We have used a model experimental system based on plasmids which carry parts of the SV40 regulatory region. The results demonstrate that a specific nucleoprotein structure at the region is formed early after transfection. The overall structure is maintained throughout the viral life cycle. The observed DNase digestion pattern is consistent with the presence of a mixed population of viral minichromosomes with various, but not random, nucleosomal arrangements in that region. Specific modulations, which are associated with the various stages of the viral life cycle, are superimposed on the general structure. The most dramatic changes occur at nucleotides 34 and 113, located at both ends of ses and flanking the GC-box region. Some of the changes depend on the presence of viral gene product(s), probably a late (capsid) protein. The results further suggest that the condensed minichromosome within the viral particle assumes a highly specific configuration in this region. The nucleoprotein structure is sensitive to modifications of the primary nucleotide sequence and to flanking DNA elements. There is good correlation between distortions in the nucleoprotein structure and the inability of mutant plasmids to be packaged, substantiating the requirement for proper chromatin condensation in viral packaging.

Post-translational folding of the influenza C virus glycoprotein HEF: defective processing in cells expressing the cloned gene

The post-translational processing of the influenza C virus glycoprotein HEF was analysed. In cells infected with influenza C virus, HEF protein is synthesized as a glycosylated 80K polypeptide. A post-translational conformational rearrangement involving the formation of intramolecular disulphide bonds results in a decrease in its electrophoretic mobility. Therefore, SDS-PAGE under non-reducing conditions suggests an Mr of about 100K, whereas under reducing conditions an 80K protein is observed which is in accordance with the sequence data. The 100K form was detected 10 min after synthesis of HEF, and transport to the cell surface took about 60 min. This result indicates that the conformational change presumably occurs in the endoplasmic reticulum. A difference in post-translational processing was observed when the HEF gene was expressed in the absence of other influenza C virus genes. In cells infected with recombinant simian virus 40, the 80K precursor was synthesized, but this protein was neither converted to the 100K form nor transported to the cell surface. Deletion of the short cytoplasmic tail of HEF (Arg-Thr-Lys) or replacement of the two basic amino acids by hydrophobic (Ile) or acidic residues (Glu) resulted in HEF protein which was partially converted to the 100K form. Influenza C virus glycoprotein obtained after transient expression of the HEF gene using the vaccinia virus system was completely converted to the 100K form. However, in neither expression system was HEF transported to the cell surface. The possibility is discussed that the interaction of HEF with another viral protein is required for the post-translational folding and transport of this glycoprotein. The M protein of influenza C virus is suggested as a candidate for the chaperone which might interact with the cytoplasmic tail of HEF.

Simian virus 40 small-t antigen stimulates viral DNA replication in permissive monkey cells

The simian virus 40 (SV40) large-T antigen is essential for SV40 DNA replication and for late viral gene expression, but the role of the SV40 small-t antigen in these processes is still unclear. We have previously demonstrated that small t inhibits SV40 DNA replication in vitro. In this study, we investigated the effect of small t on SV40 replication in cultured cells. CV1 monkey cell infection experiments indicated that mutant viruses that lack small t replicate less efficiently than the wild-type virus. We next microinjected CV1 cells with SV40 DNA with and without purified small-t protein and analyzed viral DNA replication efficiency by Southern blotting. Replication of either wild-type SV40 or small-t deletion mutant DNA was increased three- to fivefold in cells coinjected with purified small t. Thus, in contrast to our in vitro observation, small t stimulated viral DNA replication in vivo. This result suggests that small t has cellular effects that are not detectable in a reconstituted in vitro replication system. We also found that small t stimulated progression of permissive monkey cells--but not of nonpermissive rodent cells--from G0-G1 to the S phase of the cell cycle, possibly leading to an optimal intracellular environment for viral replication.

Simian virus 40 prevents activation of M-phase-promoting factor during lytic infection

Simian virus 40 (SV40) infection stimulates confluent cultures of monkey kidney cells into successive rounds of cellular DNA synthesis without intervening mitosis. As an initial step in defining the mechanisms responsible for viral inhibition of mitosis, M-phase-promoting factor (MPF) was examined in SV40-infected CV-1 cells passing from G2 phase into a second S phase. MPF is a serine-threonine protein kinase that is essential for mitosis in eukaryotic cells. In SV40-infected cells exiting G2 phase, there was a reduced amount of MPF-associated H1 kinase activity relative to that of uninfected cells passing through mitosis. Both subunits of MPF, cyclin B and the p34cdc2 catalytic subunit, were present and in a complex in infected cells. In uninfected cultures, passage through mitosis was associated with the dephosphorylation of the p34cdc2 subunit, which is characteristic of MPF activation. In contrast, the p34cdc2 subunit remained in the tyrosine-phosphorylated, inactive form in SV40-infected cells passing from G2 phase into a second S phase. These results suggest that although the MPF complex is assembled and modified normally, SV40 interferes with pathways leading to MPF activation.

Reversion of a simian virus 40 enhancer mutant depends on the growth conditions

The simian virus 40 (SV40) enhancer contains three 8-bp purine-pyrimidine (R:Y) alternating sequences (Z-motifs) which are known to adopt the left-handed Z-DNA conformation in vitro. Mutations at these three Z-motifs seriously impair enhancer function. Reversion of one of these mutants (dpm12) is studied in this paper. The results indicate that, depending on growth conditions, recovery of the enhancer function is achieved through different mechanisms. Mutant viruses growing in solid-agar medium do not revert. On the other hand, revertants obtained in liquid medium contain a duplication of the enhancer sequences, showing no recovery of the original Z-motifs.

The genomic instability associated with integrated simian virus 40 DNA is dependent on the origin of replication and early control region

DNA rearrangements in the form of deletions and duplications are found within and near integrated simian virus 40 (SV40) DNA in nonpermissive cell lines. We have found that rearrangements also occur frequently with integrated pSV2neo plasmid DNA. pSV2neo contains the entire SV40 control region, including the origin of replication, both promoters, and the enhancer sequences. Linearized plasmid DNA was electroporated into X1, an SV40-transformed mouse cell line that expresses SV40 large T antigen (T Ag) and shows very frequent rearrangements at the SV40 locus, and into LMtk-, a spontaneously transformed mouse cell line that contains no SV40 DNA. Stability was analyzed by subcloning G-418-resistant clones and examining specific DNA fragments for alterations in size. Five independent X1 clones containing pSV2neo DNA were unstable at both the neo locus and the T Ag locus. By contrast, four X1 clones containing mutants of pSV2neo with small deletions in the SV40 core origin and three X1 clones containing a different neo plasmid lacking SV40 sequences were stable at the neo locus, although they were still unstable at the T Ag locus. Surprisingly, five independent LMtk- clones containing pSV2neo DNA were unstable at the neo locus. LMtk- clones containing origin deletion mutants were more stable but were not as stable as the X1 clones containing the same plasmid DNA. We conclude that the SV40 origin of replication and early control region are sufficient viral components for the genomic instability at sites of SV40 integration and that SV40 T Ag is not required.

SV40 virus expression vectors

SV40 late-replacement vectors provide an excellent means for expressing large amounts of proteins from cDNAs of less than 2400 bp. The amount of protein made 28 hr after infection is sufficient for extremely brief pulse-chase protocols. At periods postinfection when cells are still healthy, sufficient protein has been made for techniques in which only a small fraction of the protein is detected, including immunocytochemistry on cryosections. Because of the ease of subcloning DNA fragments into them, the ease of making virus stocks, and the ability to achieve comparable amounts of protein expression reproducibly with different infections, these vectors are superb tools for comparing series of mutants made by site-directed mutagenesis, especially if a normal cellular environment is important for the measurements to be made.

T-antigen kinase inhibits simian virus 40 DNA replication by phosphorylation of intact T antigen on serines 120 and 123

Simian virus 40 (SV40) DNA replication begins after two large T-antigen hexamers assemble on the viral minimal origin of replication and locally unwind the template DNA. The activity of T antigen in this reaction is regulated by its phosphorylation state. A form of casein kinase I purified from HeLa nuclear extracts (T-antigen kinase) phosphorylates T antigen on physiologic sites and inhibits its activity in the unwinding reaction (A. Cegielska and D. M. Virshup, Mol. Cell. Biol. 13:1202-1211, 1993). Using a series of mutant T antigens expressed by recombinant baculoviruses in Sf9 cells, we find that the origin unwinding activities of both TS677-->A and TS677,679-->A are inhibited by the T-antigen kinase, as is wild-type T antigen. In contrast, mutants TS120-->A and TS123,679-->A are resistant to inhibition by the kinase. Thus, phosphorylation of serines 120 and 123 is necessary for inhibition of T-antigen activity. Previous studies of casein kinase I substrate specificity have suggested that acidic residues or a phosphorylated amino acid amino terminal to the target residue are required to create a casein kinase I recognition site. However, we find that the T-antigen kinase can add more than 3 mol of Pi per mol to full-length bacterially produced T antigen and that it inhibits the unwinding activity of p34cdc2-activated bacterially produced T antigen. Since no prior phosphorylation is present in this bacterially produced T antigen, and no acidic residues are present immediately amino terminal to serines 120 and 123, other structural elements of T antigen must contribute to the recognition signals for T-antigen kinase. In support of this conclusion, we find that while T-antigen kinase phosphorylates amino-terminal residues in bacterially produced full-length T antigen, it cannot phosphorylate bacterially produced truncated T antigen containing amino acids 1 to 259, a 17-kDa amino-terminal tryptic fragment of T antigen, nor can it phosphorylate denatured T antigen. These findings strongly suggest that the carboxy-terminal domain of T antigen is an important modifier of the recognition signals for phosphorylation of the critical amino-terminal sites by the T-antigen kinase. This conclusion is consistent with previous studies suggesting close apposition of amino- and carboxy-terminal domains of T antigen in the native protein. The three-dimensional conformation of the substrate appears to make a significant contribution to T-antigen kinase substrate specificity.

Inhibition of heterologous DNA replication by the MVMp nonstructural NS-1 protein: identification of a target sequence

The nonstructural protein NS-1 of minute virus of mice (MVMp), an autonomous parvovirus, trans-inhibits the replication of a chimeric plasmid containing the SV40 origin of replication (ori) embedded in the MVMp genome. It appears that a 157-bp 5' proximal sequence of MVMp DNA is sufficient, in the presence of NS-1, to cause the inhibition of DNA replication driven by the SV40 ori placed on the same molecule. This effect is not dependent on the orientation of the MVMp target sequence and results from both a reduced level of utilization of SV40 ori and the blockage of progressing replication forks at the level of the target. Furthermore, replication driven by Epstein-Barr virus origin (oriP) is trans-inhibited by MVMp but this inhibition does not require the presence of parvoviral sequences in cis. On the basis of sequence homologies between EBV oriP and MVMp 5' terminal sequence, it is proposed that the direct or indirect interaction of NS-1 with parvovirus-like sequences present in heterologous viral and possibly also cellular genomes may result in an inhibition of DNA replication.

Human corneal epithelial primary cultures and cell lines with extended life span: in vitro model for ocular studies

PURPOSE

To develop an in vitro model of human corneal epithelium that can be propagated in serum-free medium that is tissue specific, species specific, and continuously available.

METHODS

Primary explant cultures from human cadaver donor corneas were generated and subsequently infected with Adeno 12-SV40 (Ad12-SV40) hybrid virus or transfected with plasmid RSV-T.

RESULTS

Several lines of human corneal epithelial cells with extended life span were developed and characterized. Propagation of both primary cultures and lines with extended life span, upon collagen membranes at an air-liquid interface, promoted multilayering, more closely approximating the morphology observed in situ.

CONCLUSIONS

In vitro models, using primary cultures of corneal epithelium and lines of corneal epithelial cells with extended life span, retain a variety of phenotypic characteristics and may be used as an adjunct to ocular toxicology studies and as a tool to investigate corneal epithelial cell biology.

Analysis of G418-selected Rat2 cells containing prototype, variant, mutant, and chimeric JC virus and SV40 genomes

The human polyomavirus JC virus (JCV) is highly tumorigenic in rodents, but transforms cells in culture inefficiently. To explore the basis for JCV's restricted transforming behavior, nonpermissive Rat2 cells were contransfected with pSV2-neo (encodes G418 resistance) and viral DNAs including prototype, variant, and mutant JCV genomes and two JCV-SV40 chimeras. By selecting cells displaying G418 resistance, lines were established that contain viral DNA and exhibit a wide range of transformed phenotypes. The G418-resistant lines were tested for their ability to grow under anchorage-independent conditions, to overgrow a monolayer of untransformed cells, and to form dense colonies on plastic. Expression of the viral T and t proteins and interaction of T protein with the cellular anti-oncoprotein p53 were measured. Also determined was the number of intact viral early coding regions integrated within the cellular DNA. The results of these studies suggested that most of the G418-resistant lines failed to express JCV T protein above a minimum threshold level required for their conversion to a fully transformed phenotype. In anchorage-independent growth assays, higher levels of a 17-kDa T-related peptide in JCV transformants appeared to compensate for decreased T antigen levels. Comparison of the T to p53 ratios in the cell lysates suggested that the quaternary structure of the JCV protein differed from that of its SV40 counterpart in the T-p53 complex. The presence of multiple vs single integrated copies of the viral genome in the cells did not correlate with elevated T antigen expression or an enhanced transformation status.

Opening and refolding of simian virus 40 and in vitro packaging of foreign DNA

Simian virus 40 (SV40) can be disassembled under mild conditions by reducing disulfide bonds in the capsid and removing calcium ions. The nucleoprotein complexes formed, analyzed by electron microscopy, were circular and made up of 59 +/- 4 subunits, each with a diameter of about 10 nm. The complexes contained the viral DNA, histones, and the viral capsid proteins. The complexes had much-reduced infectivities compared with intact SV40. Addition of calcium ions to the disrupted virus caused the nucleoprotein complexes to refold into virus-like structures which sedimented at the same rate as intact SV40 and regained infectivity. Treatment of the disrupted SV40 with a high concentration of salt dissociated the viral proteins from the DNA. Lowering stepwise the salt concentration, removing the reducing agent, and adding calcium ions allowed structures to be reformed, and these structures sedimented, like SV40, at 240S and were infectious. The plaque-forming ability of the reconstituted particles was between that of the dissociated components and that of intact SV40. The addition of purified DNA of polyomavirus to the dissociated SV40 before the lowering of the salt concentration showed that virus-like structures could be formed from SV40 proteins and a foreign DNA.

Expression of mouse furin in a Chinese hamster cell resistant to Pseudomonas exotoxin A and viruses complements the genetic lesion

RPE.40 is a strain of mutated CHO-K1 cells with elevated resistance to Pseudomonas exotoxin A, Sindbis virus, and Newcastle disease virus. Virus resistance is due to an inability to cleave precursor viral membrane glycoproteins and produce infectious virions. Transfection of RPE.40 cells with cDNA for mouse furin causes them to lose all resistance and become as sensitive as wild-type cells to the toxin and viruses. Transfection of RPE.40 cells with cDNA for the related yeast protease Kex2 reduces their resistance to the toxin and viruses, but does not completely eliminate it.

Wild-type p53 is not a negative regulator of simian virus 40 DNA replication in infected monkey cells

To analyze the proposed growth-inhibitory function of wild-type p53, we compared simian virus 40 (SV40) DNA replication in primary rhesus monkey kidney (PRK) cells, which express wild-type p53, and in the established rhesus monkey kidney cell line LLC-MK2, which expresses a mutated p53 that does not complex with large T antigen. SV40 DNA replication proceeded identically in both cell types during the course of infection. Endogenously expressed wild-type p53 thus does not negatively modulate SV40 DNA replication in vivo. We suggest that inhibition of SV40 DNA replication by wild-type p53 in in vitro replication assays is due to grossly elevated ratios of p53 to large T antigen, thus depleting the replication-competent free large T antigen in the assay mixtures by complex formation. In contrast, the ratio of p53 to large T antigen in in vivo replication is low, leaving the majority of large T antigen in a free, replication-competent state.

Structural requirements for simian virus 40 replication and virion maturation

The nuclear matrix plays an important role in simian virus 40 (SV40) DNA replication in vivo, since functional replication complexes containing large T and replicating SV40 minichromosomes are anchored to this structure (R. Schirmbeck and W. Deppert, J. Virol. 65:2578-2588, 1991). In the present study, we have analyzed the course of events leading from nuclear matrix-associated replicating SV40 minichromosomes to fully replicated minichromosomes and, further, to their encapsidation into mature SV40 virions. Pulse-chase experiments revealed that newly replicated SV40 minichromosomes accumulated at the nuclear matrix and were directly encapsidated into DNase-resistant SV40 virions at this nuclear structure. Alternatively, a small fraction of newly replicated minichromosomes left the nuclear matrix to associate with the cellular chromatin. During the course of infection, progeny virions continuously were released from the nuclear matrix to the cellular chromatin and into the cytoplasm-nucleoplasm. The bulk of SV40 progeny virions, however, remained at the nuclear matrix until virus-induced cell lysis.

Role of nuclear pore complex in simian virus 40 nuclear targeting

Cytoplasmically injected simian virus 40 (SV40) virions enter the nucleus through nuclear pore complexes (NPCs) and can express large T antigen shortly thereafter (J. Clever, M. Yamada, and H. Kasamatsu, Proc. Natl. Acad. Sci. USA 88:7333-7337, 1991). The nuclear import of the protein components of introduced SV40 was reversibly arrested by chilling and energy depletion, corroborating our previous observation that the nuclear entry of injected SV40 is blocked in the presence of wheat germ agglutinin and an antinucleoporin monoclonal antibody (mAb414), general inhibitors of NPC-mediated import. The nuclear accumulation of virion protein components and large T antigen in nonpermissive NIH 3T3 cells was similar to that in the permissive host, indicating that the ability to use NPCs as a route of nuclear entry appears to be a general property of the injected virus. Injected virions were capable of completing their lytic cycle and forming plaques in permissive cells. During the early phase of SV40 infection, the cytoplasmic injection of mAb414 effectively blocked nuclear T-antigen accumulation for up to 8 h of infection but had very little effect after 12 h of infection. The time-dependent interference with nuclear T-antigen accumulation by the antinucleoporin antibody is consistent with the hypothesis that the infecting virions enter the nucleus through NPCs. The interference study also suggests that the early phase of infection consists of at least two steps: a step for virion cell entry and intracytoplasmic trafficking and a step for virion nuclear entry followed by large-T-antigen gene expression and subsequent nuclear localization of the gene product. Virions were visualized as electron-dense particles in ultrathin sections of samples in which transport was permitted or arrested. In the former cells, electron-dense particles were predominantly observed in the nucleus. The virions were distributed randomly and nonuniformly in the nucleoplasm but were not observed in heterochromatin or in nucleoli. In the latter cells, the electron-dense particles were seen intersecting the nuclear envelope, near the inner nuclear membrane, and in NPCs. In tangential cross sections of NPCs, which appeared as donut-shaped structures, a spherical electron-dense particle was observed in the center of the structure. Immunoelectron microscopy revealed that NPCs were selectively decorated with 5-nm colloidal gold particles-anti-Vp1 immunoglobulin G at the cytoplasmic entrance to and in NPCs, confirming that the morphologically observed electron-dense particles in NPCs contain the viral structural protein. These results support the hypothesis that the nuclear import of SV40 is catalyzed through NPCs by an active transport mechanism that is similar to that of other karyophiles.

Replication of SV40 minichromosomes in vitro

We operationally define two forms of SV40 minichromosomes, a 75S-form, prepared at low salt concentration, referred to as native minichromosomes, and a 50S-form, obtained after treatment with 0.5 M potassium acetate, the salt-treated minichromosomes. Both preparations of minichromosomes serve well as templates for replication in vitro. Their respective replication products are strikingly different: replicated native minichromosomes contain a densely packed array of the maximal number of nucleosomes whereas replicated salt-treated minichromosomes carry, on average, half of the maximal number. We conclude that in both cases parental nucleosomes are transferred to progeny DNA, and, in addition, that an assembly of new nucleosomes occurs during the replication of native minichromosomes. This is apparently due to the presence of a nucleosome assembly factor as a constituent of native minichromosomes that dissociates upon treatment with salt. We further show that preparations of minichromosomes usually contain significant amounts of copurifying hnRNP particles and SV40 virion precursor particles. However, these structures do not detectably affect the replication and the chromatin assembly reactions.

Two synthetic Sp1-binding sites functionally substitute for the 21-base-pair repeat region to activate simian virus 40 growth in CV-1 cells

The 21-bp repeat region of simian virus 40 (SV40) activates viral transcription and DNA replication and contains binding sites for many cellular proteins, including Sp1, LSF, ETF, Ap2, Ap4, GT-1B, H16, and p53, and for the SV40 large tumor antigen. We have attempted to reduce the complexity of this region while maintaining its growth-promoting capacity. Deletion of the 21-bp repeat region from the SV40 genome delays the expression of viral early proteins and DNA replication and reduces virus production in CV-1 cells. Replacement of the 21-bp repeat region with two copies of DNA sequence motifs bound with high affinities by Sp1 promotes SV40 growth in CV-1 cells to nearly wild-type levels, but substitution by motifs bound less avidly by Sp1 or bound by other activator proteins does not restore growth. This indicates that Sp1 or a protein with similar sequence specificity is primarily responsible for the function of the 21-bp repeat region. We speculate about how Sp1 activates both SV40 transcription and DNA replication.

Host range analysis of a chimeric simian virus 40 genome containing the BKV capsid genes

Simian virus 40 (SV40) propagates poorly in cells from human embryonic kidney (HEK) and human fetal fibroblasts (HFF) while BK virus grows well in many human cell types. It has been suggested that sequences within the SV40 late region but not within the BKV late region may act to inhibit growth of virus in HEK and HFF cells. In order to test this and to identify a late region host range function, we have replaced the late region of wtSV40 DNA with the late region of RFV (a variant of BKV) to produce an intermolecular hybrid or chimera. The constructed SV40/RFV chimeric genome contained approx. 5900 base pairs, more than 650 base pairs greater than wtSV40. Nevertheless, when introduced by transfection the chimera appeared to be infectious. Three chimeric genomes were recovered from infected cells and all contained deletions of nearly 600 base pairs, exclusively at the region of the 3' terminal junction. Since all three chimeras propagated in human HFF and HEK cells, the RFV late region and not the RFV regulatory region possesses a host range function required for growth in human cells. Analysis of T-antigen gene expression suggests that the replacement of the SV40 late region with the BKV late region leads to full expression of the SV40 early region in human cells. Two chimeras exhibited a BKV-like host range and the third exhibited both a BKV and an SV40-like host range. We determined precisely which sequences were deleted in each chimera and we exchanged 3' terminal junction fragments containing these deletions, between two chimeras with different host ranges. From these experiments we demonstrated that: (1) The 3' terminus of the SV40 large T-antigen gene is required for growth of SV40/RFV in TC-7 and CV-1 simian cells but not for growth in human cells; (2) while the SV40 late region is refractory for growth in human cells, the RFV late region is not refractory for growth in simian cells; (3) the 3' terminus of the RFV T-antigen gene is not required for growth in human cells. The results of the 3' terminal junction exchanges and studies of early gene expression also demonstrate that BKV and SV40 can penetrate human and simian cells, even when they failed to grow in one cell type.

A cis-acting DNA signal for encapsidation of simian virus 40

Encapsidation of simian virus 40 is a complex biological process involving DNA-protein and protein-protein interactions in the formation of a unique three-dimensional structure around the viral minichromosome. A pseudoviral system developed in our laboratory, in which the viral early and late gene products are supplied in trans (by helpers), was used to analyze the encapsidation process independent of viral gene expression. With this experimental system we have discovered a requirement for a specific DNA signal for encapsidation, ses (for simian virus 40 encapsidation signal).ses is present within a 200-bp DNA fragment, which includes, in addition to the viral origin of replication (ori), six GGGCGG repeats (GC boxes) and 26 bp of the enhancer element. Deletion of the GC boxes and the enhancer sequences almost abolished encapsidation, while DNA replication was only moderately decreased. The ability to encapsidate was not regained by reinserting a DNA fragment carrying ses in the sesdeleted plasmid 2 kbp away from the ori, suggesting that for encapsidation the two DNA elements have to be close to each other. These findings afford novel strategies for the investigation of viral encapsidation.

Efficient in vivo encapsidation of a shuttle vector into pseudo-simian virus 40 virions using a shuttle virus as helper

We have designed shuttle vectors containing the late region of simian virus 40 (SV40) DNA (coding for the capsid proteins) which could be encapsidated into pseudo-SV40 virions during passage in monkey cells. We describe here the use of these shuttle viruses as helpers for the encapsidation of another shuttle vector into viral particles. Following cotransfection into monkey cells, the efficiency of encapsidation was similar for the shuttle virus and the other plasmid. The amounts of pseudo-SV40 virions recovered from the two vectors reflected the amounts of their DNA present in monkey cells. Thus, the presence of the SV40 late region did not confer any significant advantage for encapsidation. The encapsidation of any shuttle vector into pseudo-SV40 virions is therefore possible and efficient, shuttle viruses constituting an interesting alternative to the use of SV40 as helper in this process.

Simian virus 40 mutants with amino-acid substitutions near the amino terminus of large T antigen

A series of amino-acid substitution mutants has been made with changes in the region of simian virus 40 large tumor antigen (T antigen) that is shared with the small tumor antigen (t antigen). Both single and multiple amino-acid replacements were obtained using the heteroduplex deletion loop method and sodium bisulfite as the mutagen. The mutants could be divided into five phenotypic classes on the basis of their biological properties: a) mutants whose changes did not affect their ability to propagate on permissive monkey cells, nor to transform nonpermissive rodent cells; b) mutants that were not viable, replicated their DNA to 5% or less of wild type, but were positive for transformation; c) mutants that were not viable, replicated their DNA to 5% or less of wild type, and were defective for transformation; and d) mutants that completely lost all three activities coordinately. In addition, one mutant with changes in this region, 5002, replicated its DNA to about 50% of wild type, had an impaired transformation activity, and produced virions at a level of about 4% that of wild type.

Mouse DNA primase plays the principal role in determination of permissiveness for polyomavirus DNA replication

We have investigated the species-specific replication of polyomavirus DNA in the cell-free system that was established previously (Y. Murakami, T. Eki, M. Yamada, C. Prives, and J. Hurwitz, Proc. Natl. Acad. Sci. USA 83:6347-6351, 1986). Extracts from various species of cells supported polyomavirus DNA replication in a species-specific manner that was consistent with the host range specificity of polyomavirus; extracts prepared from mouse and hamster cells were active, whereas extracts prepared from human, monkey, and insect cells were inactive. The addition of DNA polymerase alpha-primase purified from mouse cells induced the replication of polyomavirus DNA in a cell-free system containing polyomavirus large tumor antigen and nonpermissive cell extracts, such as human and insect cell extracts. Isolated mouse DNA primase alone also induced polyomavirus DNA replication in human cell extracts but not in insect cell extracts, indicating that mouse DNA primase plays the principal role in determining permissiveness for polyomavirus DNA replication.

Specific mutation of a regulatory site within the ATP-binding region of simian virus 40 large T antigen

In an attempt to distinguish simian virus 40 (SV40) large T antigen (T) binding to ATP from hydrolysis, specific mutations were made in the ATP-binding site of T according to our model for the site (M. K. Bradley, T. F. Smith, R. H. Lathrop, D. M. Livingston, and T. A. Webster, Proc. Natl. Acad. Sci. USA 84:4026-4030, 1987). Two acidic residues predicted to make contact with the magnesium phosphate were changed to alanines. The mutated T gene was completely defective for viral DNA synthesis and for virion production, and it was dominant defective for viral DNA replication. The defective T gene encoded a stable product (2905T) that oncogenically transformed mouse cell lines. 2905T, immunoprecipitated from transformed-cell extracts, bound SV40 origin DNA specifically and, surprisingly, it was active as an ATPase. A recombinant baculovirus was constructed for the production and purification of the mutant protein for detailed biochemical analyses. 2905T had only 10% of the ATPase and helicase of wild-type T. The Km of 2905T for ATP in ATPase assays was the same as the Km of wild-type T. ATP activated the ATPase activity of wild-type T, but not of 2905T. As tested by gel bandshift assay, 2905T bound to SV40 origin DNA and to individual sites I and II with affinities similar to that of the wild type. However, ATP did not modulate the DNA-binding activity of mutant T to site II. Therefore, this mutation in the ATP-binding site in T resulted in defects in the interaction between the protein and ATP that appeared to be responsible for the determination of the active state of T for DNA binding versus ATPase.

Phenotype-specific phosphorylation of simian virus 40 tsA mutant large T antigens in tsA N-type and A-type transformants

To identify molecular differences between simian virus 40 (SV40) tsA58 mutant large tumor antigen (large T) in cells of tsA58 N-type transformants [FR(tsA58)A cells], which revert to the normal phenotype after the cells are shifted to the nonpermissive growth temperature, and mutant large T in tsA58 A-type transformants [FR(tsA58)57 cells], which maintain their transformed phenotype after the temperature shift, we asked whether the biological activity of these mutant large T antigens at the nonpermissive growth temperature might correlate with phosphorylation at specific sites. At the permissive growth temperature, the phosphorylation patterns of the mutant large T proteins in FR(tsA58)A (N-type) cells and in FR(tsA58)57 (A-type) cells were largely indistinguishable from that of wild-type large T in FR(wt648) cells. After a shift to the nonpermissive growth temperature, no significant changes in the phosphorylation patterns of wild-type large T in FR(wt648) or of mutant large T in FR(tsA58)57 (A-type) cells were observed. In contrast, the phosphorylation pattern of mutant large T in FR(tsA58)A (N-type) cells changed in a characteristic manner, leading to an apparent underphosphorylation at specific sites. Phosphorylation of the cellular protein p53 was analyzed in parallel. Characteristic differences in the phosphorylation pattern of p53 were observed when cells of N-type and A-type transformants were kept at 39 degrees C as opposed to 32 degrees C. However, these differences did not relate to the different phenotypes of FR(tsA58)A (N-type) and FR(tsA58)57 (A-type) cells at the nonpermissive growth temperature. Our results, therefore, suggest that phosphorylation of large T at specific sites correlates with the transforming activity of tsA mutant large T in SV40 N-type and A-type transformants. This conclusion was substantiated by demonstrating that the biological properties as well as the phosphorylation patterns of SV40 tsA28 mutant large T in cells of SV40 tsA28 N-type and A-type transformants were similar to those in FR(tsA58)A (N-type) and in FR(tsA58)57 (A-type) cells, respectively. The phenotype-specific phosphorylation of tsA mutant large T in tsA A-type transformants probably is a cellular process induced during establishment of SV40 tsA A-type transformants, since tsA28 A-type transformant cells could be obtained by a large-T-dependent in vitro progression of cells of the tsA28 N-type transformant tsA28.3 (M. Osborn and K. Weber, J. Virol. 15:636-644, 1975).