Self-assembly of simian virus 40 large T antigen oligomers by divalent cations

Delivery of plasmid DNA to shrimp hemocytes by Infectious hypodermal and hematopoietic necrosis virus (IHHNV) nanoparticles expressed from a baculovirus insect cell system

Virus-like particles (VLPs) are potential containers for delivery of therapeutic agents at the nanoscale. In this study, the capsid protein of Infectious hypodermal and hematopoietic necrosis virus (IHHNV) was expressed in a baculovirus insect cell system. The 37-kDa recombinant protein containing the hexahistidine residues (His Tag) at N-terminal was purified using immobilized metal affinity chromatography (IMAC) and assembled into VLPs with a diameter of 23 ± 3 nm analyzed by transmission electron microscopy. We also verified that disassembly/reassembly of IHHNV-VLPs was controlled in the presence and absence of DTT. The efficiency of IHHNV-VLPs to encapsulate plasmid DNA was about 48.2%, and the VLPs encapsulating the pcDNA3.1(+)-EGFP plasmid DNA could recognize the primary shrimp hemocytes and deliver the loaded plasmid into cells by detection of expressed enhanced green fluorescent protein (EGFP). These results implied that the IHHNV-VLPs might be a good candidate for packaging and delivery of expressible plasmid DNA, and may produce an antiviral product in shrimp cells for gene therapy.

Encapsulation and delivery of plasmid DNA by virus-like nanoparticles engineered from Macrobrachium rosenbergii nodavirus

Virus-like particles (VLPs) are potential candidates in developing biological containers for packaging therapeutic or biologically active agents. Here, we expressed Macrobrachium rosenbergii nodavirus (MrNv) capsid protein (encoding amino acids M1-N371 with 6 histidine residuals) in an Escherichia coli BL21(DE3). These easily purified capsid protein self-assembled into VLPs, and disassembly/reassembly could be controlled in a calcium-dependent manner. Physically, MrNv VLPs resisted to digestive enzymes, a property that should be advantageous for protection of active compounds against harsh conditions. We also proved that MrNv VLPs were capable of encapsulating plasmid DNA in the range of 0.035-0.042 mol ratio (DNA/protein) or 2-3 plasmids/VLP (assuming that MrNV VLPs is T=1, i made up of 60 capsid monomers). These VLPs interacted with cultured insect cells and delivered loaded plasmid DNA into the cells as shown by green fluorescent protein (GFP) reporter. With many advantageous properties including self-encapsulation, MrNv VLPs are good candidates for delivery of therapeutic agents.

Studies on the parameters controlling the stability of the TET peptidase superstructure from Pyrococcus horikoshii revealed a crucial role of pH and catalytic metals in the oligomerization process

The TET proteases from Pyrococcus horikoshii are metallopeptidases that form large dodecameric particles with high thermal stability. The influence of various physico-chemical parameters on PhTET3 quaternary structure was investigated. Analytical ultracentrifugation and biochemical analyses showed that the PhTET3 quaternary structure and enzymatic activity are maintained in high salt and that the complex is stable under extreme acidic conditions. Under basic pH conditions the complex disassembled into a low molecular weight species that was identified as folded dimer. Metal analyses showed that the purified enzyme only contains two equivalent of zinc per monomer, corresponding to the metal ions responsible for catalytic activity. When these metals were removed by EDTA treatment, the complex dissociated into the same dimeric species as those observed at high pH. Dodecameric TET particles were obtained from the metal free dimers when 2mM of divalent ions were added to the protein samples. Most of the dimers remained assembled at high temperature. Thus, we have shown that dimers are the building units in the TET oligomerization pathway and that the active site metals are essential in this process.

Relationship of oligomerization to DNA binding of Wheat dwarf virus RepA and Rep proteins

Members of the genus Mastrevirus (family Geminiviridae) produce a complementary-sense (c-sense) transcription unit with the potential to encode two proteins, RepA and Rep. In the present work, we have studied the DNA-protein complexes formed by the Wheat dwarf virus (WDV) RepA protein within the WDV large intergenic region. WDV RepA forms large nucleoprotein complexes near the TATA boxes of the viral complementary-sense and virion-sense (v-sense) promoters (the RepA C- and V-complexes, respectively), a location similar to those of WDV Rep-DNA complexes but with distinct DNase I footprints. We have also studied the relationship of oligomerization of WDV RepA and Rep proteins to DNA-protein complex formation. Using chemical cross-linking, we have determined that both WDV proteins can form oligomers in solution. Interestingly, the pH is critical for the monomer-oligomer equilibrium and small changes produce a displacement in such a way that at pH </= 7.0, the predominant species is an octamer while at pH >/= 7.4 it is a monomer. Complex formation is also strongly affected by pH and occurs more efficiently at pH 7.0-7.4. We found that preformed oligomers interact very poorly with DNA. Thus, our data are consistent with a stepwise model for protein-DNA complex assembly in which monomers interact with DNA and then with other monomers to assemble an oligomeric structure on the DNA. These results may be relevant for studies on the DNA binding, replication, and transcription properties of geminivirus proteins.

Regulation of p53 mediated transactivation by the beta-subunit of protein kinase CK2

The growth suppressor protein p53 plays a main part in cellular growth control. Two of its key functions are sequence specific DNA binding and transactivation. Functions of p53 in growth control are regulated at least in part by its interaction with protein kinases. p53 binds to protein kinase CK2, formerly known as casein kinase 2, and it is phosphorylated by this enzyme. CK2 is composed of two regulating beta-subunits and two catalytic alpha- or alpha'-subunits and the interaction with p53 is mediated by the regulatory beta-subunit of CK2. Recently we showed that the beta-subunit could inhibit the sequence specific DNA binding activity of p53 in vitro. Based on this finding, we asked if a coexpression of the beta-subunit of CK2 with p53 in mammalian cells could inhibit the DNA binding activity of p53 in a physiological context. We found that the coexpression of the beta-subunit showed the same inhibitory effect as in the previous assays with purified proteins. Then, we investigated the effects of the coexpression of the beta-subunit of CK2 on the transactivation and transrepression activity of p53. We found that transactivation of the mdm2, p21(WAF1/CIP1) and cyclin G promoter was inhibited in three different cell lines whereas transactivation of the bax promoter was not affected in COS1 cells but down-regulated in MCO1 and SaosS138V21 cells. p53 mediated transrepression of the fos promoter was not influenced by coexpression of the CK2 beta-subunit. Taken together we propose a cell type dependent fine regulation of the p53 transactivation function by the CK2 beta-subunit in vivo, which does not affect p53 mediated transrepression.

A casein-kinase-2-related protein kinase is tightly associated with the large T antigen of simian virus 40

The simian virus 40 (SV40) large T antigen is a multifunctional protein involved in SV40 cell transformation and lytic virus infection. Some of its activities are regulated by interaction with cellular proteins and/or by phosphorylation of T antigen by various protein kinases. In this study, we show that immuno-purified T antigen from SV40-transformed cells and from baculovirus-infected insect cells is tightly associated with a protein kinase that phosphorylates T antigen in vitro. In the presence of heparin or a peptide resembling a protein kinase CK2 recognition site, the phosphorylation of T antigen by the associated kinase is reduced whereas a p34cdc2-kinase-specific peptide has no influence. In addition, the T-antigen-associated protein kinase can use GTP and ATP as phosphate donors. These properties together with the observation that immunopurified T antigen can be phosphorylated by the addition of protein kinase CK2 suggest that at least one of the T-antigen-associated protein kinases is CK2 or a protein-kinase-CK2-related enzyme. The association of recombinant CK2 with T antigen was strongly confirmed by in vitro binding studies. Experiments with temperature-sensitive SV40-transformed cells provide evidence for a close correlation between cell transformation and phosphorylation of T antigen by the associated protein kinase.

The interaction of SV40 large T antigen with unspecific double-stranded DNA: an electron microscopic study

T antigen, an early protein encoded by simian virus 40 (SV40), is a specific DNA-binding protein with high affinity for elements in the viral origin of replication where it forms a double-hexameric complex as a prerequisite for DNA untwisting and, in the presence of ATP hydrolysis, for DNA unwinding. Like other specific DNA-binding proteins, T antigen also associates with DNA strands of random sequence albeit at reduced affinity. In addition, T antigen is able to unwind unspecific DNA sequences starting from internal binding sites. This property could be a step in the pathway leading to the chromosomal rearrangements that are frequently observed in SV40-transformed cells. This possibility prompted us to investigate the binding of T antigen to unspecific DNA using electron microscopy. We observed that the protein binds randomly to many unspecific DNA sites excluding a preference for particular DNA sequences or structural features. Addition of ATP to the binding buffer induces the formation of oligomeric, possibly hexameric, T antigen complexes that frequently align to form long arrays of DNA-bound protein. Magnesium salts induce the formation of tightly packed T antigen aggregates which bind to DNA to form many DNA branches and loops that emanate from the aggregated protein core. Upon ATP hydrolysis, aggregated T antigen catalyzes the unwinding of DNA duplices.

Cooperation of p53 and polyoma virus middle T antigen in the transformation of primary rat embryo fibroblasts

Cell transformation in vivo seems to be a multistep process. In in vitro studies certain combinations of two oncogenes, a cytoplasmic gene product together with a nuclear gene product, are sufficient to transform primary rodent cells. Polyoma virus large T antigen can immortalize and, in cooperation with polyoma virus middle T antigen, transform primary cells. On the other hand mutant mouse p53 can also immortalize and, in cooperation with an activated Ha-ras oncogene, transform primary cells. In the present study we analyzed whether mutant p53 can replace polyoma virus large T antigen in a cell transformation assay with polyoma virus middle T antigen. Transfection of mutant p53 alone resulted in a cell line which had retained the actin cable network, grew poorly in medium with low concentration of serum, and failed to grow in semisolid agar. Cotransfection of mutant p53 together with polyoma virus middle T led to cells which grew in medium containing low serum concentration, grew well in semisolid agar, and displayed an altered morphology with the tendency to overgrow the normal monolayer. By these criteria these cells were considered fully transformed. The rate of p53 synthesis was similar in both cell lines. However, only p53 from the transformed cell line turned out to be stable. Cells transformed by mutant p53 and polyoma virus middle T expressed nearly the same amount of the c-src-encoded pp60c-src protein as cells transformed by the same p53 and cotransfected activated Ha-ras oncogene. However, only the polyoma virus middle T/p53-transformed cells exhibited an elevated level of pp60c-src-specific tyrosine kinase activity. Thus, despite different mechanisms leading to cell transformation, mutant p53 can replace polyoma virus large T antigen and polyoma virus middle T can replace the activated Ha-ras oncogene in cell transformation.

Protein-protein interactions in high molecular weight forms of the transformation-related phosphoprotein p53

The transformation-related cellular phosphoprotein p53 interacts with a variety of viral and cellular proteins and with itself to form high molecular weight complexes. The formation of high molecular weight complexes correlates with the transformed morphology of the cells whereas in non-transformed cells low molecular weight forms are predominant. Thus, aggregation seems to be involved in the regulation of biological functions of p53. Analyzing wild-type and mutant p53 in the same cellular environment i.e. after an in vitro transcription/translation reaction in rabbit reticulocytes we found high molecular weight forms for wild-type and mutant p53. The sedimentation profile resembled the profile obtained for mutant p53 from transformed cells. As shown by dilution experiments, aggregation of p53 was not due to high p53 protein concentrations. Although p53 is known to bind RNA, treatment with RNAse did not change the aggregation state of p53 suggesting that RNA may not contribute to the quaternary structure of p53. High molecular weight aggregates of p53 were resistant to treatment with 1 M NaCl and also stable in weak acidic conditions. Alkaline pH as well as treatment with 3.5 M NaCl led to a disaggregation of high molecular weight complexes of p53. This treatment resulted in low molecular weight forms consisting probably of dimers to tetramers whereas monomers of p53 are hardly detectable. A nearly complete disaggregation was obtained only with the ionic denaturing detergent sodium dodecyl sulfate. Therefore, one has to assume different types of protein-protein interactions leading to the various quaternary structures of p53.

Correlation of metabolic stability and altered quaternary structure of oncoprotein p53 with cell transformation

The phosphoprotein p53 seems to be implicated in various processes connected with cell transformation and in particular with the regulation of cell cycle and probably DNA replication. In the present paper we have analyzed two sets of closely related cell lines expressing the same p53 which exhibited either a nontransformed or a transformed phenotype. These cell lines were used to study biochemical properties of the p53 protein which might be correlated with cell transformation. We found a positive correlation among an elevated stability of p53, the formation of high-molecular-weight forms of p53, and the transformed phenotype of the corresponding cell lines. Furthermore, these data indicate that self-aggregation prevents p53 from rapid degradation. By a comparative analysis of the stability and oligomerization properties of mutant p53 and wild-type p53, we could demonstrate that elevated stability and self-aggregation of p53 are correlated with the transformed phenotype of the cells and independent of a particular mutation in the p53 gene.

The retinoblastoma susceptibility gene product undergoes cell cycle-dependent dephosphorylation and binding to and release from SV40 large T

Synchronized monkey cells pulse-labeled with [35S]-methionine and chased for various lengths of time were extracted, and immunoprecipitations were performed using monoclonal antibodies directed against the retinoblastoma protein (RB) and SV40 T antigen (T). By following a discrete population of these two proteins through the cell cycle, the following information was obtained. RB, which is wholly unphosphorylated in G1, became phosphorylated at the beginning of S and remained phosphorylated through S and G2. RB was, then, completely dephosphorylated between the end of G2 and the beginning of G1. Second, while all of the detectable unphosphorylated RB can be found complexed with T, these complexes present during G1 dissociated in S and reformed again in M or early G1. Finally, T molecules appeared to oligomerize prior to binding RB. Thus, complex formation between T and RB may be regulated in part by the cell cycle-dependent phosphorylation and dephosphorylation of RB and by the quaternary structure of T.

Expression of p53 in human leukemic cell lines

The cell-encoded p53 antigen seems to be tightly associated with various human malignancies. We have analyzed biochemical properties of p53 in two different cell lines derived from patients with ALL or ANLL. p53 was found in elevated levels in both leukemic cell lines compared to unstimulated or stimulated normal lymphocytes. High levels of p53 in these cell lines are due to an extended stability of p53 protein rather than to different rates of synthesis. p53 from both cell lines formed low- and high-molecular weight oligomers which revealed that p53 exists in a heterogenous population in these tumor cells. The presence of immunologically different subsets of p53 was demonstrated by sequential immunoprecipitation experiments with different p53 specific monoclonal antibodies. Our results showed structural and immunological variabilities of p53 in cell lines derived from human tumors and may thus provide an insight into the role p53 may play in human malignancies.

Linker insertion mutants of simian virus 40 large T antigen that show trans-dominant interference with wild-type large T antigen map to multiple sites within the T-antigen gene

Linker insertion mutants affecting the simian virus 40 (SV40) large tumor (T) antigen were constructed by inserting a 12-base-pair oligonucleotide linker into restriction endonuclease cleavage sites located within the early region of SV40. One mutant, with the insertion at amino acid 5, was viable in CV-1p and BSC-1 cells, indicating that sequences very close to the amino terminus of large T could be altered without affecting the lytic infection cycle of SV40. All other mutants affecting large T were not viable. In complementation assays between the linker insertion mutants and either a late-gene mutant, dlBC865, or a host range/helper function (hr/hf) mutant, dlA2475, delayed complementation was seen with the 6 of the 10 nonviable mutants. Of these 10 mutants, 5 formed plaques 3 to 4 days later than in control complementations, while complementation by one of the mutants, inA2827, with an insertion at amino acid 520, was delayed more than 1 week. Most mutants which showed delayed complementation replicated less well in Cos-1 cells than did a control mutant, dlA1209, which produced no T antigen. The replication of inA2827(aa520) was reduced by more than 90%. Similar interference with viral DNA replication was seen when CV-1, HeLa, or 293 cells were cotransfected with an origin-defective plasmid encoding wild-type large T antigen and with inA2827(aa520). Only one of the mutant T antigens, inA2807(aa303), was unstable. These results indicate that some of the mutant T antigens interfered with functions of wild-type T required for viral DNA replication. However, not all of the mutants which showed delayed complementation also showed interference with viral DNA replication. This indicates that mutant large T antigens may interfere trans dominantly with multiple activities of wild-type large T antigen.

ATP-dependent assembly of double hexamers of SV40 T antigen at the viral origin of DNA replication

Simian virus 40 (SV40) replicates in nuclei of human and monkey cells. One viral protein, large tumour (T) antigen, is required for the initiation of DNA replication. The development of in vitro replication systems which retain this property has facilitated the identification of the cellular components required for replication. T antigen recognizes the pentanucleotide 5'-GAGGC-3' which is present in four copies within the 64 base-pairs (bp) of the core origin. In the presence of ATP it binds with increased affinity forming a distinctive, bilobed structure visible in electron micrographs. As a helicase, it unwinds SV40 DNA bidirectionally from the origin. We report here that in vitro and in the presence of ATP, T antigen assembles a double hexamer, centred on the core origin and extending beyond it by 12 bp in each direction. The assembly of this dodecamer initiates an untwisting of the duplex by 2-3 turns. In the absence of ATP, a tetrameric structure is the largest found at the core origin. In the absence of DNA, but in the presence of ATP or its non-hydrolysable analogues, T antigen assembles into hexamers. This suggests that ATP effects an allosteric change in the monomer. The change alters protein-protein interactions and allows the assembly of a double hexamer, which initiates replication at the core origin.

SV40 T-antigen binding to site II is functionally separated from binding to site I

During lytic infection SV40 T antigen binds specifically to three different regions of the SV40 DNA to initiate viral DNA replication and to regulate early and late transcription. We have used the recently described plasmids pKB1, containing a 23-bp oligonucleotide coding for site I, pdl1085 containing sites II and III together with SV40 specific flanking sequences, and as a control pATC, a plasmid which contains all three binding sites (D. Müller et al. (1987), Virology 161, 81-91) to analyze the differential binding of T antigen to these individual binding sites in the course of an SV40 infection. We found that shortly after infection the amount of bound DNA increased with the concentration of T antigen reaching a steady-state level at about 20 hr after infection. In comparison to binding at site I, binding to site II appeared with a delay of about 8-9 hr corresponding to the onset of viral DNA replication. The correlation between binding of T antigen to site II and the SV40 DNA replication could be further corroborated by using T antigen from the heat-sensitive mutant tsA58 which completely failed to bind to site II at nonpermissive temperature but exhibited a residual binding to site I. This reduced binding to site I proved insufficient for the proper functioning of autorepression. Our results support the hypothesis that distinctly different subclasses of T-antigen binding to site I or site II may exist.

Variable expression of SV40 large T antigen in CV1 cell clones

Using immunofluorescence and immunoadsorption, CV1 cell clones MA2, V4, USA3, TR7 and P3 infected with SV40 were found to express variably SV40 large T antigen. The monoclonal antibody used was Pab 419. The results indicate that P3 cells express T antigen to a considerable level as early as 10 h post-infection, while that of TR7 and USA3 cells is minute as judged from their positive nuclei. MA2 and V4 cells did not show any positive nuclei over this period of infection. At 20 h post-infection MA2, V4 and USA3 cells developed a considerable amount of fluorescence in their nuclei while TR7 and P3 cells produced high values. By immunoadsorption of cell extracts for the same periods of infection, similar results were obtained on the electrophoretograms. We also relate these findings with those from induction of heatshock proteins by SV40 infection.

The AT-rich sequence of the SV40 control region influences the binding of SV40 T antigen to binding sites II and III

During lytic infection SV40 T antigen binds specifically to three different regions of the SV40 DNA to initiate DNA replication and to regulate early and late transcription. We constructed plasmids containing either 23-bp synthetic oligonucleotides representing site I or II or SV40 DNA fragments with combinations of binding sites II and III with or without SV40 specific flanking regions. These plasmids were used to determine which sequences are sufficient for specific binding to isolated regions II and III. Under identical conditions T antigen bound in a sensitive in vitro binding assay efficiently to site I but not to the corresponding oligonucleotide of site II. Binding to site II could only be observed in the presence of the adjacent 17-bp AT-rich region of the SV40 DNA. On account of the markedly low affinity for binding site II, T antigen concentrations were required which exceeded those necessary to achieve saturation of binding to site I. The very low affinity for isolated site III could be slightly raised by the same AT-rich region. An increased binding to site II at 37 degrees compared to 0 degree in the presence of this region points to an indirect influence on the DNA structure of the binding site.

Dimers and complexes with p53 are the prevalent oligomeric forms of a transforming nonkaryophilic T antigen of simian virus 40

The oligomers formed by a mutant nonkaryophilic large T antigen of simian virus 40, which lacks residues 110 through 152 of normal large T antigen and transforms only established cells (L. Fischer-Fantuzzi and C. Vesco, Proc. Natl. Acad. Sci. USA 82:1891-1895, 1985), were found to consist predominantly of dimers. Anti-p53 antibodies precipitated 14 to 16S complexes containing the mutant nonkaryophilic large T antigen and p53 from extracts of transformed cells, and anti-p53 indirect immunofluorescence stained these cells in the cytoplasm.

Identification of calmodulin activity in purified retroviruses

Several viruses have been shown to require calcium for their function, and to bind calcium at specific sites. However, the nature of the calcium binding molecule on viruses has not been established. One possibility is the ubiquitous calcium-binding protein calmodulin. Our studies were designed to determine whether feline leukemia virus contained calmodulin. Accordingly, we tested purified feline leukemia virus for the presence of calmodulin-like activity. The virus, like authentic calmodulin, activated cyclic AMP phosphodiesterase. The ability of the virus to activate the enzyme was blocked in the presence of the known calmodulin inhibitors trifluoperazine and W-7. This indirect evidence for the presence of calmodulin was confirmed by radioimmunoassay. Several other retroviruses were also tested using radioimmunoassay and found to contain calmodulin. Our results indicate that the calcium binding site in retroviruses may be calmodulin.

Complex formation of simian virus 40 large T antigen with cellular protein p53

We investigated the formation of native complexes between simian virus 40 large T antigen and the cellular protein p53 (T-p53) by using simian virus 40 tsA58-transformed mouse fibroblasts (tsA58 F2b). We observed that newly synthesized p53 bound to all structural subclasses of large T antigen detectable on sucrose density gradients. This led to various intermediates of T-p53 complexes which converted within 2 h into typical mature aggregates. The final levels of stable T-p53 complexes seemed to be determined by p53 rather than by large T antigen.

Regions of SV40 large T antigen necessary for oligomerization and complex formation with the cellular oncoprotein p53

The simian virus 40 (SV40) T antigen is composed of 708 amino acids and forms monomers and various oligomers and, in small amounts, heterologous complexes with the cellular oncoprotein p53 (T-p53). Using SV40 mutants coding for T antigen fragments which are either deleted in the N-terminal half or truncated by various lengths at the C-terminal end, we found that a region between amino acids 114 and 152 and a C-terminal region up to amino acid 669 are essential for the formation of high Mr oligomers of T antigen. Furthermore, only the C-terminal end up to amino acid 669 is essential for T-p53 complex formation but not the N-terminus up to amino acid 152.

Biochemical properties of a transforming nonkaryophilic T antigen of SV40

We reconstructed into wt SV40 DNA a previously described deletion of the A gene, eliminating amino acids 110 through 152 of the large T (L. Fischer-Fantuzzi and C. Vesco (1985) Proc. Natl. Acad. Sci. USA 82, 1891-1895); the gene product of the new recombinant pACTSV2, like the previous product, has a cytoplasmic instead of a nuclear localization and efficiently transforms NIH3T3 cells. Three main functions of this nonkaryophilic large T (NKLT) were examined, and the results obtained were the following: the NKLT does not bind to the SV40 origin DNA under conditions where the normal large T shows specific binding; the NKLT has conserved the ability to form high molecular weight aggregates; the NKLT becomes phosphorylated in vivo at only two residues: serine 639 and threonine 701. This indicates that the NH2-terminal phosphorylation of the large T is unnecessary for established-cell transformation. In addition, this and previous evidence (K. H. Scheidtmann et al. (1984) J. Virol. 50, 636-640) suggest that the lack of phosphorylation in serines 106, 676, 677, and 679 may constitute a characteristic of the large T molecules with extranuclear localization.

SV40 large T-antigen and transformation related protein p53 are associated in situ with nuclear RNP structures containing hnRNA of transformed cells

The localization of SV40 large T-antigen (T-Ag) and the cellular protein p53 in the nuclei of mouse and human SV40-transformed cells and of a methylcholanthrene-transformed mouse cell line, was studied. Their detection by ultrastructural immunocytochemistry with specific monoclonal antibodies employed two complementary methods used in parallel. These consisted of indirect immunoperoxidase labelling carried out before embedment on Triton-permeabilized cells, or indirect immunogold labelling applied to thin sections of cells embedded in Lowicryl K4M. The results indicate that in SV40-transformed cells both proteins are chiefly localized on peri- and interchromatin RNP fibrils. This shows that they occur in structures involved in the synthesis and processing of hnRNA. The nucleoli and chromatin did not appear to be labelled. In methylcholanthrene-transformed cells the protein p53 (in the absence of large T-Ag) was also detected on peri- and interchomatin fibrils. Taken together with recent results which demonstrated that, during lytic infection, T-Ag was associated chiefly with cellular chromatin (Harper, F, Florentin, Y & Puvion, E, Exp cell res 161 (1985) 434) [33], our experiments provide evidence that the transforming function of SV40 large T-Ag is dissociable from its function in SV40 lytic infection in terms of its subnuclear distribution.

Simian virus 40 large T antigen oligomers: analysis of electrophoresis in the absence of detergent

Large T antigen of simian virus 40 is found as monomeric and oligomeric species in transformed cells. These can be demonstrated in cell extracts by velocity centrifugation in sucrose gradients. We analyzed them further in a transformed human line cell (SV80) and a transformed mouse line cell (SVT2). Individual fractions from sucrose gradients were subjected to polyacrylamide gel electrophoresis in the absence of detergent. T-antigen species were then detected by protein blotting and antibody overlay with polyclonal anti-D2 T antibody or monoclonal Pab419, Pab101, or Pb1700 antibody. The rapidly sedimenting species (14S and larger) of large T antigen from both cell lines reproducibly showed two major bands with estimated molecular weights of 670,000 and 850,000. A third band of 1,200,000 was more prominent in SVT2 cells than in SV80 cells. In SV80 cells the slowly sedimenting species of large T antigen (5S to 11S) contained two reproducible bands. A band with a molecular weight of 95,000 was the predominant one in all fractions between 5S and 11S. A relatively minor band with a molecular weight of 230,000 was found in fractions between 9S and 11S. The low-molecular-weight forms were seen in SVT2 cells only when a prominent peak at 5S to 7S was present, that is, when extracts were stored before analysis. In fresh extracts, the low-molecular-weight bands and slowly sedimenting forms were absent.

Oligomerization of simian virus 40 tumor antigen may be involved in viral DNA replication

Biological implications of the oligomerization of simian virus 40 (SV40) large T antigen for viral DNA replication were studied by using two temperature-sensitive SV40 A-gene mutants, tsA 58 and tsA 1499. Both mutants are defective at elevated temperature for viral DNA replication whereas tsA 58 is like most other tsA mutants additionally heat sensitive for cell transformation. We found that in contrast to tsA 58 encoded T antigen, tsA 1499 T antigen is thermostable in the ability to bind specifically to the origin of replication of SV40 DNA. Detailed structural analysis of tsA 1499 T antigen by sucrose density gradient centrifugation revealed that it is strictly temperature sensitive for the formation of homologous oligomers but, as we reported previously (M. Montenarh, M. Kohler, and R. Henning, 1984, J. Virol, 49, 658-664), not for the association with the cellular phosphoprotein p53. These observations are compatible with the idea that, in addition to the specific origin-binding ability as well as other functional features, the oligomerization of T antigen may be essential for viral DNA replication.

Relationship of phosphorylation to the oligomerization of SV40 T antigen and its association with p53

The potential significance of the phosphorylation of SV40 large T antigen for oligomers and complexes with the cellular protein p53 was investigated. We observed that T antigen oligomers remain stable after enzymatic dephosphorylation by alkaline phosphatase up to 80%. Separate analysis of free and p53-bound T antigen revealed a considerably lower phosphorylation of the p53-bound subclass. Therefore, a simple correlation between the overall phosphorylation of T antigen and the formation of oligomers and T-p53 complexes is highly unlikely.

Differential phosphorylation of cytoplasmic and nuclear variants of simian virus 40 large T antigen encoded by simian virus 40-adenovirus 7 hybrid viruses

The phosphorylation patterns of cytoplasmic and nuclear forms of simian virus 40 large T antigen encoded by simian virus 40-adenovirus 7 hybrid viruses were analyzed by two-dimensional peptide mapping. The PARA(cT) mutant which encodes a large T antigen defective for nuclear transport was used as source for cytoplasmic large T antigen. The data suggest that the large T antigen is phosphorylated in a sequential manner at a subset of sites in the cytoplasm and at additional sites in the nucleus.

DNA-binding activity of simian virus 40 large T antigen correlates with a distinct phosphorylation state

The state of phosphorylation and the relationship of various subclasses of simian virus 40 large T antigen (large T) differing in DNA-binding activity, degree of oligomerization, age, and subcellular distribution were investigated. Young large T (continuously labeled for 4 h late in infection) comprised about 20% of the total cellular large T. It was phosphorylated to a low degree and existed primarily in a monomeric form, sedimenting at 5S. More than 50% of this fraction bound to simian virus 40 DNA, preferentially to origin-containing sequences. Old large T (continuously labeled for 17 h, followed by a 4-h chase) represented the majority of the population. It was highly phosphorylated and predominantly in an oligomeric form, sedimenting at 15S to 23S. Only 10 to 20% of this fraction bound to simian virus 40 DNA. Another subclass of large T which was extracted from nuclei with 0.5 M salt resembled newly synthesized molecules in all properties tested; it was phosphorylated to a low degree, sedimented at 5S, and bound to viral DNA with high efficiency (greater than 70%). Two-dimensional phosphopeptide analysis of the individual subclasses revealed two distinct phosphorylation patterns, one characteristic for young, monomeric, and DNA-binding large T, the other for old, oligomeric, and non-DNA-binding large T. All sites previously identified in unfractionated large T (K.H. Scheidtmann et al., J. Virol. 44:116-133, 1982) were also phosphorylated in the various subclasses, but to different degrees. Peptide maps of the DNA-binding fraction, the 5S form, and the nuclear high-salt fraction showed two prominent phosphopeptides not previously characterized. Both peptides were derived from the amino-terminal region of large T, presumably involved in origin binding, and probably represent partially phosphorylated intermediates of known phosphopeptides. Our data show that the DNA-binding activity, age, and oligomerization of large T correlate with distinct states of phosphorylation. We propose that differential phosphorylation might play a role in the interaction of large T with DNA.

Oligomerization of simian virus 40 large T antigen is not necessarily repressed by temperature-sensitive A gene lesions

Simian virus 40 large T antigen is a multifunctional protein which exists in different molecular weight forms. According to several reports, T antigen encoded by temperature-sensitive simian virus 40 A locus mutants (tsA) is unable to oligomerize into high-molecular-weight species. To try to correlate structural and functional properties, we selected tsA58 and tsA1499, both of which are heat sensitive for lytic growth, but only tsA58 is heat sensitive for transformation. Here we report that at permissive and nonpermissive temperatures, T antigen from tsA1499-infected monkey cells retained the ability to oligomerize, whereas reported previously, tsA58 T antigen failed to oligomerize at the nonpermissive temperature. Furthermore, we studied the formation of complexes between T antigen and the cellular p53 protein (T-p53) late in infection. Corresponding to its heat-stable oligomerization properties, T antigen encoded by tsA1499 formed T-p53 complexes regardless of temperature. In contrast, tsA58 encoded T-p53 complexes, preformed at the permissive temperature, remained heat stable after shifting up to the nonpermissive temperature; but at this temperature no new T-p53 complexes arose. The mutants did not replicate viral DNA at the nonpermissive temperature, suggesting that neither the oligomerization of T antigen nor the formation of T-p53 complexes seems to be sufficient for viral DNA replication or for the expression of late viral proteins.