Acylation: a new post-translational modification specific for plasma membrane-associated simian virus 40 large T-antigen

A Role of Sp1 Binding Motifs in Basal and Large T-Antigen-Induced Promoter Activities of Human Polyomavirus HPyV9 and Its Variant UF-1

Human polyomavirus 9 (HPyV9) was originally detected in the serum of a renal transplant patient. Seroepidemiological studies showed that ~20-50% of the human population have antibodies against this virus. HPyV9 has not yet been associated with any disease and little is known about the route of infection, transmission, host cell tropism, and genomic variability in circulating strains. Recently, the HPyV9 variant UF-1 with an eight base-pair deletion, a thirteen base-pair insertion and with point mutations, creating three putative Sp1 binding sites in the late promoter was isolated from an AIDS patient. Transient transfection studies with a luciferase reporter plasmid driven by HPyV9 or UF1 promoter demonstrated that UF1 early and late promoters were stronger than HPyV9 promoters in most cell lines, and that the UF1 late promoter was more potently activated by HPyV9 large T-antigen (LTAg). Mutation of two Sp1 motifs strongly reduced trans-activation of the late UF1 promoter by HPyV9 LTAg in HeLa cells. In conclusion, the mutations in the UF1 late promoter seem to strengthen its activity and its response to stimulation by HPyV9 LTAg in certain cells. It remains to be investigated whether these promoter changes have an influence on virus replication and affect the possible pathogenic properties of the virus.

The large tumor antigen: a "Swiss Army knife" protein possessing the functions required for the polyomavirus life cycle

The SV40 large tumor antigen (L-Tag) is involved in the replication and cell transformation processes that take place during the polyomavirus life cycle. The ability of the L-Tag to interact with and to inactivate the tumor suppressor proteins p53 and pRb, makes this polyfunctional protein an interesting target in the search for compounds with antiviral and/or antiproliferative activities designed for the management of polyomavirus-associated diseases. The severe diseases caused by polyomaviruses, mainly in immunocompromised hosts, and the absence of licensed treatments, make the discovery of new antipolyomavirus drugs urgent. Parallels can be made between the SV40 L-Tag and the human papillomavirus (HPV) oncoproteins (E6 and E7) as they are also able to deregulate the cell cycle in order to promote cell transformation and its maintenance. In this review, a presentation of the SV40 L-Tag characteristics, regarding viral replication and cellular transformation, will show how similar these two processes are between the polyoma- and papillomavirus families. Insights at the molecular level will highlight similarities in the binding of polyoma- and papillomavirus replicative helicases to the viral DNA and in their disruptions of the p53 and pRb tumor suppressor proteins.

Initial characterization of the membrane-associated form of ICP4 of herpes simplex virus type 1

The immediate-early gene product, ICP4, of herpes simplex virus type 1 (HSV-1) is one of the major transcriptional regulatory proteins in the virus replicative process and is localized primarily within the nucleus soon after its synthesis. Earlier studies have shown that detectable amounts of ICP4 are also associated with the plasma membranes of infected cells (F. Yao and R. J. Courtney, J. Virol. 65:1516-1524, 1991). To extend our understanding of the properties of the membrane-associated ICP4, we have used various electrophoretic techniques, including sodium dodecyl sulfate-polyacrylamide gel electrophoresis, two-dimensional gel electrophoresis, and isoelectric focusing, to compare the membrane- and nuclear-associated forms of ICP4. The data from all of these methods revealed that a single unique form of ICP4 associates with plasma membranes of HSV-1-infected cells. While multiple forms of ICP4 were detected in infected cell nuclei, the membrane-associated form of ICP4 appeared to have a lower apparent molecular weight and a more acidic pI than the various forms of ICP4 found in infected cell nuclei. These results suggest that a novel form of ICP4 may associate with plasma membranes of HSV-1-infected cells. A recombinant adenovirus, AdICP4 (encoding an ICP4 protein), was used to determine the role that other herpesvirus proteins may play in the membrane association of ICP4. The results suggest that the expression of other HSV-1 proteins is not required for the membrane association of ICP4.

Biochemical characterization of phosphorylation site mutants of simian virus 40 large T antigen: evidence for interaction between amino- and carboxy-terminal domains

The simian virus 40 large T antigen is phosphorylated at eight or more sites that are clustered in an amino-terminal region and a carboxy-terminal region of the protein. Mutants carrying exchanges at these phosphorylation sites have been generated in vitro by bisulfite or oligonucleotide-directed mutagenesis and analyzed for their phosphorylation patterns. Two-dimensional phosphopeptide analyses of the mutant large T antigens confirmed most of the previously identified phosphorylation sites, namely, serine residues 106, 112, 123, 639, 677, and 679 and threonine residues 124 and 701. In addition, serine residue 120 was identified as a new site, whereas serines residues 111 and 676 were excluded. Interestingly, several of the mutants exhibited secondary effects in that a mutation in the amino-terminal region affected phosphorylation at distant and even carboxy-terminal sites and vice versa. Thus, the amino- and carboxy-terminal domains appear to be in close proximity in the three-dimensional structure of large T antigen. The possible consequences of the above findings and the role of phosphorylation are discussed.

Acylation of viral and eukaryotic proteins

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Expression of simian virus 40 T antigen in insect cells using a baculovirus expression vector

Simian virus 40 (SV40) large T and small t antigens were synthesized in insect cells using the baculovirus Autographa californica as an expression vector. A recombinant virus containing a genomic copy of the SV40 early region expressed high levels of small t antigen but only low levels of large T antigen. However, very high levels of T antigen synthesis were observed when viruses were constructed with a cDNA copy of the large T antigen mRNA. Insect cells were capable of modifying T antigen by phosphorylation, palmitylation, glycosylation, and oligomerization. Functional assays demonstrated that the origin-specific DNA binding, ATPase, and helicase activities of insect cell-derived T antigen were comparable to T antigen synthesized in mammalian cells. Use of the baculovirus vector system to produce T antigen should facilitate future investigations requiring large quantities of T antigen.

Fine mapping two distinct antigenic sites on simian virus 40 (SV40) T antigen reactive with SV40-specific cytotoxic T-cell clones by using SV40 deletion mutants

The existence of two distinct antigenic sites at the surface of simian virus 40 (SV40)-transformed H-2b cells has been previously demonstrated (A. E. Campbell, L. F. Foley, and S. S. Tevethia, J. Immunol. 130:490-492, 1983) by using two independently isolated SV40-specific cytotoxic T-lymphocyte (CTL) clones, K11 and K19. We identified amino acids in the amino-terminal half of SV40 T antigen that are essential for the recognition of antigenic sites by these CTL clones by using H-2b cells transformed by mutants that produce T antigen truncated from the amino-terminal or carboxy-terminal end or carrying overlapping internal deletions in the amino-terminal regions of SV40 T antigen. The results show that CTL clone K11 failed to recognize and lyse target cells missing SV40 T-antigen amino acids 189 to 211, whereas CTL clone K19 lysed these cells. The cell lines missing SV40 T-antigen amino acids 220 to 223 and 220 to 228 were not lysed by CTL clone K19 but were susceptible to lysis by CTL clone K11. Two other cell lines missing amino acids 189 to 223 and 189 to 228 of SV40 T antigen were not lysed by either of the CTL clones but were lysed by SV40-specific bulk-culture CTL if sufficient amounts of relevant restriction elements were expressed at the cell surface. The SV40 T-antigen amino acids critical for the recognition of an antigenic site by CTL clone K11 were identified to be 193 to 211; 220 to 223 were identified as critical for recognition by CTL clone K19. The deletion of these amino acids from the T antigen resulted in the loss of antigenic sites specific for CTL clones K11 and K19.

Phosphorylation of polyomavirus large T antigen: effects of viral mutations and cell growth state

Phosphorylation is responsible for the shift in electrophoretic mobility of polyomavirus large T antigen observed in pulse-chase or continuous-labeling experiments. Phosphorylated forms migrated more slowly than newly synthesized [35S]methionine large T antigen, and alkaline phosphatase treatment reversed the mobility shift. Analysis of phosphopeptides with Staphylococcus aureus V8 protease showed that large T antigen forms of intermediate mobility were enriched in peptides 1 to 4, 8, and 9, while the slower migrating species had all nine phosphopeptides, including peptides 5 and 7. The phosphorylations represented by phosphopeptides 5 and 7 were of particular interest. These phosphopeptides were entirely lacking in large T antigen from tsa mutants such as ts616 labeled at the nonpermissive temperature. Also, the phosphorylation of peptides 5 and 7 depends on the growth state of the cell. Early in infection of quiescent cells intermediate mobility forms of large T antigen with little or no phosphorylation, particularly of peptides 5 and 7, were seen, whereas peptides 5 and 7 were well represented at the same time in patterns from growing cells. Later in infection of growth-arrested cells, these phosphorylations were observed, suggesting that infection stimulates the relevant kinase. Because large T antigen of hrt mutants, which lack middle and small T antigens, showed phosphorylation of peptides 5 and 7, large T antigen was apparently responsible for the stimulation. Because some differences in the distribution of phosphopeptides were noted between hrt mutants and the wild type, middle T antigen, small T antigen, or both may play a modulating role in large T antigen phosphorylation.

Kinetics of nuclear transport and oligomerization of simian virus 40 large T antigen

The kinetics of nuclear transport and of oligomerization of simian virus 40 (SV40) large T antigen in lytically infected cells were investigated by pulse-chase experiments, cell fractionation, and sedimentation analyses in sucrose gradients. After synthesis, large T was rapidly translocated to the nucleus. Within 10 min, half of the pulse-labeled molecules had entered the nucleus and after an additional 30 min, nuclear accumulation of large T reached a constant plateau of about 95%. Within that time, the majority of large T was in monomeric form suggesting that nuclear transport takes place in this state. In the nucleus, conversion to tetramers proceeded slowly and steadily. By 60 min half of the molecules had formed tetramers and by 6 hr a steady-state ratio between tetramers and monomers of 4:1 was observed. A small fraction of large T remaining in the cytoplasm oligomerized considerably faster than large T in the nuclear fraction. This phenomenon of accelerated oligomerization was also observed with a mutant of large T defective for nuclear transport. Perhaps, the nuclear envelope is a barrier for the complex forms of large T which prevents premature oligomers in the cytoplasm from entering the nucleus and oligomers in the nucleus from migrating back to the cytoplasm.

Replicative functions of the SV40(cT)-3 mutant defective for nuclear transport of T antigen

The SV40(cT)-3 mutant is defective in transport of SV40 large tumor antigen (T-ag) to the nucleus. Several properties of T-ag associated with SV40 lytic infection and attributed to its nuclear localization were examined to determine whether biologically significant levels of the mutant T-ag (cT-ag) that were immunologically undetectable were transported to the nucleus in SV40(cT)-3-infected TC-7 cells. SV40(cT)-3 was defective in regulation of T-ag synthesis and initiation of viral DNA synthesis. These defects were presumably due to the lack of nuclear transport of cT-ag, since cT-ag was capable of interacting with the SV40 origin of viral DNA synthesis in a solution binding assay. The level of fatty acid acylation, a modification specific for the cell surface associated T-ag, was not affected by the cT mutation. The cT mutation sufficiently suppressed the nuclear transport of wild-type (WT) T-ag in SV40(cT)-3-infected COS-1 cells to result in the cessation of WT-T-ag-stimulated SV40(cT)-3 viral DNA synthesis. These results are discussed with respect to the recent findings that SV40(cT)-3 is fully competent for the transformation of established cell lines and the induction of cellular DNA synthesis in quiescent cells.

Evidence for transmembrane orientation of acylated simian virus 40 large T antigen

In mKSA cells (a simian virus 40-transformed BALB/c mouse tumor cell line), plasma membrane-associated large T antigen (large T) is found in two subfractions of the plasma membrane; a minor amount of large T is recovered from the Nonidet P-40 (NP-40)-soluble plasma membrane fraction, whereas the majority is tightly bound to a substructure of the plasma membrane, the plasma membrane lamina (PML). Only PML-associated large T is fatty acid acylated (U. Klockmann and W. Deppert, EMBO J. 2:1151-1157, 1983). We have analyzed whether these two forms of plasma membrane-associated large T might differ in features like cell surface expression or metabolic stability. In addition, we have asked whether one of the two large Ts might represent the hypothetic, large T-related protein T* (D. F. Mark and P. Berg, Cold Spring Harbor Symp. Quant. Biol. 44:55-62, 1979). We show that in mKSA cells grown in suspension culture, large T associated with the PML is also exposed on the cell surface. This form of large T, therefore, exhibits properties of a transmembrane protein. Large T in the NP-40-soluble plasma membrane fraction could not be labeled with radioiodine on the cell surface and, for this reason, does not seem to be oriented towards the cell surface. In contrast, when mKSA cells were grown on substratum (culture dish), we found that in these cells both NP-40-soluble large T as well as large T anchored in the PML could be cell surface iodinated. We also have analyzed the plasma membrane association of surface T antigen in mKSA cells grown in a mouse as ascites tumor. In tumor cells, only PML-bound large T is cell surface associated. We conclude that differences in extractibility of cell surface-associated large T most likely depend on cell shape and are not an artifact of cell culture. Both NP-40-soluble and PML-bound large Ts are associated with the plasma membrane in a metabolically stable fashion. Neither of the two large Ts represents T*.

Induction of cellular DNA synthesis by a simian virus 40 mutant defective in nuclear transport of T antigen

The simian virus 40 (SV40) (cT)-3 mutant [SV40(cT)-3], which is defective in nuclear transport of T antigen, was utilized to determine whether cellular DNA synthesis can be stimulated by SV40 in the absence of detectable nuclear T antigen. Cellular DNA synthesis was examined in the temperature-sensitive cell cycle mutants, BHK ts13 and BHK tsAF8, after microinjection of quiescent cells with plasmid DNA containing cloned copies of wild-type SV40 or SV40(cT)-3. The efficiency of induction of cellular DNA synthesis was identical for both wild-type SV40 and SV40(cT)-3 in both cell lines. The results suggest that cell surface-associated T antigen, either alone or possibly in combination with minimal amounts of nuclear T antigen below our limit of detection, is able to stimulate cellular DNA synthesis.

Protein fatty acyltransferase is located in the rough endoplasmic reticulum

The fatty acid acylation of polypeptides was studied in vivo and in vitro by incorporation of radiolabeled palmitic acid into Semliki Forest viral polypeptides. Utilizing a cell-free system for acylation protein fatty acyltransferase was characterized as an integral membrane protein. No acylation activity was detected in the cytosol. During subcellular fractionation of a variety of mammalian or avian cells the enzyme was localized to the rough endoplasmic reticulum. Therefore this posttranslational hydrophobic modification starts earlier in the biosynthesis of acylated polypeptides than previously believed.

SV40 T antigen and the exocytotic pathway

A chimeric gene consisting of DNA coding for the 15-amino acid signal peptide of influenza virus hemagglutinin and the C-terminal 694 amino acids of SV40 large T antigen was inserted into a bovine papilloma virus (BPV) expression vector and introduced into NIH-3T3 cells. Cell lines were obtained that express high levels (approximately 5 X 10(6) molecules/cell) of the chimeric protein (HA-T antigen). The biochemical properties and intracellular localization of HA-T antigens were compared with those of wild-type T antigen. Wild-type T antigen. Wild-type T antigen is located chiefly in the cell nucleus, although a small fraction is detected on the cell surface. By contrast, HA-T antigen is found exclusively in the endoplasmic reticulum (ER). During biosynthesis, HA-T antigen is co-translationally translocated across the membrane of the ER, the signal peptide is cleaved and a mannose-rich oligosaccharide is attached to the polypeptide (T antigen contains one potential N-linked glycosylation site at Asn154). HA-T antigen does not become terminally glycosylated or acylated and little or none reaches the cell surface. These results suggest that T antigen is incapable of being transported along the exocytotic pathway. To explain the presence of wild-type T antigen on the surface of SV40-transformed cells, an alternative route is proposed involving transport of T antigen from the nucleus to the cell surface.

Induction of cellular DNA synthesis by a simian virus 40 mutant defective in nuclear transport of T antigen

The simian virus 40 (SV40) (cT)-3 mutant [SV40(cT)-3], which is defective in nuclear transport of T antigen, was utilized to determine whether cellular DNA synthesis can be stimulated by SV40 in the absence of detectable nuclear T antigen. Cellular DNA synthesis was examined in the temperature-sensitive cell cycle mutants, BHK ts13 and BHK tsAF8, after microinjection of quiescent cells with plasmid DNA containing cloned copies of wild-type SV40 or SV40(cT)-3. The efficiency of induction of cellular DNA synthesis was identical for both wild-type SV40 and SV40(cT)-3 in both cell lines. The results suggest that cell surface-associated T antigen, either alone or possibly in combination with minimal amounts of nuclear T antigen below our limit of detection, is able to stimulate cellular DNA synthesis.

DNA-binding properties of phosphorylated and dephosphorylated D2-T antigen, a simian-virus-40 T-antigen-related protein

I have examined the role of phosphorylation of D2-T antigen in its DNA-binding properties and ATPase activity. Treatment of partially purified D2-T antigen with alkaline phosphatase resulted in removal of maximally 90% of the phosphate label associated with the radio-labeled protein. The specific and nonspecific DNA-binding properties of partially dephosphorylated D2-T antigen were identical to those of the untreated control. In contrast, acid phosphatase was able to dephosphorylate D2-T antigen quantitatively. The general affinity for DNA of the completely dephosphorylated protein was unchanged or eventually slightly increased. However, its specific affinity for a restriction fragment containing the canonical T-antigen-binding sites was drastically reduced as shown by competition with unlabeled salmon sperm DNA. The results imply that nonspecific DNA binding of D2-T antigen is unaffected by phosphorylation whereas a specific phosphorylation site seems to be involved in the formation and/or stabilization of the specific protein-DNA complex. On the other hand, the ATPase activity of D2-T antigen seems to be unaffected by the degree of phosphorylation.

Modification of simian virus 40 large tumor antigen by glycosylation

The SV40-encoded transforming protein, large tumor antigen (T-ag), is multifunctional. Chemical modifications of the T-ag polypeptide may be important for its multifunctional capacity. T-ag is additionally modified by glycosylation. T-ag was metabolically labeled in SV40-infected cells with tritiated galactose or glucosamine, but not with mannose or fucose. The identity of glycosylated T-ag was established by immunoprecipitation with a variety of T-ag-specific antisera, including monoclonal antibodies. Incorporation of labeled sugar into T-ag was inhibited in the presence of excess unlabeled sugars, but not in the presence of excess unlabeled amino acids. Labeled monosaccharides could be preferentially removed from T-ag with a mixture of glycosidic enzymes. In addition, galactose was removed from purified T-ag by acid hydrolysis and identified as such by thin-layer chromatography. T-ag oligosaccharides were resistant to treatment with EndoH, and glycosylation was not inhibited by tunicamycin. Together, these data strongly suggest that T-ag is glycosylated. Several characteristics, including lack of mannose labeling, EndoH resistance, and tunicamycin resistance, suggest that T-ag is not an N-linked glycoprotein. Rather, these properties are more consistent with the identification of T-ag as an O-linked glycoprotein.

Plasma membrane orientation of simian virus 40 T antigen in three transformed cell lines mapped with monoclonal antibodies

Simian virus 40 large T antigen transforms cells from several species. Recent studies show that it is present on the cell surface. As in other tumor virus systems, this may be important for transformation. We have used a radioimmunoassay to map antigenic determinants on living and formaldehyde-fixed transformed cells with six different monoclonal antibodies to T antigen. Nonrelevant monoclonal antibodies of the same subclasses served as controls. With the transformed mouse line SVT2, antibody PAb 101, which reacts with the C-terminal region of T antigen, and PAb 1700, which is directed against an internal region of T, reacted with both formaldehyde-fixed and living cells. Antibodies PAb 402 (C terminus) and 419 (N terminus) reacted only with living cells, their determinants being destroyed upon formaldehyde fixation. Antibodies PAb 405 (C terminus) and 100 (internal) fail to react on either fixed or living cells. Similar results were obtained on the simian virus 40-transformed human line SV80 and the fixed hamster line CHLwt23, although all antibodies failed to react with living CHLwt23 cells. The data suggest that T antigen is inserted into the plasma membrane of transformed cells in a specific, nonrandom manner, with the C and N termini exposed on the cell surface and the midportion either buried in the lipid bilayer, hidden by the tertiary structure of T antigen, or masked by a post-translational modification such as fatty acid acylation.

Demonstration of T antigens on the surface of cells transformed with primate polyoma viruses

Primate polyoma virus-transformed hamster, mouse, and rat cell lines were examined by indirect immunofluorescence staining for cell surface-associated T antigens, by using a rabbit antiserum prepared against sodium dodecyl sulfate-denatured large T antigen of simian virus 40 (anti-SV40-SDS-T serum). Positive surface staining was shown not only on SV40-transformed cells, but also on BK and JC virus-transformed cells. In contrast, normal cells and cells transformed with mouse polyoma-, human adeno-, and murine sarcoma viruses were negative. The data on SV40-transformed cells confirmed the reports of others demonstrating the cell surface location of SV40 large T antigen, and the data on BK and JC virus-transformed cells proved that these cells have cell-surface T antigens that cross-react with anti-SV40-SDS-T serum.

Membrane interactions of simian virus 40 large T-antigen: influence of protein sequences and fatty acid acylation

To sort out possible influences of protein sequences and fatty acid acylation on the plasma membrane association of simian virus 40 large T-antigen, we have analyzed the membrane interactions of carboxy-terminal fragments of large T-antigen, encoded by the adenovirus type 2 (Ad2+)-simian virus 40 hybrid viruses Ad2+ND1 and Ad2+ND2. The 28,000 (28K)-molecular-weight protein of Ad2+ND1 as well as the 42K and 56K proteins of Ad2+ND2 associate preferentially with membranous structures and were found in association with the membrane system of the endoplasmic reticulum and with plasma membranes. Neither the endoplasmic reticulum membrane- nor the plasma membrane-associated 28K protein of Ad2+ND1 is fatty acid acylated. We, therefore, conclude that fatty acid acylation is not necessary for membrane association of this protein and suggest that an amino acid sequence in this protein is responsible for its membrane interaction. In contrast, the 42K and 56K proteins of Ad2+ND2 in plasma membrane fractions contain fatty acid. However, the interaction of these proteins with the plasma membrane differs from that of the 28K protein of Ad2+ND1: whereas the 28K protein of Ad2+ND1 interacts stably with Nonidet P-40-soluble constituents of the plasma membrane, the 42K and 56K proteins of Ad2+ND2 are tightly bound to the Nonidet P-40-insoluble plasma membrane lamina. Thus, an amino acid sequence in the amino-terminal region of the 28K protein confers membrane affinity to these proteins, whereas a region between the amino-terminal end of the 42K protein of Ad2+ND2 and the amino-terminal end of the 28K protein of Ad2+ND1 contains a reactive site for fatty acid acylation. This posttranslational modification correlates with the stable association of the 42K and 56K proteins with the plasma membrane lamina. We suggest that the same sequences also mediate the proper plasma membrane association of large T-antigen in simian virus 40-transformed cells.

Antigenic structure of simian virus 40 large tumor antigen and association with cellular protein p53 on the surfaces of simian virus 40-infected and -transformed cells

The antigenic structure of simian virus 40 (SV40) large tumor antigen (T-ag) in the plasma membranes of SV40-transformed mouse cells and SV40-infected monkey cells was characterized as a step toward defining possible biological function(s). Wild-type SV40, as well as a deletion mutant of SV40 (dl1263) which codes for a truncated T-ag with an altered carboxy terminus, was used to infect permissive cells. Members of a series of monoclonal antibodies directed against antigenic determinants on either the amino or the carboxy terminus of the T-ag polypeptide were able to precipitate surface T-ag (as well as nuclear T-ag) from both SV40-transformed and SV40-infected cells. Cellular protein p53 was coprecipitated with T-ag by all T-ag-reactive reagents from the surface and nucleus of SV40-transformed cells. In contrast, T-ag, but not T-ag-p53 complex, was recovered from the surface of SV40-infected cells. These results confirm that nuclear T-ag and surface T-ag are highly related molecules and that a complex of SV40 T-ag and p53 is present at the surface of SV40-transformed cells. Detectable levels of such a complex do not appear to be present on SV40-infected cells. Both the carboxy and amino termini of T-ag are exposed on the surfaces of SV40-transformed and -infected cells. The possible relevance of the presence of a T-ag-p53 complex on the surface of SV40-transformed cells and its absence from SV40-infected cells is considered.

Membrane interactions of simian virus 40 large T-antigen: influence of protein sequences and fatty acid acylation

To sort out possible influences of protein sequences and fatty acid acylation on the plasma membrane association of simian virus 40 large T-antigen, we have analyzed the membrane interactions of carboxy-terminal fragments of large T-antigen, encoded by the adenovirus type 2 (Ad2+)-simian virus 40 hybrid viruses Ad2+ND1 and Ad2+ND2. The 28,000 (28K)-molecular-weight protein of Ad2+ND1 as well as the 42K and 56K proteins of Ad2+ND2 associate preferentially with membranous structures and were found in association with the membrane system of the endoplasmic reticulum and with plasma membranes. Neither the endoplasmic reticulum membrane- nor the plasma membrane-associated 28K protein of Ad2+ND1 is fatty acid acylated. We, therefore, conclude that fatty acid acylation is not necessary for membrane association of this protein and suggest that an amino acid sequence in this protein is responsible for its membrane interaction. In contrast, the 42K and 56K proteins of Ad2+ND2 in plasma membrane fractions contain fatty acid. However, the interaction of these proteins with the plasma membrane differs from that of the 28K protein of Ad2+ND1: whereas the 28K protein of Ad2+ND1 interacts stably with Nonidet P-40-soluble constituents of the plasma membrane, the 42K and 56K proteins of Ad2+ND2 are tightly bound to the Nonidet P-40-insoluble plasma membrane lamina. Thus, an amino acid sequence in the amino-terminal region of the 28K protein confers membrane affinity to these proteins, whereas a region between the amino-terminal end of the 42K protein of Ad2+ND2 and the amino-terminal end of the 28K protein of Ad2+ND1 contains a reactive site for fatty acid acylation. This posttranslational modification correlates with the stable association of the 42K and 56K proteins with the plasma membrane lamina. We suggest that the same sequences also mediate the proper plasma membrane association of large T-antigen in simian virus 40-transformed cells.

Monoclonal antibodies against simian virus 40 nuclear large T tumour antigen: epitope mapping, papova virus cross-reaction and cell surface staining

Thirty six cloned hybridomas have been isolated which produce monoclonal antibodies directed against simian virus 40 (SV40) large T tumour antigen. They have been shown to recognize at least six different epitopes along the T antigen polypeptide according to their reaction with the various truncated forms of T antigen expressed by adenovirus-SV 40 hybrid viruses. Sixteen antibodies cross-react with cells infected by the closely related human BK virus. Only two antibodies, PAb1604 and PAb1614, directed against different epitopes of the SV40 T antigen, cross-react with polyoma large T tumour antigen which has a more limited amino acid sequence homology. This cross-reaction is rarely seen with polyclonal antibodies. Monoclonal antibody PAb1620 gave nuclear immunofluorescence only with murine cells transformed by SV40 and was found to react with a complex of T-antigen and 53 000-dalton host-coded protein. All the monoclonal antibodies react with nuclear T antigen and all but four antibodies stained the surface of SV40-transformed cells. These were four of the five antibodies directed against the central third of the T antigen. Thus the monoclonal antibodies show that cell surface T antigen differs from nuclear T antigen, either in accessibility or structure.

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.

Dynamic nature of the association of large tumor antigen and p53 cellular protein with the surfaces of simian virus 40-transformed cells

A molecular complex of simian virus 40 large tumor antigen (T-Ag) and p53 cellular protein is present on the surface of simian virus 40-transformed mouse cells. The stability of the association of the two proteins with the cell surface was characterized. Cells were either surface iodinated by the lactoperoxidase technique or metabolically labeled with [35S]methionine, and surface antigens were detected by differential immunoprecipitation with specific antibodies immediately after labeling or after incubation at 37 degrees C. A rapid, concomitant disappearance of T-Ag and p53 from the cell surface was observed. The half-life of iodinated surface T-Ag was less than 30 min, whereas that of [35S]methionine-labeled surface T-Ag was 1 to 2 h. Although T-Ag and p53 were rapidly lost, both were also rapidly replaced on the cell surface, since newly exposed molecules could be detected when cells were reiodinated after a 2-h chase period. Control experiments established that the loss of the surface molecules was not induced by the iodination reaction. The appearance of surface T-Ag was prevented when cellular protein synthesis was inhibited with cycloheximide. The disappearance and replacement of T-Ag and p53 appeared to be energy-independent processes, as neither was inhibited by sodium azide or 2,4-dinitrophenol. Incubation of iodinated cells at 4 degrees C did block the loss of T-Ag and p53. These observations suggest that T-Ag and p53 are coordinately turned over in the plasma membrane. The nature of the association of the T-Ag-p53 complex with the cell surface can best be described as highly dynamic.

Tightly associated lipids may anchor SV40 large T antigen in plasma membrane

Simian virus 40 (SV40) large T antigen, a multifunctional protein necessary for lytic growth and cell transformation, is located mainly in the nucleus and in small amounts on the cell surface (surface T). Surface T may have a passive role in SV40 tumour rejection by cytotoxic T cells as a component of SV40-TSTA (tumour-specific transplantation antigen). The unusual induction of this immune response by immunizing mice with soluble T antigen led us to investigate the in vitro binding of T antigen to the surface of living cells in more detail. Our results show that native surface T and a minor subset of large T antigen having a high cell surface binding affinity in vitro, behave like integral membrane proteins. Several viral proteins including SV40 T antigen and cellular proteins seem to be linked to fatty acids (acylation). To analyse whether this mechanism is involved in the stable attachment of in vitro-bound T antigen to the plasma membrane of living target cells, we determined the degree of labelling of this molecule by using target cells prelabelled with 3H-fatty acid. Here we report that T antigen extracted from unlabelled SV40-transformed cells (SV80) becomes 3H-labelled after in vitro binding to the cell surface of 3H-palmitate-prelabelled HeLa cells. These results suggest that T antigen attached externally to living cells, may be anchored by tightly linked lipids.

Acylated simian virus 40-specific proteins in the plasma membrane of HeLa cells infected with adenovirus 2-simian virus 40 hybrid virus Ad2+ND2

HeLa cells infected with the adenovirus 2-simian virus 40 (Ad2+SV40) hybrid virus Ad2+ND2 were labeled with either [35S]methionine or [3H]palmitate and fractionated into cytoplasmic, nuclear, and plasma membrane fractions. Analysis of these fractions by sodium dodecyl sulfate-polyacrylamide gel electrophoresis showed that the SV40-specific proteins in the plasma membrane fraction were specificially acylated.

Acylated simian virus 40 large T-antigen: a new subclass associated with a detergent-resistant lamina of the plasma membrane

We have analyzed the plasma membrane association of the SV40 large tumor antigen (large T) in SV40-transformed BALB/c mouse tumor cells (mKSA). Isolated plasma membranes were subfractionated: treatment with the non-ionic detergent Nonidet P40 (NP40) resulted in a NP40-resistant plasma membrane lamina, which could be further extracted with the zwitterionic detergent Empigen BB. Analysis of the different plasma membrane fractions revealed that only about one third of large T associated with isolated plasma membranes could be solubilized with NP40. The residual plasma membrane-associated large T was tightly bound to the NP40-resistant lamina of the plasma membrane from which it was released by treatment with the zwitterionic detergent Empigen BB. Further evidence for a specific interaction of a distinct subclass of large T with the plasma membrane was provided by showing that only T associated with the NP40-resistant lamina of the plasma membrane contained covalently bound fatty acid. Neither nuclear large T nor large T in the NP40-soluble plasma membrane fraction could be labeled with [3H]palmitic acid. Our results indicate that an acylated subclass of large T interacts specifically with a structure of the plasma membrane, suggesting that it might be involved in a membrane-dependent biological function.