Virion assembly defect of polyomavirus hr-t mutants: underphosphorylation of major capsid protein VP1 before viral DNA encapsidation

The Major Capsid Protein, VP1, of the Mouse Polyomavirus Stimulates the Activity of Tubulin Acetyltransferase 1 by Microtubule Stabilization

Viruses have evolved mechanisms to manipulate microtubules (MTs) for the efficient realization of their replication programs. Studying the mechanisms of replication of mouse polyomavirus (MPyV), we observed previously that in the late phase of infection, a considerable amount of the main structural protein, VP1, remains in the cytoplasm associated with hyperacetylated microtubules. VP1–microtubule interactions resulted in blocking the cell cycle in the G2/M phase. We are interested in the mechanism leading to microtubule hyperacetylation and stabilization and the roles of tubulin acetyltransferase 1 (αTAT1) and deacetylase histone deacetylase 6 (HDAC6) and VP1 in this mechanism. Therefore, HDAC6 inhibition assays, αTAT1 knock out cell infections, in situ cell fractionation, and confocal and TIRF microscopy were used. The experiments revealed that the direct interaction of isolated microtubules and VP1 results in MT stabilization and a restriction of their dynamics. VP1 leads to an increase in polymerized tubulin in cells, thus favoring αTAT1 activity. The acetylation status of MTs did not affect MPyV infection. However, the stabilization of MTs by VP1 in the late phase of infection may compensate for the previously described cytoskeleton destabilization by MPyV early gene products and is important for the observed inhibition of the G2→M transition of infected cells to prolong the S phase.

Production and biomedical applications of virus-like particles derived from polyomaviruses

Virus-like particles (VLPs), aggregates of capsid proteins devoid of viral genetic material, show great promise in the fields of vaccine development and gene therapy. These particles spontaneously self-assemble after heterologous expression of viral structural proteins. This review will focus on the use of virus-like particles derived from polyomavirus capsid proteins. Since their first recombinant production 27 years ago these particles have been investigated for a myriad of biomedical applications. These virus-like particles are safe, easy to produce, can be loaded with a broad range of diverse cargoes and can be tailored for specific delivery or epitope presentation. We will highlight the structural characteristics of polyomavirus-derived VLPs and give an overview of their applications in diagnostics, vaccine development and gene delivery.

Assembly of simple icosahedral viruses

Icosahedral viruses exhibit elegant pathways of capsid assembly and maturation regulated by symmetry principles. Assembly is a dynamic process driven by consecutive and genetically programmed morphogenetic interactions between protein subunits. The non-symmetric capsid subunits are gathered by hydrophobic contacts and non-covalent interactions in assembly intermediates, which serve as blocks to build a symmetric capsid. In some cases, non-symmetric interactions among intermediates are involved in assembly, highlighting the remarkable capacity of capsid proteins to fold into demanding conformations compatible with a closed protein shell. In this chapter, the morphogenesis of structurally simple icosahedral viruses, including representative members of the parvoviruses, picornaviruses or polyomaviruses as paradigms, is described in some detail. Icosahedral virus assembly may occur in different subcellular compartments and involve a panoplia of cellular and viral factors, chaperones, and protein modifications that, in general, are still poorly characterized. Mechanisms of viral genome encapsidation may imply direct interactions between the genome and the assembly intermediates, or active packaging into a preformed empty capsid. High stability of intermediates and proteolytic cleavages during viral maturation usually contribute to the overall irreversible character of the assembly process. These and other simple icosahedral viruses were pioneer models to understand basic principles of virus assembly, continue to be leading subjects of morphogenetic analyses, and have inspired ongoing studies on the assembly of larger viruses and cellular and synthetic macromolecular complexes.

Global analysis of modifications of the human BK virus structural proteins by LC-MS/MS

BK virus, a human polyomavirus, may cause nephritis and urological disorders in patients who have undergone renal transplantation. Little is known about the characteristics of the BK viral proteins. In the current study, BK viral proteins were characterized by immunoblotting and LC-MS/MS. The results revealed that BK virus is composed of three structural proteins, VP1, VP2, and VP3 and four cellular histones, H2A, H2B, H3, and H4. The major structural protein, VP1, can be divided into 16 subspecies by two-dimensional gel electrophoresis. Modifications of VP1, VP2, and VP3 were comprehensively identified by LC-MS/MS. The presence of acetylation, cysteinylation, carboxymethylation, carboxyethylation, formylation, methylation, methylthiolation, oxidation, dioxidation, and phosphorylation could be identified. This is the first report providing an analysis of the global modifications present on polyomavirus structural proteins. The identification of these modifications of VP1, VP2, and VP3 should facilitate an understanding of the physiology of BKV during its life cycle.

Polyomavirus small T antigen controls viral chromatin modifications through effects on kinetics of virus growth and cell cycle progression

Minichromosomes of wild-type polyomavirus were previously shown to be highly acetylated on histones H3 and H4 compared either to bulk cell chromatin or to viral chromatin of nontransforming hr-t mutants, which are defective in both the small T and middle T antigens. A series of site-directed virus mutants have been used along with antibodies to sites of histone modifications to further investigate the state of viral chromatin and its dependence on the T antigens. Small T but not middle T was important in hyperacetylation at major sites in H3 and H4. Mutants blocked in middle T signaling pathways but encoding normal small T showed a hyperacetylated pattern similar to that of wild-type virus. The hyperacetylation defect of hr-t mutant NG59 was partially complemented by growth of the mutant in cells expressing wild-type small T. In contrast to the hypoacetylated state of NG59, NG59 minichromosomes were hypermethylated at specific lysines in H3 and also showed a higher level of phosphorylation at H3ser10, a modification associated with the late G(2) and M phases of the cell cycle. Comparisons of virus growth kinetics and cell cycle progression in wild-type- and NG59-infected cells showed a correlation between the phase of the cell cycle at which virus assembly occurred and histone modifications in the progeny virus. Replication and assembly of wild-type virus were completed largely during S phase. Growth of NG59 was delayed by about 12 h with assembly occurring predominantly in G(2). These results suggest that small T affects modifications of viral chromatin by altering the temporal coordination of virus growth and the cell cycle.

Independent contributions of polyomavirus middle T and small T to the regulation of early and late gene expression and DNA replication

We previously showed that murine polyomavirus mutants that lack both middle T (MT) and small T (ST) functions have a severe pleiotropic defect in early and late viral gene expression as well as genome amplification. The respective contribution of MT and ST to this phenotype was unclear. This work separates the roles of MT and ST in both permissive mouse cells and nonpermissive rat cells. It demonstrates for the first time a role for both proteins. To gain insight into the signaling pathways that might be required, we focused on MT and its mutants. The results show that each of the major MT signaling connections, Shc, phosphatidylinositol 3'-kinase, and phospholipase C gamma1, could contribute in an additive way. Unexpectedly, a mutant lacking all these connections because the three major tyrosines had been converted to phenylalanine retained some activity. A mutant in which all six MT C-terminal tyrosines had been mutated was inactive. This suggests a novel signaling pathway for MT that uses the minor tyrosines. What is common to ST and the individual MT signaling pathways is the ability to signal to the polyomavirus enhancer, in particular to the crucial AP-1 and PEA3/ets binding sites. This connection explains the pleiotropy of MT and ST effects on transcription and DNA replication.

Polyomavirus hr-t mutant-specific induction of a G2/M cell-cycle arrest that is not overcome by the expression of middle T and/or small T

The polyomavirus hr-t class of mutants has served as a major prototype to study the function of middle T + small T in the virus lytic cycle, Biochem. Biophys. Acta 695 (2), 69-95). The properties of these middle T + small T defective mutants were defined by comparisons with "wild-type" strains reconstructed by marker rescue. Similar comparisons in the A2 genetic background have revealed a number of differences, J. Virol. 75, 8380-8389). Here we describe a major divergence in their effects on cell-cycle progression of both permissive mouse NIH3T3 cells and semipermissive Fischer rat FR3T3 cells. Infection of NIH3T3 or FR3T3 cells in serum-rich medium with wild-type A2 (WTA2) or WTA2-derived middle T + small T-defective mutants did not perturb cell cycling, tested up to entry into the third cycle. In contrast, infection with four hr-t mutants analyzed, examined in detail with mutant B2, resulted in an accumulation of cells in G2/M in a dose-dependent and serum-independent manner. The arrest began in the first cell cycle. At multiplicities of infection above 10 PFU/cell, 50-80% of the cell population became arrested by the end of the second cycle. FR3T3 arrested cells detached from the monolayer with a rounded up morphology. Three other hr-t mutants investigated were also found to arrest cells in G2/M. Expression of middle T and/or small T either in trans or in cis did not abrogate this cell-cycle arrest, as demonstrated in the latter case with the middle T + small T expressing strain "wtB2" obtained by repair of the B2 deletion. In FR3T3 cells, the induction of a cell-cycle arrest by wtB2 was accompanied by a severe delay and reduction in neoplastic transformation relative to WTA2 used at equal dose. Mutation(s) in the C-terminal domain of large T antigen, upstream of the site-specific DNA binding activity, is necessary for the cell-cycle block. The possible causes for the cell-cycle block are discussed.

Role of middle T-small T in the lytic cycle of polyomavirus: control of the early-to-late transcriptional switch and viral DNA replication

A comparative analysis of the lytic cycle of wild-type polyomavirus and middle T and small T defective mutants was carried out in the A2 genetic background. The results contrast with those obtained in comparisons between the hr-t type and their middle-T small-T-producing partners as previously described (20). The A2-derived mutants were found to share the maturation defect previously described for the hr-t mutants. However, their defect in DNA replication was more acute, resulting in a 5- to 100-fold decrease in the accumulation of viral genomes. Furthermore, their gene expression pattern was affected. A2-derived mutants displayed an early defect resulting in a 4- to 16-h delay in the expression of large T, and an alteration of the early-to-late transcriptional switch. In wild-type A2 infection, this switch is characterized by a large increase in the accumulation of early transcripts followed by late transcripts after the appearance of middle T and small T proteins and the onset of viral DNA replication (L. Chen and M. M. Fluck, J. Virol. 75: 8368-8379, 2001). In the mutant infection, increases in both classes of transcripts were delayed and reduced, but the effect on early transcripts was more pronounced. As has been described previously for the hr-t mutants (E. Goldman, J. Hattori, and T. Benjamin, Cell 13:505-513, 1979), the magnitude of these defects depended upon experimental conditions. Experiments using cytosine beta-arabinofuranoside to reduce genome amplification suggest that the effect of middle T-small T on the transcriptional switch is not solely mediated by the effect of these protein(s) on increasing the number of templates. These data provide the first direct demonstration of an effect of middle T and/or small T in the viral transcription pattern during viral infection. The results agree with previous results obtained with plasmid reporters and with our understanding that the downstream targets of the middle T signaling pathway include three transcription factors that have binding sites in the enhancer domain that play a key regulatory role in the expression of the viral genes.

Expression of major capsid protein VP-1 in the absence of viral particles in thymomas induced by murine polyomavirus

Thymomas induced by polyomavirus strain PTA in mice are known to express the major capsid protein VP-1. Since the expression of a late structural protein such as VP-1 is considered a sign of virus replication, the present work attempted to clarify the implication of the presence of this protein in tumor cells. Electron microscopy of tumors showed a striking absence of viral particles in the vast majority of the cells. However, immunoelectron microscopy of the same samples demonstrated intranuclear VP-1 in most cells despite the absence of viral particles. Very little infectious virus was recovered from tumors. A change in the electrophoretic mobility of VP-1 from thymomas was detected compared with VP-1 from productively infected cells. The data presented in this work prove that the expression of VP-1 in polyomavirus-induced tumors is not synonymous with the presence of infectious virus, suggesting a possible defect in viral encapsidation.

Phosphorylation status of the parvovirus minute virus of mice particle: mapping and biological relevance of the major phosphorylation sites

The core of the VP-1 and VP-2 proteins forming the T=1 icosahedral capsid of the prototype strain of the parvovirus minute virus of mice (MVMp) share amino acids sequence and a common three-dimensional structure; however, the roles of these polypeptides in the virus infection cycle differ. To gain insights into this paradox, the nature, distribution, and biological significance of MVMp particle phosphorylation was investigated. The VP-1 and VP-2 proteins isolated from purified empty capsids and from virions containing DNA harbored phosphoserine and phosphothreonine amino acids, which in two-dimensional tryptic analysis resulted in complex patterns reproducibly composed by more than 15 unevenly phosphorylated peptides. Whereas secondary protease digestions and comigration of most weak peptides in the fingerprints revealed common phosphorylation sites in the VP-1 and VP-2 subunits assembled in capsids, the major tryptic phosphopeptides were remarkably characteristic of either polypeptide. The VP-2-specific peptide named B, containing the bulk of the (32)P label of the MVMp particle in the form of phosphoserine, was mapped to the structurally unordered N-terminal domain of this polypeptide. Mutations in any or all four serine residues present in peptide B showed that the VP-2 N-terminal domain is phosphorylated at multiple sites, even though none of them was essential for capsid assembly or virus formation. Chromatographic analysis of purified wild-type (wt) and mutant peptide B digested with a panel of specific proteases allowed us to identify the VP-2 residues Ser-2, Ser-6, and Ser-10 as the main phosphate acceptors for MVMp capsid during the natural viral infection. Phosphorylation at VP-2 N-terminal serines was not necessary for the externalization of this domain outside of the capsid shell in particles containing DNA. However, the plaque-forming capacity and plaque size of VP-2 N-terminal phosphorylation mutants were severely reduced, with the evolutionarily conserved Ser-2 determining most of the phenotypic effect. In addition, the phosphorylated amino acids were not required for infection initiation or for nuclear translocation of the expressed structural proteins, and thus a role at a late stage of MVMp life cycle is proposed. This study illustrates the complexity of posttranslational modification of icosahedral viral capsids and underscores phosphorylation as a versatile mechanism to modulate the biological functions of their protein subunits.

Use of electron microscopic and immunogold labeling techniques to determine polyomavirus recombinant VP1 capsid-like particles entry into mouse 3T6 cell nucleus

Murine polyomavirus major structural protein VP1 could assemble into capsid-like particles when expressed in the baculovirus system. The recombinant capsid-like particles that were purified by CsCl density gradient centrifugation were capable of packaging host DNA. Electron microscopic and immunogold labeling techniques were used to study the entry of these VP1 recombinant capsid-like particles into mouse 3T6 cells. It was found that these VP1 recombinant capsid-like particles, which lack polyomavirus minor structural proteins (VP2 and VP3), use the same mechanism to enter mouse 3T6 cell cytoplasm and nucleus as that used by native polyomavirus virions.

Murine polyomavirus infection of 3T6 mouse cells shows evidence of predominant necrosis as well as limited apoptosis

The current study was developed to determine if polyomavirus infected 3T6 mouse cells evoked an apoptotic or a necrotic mechanism during infection. Infected cells were analyzed by flow cytometry, transmission electron microscopy (TEM), DNA electrophoresis and by measuring caspase-3 enzymatic activity. Infected cells that were analyzed at 72 h post-infection showed the following: flow cytometry analysis revealed a 5% increase in apoptotic cells and a 46% increase in necrotic cells when compared to uninfected cells; electron microscopy showed 10% cells with characteristic apoptotic morphology and 40% with necrotic appearance; caspase-3 activity was found to increase two fold when compared to uninfected cells and DNA fragmentation (laddering) was clearly evident late in infection. It was concluded that infected cells predominantly showed necrosis, although some cells showed apoptosis in late infection. Recombinant capsid-like particles composed of the polyomavirus structural proteins were not able to induce cell death.

Interaction of polyomavirus internal protein VP2 with the major capsid protein VP1 and implications for participation of VP2 in viral entry

A complex of the polyomavirus internal protein VP2/VP3 with the pentameric major capsid protein VP1 has been prepared by co-expression in Escherichia coli. A C-terminal segment of VP2/VP3 is required for tight association, and a crystal structure of this segment, complexed with a VP1 pentamer, has been determined at 2.2 A resolution. The structure shows specific contacts between a single copy of the internal protein and a pentamer of VP1. These interactions were not detected in the previously described structure of the virion, but the location of VP2 in the recombinant complex is consistent with features in the virion electron-density map. The C-terminus of VP2/VP3 inserts in an unusual, hairpin-like manner into the axial cavity of the VP1 pentamer, where it is anchored strongly by hydrophobic interactions. The remainder of the internal protein appears to have significant flexibility. This structure restricts possible models for exposure of the internal proteins during viral entry.

High-resolution structure of a polyomavirus VP1-oligosaccharide complex: implications for assembly and receptor binding

The crystal structure of a recombinant polyomavirus VP1 pentamer (residues 32-320) in complex with a branched disialylated hexasaccharide receptor fragment has been determined at 1.9 A resolution. The result extends our understanding of oligosaccharide receptor recognition. It also suggests a mechanism for enhancing the fidelity of virus assembly. We have previously described the structure of the complete polyomavirus particle complexed with this receptor fragment at 3.65 A. The model presented here offers a much more refined view of the interactions that determine carbohydrate recognition and allows us to assign additional specific contacts, in particular those involving the (alpha2,6)-linked, branching sialic acid. The structure of the unliganded VP1 pentamer, determined independently, shows that the oligosaccharide fits into a preformed groove and induces no measurable structural rearrangements. A comparison with assembled VP1 in the virus capsid reveals a rearrangement of residues 32-45 at the base of the pentamer. This segment may help prevent the formation of incorrectly assembled particles by reducing the likelihood that the C-terminal arm will fold back into its pentamer of origin.

The elevation of cellular phosphatidic acid levels caused by polyomavirus transformation can be disassociated from the activation of phospholipase D

Middle T (mT), the oncogene of murine polyomavirus, causes transformation of rat fibroblasts by activating a number of signal transducing pathways usually used by polypeptide growth factors and their receptors. Here, we report data regarding the activation of signal transducing pathways involving phospholipase D (PL-D). The hydrolysis of phospholipids by PL-D produces phosphatidic acid (PA), a compound with multiple biological effects. The PA content of cells expressing wild-type mT, introduced via a number of different methods, is approximately 50% higher than their untransformed counterparts. This increase in cellular PA content is associated with an approximately 65% increase in PL-D activity in cells expressing wild-type mT. We have also examined the effects of a number of site-directed mutants of mT, on both cellular PA levels and on PL-D activity. Mutants that do not produce mT (Py808A) or that produce a truncated, nonmembrane bound mT (Py1387T) have PA levels similar to that of control cells. Cells expressing the 322YF mutant of mT (which abolishes interaction of mT with phospholipase C gamma1) show increases in both PA levels and PL-D activity that are similar to those seen with wild-type mT. Expression of mutants that abolish the interaction of mT with either shc or with phosphatidylinositol 3-kinase (250YS and 315YF, respectively) cause an increase in PL-D activity comparable to that seen with wild-type mT. However, the PA content of cells expressing these mutants is not elevated. These results suggest that mT causes activation of cellular PL-D, but this activation alone is not sufficient to cause an increase in cellular PA content. Therefore, wild-type mT must affect another, as yet unknown, step in PA metabolism.

The NS2 polypeptide of parvovirus MVM is required for capsid assembly in murine cells

Mutants of minute virus of mice (MVM) which express truncated forms of the NS2 polypeptide are known to exhibit a host range defect, replicating productively in transformed human cells but not in cells from their normal murine host. To explore this deficiency we generated viruses with translation termination codons at various positions in the second exon of NS2. In human cells these mutants were viable, but showed a late defect in progeny virion release which put them at a selective disadvantage compared to the wildtype. In murine cells, however, duplex viral DNA amplification was reduced to 5% of wildtype levels and single-strand DNA synthesis was undetectable. These deficiencies could not be attributed to a failure to initiate infection or to a generalized defect in viral gene expression, since the viral replicator protein NS1 was expressed to normal or elevated levels early in infection. In contrast, truncated NS2 gene products failed to accumulate, so that each mutant exhibited a similar NS2-null phenotype. Expression of the capsid polypeptides VP1 and VP2 and their subsequent assembly into intact particles were examined in detail. Synchronized infected cell populations labeled under pulse-chase conditions were analyzed by differential immunoprecipitation of native or denatured extracts using antibodies which discriminated between intact particles and isolated polypeptide chains. These analyses showed that at early times in infection, capsid protein synthesis and stability were normal, but particle assembly was impaired. Unassembled VP proteins were retained in the cell for several hours, but as the unprocessed material accumulated, capsid protein synthesis progressively diminished, so that at later times relatively few VP molecules were synthesized. Thus in NS2-null infections of mouse cells there is a major primary defect in the folding or assembly processes required for effective capsid production.

The structure of simian virus 40 refined at 3.1 A resolution

BACKGROUND

The structure of simian virus 40 (SV40), previously determined at 3.8 degree resolution, shows how its pentameric VP1 assembly units are tied together by extended C-terminal arms. In order to define more precisely the possible assembly mechanisms, we have refined the structure at 3.1 degree resolution.

RESULTS

New data from a high-intensity synchrotron source have been used for phase extension by electron-density averaging and refinement, exploiting only the strict 5-fold non-crystallographic symmetry for the real-space averaging steps. The accurate model enables us to study important structural features of the virus particle in detail. The remarkably invariant core of the VP1 pentamer bears the docking sites for the C-terminal arms from other pentamers. These contacts are the principal way in which pentameric assembly units are linked together in the capsid. Only at the interface between five-coordinated and six-coordinated pentamers do the pentamer cores appear to interact strongly. There are two cation-binding sites per VP1 monomer, seen in a soaking experiment with gadolinium nitrate. These sites are quite close to each other at the interfaces between pentamers.

CONCLUSION

We propose that the contact between five-coordinated and six-coordinated pentamers may help to generate a six-pentamer nucleus, with which further pentamers can assemble to generate the complete particle. Calcium ions probably stabilize the structure of the assembled particle, rather than direct its assembly.

Methylation of the polyomavirus major capsid protein VP1

Polyomavirus VP1 has been shown to be modified by phosphorylation, sulfation, acetylation and hydroxylation. The major capsid protein VP1 is now shown to be modified by methylation. Addition of cycloheximide to infected cultures followed by addition of [3H-methyl]-L-methionine and subsequent immunoprecipitation, SDS-PAGE and fluorography revealed methylation occurring on VP1. Amino acid analysis of [3H-methyl]-L-methionine-labelled polyomavirus VP1 by two-dimensional paper chromatography and HPLC of the acid-hydrolyzed protein revealed the presence of 3H-labelled trimethyllysine and monomethylarginine.

Mammary tumors induced by polyomavirus

The first known member of the Polyomavirus family, murine Polyomavirus (MPyV), was discovered because of its oncogenic properties. The genetic simplicity of MPyV (shared with all members of the Py family), the wide spectrum of tumors induced by MPyV, and the convenient properties of its natural host, the mouse, make it a particularly interesting model system to study oncogenesis. This paper briefly reviews the virus infectious cycle and our current understanding of the viral proteins that are involved in oncogenesis, and focuses on recent studies on oncogenesis of the mammary gland. Mammary gland ductal adenocarcinomas develop at high frequency and with short latency in infected immunoincompetent adult female or normal neonatal mice or in transgenic mice expressing the viral oncogene, middle T. These tumors provide excellent model systems for the study of human breast cancer.

In vitro phosphorylation of the polyomavirus major capsid protein VP1 on serine 66 by casein kinase II

Phosphorylation of the polyomavirus major capsid protein VP1 plays a role in virus assembly and may function in virus-cell recognition. Previous mapping of the in vivo phosphorylation sites on VP1 identified phosphorylation of threonine residues Thr-63 and Thr-156 (Li, M., and Garcea, R. L. (1994) J. Virol. 68, 320-327). Phosphoserine was detected in a tryptic phosphopeptide encompassing residues 58-78. Because of consensus casein kinase II (CK II) sites in this peptide, we examined the in vitro phosphorylation of the purified recombinant VP1 protein by CK II. CK II phosphorylated VP1 on serine, and the resulting tryptic phosphopeptide eluted in a 30-31 min high performance liquid chromatography fraction corresponding to residues 58-78. The VP1 tryptic phosphopeptide also co-migrated in two-dimensional peptide analysis with one of the tryptic peptides obtained from VP1 isolated after in vivo 32P labeling of virus-infected cells. A site-directed mutant VP1 protein, Ser-66 to Ala, was phosphorylated poorly by CK II in vitro. As determined by electron microscopy, all of the mutant proteins were isolated in pentameric form similar to the wild-type protein, although the Ala-66 pentamers had a tendency to self-assemble in vitro into tubular as well as capsid-like structures. These findings identify Ser-66 as a site of VP1 phosphorylation in vitro, and suggest that VP1 may serve as a substrate for CK II in vivo.

Intermediates of adeno-associated virus type 2 assembly: identification of soluble complexes containing Rep and Cap proteins

The proteins encoded by the adeno-associated virus type 2 (AAV-2) rep and cap genes obtained during a productive infection of HeLa cells with AAV-2 and adenovirus type 2 were fractionated according to solubility, cellular localization, and sedimentation properties. The majority of Rep and Cap proteins accumulated in the nucleus, where they distributed into a soluble and an insoluble fraction. Analysis of the soluble nuclear fraction of capsid proteins by sucrose density gradients showed that they formed at least three steady-state pools: a monomer pool sedimenting at about 6S, a pool of oligomeric intermediates sedimenting between 10 and 15S, and a broad pool of assembly products with a peak between 60 and 110S, the known sedimentation positions of empty and full capsids. While the soluble nuclear monomer and oligomer pool contained predominantly only two capsid proteins, the 30 to 180S assembly products contained VP1, VP2, and VP3 in a stoichiometry similar to that of purified virions. They probably represent different intermediates in capsid assembly, DNA encapsidation, and capsid maturation. In contrast, the cytoplasmic fraction of capsid proteins showed a pattern of oligomers continuously increasing in size without a defined peak, suggesting that assembly of 60S particles occurs in the nucleus. Soluble nuclear Rep proteins were distributed over the whole sedimentation range, probably as a result of association with AAV DNA. Subfractions of the Rep proteins with defined sedimentation values were obtained in the soluble nuclear and cytoplasmic fractions. We were able to coimmunoprecipitate capsid proteins sedimenting between 60 and 110S with antibodies against Rep proteins, suggesting that they exist in common complexes possibly involved in AAV DNA packaging. Antibodies against the capsid proteins, however, precipitated Rep78 and Rep68 predominantly with a peak around 30S representing a second complex containing Rep and Cap proteins.

Polyomavirus VP1 phosphorylation: coexpression with the VP2 capsid protein modulates VP1 phosphorylation in Sf9 insect cells

The polyomavirus virion has an outer capsid comprised of 72 pentamers of the VP1 protein associated with the minor virion proteins, VP2 and VP3, and the viral minichromosome. To investigate the interaction between VP1 and VP2/VP3, we mapped VP1 phosphorylation sites and assayed VP1 recognition by anti-peptide antibodies after coexpression of VP1 with VP2 or VP3 by using recombinant baculovirus vectors. VP1, expressed either alone or with VP3, was phosphorylated on serine residues, which are not modified during polyomavirus infection of mouse cells. When VP1 was coexpressed with VP2, the nonphysiologic serine phosphorylation of VP1 was decreased, and a tryptic peptide containing Thr-63, a site modified during virus infection of mouse cells, was phosphorylated. An anti-peptide antibody directed against the VP1 BC loop domain containing Thr-63 recognized VP1 expressed alone but not VP1 coexpressed with VP2 or VP3. The change in phosphorylation resulting from coexpression of two structural proteins identifies the potential of the baculovirus system for studying protein-protein interactions and defines a functional role for the VP1-VP2 interaction.

Host range and cell cycle activation properties of polyomavirus large T-antigen mutants defective in pRB binding

We have examined the growth properties of polyomavirus large T-antigen mutants that are unable to bind pRB, the product of the retinoblastoma tumor suppressor gene. These mutants grow poorly on primary mouse cells yet grow well on NIH 3T3 and other established mouse cell lines. Preinfection of primary baby mouse kidney (BMK) epithelial cells with wild-type simian virus 40 renders these cells permissive to growth of pRB-binding polyomavirus mutants. Conversely, NIH 3T3 cells transfected by and expressing wild-type human pRB become nonpermissive. Primary fibroblasts from mouse embryos that carry a homozygous knockout of the RB gene are permissive, while those from normal littermates are nonpermissive. The host range of polyomavirus pRB-binding mutants is thus determined by expression or lack of expression of functional pRB by the host. These results demonstrate the importance of pRB binding by large T antigen for productive viral infection in primary cells. Failure of pRB-binding mutants to grow well in BMK cells correlates with their failure to induce progression from G0 or G1 through the S phase of the cell cycle. Time course studies show delayed synthesis and lower levels of accumulation of large T antigen, viral DNA, and VP1 in mutant compared with wild-type virus-infected BMK cells. These results support a model in which productive infection by polyomavirus in normal mouse cells is tightly coupled to the induction and progression of the cell cycle.

Simian virus 40 large T antigen host range domain functions in virion assembly

The simian virus 40 (SV40) T antigen host range mutants dl1066 and dl1140 display a postreplicative block to plaque formation which suggests a novel role for T antigen late in the viral life cycle. The host range mutants dl1066 and dl1140 are able to grow in and plaque on BSC but not on CV1 monkey kidney cells, a normally permissive host. Previous work showed that in CV1 cells infected with dl1066 and dl1140, levels of viral DNA replication and of late capsid protein accumulation were only slightly reduced and the failure to accumulate agnoprotein was not likely to be the major factor responsible for the mutants' growth defect. Here we show that the host range mutants are defective in the assembly of viral particles. SV40 assembly proceeds as the progressive conversion of 75S viral chromatin complexes to 200S-240S assembled virions. When virus-infected cell extracts are separated on 5 to 40% sucrose gradients, wild-type extracts show the greatest accumulation of viral late protein in the 200S-240S fractions corresponding to the assembled virus peak and lesser amounts in the 75S-150S fractions corresponding to immature assembly intermediates. The host range mutants dl1066 and dl1140 grown in nonpermissive CV1 cells, however, failed to assemble any appreciable amounts of mature 200S-240S virions and accumulate 75S intermediates, whereas in permissive BSC cells, levels of assembly were more slightly reduced than those of the wild type. Analysis of the protein composition of gradient fractions suggests that SV40 assembly proceeds by a mechanism similar to that proposed for polyomavirus and suggests that the host range blockage may result from a failure of such mutants to add VP1 to 75S assembly intermediates.

Purification of recombinant budgerigar fledgling disease virus VP1 capsid protein and its ability for in vitro capsid assembly

A recombinant system for the major capsid VP1 protein of budgerigar fledgling disease virus has been established. The VP1 gene was inserted into a truncated form of the pFlag-1 vector and expressed in Escherichia coli. The budgerigar fledgling disease virus VP1 protein was purified to near homogeneity by immunoaffinity chromatography. Fractions containing highly purified VP1 were pooled and found to constitute 3.3% of the original E. coli-expressed VP1 protein. Electron microscopy revealed that the VP1 protein was isolated as pentameric capsomeres. Electron microscopy also revealed that capsid-like particles were formed in vitro from purified VP1 capsomeres with the addition of Ca2+ ions and the removal of chelating and reducing agents.

Identification of the threonine phosphorylation sites on the polyomavirus major capsid protein VP1: relationship to the activity of middle T antigen

Phosphorylation of the polyomavirus major capsid protein VP1 was examined after in vivo 32P labeling of virus-infected cells. Two phosphorylated peptide fragments of VP1 were identified by protease digestion, high-performance liquid chromatography purification, mass spectrometry, and N-terminal sequencing. The peptides from residues 58 to 78 and residues 153 to 173 were phosphorylated on threonine. Site-directed mutations were introduced at these threonine sites, and mutant viruses were reconstructed. A threonine-to-glycine change at residue 63 (mutant G63) and a threonine-to-alanine change at residue 156 (mutant A156) resulted in viruses defective in phosphorylation of the respective peptides after in vivo labeling. Growth of the mutant G63 virus was similar to that of the wild-type virus, but the mutant A156 was inefficient in assembly of 240S viral particles. Polyomavirus nontransforming host range (hr-t) mutants are defective in VP1 threonine phosphorylation when grown in nonpermissive cells (R. L. Garcea, K. Ballmer-Hofer, and T. L. Benjamin, J. Virol. 54:311-316, 1985). Proteolytic mapping of VP1 peptides after in vivo labeling from hr-t mutant virus infections demonstrated that both residues T-63 and T-156 were affected. These results suggest that the block in virion assembly in hr-t mutant viruses is associated with a defect in phosphorylation of threonine 156.

Protein species of the parvovirus minute virus of mice strain MVMp: involvement of phosphorylated VP-2 subtypes in viral morphogenesis

The pattern of induced protein species of the prototype strain of the parvovirus minute virus of mice was determined in permissive A9 mouse fibroblast cells by high-resolution two-dimensional gel electrophoresis. Identities of the viral proteins in the gels were assigned by probing two-dimensional blots with antisera raised against either purified capsids (recognizing VP-1 and VP-2) or specific coding regions of the nonstructural proteins (NS-1 and NS-2) expressed as beta-galactosidase fusion products in bacteria. All viral proteins showed posttranslational modifications, phosphate being a common substituent. The NS-1 protein migrated as a basic polypeptide in the pI range of 7.4 to 7.8 with multiple stages of modification and as a likely minor but hyperphosphorylated component in the neutral region of the gel. The NS-2 isoforms were resolved at a pI value close to 5.5 as three groups of unevenly phosphorylated polypeptides, each composed of at least two protein species. Both VP-1 and VP-2 structural polypeptides were induced as heterogeneous phosphoproteins. The major VP-2 protein could be resolved in the form of a consistent pattern of three abundant (a to c), two intermediate (d and e), and one meager (f) neutral isoelectric focusing species or subtypes. This posttranslational modification precedes and is uncoupled from viral assembly, and all of the VP-2 subtypes are packaged into empty capsids at the induced stoichiometry. However, intracellular full virions harbored additional phosphorylated subtypes (g to l) and a subtle rearrangement in the whole VP-2 composition, while mature virions purified from lysed cultures lacked these subtypes, coordinately with the emergence of six neutral VP-3 subtypes. Thus, the virion coat undergoes a chemical transition entailed by genome encapsidation, in which phosphates seem to play a major role, triggering the preferential proteolytic cleavage of the more acidic VP-2 subtypes to VP-3. Parvoviruses, with small coding capacity, may regulate some morphogenetic steps, such as assembly, genome encapsidation, and maturation, by posttranslational modifications of their structural proteins.

Mutations in the putative calcium-binding domain of polyomavirus VP1 affect capsid assembly

Calcium ions appear to play a major role in maintaining the structural integrity of the polyomavirus and are likely involved in the processes of viral uncoating and assembly. Previous studies demonstrated that a VP1 fragment extending from Pro-232 to Asp-364 has calcium-binding capabilities. This fragment contains an amino acid stretch from Asp-266 to Glu-277 which is quite similar in sequence to the amino acids that make up the calcium-binding EF hand structures found in many proteins. To assess the contribution of this domain to polyomavirus structural integrity, the effects of mutations in this region were examined by transfecting mutated viral DNA into susceptible cells. Immunofluorescence studies indicated that although viral protein synthesis occurred normally, infective viral progeny were not produced in cells transfected with polyomavirus genomes encoding either a VP1 molecule lacking amino acids Thr-262 through Gly-276 or a VP1 molecule containing a mutation of Asp-266 to Ala. VP1 molecules containing the deletion mutation were unable to bind 45Ca in an in vitro assay. Upon expression in Escherichia coli and purification by immunoaffinity chromatography, wild-type VP1 was isolated as pentameric, capsomere-like structures which could be induced to form capsid-like structures upon addition of CaCl2, consistent with previous studies. However, although VP1 containing the point mutation was isolated as pentamers which were indistinguishable from wild-type VP1 pentamers, addition of CaCl2 did not result in their assembly into capsid-like structures. Immunogold labeling and electron microscopy studies of transfected mammalian cells provided in vivo evidence that a mutation in this region affects the process of viral assembly.

Cooperation of structural proteins during late events in the life cycle of polyomavirus

The polyomavirus minor late capsid antigen, VP2, is myristylated on its N-terminal glycine, this modification being required for efficient infection of mouse cells. To study further the functions of this antigen, as well as those of the other minor late antigen, VP3, recombinant baculoviruses carrying genes for VP1, VP2, and VP3 have been constructed and the corresponding proteins have been synthesized in insect cells. A monoclonal antibody recognizing VP1, alpha-PyVP1-A, and two monoclonal antibodies against the common region of VP2 and VP3, alpha-PyVP2/3-A and alpha-PyVP2/3-B, have been generated. Reactions of antibodies with antigens were characterized by indirect immunofluorescence, immunoprecipitation, and immunoblot analysis. Immunofluorescent staining of mouse cells infected with polyomavirus showed all antigens to be localized in nuclei. When the late polyomavirus proteins were expressed separately in insect cells, however, only VP1 was efficiently transported into the nucleus; VP2 was localized discretely around the outside of the nucleus, and VP3 exhibited a diffused staining pattern in the cytoplasm. Coexpression of VP2, or VP3, with VP1 restored nuclear localization. Immunoprecipitation of infected mouse cells with either anti-VP1 or anti-VP2/3 antibodies precipitated complexes containing all three species, consistent with the notion that VP1 is necessary for efficient transport of VP2 and VP3 into the nucleus. Purified empty capsid-like particles, formed in nuclei of insect cells coinfected with all three baculoviruses, contained VP2 and VP3 proteins in amounts comparable to those found in empty capsids purified from mouse cells infected with wild-type polyomavirus. Two-dimensional gel analysis of VP1 species revealed that coexpression with VP2 affects posttranslational modification of VP1.

Polyoma virus middle T is essential for virus replication and persistence as well as for tumor induction in mice

A mutant strain of polyoma virus encoding a truncated middle T protein has been studied for its ability to replicate and induce tumors following inoculation into newborn mice. Virus replication in the acute period prior to expected onset of tumors as well as persistence of virus in older animals were followed. The mutant virus proved to be defective in replication and persistence and failed to induce tumors. These results demonstrated that middle T plays an essential role in productive viral infection in the animal. Since the mutant virus encodes normal large and small T proteins, the results also indicate that functions associated with these T antigens, including large T binding of the retinoblastoma tumor suppressor gene product and the ability to immortalize, are insufficient to cause development of tumors in this system.

Phosphorylation of the budgerigar fledgling disease virus major capsid protein VP1

The structural proteins of the budgerigar fledgling disease virus, the first known nonmammalian polyomavirus, were analyzed by isoelectric focusing and sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE). The major capsid protein VP1 was found to be composed of at least five distinct species having isoelectric points ranging from pH 6.45 to 5.85. By analogy with the murine polyomavirus, these species apparently result from different modifications of an initial translation product. Primary chicken embryo cells were infected in the presence of 32Pi to determine whether the virus structural proteins were modified by phosphorylation. SDS-PAGE of the purified virus structural proteins demonstrated that VP1 (along with both minor capsid proteins) was phosphorylated. Two-dimensional analysis of the radiolabeled virus showed phosphorylation of only the two most acidic isoelectric species of VP1, indicating that this posttranslational modification contributes to VP1 species heterogeneity. Phosphoamino acid analysis of 32P-labeled VP1 revealed that phosphoserine is the only phosphoamino acid present in the VP1 protein.

Heterogeneity in state and expression of viral DNA in polyoma virus-induced tumors of the mouse

We have examined the state and expression of polyoma viral DNA in representative epithelial and mesenchymal tumors, using a combination of biochemical and in situ methods. Results showed wide variations among tumor types and also in different regions within individual tumors, with respect to copy number of viral DNA, presence or absence of deletions, and expression of early and late viral proteins. Epithelial tumors showed the greatest heterogeneity. High copy free viral DNA, frequently with deletions, was found in all such tumors. A portion of free viral DNA was recoverable as transcriptionally active minichromosomes. Three distinct subpopulations of cells were distinguished by in situ analyses. Type 1 cells showed high copy free viral DNA and expressed the major viral capsid protein VP1; these cells appeared to be at various stages of productive (lytic) viral infection. Some productively infected cells were able to undergo mitosis; in a portion of these cells, VP1 was found in close association with the mitotic spindle. Type 2 cells contained high copy free DNA but did not express VP1; by some unknown mechanism, these cells manifest a post-replication block to late gene expression and lytic infection. Type 3 cells contained only low copy, presumably integrated, viral DNA and expressed no VP1; they thus resemble cells transformed in vitro by the virus. Epithelial tumors contained variable mixtures of these subpopulations, while mesenchymal tumors were composed of Type 3 cells only. Differences in virus-cell interactions are discussed in terms of their possible implications in tumor development.

Nuclear assembly of polyomavirus capsids in insect cells expressing the major capsid protein VP1

Polyomavirus normally assembles in the nucleus of infected mouse cells. Sf9 insect cells expressing the polyomavirus major capsid protein VP1 were examined by electron microscopy. Capsidlike particles of apparently uniform size were found in the nucleus. Immunogold electron microscopy demonstrated abundant VP1 in the cytoplasm which was not assembled into any recognizable higher-order structure. Cytoplasmic VP1 assembled after the cells were treated with the calcium ionophore ionomycin. Purified VP1 aggregates were shown by negative staining and cryoelectron microscopy to consist predominantly of particles similar to the empty T = 7 viral capsid. Thus, polyomavirus VP1 can assemble in vivo into capsids independent of other viral proteins or DNA. Nuclear assembly may result from increased available calcium in this subcellular compartment.

Infection of CV1 cells expressing the polyoma virus middle T antigen or the SV40 agnogene product with simian virus 40 host-range mutants

SV40 viruses bearing mutations at the carboxy-terminus of large T antigen exhibit a host-range phenotype: such viruses are able to grow in BSC monkey kidney cells at 37 degrees C, but give at least 10,000-fold lower yields than wild type virus in BSC cells at 32 degrees C or in CV1 monkey kidney cells at either temperature. The block to infection in the nonpermissive cell type occurs after the onset of viral DNA replication. Infectious progeny virions are produced at very low efficiency. Although capsid proteins are synthesized at decreased levels, this does not account for the magnitude of the defect. Presumably some step of virion assembly or maturation is affected in these mutants. We have previously reported that the viral agnogene product, a protein thought to be involved in viral assembly or release, fails to accumulate in CV1 cells infected with host-range mutants. In polyoma virus the middle T antigen plays a role in virion maturation by influencing the phosphorylation of capsid proteins. In this communication we show that host-range mutants fail to undergo productive infection of CV1 cells expressing middle T antigen. These mutants do form plaques on an agnoprotein-expressing cell line. However, the agnoprotein does not seem to act by correcting the mutational block but rather increases the efficiency of plaque formation.

Low probability of double integration in transformation of nonpermissive cells by polyomavirus

The fate of polyomavirus genomes in stable transformants was examined in experiments in which rat or hamster cells were infected with mixed viral populations containing either two distinguishable wild types or a wild type plus a transformation-deficient mutant. The results demonstrate that in 90% of the cases in either situation, a single polyomavirus parental genome became integrated into the host genome. Both parents in the mixed infection were present in the same cells and both persisted in the infected cells until transformants appeared, eliminating the possibility that one virus would exclude the other in the early steps of the infection process. We believe that these results can be generalized to transformation events derived from normal single infections. Thus, contrary to previous results for the number of integration sites determined by restriction endonuclease and blot hybridization analysis, it appears that the probability for more than one integration event in transformation by polyomavirus is low (1 in 10). A reinterpretation of previous data is proposed.

Synthesis, posttranslational modifications, and nuclear transport of polyomavirus major capsid protein VP1

Polyomavirus major capsid protein VP1 synthesis was studied in infected primary baby mouse kidney cells. A standard curve of VP1 protein was used to quantitate VP1 in the cytoplasm and nucleus of infected cells during the time course of infection. Polyomavirus VP1 continued to be accumulated in the cytoplasm of the cells until 27 h postinfection, at which time the synthesis of VP1 leveled off. VP1 continued to accumulate in the nucleus of the infected cells throughout the course of infection. The presence of the six isospecies, A to F, of polyomavirus VP1 was also studied to determine the relative quantity of each species during the time course of infection. All six species were found in the cytoplasm and nucleus of infected cells at various times postinfection. However, the relative quantity of each species was different at early as compared with later times of infection. In addition, phosphorylated VP1 was found in isolated polyribosomes of infected cells, suggesting that phosphorylation of VP1 is a cotranslational modification. Examination of the effect of macromolecular synthesis on the transport of VP1 into the nucleus of infected baby mouse kidney cells as well as the rate of its nuclear accumulation during and after protein synthesis inhibition revealed that the continual transport and accumulation of VP1 in the nucleus required protein synthesis.

Hydroxyproline in the major capsid protein VP1 of polyomavirus

Amino acid analysis of [3H]proline-labeled polyomavirus major capsid protein VP1 by two-dimensional paper chromatography of the acid-hydrolyzed protein revealed the presence of 3H-labeled hydroxyproline. Addition of the proline analog L-azetidine-2-carboxylic acid to infected mouse kidney cell cultures prevented or greatly reduced hydroxylation of proline in VP1. Immunofluorescence analysis performed on infected cells over a time course of analog addition revealed that virus proteins were synthesized but that transport from the cytoplasm to the nucleus was impeded. A reduction in the assembly of progeny virions demonstrated by CsCl gradient purification of virus from [35S]methionine-labeled infected cell cultures was found to correlate with the time of analog addition. These results suggest that incorporation of this proline analog into VP1, accompanied by reduction of the hydroxyproline content of the protein, influences the amount of virus progeny produced by affecting transport of VP1 to the cell nucleus for assembly into virus particles.

Mutational analysis of polyomavirus small-T-antigen functions in productive infection and in transformation

The function of polyomavirus small T antigen in productive infection and in transformation was studied. Transfection of permissive mouse cells with mixtures of mutants that express only one type of T antigen showed that small T antigen increased large-T-antigen-dependent viral DNA synthesis approximately 10-fold. Under the same conditions, small T antigen was also essential for the formation of infectious virus particles. To analyze these activities of small T antigen, mutants producing protein with single amino acid replacements were constructed. Two mutants, bc1073 and bc1075, were characterized. Although both mutations led to the substitution of amino acid residues of more than one T antigen, the phenotype of both mutants was associated with alterations of the small T antigen. Both mutant proteins had lost their activity in the maturation of infectious virus particles. The bc1075 but not the bc1073 small T antigen had also lost its ability to stimulate viral DNA synthesis in mouse 3T6 cells. Finally, both mutants retained a third activity of small T antigen: to confer on rat cells also expressing middle T antigen the ability to grow efficiently in semisolid medium. The phenotypes of the mutants in these three assays suggest that small T antigen has at least three separate functions.

Separation of host range from transformation functions of the hr-t gene of polyomavirus

hr-t mutants of polyomavirus are defective in virus growth as well as in cell transformation, and have genetic alterations that invariably affect both the middle and small T proteins. We have examined the growth properties of three site-directed mutants that either eliminate or alter the middle T without affecting the small T protein. Mutant 808A encodes large and small T proteins but no middle T; it grew poorly in NIH 3T3 cells. In contrast, mutants 1387T and 1178T which express altered middle T along with normal large and small T proteins grew nearly as well as wild-type virus. Thus, although the altered middle T proteins encoded by 1387T and 1178T are defective for cell transformation, they retained the ability to induce expression of a cellular permissivity factor(s) required for virus production. At the biochemical level, the induction of permissivity by middle T was manifested primarily in terms of phosphorylation of VP1 on threonine and in efficient encapsidation of viral DNA to form infectious virus. The natural role of middle T involves regulation of phosphorylation events, and can be enacted, at least in part, independently of interactions with pp60c-src.

Polyomavirus middle T antigen induces ribosomal protein S6 phosphorylation through pp60c-src-dependent and -independent pathways

Phosphorylation of ribosomal protein S6 is elevated in polyomavirus-infected cells. This elevation results only in part from activation of S6 kinase activity. These effects appear to reflect independent activities of wild-type middle T antigen. Hr-t mutant NG59, encoding a defective middle T protein, and mutant Py808A, encoding no middle T protein, were unable to induce S6 kinase activity or elevate S6 phosphorylation. Two other site-directed mutants encoding altered middle T proteins did elevate S6 phosphorylation while only weakly stimulating S6 kinase activity. These results suggest at least two independent pathways leading to elevation of S6 phosphorylation. One pathway leads to induction of S6 kinase activity following activation of pp60c-src by transformation-competent middle T antigen. Another pathway operates independently of S6 kinase induction and can be regulated by transformation-defective middle T mutants such as Py1387T. This mutant, encoding a truncated middle T protein that failed to associate with the plasma membrane and to activate pp60c-src, caused increased levels of S6 phosphorylation without detectably increasing S6 kinase activity. The ability of mutants such as Py1387T to induce S6 phosphorylation correlated with their ability to increase phosphorylation of VP1, an event linked to maturation of infectious virions.

Polyomavirus middle T antigen induces ribosomal protein S6 phosphorylation through pp60c-src-dependent and -independent pathways

Phosphorylation of ribosomal protein S6 is elevated in polyomavirus-infected cells. This elevation results only in part from activation of S6 kinase activity. These effects appear to reflect independent activities of wild-type middle T antigen. Hr-t mutant NG59, encoding a defective middle T protein, and mutant Py808A, encoding no middle T protein, were unable to induce S6 kinase activity or elevate S6 phosphorylation. Two other site-directed mutants encoding altered middle T proteins did elevate S6 phosphorylation while only weakly stimulating S6 kinase activity. These results suggest at least two independent pathways leading to elevation of S6 phosphorylation. One pathway leads to induction of S6 kinase activity following activation of pp60c-src by transformation-competent middle T antigen. Another pathway operates independently of S6 kinase induction and can be regulated by transformation-defective middle T mutants such as Py1387T. This mutant, encoding a truncated middle T protein that failed to associate with the plasma membrane and to activate pp60c-src, caused increased levels of S6 phosphorylation without detectably increasing S6 kinase activity. The ability of mutants such as Py1387T to induce S6 phosphorylation correlated with their ability to increase phosphorylation of VP1, an event linked to maturation of infectious virions.

Detection of phosphorylated forms of Moloney murine leukemia virus major capsid protein p30 by immunoprecipitation and two-dimensional gel electrophoresis

We detected phosphorylation of the major Moloney murine leukemia virus (M-MuLV) capsid polypeptide, p30, by using 32Pi-labeled virions. This was observed both on two-dimensional polyacrylamide gels directly or on one-dimensional gels of viral lysates that had been immunoprecipitated with monospecific goat anti-p30 serum. The phosphorylation event had been difficult to detect because pp12 the major virion phosphoprotein incorporates almost all of the 32P label added to infected cells (Y. Yoshinaka and R. B. Luftig, Virology 116:181-195, 1982). When immunoprecipitates from M-MuLV lysates labeled with 32Pi were compared with those labeled with [35S]methionine, it was calculated that the degree of phosphorylation at the p30 domain of Pr65gag was only 0.22 to 0.54% relative to phosphorylation at the p12 domain. Two-dimensional gel electrophoresis of the 32P-labeled p30 immunoprecipitates showed that there were three phosphorylated p30 forms with isoelectric points (pIs) of 5.7, 5.8, and 6.0. These forms were generally more acidic than the [35S]methionine-labeled p30 forms, which had pIs of 6.0, 6.1, 6.3 (the major constituent with greater than 80% of the label), and 6.6. The predominant phosphoamino acid of the major phosphorylated p30 form (pI 5.8) was phosphoserine. Further, tryptic peptide analysis of this p30 form showed that only one peptide was predominantly phosphorylated. Based on a comparison of specific labeling of p30 tryptic peptides with [14C]serine, [35S]methionine, and 32Pi, we tentatively assigned the phosphorylation site to a 2.4-kilodalton NH2-terminal peptide containing triple tandem serines spanning the region from amino acids 4 to 24.

Polyomavirus early region alternative poly(A) site: 3'-end heterogeneity and altered splicing pattern

The position of an alternative polyadenylation [poly(A)] site at the 3' end of the polyomavirus middle T antigen (T-Ag) coding sequences suggests the possibility of a functional role for this site in early gene regulation. The fine structure of this alternative poly(A) site was determined by cDNA sequence and 3' S1 analyses. Cleavage-poly(A) was found to be heterogeneous, occurring at multiple CA dinucleotides downstream from the AATAAA signal sequence. About 50% of the alternative poly(A) takes place upstream from the middle T-Ag stop codon. In addition, the pattern of splicing of transcripts with the alternative poly(A) site differed from that with the major poly(A) site at the end of the early region. The ratio of the small and middle T-Ag splices to the large T-Ag splice for the alternative poly(A)+ mRNAs is about 2.5 times that found for mRNAs with the major poly(A) site. The altered splicing pattern and 3'-end heterogeneity of the alternative poly(A)+ mRNAs would result in preferential translation of small T-Ag (to a greater degree) and middle T-Ag over large T-Ag at later times in the polyomavirus lytic cycle.

Mutants of polyomavirus middle-T antigen

Polyomavirus middle-T antigen induces the transformation of established cell lines in culture and is known to interact with and/or modulate the activity of several enzymes (pp60c.src, protein kinase C and phosphatidylinositol kinase) in vitro. This review is a compilation of the reported mutants of middle-T antigen and their biochemical and biological properties as they relate to the transformation event. The mutants of polyomavirus middle-T antigen have been previously classified phenotypically. Given the now large number of mutants, the classification presented here is based upon the position within the molecule. A model of middle-T is presented in which the protein is considered as consisting of three domains: a hydrophobic domain (the putative membrane-binding domain), the amino-terminal half of the molecule (the putative pp60c.src-binding domain) and the intervening amino acids (the putative modulatory domain). A current model for the induction of transformation by polyomavirus middle-T is presented.

Polyomavirus major capsid protein VP1 is modified by tyrosine sulfuration

Polyomavirus was propagated in primary mouse kidney cell monolayers and 35S-sulfate labeled by maintaining the infected cells in serum-free Eagle medium supplemented with 35S-labeled sodium sulfate. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis of CsCI gradient-purified 35S-sulfate-labeled virions followed by fluorography indicated that the polyomavirus-coded major capsid protein VP1 incorporated this radiolabel. Two-dimensional gel electrophoresis followed by fluorography revealed 35S-sulfate incorporation into only two of the six VP1 isoelectric species (E and F). Amino acid analysis of 35S-sulfate labeled VP1 by enzymatic hydrolysis followed by two-dimensional thin-layer electrophoresis revealed the presence of 35S-sulfate-labeled tyrosine-O-sulfate.

Myristic acid is coupled to a structural protein of polyoma virus and SV40

In the lytic cycle of papova viruses, both uncoating of the viral genome after infection and assembly of functional virions take place in the cell nucleus. The mechanisms by which newly internalized virions are targeted to the nucleus and viral DNA encapsidated into particles are poorly understood. Although the major capsid protein VP1 is involved in endocytosis, and largely defines virion structure, the functions of the minor proteins VP2 and VP3 have remained obscure. Here we show that VP2 from both polyoma virus and simian virus 40 (SV40) is covalently linked to myristic acid; this is the first report of a myristylated protein in the nucleus and of a fatty acid being important in the structure of a nonenveloped virus. We consider the implications of this unusual modification on encapsidation and suggest that VP2 may be a scaffolding protein for virion assembly.

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.

Regulation of c-myc and c-fos mRNA levels by polyomavirus: distinct roles for the capsid protein VP1 and the viral early proteins

The levels of c-myc, c-fos, and JE mRNAs accumulate in a biphasic pattern following infection of quiescent BALB/c 3T3 mouse cells with polyomavirus. Maximal levels of c-myc and c-fos mRNAs were seen within 1 hr and were nearly undetectable at 6 hr after infection. At 12 hr after infection mRNA levels were again maximal and remained elevated thereafter. Empty virions (capsids) and recombinant VP1 protein, purified from Escherichia coli, induced the early but not the late phase of mRNA accumulation. Virions, capsids, and recombinant VP1 protein stimulated [3H]thymidine nuclear labeling and c-myc mRNA accumulation in a dose-responsive manner paralleling their affinity for the cell receptor for polyoma. The second phase of mRNA accumulation is regulated by the viral early gene products, as shown by polyomavirus early gene mutants and by a transfected cell line (336a) expressing middle tumor antigen upon glucocorticoid addition. These results suggest that polyomavirus interacts with the cell membrane at the onset of infection to increase the levels of mRNA for cellular genes associated with cell competence for DNA replication, and subsequently these levels are maintained by the action of the early viral proteins.

Differences in biological activity and structural protein VP1 phosphorylation of polyomavirus progeny resulting from infection of primary mouse kidney and primary mouse embryo cell cultures

Both primary mouse kidney and primary mouse embryo cells in culture were used for polyomavirus progeny production. Examination of polyomavirus virion structural integrity revealed that mouse embryo cell progeny contained a threefold greater population of unstable particles when compared with mouse kidney cell progeny. Differences in biological activity between these two progeny virion types were also shown. Mouse kidney cell progeny compared with mouse embryo cell progeny exhibited a 10-fold greater ability to agglutinate guinea pig erythrocytes, a 3-fold lower ability to become internalized into monopinocytotic vesicles, and a 2-fold lower ability to initiate a productive infection based on positive nuclear immunofluorescence when mouse embryo host cell cultures were used. The mouse kidney progeny were also found to bind to host cells less specifically than the mouse embryo cell progeny. When these two progeny virion types were labeled in vivo with 32P and subjected to isoelectric focusing followed by sodium dodecyl sulfate-polyacrylamide gel electrophroesis in the second dimension, differences in the phosphorylation pattern of the major virus-encoded structural protein VP1 species were observed. It was revealed that species D and E of mouse kidney cell progeny were phosphorylated to the same degree, while mouse embryo cell progeny species E and F were phosphorylated equally. These data suggest that the host cells play a role in modulating the biological activity of the virus by affecting the degree and site-specific phosphorylation of the major capsid protein VP1 which may influence the recognition of virus attachment proteins for specific cellular receptors.