Origin of the polyoma virus-associated endonuclease

Neutralization serotyping of BK polyomavirus infection in kidney transplant recipients

BK polyomavirus (BKV or BKPyV) associated nephropathy affects up to 10% of kidney transplant recipients (KTRs). BKV isolates are categorized into four genotypes. It is currently unclear whether the four genotypes are also serotypes. To address this issue, we developed high-throughput serological assays based on antibody-mediated neutralization of BKV genotype I and IV reporter vectors (pseudoviruses). Neutralization-based testing of sera from mice immunized with BKV-I or BKV-IV virus-like particles (VLPs) or sera from naturally infected human subjects revealed that BKV-I specific serum antibodies are poorly neutralizing against BKV-IV and vice versa. The fact that BKV-I and BKV-IV are distinct serotypes was less evident in traditional VLP-based ELISAs. BKV-I and BKV-IV neutralization assays were used to examine BKV type-specific neutralizing antibody responses in KTRs at various time points after transplantation. At study entry, sera from 5% and 49% of KTRs showed no detectable neutralizing activity for BKV-I or BKV-IV neutralization, respectively. By one year after transplantation, all KTRs were neutralization seropositive for BKV-I, and 43% of the initially BKV-IV seronegative subjects showed evidence of acute seroconversion for BKV-IV neutralization. The results suggest a model in which BKV-IV-specific seroconversion reflects a de novo BKV-IV infection in KTRs who initially lack protective antibody responses capable of neutralizing genotype IV BKVs. If this model is correct, it suggests that pre-vaccinating prospective KTRs with a multivalent VLP-based vaccine against all BKV serotypes, or administration of BKV-neutralizing antibodies, might offer protection against graft loss or dysfunction due to BKV associated nephropathy.

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.

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.

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.

Anti-idiotypic antibodies to a polyomavirus monoclonal antibody recognize cell surface components of mouse kidney cells and prevent polyomavirus infection

Anti-idiotypic antibodies have been successfully used to identify and isolate the receptor for several cell ligands. To prepare an immunologic probe for identification of the polyomavirus receptor on mouse kidney cells, polyclonal antisera against antipolyomavirus antibodies were prepared in rabbits. Fab fragments of the previously characterized monoclonal antibody E7, which neutralizes polyomavirus infection, were used for immunization (S. J. Marriott and R. A. Consigli, J. Virol. 56:365-372, 1985). Sera containing the greatest anti-idiotype activity were identified by enzyme-linked immunosorbent assay (ELISA) and purified by a series of affinity columns. The anti-idiotypic antibodies recognized the E7 idiotope in an ELISA, and anti-idiotype binding could be inhibited by preincubation of E7 monoclonal antibody with polyomavirus virions. When mixed with anti-idiotype immunoglobulin G (IgG), E7 was no longer capable of binding or immunoprecipitating polyomavirus virions or neutralizing polyomavirus infection. Direct immunofluorescence showed anti-idiotype IgG reactivity with a cell surface component of mouse kidney cells. Anti-idiotype F(ab')2 effectively competed with polyomavirus for binding to mouse kidney cells and displayed binding kinetics similar to those of polyomavirus. Virus infection of mouse kidney cells was blocked in a dose-dependent manner following treatment of the cells with anti-idiotype IgG. The anti-idiotype identified several proteins (95, 50, and 24 to 31 kilodaltons) in an immunoblot of mouse kidney cell membrane proteins but reacted predominantly with a single 50-kilodalton protein in a radioimmunoassay. The anti-idiotype failed to react with virus proteins in three assays, including ELISA, immunoprecipitation, and immunoblotting. The implications of this work for future identification and characterization of the polyomavirus receptor on mouse kidney cells are discussed.

Localization of calcium on the polyomavirus VP1 capsid protein

Our laboratory has previously shown that the divalent cation Ca2+ is an integral part of the polyomavirus and plays a major role in stabilizing the intact virion structure. In this report, we show that calcium is sequestered on the major capsid protein VP1 of polyomavirus. The virion structural proteins were separated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis before being transferred to nitrocellulose and probed with 45CaCl2. Autoradiography revealed 45Ca binding exclusively to VP1. Increasing the amount of VP1 transferred to the nitrocellulose resulted in a concomitant increase in 45Ca binding. 45Ca binding to VP1 could be reduced by competition with an excess of unlabeled CaCl2. Separation of the species of VP1 by two-dimensional gel electrophoresis before electroblotting and probing with 45CaCl2 revealed that all six species (A to F) bind the radiolabeled calcium. Formic acid cleavage of the 43-kilodalton (kDa) VP1 protein into 29-, 18-, and 16-kDa fragments before 45Ca-binding analysis revealed that only the 18- and 16-kDa carboxyl-terminal fragments of this protein bind 45Ca.

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.

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.

Octyl-beta-D-glucopyranoside extracts polyomavirus receptor moieties from the surfaces of mouse kidney cells

Polyomavirus receptor moieties were extracted from the surfaces of mouse kidney cells with the nonionic detergent octyl-beta-D-glucopyranoside. Following extraction with this detergent, mouse kidney cells were refractory to polyomavirus infection. Binding studies demonstrated that this loss of susceptibility resulted from extraction of a peripheral membrane protein or proteins required for proper virus attachment to and infection of mouse kidney cells. Infection of extracted mouse kidney cells returned following a 2-h recovery period. However, the presence of cycloheximide or tunicamycin in the recovery media interfered with recovery from infection. Cells could be infected immediately after extraction by supplying them with the extracted moieties prior to or concomitant with infection. A complex of polyomavirus and the extracted receptor protein was formed by in vitro incubation and was stable in sucrose gradient analysis. Functional receptor moieties were prepared in the form of liposomes from the detergent extract. The virus-receptor complex was immunoprecipitated with anti-polyomavirus immunoglobulin G, and the portion of the complex contributed by the cell was identified. Immunoblot analysis of the mouse kidney cell detergent extract with a receptor-specific 125I-labeled anti-idiotypic antibody or 125I-labeled polyomavirus demonstrated several reactive proteins. Attachment of polyomavirus to mouse kidney cells, followed by extraction of the virus-receptor complex, identified polyomavirus-binding proteins similar to those observed in in vitro binding. Proteins with molecular weights of approximately 95,000, 50,000 and 25,000 to 30,000 were consistently observed in all receptor assays. The relationship between these proteins and their possible involvement as the cell receptor for polyomavirus are discussed.

Cross-linking of a polyomavirus attachment protein to its mouse kidney cell receptor

We used photoaffinity cross-linking with the heterobifunctional cross-linker N-hydroxysuccinimidyl 4-azidobenzoate (HSAB) to covalently link polyomavirus to a mouse kidney cell surface component. The virus-HSAB combination was adsorbed to the cells and then cross-linked and isolated in monopinocytotic vesicles from the cells after endocytosis. The cross-linked product was identified on sodium dodecyl sulfate-polyacrylamide gels by the presence of a new band carrying 125I-labeled virion protein with a higher molecular mass than the normal virion protein bands. A single new band, with an apparent molecular mass of 120 kilodaltons (120 kDa), was identified by this procedure. This band was formed only in the presence of the HSAB cross-linker when virions were bound to the cells. The band also copurified with cross-linked virions when virion-containing vesicles were treated with detergent to remove the cell membrane. Antibody treatments that blocked up to 100% of virus binding and internalization also blocked cross-linking, as measured by the formation of the 120-kDa band. The 120-kDa band was characterized by preparation of antibody against the excised band from the gel. This antibody was shown to have the expected dual specificity for polyomavirus VP1 sequences and plasma membrane proteins, as analyzed on Western blots. The anti-120-kDa antibody was also shown by immunofluorescence to bind to the surface of mouse kidney cells. These data have demonstrated that molecules of possible biological significance in the binding of polyomavirus to mouse kidney cells have been cross-linked and that cell surface molecules have been identified that may be characterized further for possible receptor function in polyomavirus attachment.

Production and characterization of monoclonal antibodies to polyomavirus major capsid protein VP1

Four hybridoma cell lines producing monoclonal antibodies against intact polyoma virions were produced and characterized. These antibodies were selected for their ability to react with polyoma virions in an enzyme-linked immunosorbent assay. The antibodies immunoprecipitated polyoma virions and specifically recognized the major capsid protein VP1 on an immunoblot. Distinct VP1 isoelectric species were immunoprecipitated from dissociated virion capsomere preparations. Two-dimensional gel electrophoresis demonstrated antibody reactivity with specific VP1 species. Monoclonal antibodies E7 and G9 recognized capsomeres containing VP1 species D, E, and F, while monoclonal antibodies C10 and D3 recognized capsomeres containing species B and C. Two of the monoclonal antibodies, E7 and G9, were capable of neutralizing viral infection and inhibiting hemagglutination. The biological activity of the monoclonal antibodies correlated well with the biological function of the species with which they reacted.

Identification and protein analysis of polyomavirus assembly intermediates from infected primary mouse embryo cells

A method is described for the isolation of polyoma virus assembly intermediates from infected mouse embryo cells. Sucrose gradient profiles revealed the presence of 90 S, 200 S, and 240 S intermediates. These intermediates were shown to be sensitive to a number of factors: ionic condition of the isolation buffer, presence of chelating agents and nonionic detergents during isolation, and sonication of nuclei during extraction of intermediates. Pulse-chase experiments demonstrated that the order of formation of the intermediates to be 90 S----240 S, with the 200 S particles as a possible intermediate form linking the 90 S and 240 S particles. Viral structural proteins VP1, VP2, and VP3 were shown to be present on all three intermediates, but the ratio of each protein varied on each intermediate species. Two-dimensional gel electrophoresis demonstrated that the distribution of the VP1 isoelectric focusing species were different among the three intermediates. Histone H1 was found exclusively with the 90 S species.

Fluorographic detection of [3H]thymidine-labeled deoxyribonucleic acid using agarose gels infused with 2,5-diphenyloxazole prior to electrophoresis

A fluorographic procedure for the detection of [3H]thymidine-labeled deoxyribonucleic acids electrophoresed in agarose gels was developed. 2,5-Diphenyloxazole (PPO) was added to the agarose solution before pouring of the gel for electrophoresis. This procedure did not interfere with the electrophoretic mobility of the DNA molecules. The radioactive detection efficiency was found to be improved over an existing procedure whereby the agarose gel was infused with PPO after electrophoresis with the aid of acetic acid.

Decline in infectivity of simian virus 40 by sodium deoxycholate and its restoration with the extract of monkey kidney cells

Plaque-forming activity and T-antigen-synthesizing activity in the crude preparation of simian virus 40 (SV40) decreased to 1/20-27 after treatment with 0.5% sodium deoxycholate (DOC) for 30 min at 37 degrees C. A full restoration of the activity occurred after incubation of DOC-treated virions with the extract of monkey CV-1 cells, host cells for productive infection with SV40. Analysis by sedimentation through 15% sucrose to CsCl cushion (rho = 1.327 g/cm3) revealed that virions in the [35S]methionine-labeled crude virus preparation sedimented to the interface between CsCl and sucrose, and that treatment with DOC resulted in the loss of infectivity and the appearance of virions sedimentable into CsCl cushion. The [35S]methionine-labeled purified virions (prepared after treatment with DOC and sedimentable into CsCl cushion) sedimented to the CsCl-sucrose interface after incubation with the cell extract, with restoration of infectivity. The infectivity-restoring activity of the cell extract was sensitive to ethyl ether, partially sensitive to heating at 75 degrees-97 degrees for 30 min, but resistant to treatment with DNase (50 micrograms/ml), RNase (40 micrograms/ml), or trypsin (0.05%) for 30 min at 37 degrees. These results suggest that lipid-related cellular components bind stably to virions of SV40 and facilitate an efficient infection.

Isolation and characterization of monopinocytotic vesicles containing polyomavirus from the cytoplasm of infected mouse kidney cells

Monopinocytotic vesicles containing polyomavirus were isolated from the cytoplasm of mouse kidney cells infected with polyomavirus using sucrose density gradients. Nonenclosed, membrane-associated virions released by the action of neuraminidase separated from vesicle-enclosed virions in the sucrose gradient. Marker enzyme assays indicated the derivation of the vesicle membrane from the plasma membrane of the cell. The 125I-labeled virus enclosed in the vesicle sedimented more slowly in the gradient and was not observed unless infection and endocytosis had occurred. Detergent treatment of virion-containing vesicles caused the release of polyomavirus with sedimentation properties similar to those of purified polyoma virions. In addition, sodium dodecyl sulfate-polyacrylamide gel electrophoresis analysis of virion proteins from vesicles containing virions demonstrated patterns of proteins similar to those of purified intact virions. Electron microscopy confirmed the presence of single intact virions inside vesicles. The study of these monopinocytotic virion-containing vesicles represents a further step in elucidating the early events of polyomavirus infection.

Chemical cleavage of polyomavirus major structural protein VP1: identification of cleavage products and evidence that the receptor moiety resides in the carboxy-terminal region

As a first step toward identifying the various functional regions of the polyomavirus major capsid protein VP1, we used recently developed methods for the chemical cleavage of proteins and the available polyomavirus sequence data to devise a scheme to produce large, identifiable peptides and generate a cleavage map of VP1. Formic acid (75%) was found to cleave VP1 at only two sites, producing three peptides of apparent molecular weights of 29,000, 16,000, and 2,000. The order of peptides in intact VP1 was determined by recleavage of partial products and was found to be 29,000, 16,000, and 2,000. Two-dimensional peptide mapping studies of 125I-labeled VP1 formic acid peptides established that the limit products of formic acid digestion contained mutually exclusive sets of labeled peptides when either trypsin or chymotrypsin was used and that together the formic acid peptides contained all of the 125I-labeled tryptic and chymotryptic peptides found in VP1. Iodosobenzoic acid (IBA) digestion produced four peptides separable by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, with apparent molecular weights of 12,000, 8,000, 7,000, and 5,000. The approximate positions of the IBA peptides in the VP1 sequence were determined by cleavage of formic acid fragments with IBA. The number of peptides produced, their respective sizes, and their order in the intact VP1 molecule agree with predictions made from available sequence data, both for formic acid cleavage and IBA cleavage. In addition, the numbers of 125I-labeled tryptic peptides produced from digestion of VP1 formic acid peptides also agree with predictions made from the sequence information. These data establish with reasonable certainty that the peptides produced by formic acid cleavage and IBA cleavage of VP1 are indeed those predicted. Antibodies raised against spontaneously produced, previously undefined polypeptides resulting from degradation of VP1 reacted exclusively with the formic acid peptides derived from the C-terminal portion of VP1. These antibodies inhibited hemagglutination and neutralized polyomavirus virions. We interpret this to mean that at least some of the antigenic determinants of the receptor moiety reside in this portion of the VP1 sequence.

Comparison of nonphosphorylated and phosphorylated species of polyomavirus major capsid protein VP1 and identification of the major phosphorylation region

The major virion protein of polyomavirus, VP1, consists of about six isoelectric species designated A through F. The minor species D, E, and F are phosphorylated and are thought to serve as viral receptors. We first wanted to distinguish whether all VP1 species are derived by post-translational modification from a common amino acid sequence or whether one or more of the species contain a region(s) of altered amino acid sequence resulting from alternate mRNA processing. We compared the VP1 species by detailed peptide mapping with several combinations of specific protease and radioisotopic labels. This approach enabled us to examine more than 80% of the predicted VP1 sequence, including the amino-and carboxy-termini. We found no evidence of sequence differences among any of the VP1 species. The specific incorporation of 32Pi was found to be the same for all of the phosphorylated species. Comparison of the phosphorylation sites of in vivo 32Pi-labeled D, E, and F by peptide mapping showed them to be identical. Each phosphorylated species contained a single major phosphopeptide and several minor phosphopeptides. The major phosphoamino acid, identified by acid hydrolysis, was phosphothreonine, with phosphoserine also present. By using chemical cleavage methods, we localized the major phosphorylation region to a central portion of the VP1 sequence. We discuss some features of this region and relate this information to functional implications of phosphorylation.

Generation of capsids from unstable polyoma virions

Polyomavirus was purified from infected mouse cell lysates under mild physiological conditions. When analyzed in a sucrose gradient, a major virus peak (240S) was identified. This sucrose-isolated virus could be divided into two populations based on its stability to CsCl gradient centrifugation. Members of the unstable population were shown to eject their DNA cores when subjected to CsCl gradient centrifugation, forming empty capsids, whereas the stable population was unaffected by the same CsCl treatment. Formaldehyde fixation of the 240S virus particles stabilized the virions and prevented ejection of DNA and generation of empty capsids. When formaldehyde-fixed 240S virus was examined with the electron microscope, only full virions were observed. These results indicate that polyoma capsids are not preformed in vivo, but instead are generated when infected cell lysates are subjected to harsh CsCl purification procedures.

Efficient transfer of proteins from acetic acid-urea and isoelectric-focusing gels to nitrocellulose membrane filters with retention of protein antigenicity

A method which facilitates the rapid and quantitative electrophoretic transfer of proteins from gels not containing sodium dodecyl sulfate (SDS) to nitrocellulose membranes is described. The equilibration of non-SDS-polyacrylamide gel electrophoretic gels in a buffer containing SDS confers a net negative charge to the proteins present, presumably as a result of the formation of SDS-protein complexes. Proteins from gels equilibrated in the SDS buffer and then electroblotted in a Tris-glycine buffer at pH 8.3 are transferred with much greater efficiency than are proteins from untreated gels. The method has been shown to significantly enhance the electrophoretic transfer of polyoma viral proteins resolved in either acetic acid-urea or isoelectric-focusing gels to nitrocellulose membranes, and it is suggested that the method should have universal applicability to all gel electrophoresis systems currently employed. The proteins from isoelectric-focusing gels treated with SDS and transferred to nitrocellulose membranes were found to retain antigenicity to antisera prepared against either denatured or native viral proteins.

Biochemical studies on structural and nonstructural proteins of the African green monkey B-lymphotropic papovavirus (LPV)

African green monkey (AGM) B-lymphotropic papovavirus (LPV) particles were separated from infected B-lymphoma BJA-B cells by neuraminidase and deoxycholate treatment and were further purified twice by CsCl density centrifugation. The SDS-PAGE analysis of virus particles banding at a density of 1.3510 g/ml and radioactively labeled by 125I revealed a major polypeptide of 40,000 and two minor polypeptides of 42,000 and 29,000. In addition, in infected BJA-B cells, all three viral structural polypeptides could be identified by immunoprecipitation. A nonstructural phosphopolypeptide of approximately 90,000 MW could be detected when sera against SDS-denatured SV40 T antigen or an AGM serum pool were used for immunoprecipitation. It is suggested that the 90K polypeptide of LPV represents an equivalent to T antigens of other papovaviruses.

Improved infectivity of reassembled polyoma virus

Polyoma virus was dissociated into capsomeres (18, 12, and 5S) and a DNA-protein complex (48S) with the Ca2+ chelator, ethyleneglycol-bis-N,N'-tetraacetic acid, and the reducing agent, 2-mercaptoethanol. The reaction was maintained at pH 5.0. Reassembly of the dissociated components to complete virions was accomplished by dialyzing these components overnight at 4 degrees C against the reassembly buffer containing CaCl2, dimethylsulfoxide, Triton X-100, and 0.01 M Tris-acetic acid (pH 5.0). Reconstructed particles ranged from 240S complete virions to lighter intermediate species. Approximately 25% of the dissociated particles could be physically reassembled to complete virions. These virions regained 12.5% of their hemagglutination ability and as much as 6.7% of their original infectivity. The infectivity of these reassembled particles represented a 100-fold increase in infectivity compared with that of the particles that were dissociated and reassembled at pH 7.4. Biochemical analysis showed that the polyoma viral receptor of the virions reassembled at pH 7.4 was greatly reduced, whereas virions reassembled at pH 5.0 retained their receptor. Reassembly could be further improved by additions of either exogenous capsomeres or DNA-protein complex to the reassembly reaction mixture.

Differences in the subpopulations of the structural proteins of polyoma virions and capsids: biological functions of the multiple VP1 species

The structural proteins of polyoma virions and capsids were analyzed by isoelectric focusing and sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Polyoma virion VP1 was found to be composed of six distinct species which had pI's between pH 6.75 and 5.75. Polyoma capsid VP1 was found to contain four species with pI's between pH 6.60 and 5.75. The different forms of virion and capsid VP1 appeared to be generated by modifications (phosphorylation and acetylation) of the initial translation product. The most basic of the virion VP1 species (pI, pH 6.75) was absent in capsids and was found to be exclusively associated with the viral nucleoprotein complex. Three of the virion VP1 species and three of the capsid VP1 species were found in capsomere preparations enriched for hexon subunits. Two VP1 species were specifically immune precipitated from virions with hemagglutination-inhibiting antibodies. These two VP1 species were common to both virions and capsids. Polyoma virions, but not capsids, possessed a single VP1 species which was immune precipitated with neutralizing antibodies. Both virion and capsid VP2 were found to have pI's of approximately pH 5.50. Virion VP3 had a pI of approximately pH 7.00, whereas capsid VP3 had a pI of approximately pH 6.50.

Efficient transcription of a compact nucleoprotein complex isolated from purified simian virus 40 virions

Simian virus 40 (SV40) virions were dissociated in vitro by treatment with ethylene glycol-bis-N-N'-tetraacetic acid and dithiothreitol. The compact nucleo-protein core released as a result of the dissociation had a sedimentation value of 110 to 115S compared with a value of 240S for intact virions. The viral cores contained a fraction of the viral proteins VP(1) and VP(2) in addition to the proteins found associated with the viral minichromosome, i.e., VP(3) and histones H(2)A, H(2)B, H(3), and H(4). Our results suggest that the association of VP(1), VP(2), or both with the viral minichromosome, in addition to maintaining a highly compact structure, modifies the transcriptional properties of the nucleoprotein complex. In the presence of saturating amounts of Escherichia coli RNA polymerase, 95 to 100% of the SV40 nucleoprotein cores were able to form transcriptional complexes. Sedimentation analysis of the core transcriptional complex indicated that the initiation and elongation of nascent RNA chains occurred on the compact SV40 core. Cesium chloride density gradient analysis of the SV40 virion core before and after transcription indicated that no substantial loss of protein occurred during the process of transcription. RNA synthesized from SV40 cores was a fairly homogeneous 16 to 18S species with an average chain length of approximately 2,300 nucleotides. Hybridization analysis of this RNA indicated that specific recognition of RNA polymerase promoter sites was preserved, since transcription was asymmetric, occurring preferentially on the "early" SV40 DNA strand. The rate of incorporation of ribonucleoside triphosphates into acid-insoluble RNA with SV40 cores as the template was 70 to 95% of that obtained with supercoiled SV40 form I DNA. SV40 minichromosomes, under identical transcription assay conditions, had an incorporation rate which was 20% of that obtained with SV40 form I DNA. These results show that association of protein VP(1) or VP(2) or both enhances the transcriptional activity and suggest that these "late" viral proteins may play a role in the regulation of expression of the SV40 genome.

Separation of neutralizing and hemagglutination-inhibiting antibody activities and specificity of antisera to sodium dodecyl sulfate-derived polypeptides of polyoma virions

Antisera to the sodium dodecyl sulfate (SDS)-polyacrylamide gel-derived polyoma virion polypeptides were used in immunoprecipitation experiments with ethylene glycol-bis-N,N'-tetraacetic acid (EGTA)-dissociated polyoma virions and capsids to determine the specificity of the antipolyoma polypeptide sera. Additionally, a technique for applying 125I-labeled immunoglobulins to SDS-polyacrylamide gels was used to explore the antigenic specificities of the antisera. The results demonstrated that antisera directed against the SDS-gel-derived VP1, VP2, and VP3 did not react with native polyoma proteins, but would react with the appropriate antigens on denatured polyoma proteins. Antisera against the histone region of such gels reacted with native and denatured polyoma VP1. Separation of neutralizing antibodies from hemagglutination inhibition (HAI) antibodies to polyoma in antisera directed against the histone region of polyacrylamide gels was done by using a polyoma capsid affinity column. The antibodies eluted from this column which did not react with capsids possessed only neutralizing activity, whereas antibodies which bound to capsids possessed only HAI activity. These isolated immunoglobulin G fractions were then used in immunoprecipitation experiments to demonstrate that the antigenic determinants responsible for the HAI activity of the serum were contained on a 16,000-dalton polypeptide, whereas those antigenic determinants responsible for neutralizing activity were contained on a 14,000-dalton polypeptide. Both of these polypeptides present in the histone region of the SDS-gels appeared to be derived from the major virion protein VP1.

Isolation and characterization of polyoma uncoating intermediates from the nuclei of infected mouse cells

A method was developed which enabled the efficient recovery of polyoma uncoating intermediates from the nuclei of infected cells at early times after infection (15 min to 12 h). Cells were infected with radiolabeled virus and lysed with the detergent Nonidet P-40. The nuclei were then collected and sonicated, and the products were analyzed on sucrose gradients. The uncoating intermediate sedimented at 190S and was a viral DNA-protein complex closely associated with a structure of host origin. The host material associated with the 190S uncoating intermediate was determined by polyacrylamide gel electrophoresis and visualized by electron microscopy. The amount of 190S uncoating intermediate found in the nucleus increased with time after infection. The viral DNA was predominantly for I. All of the viral proteins were present in the 190S uncoating intermediate in amounts similar to those found in viral DNA-protein complex cores.

Differential adsorption of polyoma virions and capsids to mouse kidney cells and guinea pig erythrocytes

Adsorption of 125I-labeled polyoma virions and capsids to the surface of mouse kidney cells (MKC) and guinea pig erythrocytes was examined. Purified polyoma capsids lack the ability to compete with polyoma virions for specific binding sites on the surface of MKC. These same capsids were, however, able to block virion adsorption to guinea pig erythrocytes. UV-inactivated virions blocked cellular receptors on MKC and thus inhibited infectious virions from infecting the cells. Capsids were unable to inhibit virion infection of MKC. Adsorption of polyoma virions to MKC and infection of these cells were found to be independent of the ability of the virions to agglutinate guinea pig erythrocytes.

In vitro reassembly of infectious polyoma virions

Initial experiments in our laboratory have successfully reassembled infectious polyoma virions from dissociated virion products. Virions treated with ethyleneglycol-bis-N,N'-tetraacetic acid and the reducing agent beta-mercaptoethanol at pH 7.5 were dissociated to a 48S DNA-protein complex and capsomere subunits. The virion dissociation products were not infectious by plaque assay and lacked hemagglutination activity. These virion dissociation products were reassembled to intact virions by overnight dialysis against a reassembly buffer containing CaCl2, dimethyl sulfoxide, and Triton X-100 in phosphate-buffered saline at pH 7.4. The biophysical characteristics of the reassembled virions were identical to those of untreated virions in that the reassembled virions had a sedimentation value of 240S in sucrose gradients and a buoyant density of 1.315 g/cm3 in CsCl isopycnic gradients. The reassembled virions were intact as determined by electron microscopy and were found to be 60% resistant to DNase I treatment. Biologically, the reassembled purified virions were found to partially regain both hemagglutinating activity and plaque-forming ability.

Chromatographic separation of the polyoma virus proteins and renaturation of the isolated VP1 major capsid protein

Treatment of purified polyoma virions with 6 M guanidine-hydrochloride and 0.01 M beta-mercaptoethanol resulted in the immediate loss of both hemagglutinating and plaque-forming ability. Gel filtration through Sepharose CL-6B beads allowed separation of the dimer, VP1, VP2, VP3, and histone proteins VP4-7 in highly purified form. Renaturation of the purified VP1 protein resulted in the formation of subunits that were morphologically, biophysically, and immunologically similar to native virion capsomeres.

Characterization of a DNA-protein complex and capsomere subunits derived from polyoma virus by treatment with ethyleneglycol-bis-N,N'-tetraacetic acid and dithiothreitol

Treatment of polyoma virions with ethyleneglycol-bil-N,N'-tetraacetic acid (EGTA) and dithiothreitol (DTT) at pH 8.5 resulted in the dissociation of the virions into a DNA-protein complex and individual structural capsomere subunits. The sedimentation value of the DNA-protein complex in sucrose gradients was approximately 48S, and it had a density of 1.45 g/cm3 in equilibrium CsCl gradients. Alkaline sucrose analysis of the DNA within this DNA-protein complex demonstrated that approximately 75% of the DNA is component 1. The proteins associated with the DNA were dissociated by treatment with either NaCl or the anionic detergent Sarkosyl. VP1 and the histone proteins VP 4--7 were the major proteins associated with the DNA. Treatment of the DNA-protein complex with alkaline pH resulted in the specific removal of FP1. Electron microscopy of the 48S DNA-protein complex demonstrated that it is a very tightly coiled structure that is slightly larger than the intact virion. Treatment of the complex with either NaCl or with pH 10.5 buffer resulted in the loss of protein and subsequent loosening of the DNA-protein complex such that the DNA could be visualized. The capsomere subunits released as a result of the EGTA-DTT treatment sedimented as 18S, 12S, and 5S subunits in sucrose gradients. Electrophoretic analysis of the isolated capsomeres demonstrated that VP1, VP2, and VP3 were present in each species, although the ratios of the proteins varied. In addition to the structural proteins, histones VP 4--7 were found to be predominantly associated with the 5S capsomere subunit.

Ribonuclease activities associated with purified foot and mouth disease virus

Ribonuclease activities internally and externally associated with purified foot-and mouth disease virus were detected. The outer activity was easily removed by cesium chloride or by detergent (Sarkosyl). The inner activity is not removable by any procedure used and could be the enzyme responsible for the heterogeneity normally observed in the extracted FMDV-RNA. It is not known at present if both activities are related to the same or to different enzymes.

Dissociation of polyoma virus by the chelation of calcium ions found associated with purified virions

Analysis of polyoma virions by X-ray fluorometry demonstrated that calcium (Ca2+) was associated with the purified virion. Treatment of purified virions with ethyleneglycol-bis-N,N'-tetraacetic acid (EGTA), which chelates Ca2+, and the reducing agent dithiothreitol caused the virions to dissociate. Electron microscopy revealed that the virions were dissociated to the capsomere level. Incubation of polyoma virions with 150 mM NaCl, 10 mM EGTA, and 3 mM dithiothreitol was optimum for the dissociation reaction. The pH for the dissociation reaction ranged from 7.5 to 10.5. Cesium chloride density gradient centrifugation indicated that both EGTA and dithiothreitol were necessary for dissociation to occur; neither reagent alone dissociated the virus. The major protein product of the dissociated viral particles sedimented at 12S. Relationships between these experiments and the alkaline carbonate-bicarbonate dissociation of polyoma are discussed.

Purification of an endonuclease from adenovirus-infected KB cells

This report describes the purification of an endonuclease from extracts of adenovirus-type-2-infected KB cells. Endonuclease activity can also be detected in extracts of uninfected KB cells and the enzyme activities from extracts of uninfected and adenovirus-infected cells are very similar, if not identical. The enzyme has its maximal activity at pH 4.0. The enzyme found in uninfected and adenovirus-infectedcells is, however, strikingly different from an endonuclease isolated from calf serum. Hence, the endonuclease described is probably not a contaminant derived from the medium in which the KB cells were propagated. The endonuclease in crude extracts from uninfected or adenovirus-infected KB cells can be activated or its activity enhanced by treatment of the extracts with proteolytic enzymes, like pronase or trypsin. Evidence has been presented suggesting that this activation is due to proteolytic cleavage of an inhibitor present in crude extracts of uninfected and adenovirus-type-2-infected KB cells. A second endonuclease has been found in extracts of infected and uninfected cells with optimal activity at pH 7.2 and this endonuclease can be separated from the one with a pH optimum at 4.0.

Immunological reactivity of antisera to sodium dodecyl sulfate-derived polypeptides of polyoma virions

A study was undertaken to produce antisera to sodium dodecyl sulfate-derived polyoma virion polypeptides. With the use of this antisera, it was possible to detect, by immunofluorescence, cytoplasmic synthesis of V1, V2, and V3 polypeptides at 18 h postinfection and subsequent transport to the nucleus by 22 h postinfection. Anti-V1, anti-V2, and anti-V3 sera did not react with intact virions in an immunodiffusion assay, nor did they possess hemagglutination inhibition or viral neutralization activity. Antiserum produced against the four host histone polypeptides (V4 through V7) demonstrated immunofluorescence when reacted with polyoma-infected cells but not with uninfected cells. Antihistone serum was also capable of neutralizing viral infectivity, inhibiting hemagglutination and reacting with whole virions in an immunodiffusion assay.

Structural proteins of polyoma virus: proteolytic degradation of virion proteins by exogenous and by virion-associated proteases

A model has previously been proposed for the genetic relatedness of the structural proteins of polyoma virus, based upon similarities in the peptide maps of the major capsid protein VP1 with the virion proteins VP2 and VP3. Newer evidence suggests that this model is incorrect, and that protein VP1 is a product of one viral gene and that the multiple components of VP2 and VP3 are products of a second viral gene. Two-dimensional peptide maps of several preparations of polyoma purified separately from four separate infected-cell lysates has shown a variable content of VP1 peptides in proteins VP2 and VP3, with some preparations being free of detectable VP1 material in VP2 and VP3. An alternative explanation for the presence of VP1 peptides in the regions of VP2 and VP3 of some polyoma preparations involves the cleavage of proteins of polyoma virions during exposure to proteolytic enzymes in lysates of infected cells or to endogenous proteolytic activity of virions. Prolonged incubation of infected-cell lysates at 37 degrees C leads to an increase in the amount of 86,000-dalton dimer of VP1, a decrease in the relative amount of VP1, a decrease in or a loss of the lower band of VP2, and the appearance of a new major protein band of approximately 29,000 daltons. Two-dimensional peptide maps of the new 29,000-dalton protein show that it contains some VP1 peptides, indicating that this protein is derived from proteolytic cleavage of VP1. In addition, extensively purified polyoma virus contains a proteolytic activity that can be activated during disruption of the virus with 0.2 M Na2CO3-NaHCO3 (pH 10.6) in the presence of 5 X 10(-3) M dithiothreitol.

Origin of polyoma virus-associated endonuclease

Polyoma virus particles purified from infected cells, but not from the culture medium, exhibited an endonuclease activity distinct from the serum contaminant recently described. This endonuclease cleaved form I polyoma DNA once only per molecule, at one of three possible sites corresponding to the known adenosine-ribosylthymine-rich regions of the molecule.