The lymphocyte-specific protein LSP1 is associated with the cytoskeleton and co-caps with membrane IgM

LSP1 is a lymphocyte-specific intracellular Ca2(+)-binding protein. We found previously that a fraction of the total cellular pool of LSP1 protein accumulates at or near the cytoplasmic face of the plasma membrane. LSP1 protein was also shown to be present in the cytoplasm. Here we report that approximately 10% of the total intracellular LSP1 protein is associated with the Nonidet P-40 insoluble cytoskeleton of the mIgM+, mIgD+ B lymphoma cell line BAL17. Variation in conditions of extraction did not alter this value. To rule out the possibility that LSP1 associates with the nucleus that is also present in the detergent insoluble pellet, we prepared a separate nuclear fraction essentially free of cytoskeletal material and found only trace amounts of LSP1 protein. After accounting for yield losses during subcellular fractionation by measuring the recovery of 125I-labeled membrane IgM, or of the cytoplasmic marker enzyme lactate dehydrogenase activity, the LSP1 in membrane fractions was calculated to represent approximately 30% of the total cellular LSP1 and cytoplasmic LSP1 accounted for approximately 55% of the total. Approximately 75% of the plasma membrane LSP1 protein was soluble in 1% Nonidet P-40 containing buffer, indicating that the majority of the LSP1 in the plasma membrane fraction was distinct from the cytoskeletal LSP1 protein. The preparation of membrane fractions in the presence of 1 M NaCl, or washing of membranes in 3 M KCl did not diminish the levels of membrane LSP1. These results show the existence of three discrete intracellular LSP1 pools. Double label immunofluorescence studies showed that the peripheral ring-like distribution of LSP1 in BAL17 cells became a distinct cap upon cross-linking the mIgM. These intracellular LSP1 caps were always found to be located directly underneath the mIgM caps.     

Functional complementation of nuclear targeting-defective mutants of simian virus 40 structural proteins.

Structural proteins of simian virus 40 (SV40), Vp2 and Vp3 (Vp2/3) and Vp1, carry individual nuclear targeting signals, Vp3(198-206) (Vp2(316-324) and Vp1(1-8), respectively, which are encoded in different reading frames of an overlapping region of the genome. How signals coordinate nuclear targeting during virion morphogenesis was examined by using SV40 variants in which there is only one structural gene for Vp1 or Vp2/3, nuclear targeting-defective mutants thereof, Vp2/3(202T) and Vp1 delta N5, or nonoverlapping SV40 variants in which the genes for Vp1 and Vp2/3 are separated, and mutant derivatives of the gene carrying either one or both mutations. Nuclear targeting was assessed immunocytochemically following nuclear microinjection of the variant DNAs. When Vp2/3 and Vp1 mutants with defects in the nuclear targeting signals were expressed individually, the mutant proteins localized mostly to the cytoplasm. However, when mutant Vp2/3(202T) was coexpressed in the same cell along with wild-type Vp1, the mutant protein was effectively targeted to the nucleus. Likewise, the Vp1 delta N5 mutant protein was transported into the nucleus when wild-type Vp2/3 was expressed in the same cells. These results suggest that while Vp1 and Vp2/3 have independent nuclear targeting signals, additional signals, such as those defining protein-protein interactions, play a concerted role in nuclear localization along with the nuclear targeting signals of the individual proteins.     

Identification of amino acid residues within simian virus 40 capsid proteins Vp1, Vp2, and Vp3 that are required for their interaction and for viral infection

Interaction of simian virus 40 (SV40) major capsid protein Vp1 with the minor capsid proteins Vp2 and Vp3 is an integral aspect of the SV40 architecture. Two Vp3 sequence elements mediate Vp1 pentamer binding in vitro, Vp3 residues 155 to 190, or D1, and Vp3 residues 222 to 234, or D2. Of the two, D1 but not D2 was necessary and sufficient to direct the interaction with Vp1 in vivo. Rational mutagenesis of Vp3 residues (Phe157, Ile158, Pro164, Gly165, Gly166, Leu177, and Leu181) or Vp1 residues (Val243 and Leu245), based on a structural model of the SV40 Vp1 pentamer complexed with Vp3 D1, was carried out to disrupt the interaction between Vp1 and Vp3 and to study the consequences of these mutations for viral viability. Altering these residues to bulky, charged residues blocked the interaction in vitro. When these alterations were introduced into the viral genome, they reduced viral viability. Mutants with alterations in Vp1 Val243, Leu245, or both to glutamate were nearly nonviable, whereas those with Vp3 alterations reduced, but did not eliminate, viability. Our results defined the residues of Vp1 and the minor capsid proteins that are essential for both the interaction of the capsid proteins and viral viability in permissive cells.     

Minor capsid proteins of simian virus 40 are dispensable for nucleocapsid assembly and cell entry but are required for nuclear entry of the viral genome

We investigated the roles of simian virus 40 capsid proteins in the viral life cycle by analyzing point mutants in Vp1 and Vp2/3, as well as a deletion mutant lacking the Vp2/3 coding sequence. The Vp1 mutants (V243E and L245E) and the Vp2/3 mutants (F157E-I158E and P164R-G165E-G166R) were previously shown to be defective in Vp1-Vp2/3 interaction and to be noninfectious or poorly infectious, respectively. Here, we show that all these point mutants form stable particles following DNA transfection into cells. The Vp2/3-mutant particles contained very low levels of Vp2/3, whereas the Vp1 mutant particles contained no detectable Vp2/3. As expected, the deletion mutant also formed particles that were noninfectious. We further characterized the two Vp1 point mutants and the deletion mutant. All three mutant particles comprised Vp1 and histone-associated viral DNA, and all were able to enter cells. However, the mutant complexes failed to associate with host importins (owing to the loss of the Vp2/3 nuclear localization signal), and the mutant viral DNAs prematurely dissociated from the Vp1s, suggesting that the nucleocapsids did not enter the nucleus. Consistently, all three mutant particles failed to express large T antigen. Together, our results demonstrate unequivocally that Vp2/3 is dispensable for the formation of nucleocapsids. Further, the nucleocapsids' ability to enter cells implies that Vp1 contains the major determinants for cell attachment and entry. We propose that the major role of Vp2/3 in infectivity is to mediate the nuclear entry of viral DNA.     

Simian Virus 40 Vp1 DNA-Binding Domain Is Functionally Separable from the Overlapping Nuclear Localization Signal and Is Required for Effective Virion Formation and Full Viability

A DNA-binding domain (DBD) was identified on simian virus 40 (SV40) major capsid protein Vp1, and the domain's function in the SV40 life cycle was examined. The DBD was mapped by assaying various recombinant Vp1 proteins for DNA binding in vitro. The carboxy-terminal 58-residue truncated Vp1DeltaC58 pentamer bound DNA with a K(d) of 1.8 x 10(-9) M in terms of the protein pentamer, while full-length Vp1 and carboxy-terminal-17-truncated Vp1DeltaC17 had comparable apparent K(d)s of 5.3 x 10(-9) to 7.3 x 10(-9) M in terms of the protein monomers. Previously identified on Vp1 was a nuclear localization signal (NLS) consisting of two N-terminal basic clusters, NLS1 (4-KRK-6) and NLS2 (15-KKPK-18). Vp1DeltaC58 pentamers harboring multiple-point mutations in NLS1 (NLSm1), NLS2 (NLSm2), or both basic clusters (NLSm1. 2) had progressively decreased DNA-binding activity, down to 0.7% of the Vp1DeltaC58 level for NLSm1. 2 Vp1. These data, along with those of N-terminally truncated proteins, placed the DBD in overlap with the bipartite NLS. The role of the Vp1 DBD during infection was investigated by taking advantage of NLS phenotypic complementation (N. Ishii, A. Nakanishi, M. Yamada, M. H. Macalalad, and H. Kasamatsu, J. Virol. 68:8209-8216, 1994), in which an NLS-defective Vp1 could localize to the nucleus in the presence of wild-type minor capsid proteins Vp2 and Vp3. This approach made it possible to dissect the role of the bifunctional Vp1 NLS-DBD in virion assembly in the nucleus. Mutants of the viable nonoverlapping SV40 (NO-SV40) DNA NLSm1, NLSm2, and NLSm1. 2 replicated normally following transfection into host cells and produced capsid proteins at normal levels. All mutant Vp1s were able to interact with Vp3 in vitro. The mutants NLSm1 and NLSm1. 2 were nonviable, and the mutant Vp1s unexpectedly failed to localize to the nucleus though Vp2 and Vp3 did, suggesting that the mutated NLS1 acted as a dominant signal for the cytoplasmic localization of Vp1. Mutant NLSm2, for which the mutant Vp1's nuclear localization defect was complemented by Vp2 and Vp3, displayed a 5,000-fold reduced viability. Analysis of NLSm2 DNA-transfected cell lysate revealed a 10-fold reduction in the level of DNase I-protected viral DNA, and yet virion-like particles were found among the DNase I-resistant material. Collective results support a role for Vp1 NLS2-DBD2 in the assembly of virion particles. The results also suggest that this determinant can function in the infection of new cells.     

Separate basic region motifs within the adeno-associated virus capsid proteins are essential for infectivity and assembly

Adeno-associated virus (AAV) is gaining momentum as a gene therapy vector for human applications. However, there remain impediments to the development of this virus as a vector. One of these is the incomplete understanding of the biology of the virus, including nuclear targeting of the incoming virion during initial infection, as well as assembly of progeny virions from structural components in the nucleus. Toward this end, we have identified four basic regions (BR) on the AAV2 capsid that represent possible nuclear localization sequence (NLS) motifs. Mutagenesis of BR1 ((120)QAKKRVL(126)) and BR2 ((140)PGKKRPV(146)) had minor effects on viral infectivity ( approximately 4- and approximately 10-fold, respectively), whereas BR3 ((166)PARKRLN(172)) and BR4 ((307)RPKRLN(312)) were found to be essential for infectivity and virion assembly, respectively. Mutagenesis of BR3, which is located in Vp1 and Vp2 capsid proteins, does not interfere with viral production or trafficking of intact AAV capsids to the nuclear periphery but does inhibit transfer of encapsidated DNA into the nucleus. Substitution of the canine parvovirus NLS rescued the BR3 mutant to wild-type (wt) levels, supporting the role of an AAV NLS motif. In addition, rAAV2 containing a mutant form of BR3 in Vp1 and a wt BR3 in Vp2 was found to be infectious, suggesting that the function of BR3 is redundant between Vp1 and Vp2 and that Vp2 may play a role in infectivity. Mutagenesis of BR4 was found to inhibit virion assembly in the nucleus of transfected cells. This affect was not completely due to the inefficient nuclear import of capsid subunits based on Western blot analysis. In fact, aberrant capsid foci were observed in the cytoplasm of transfected cells, compared to the wild type, suggesting a defect in early viral assembly or trafficking. Using three-dimensional structural analysis, the lysine- and arginine-to-asparagine change disrupts hydrogen bonding between these basic residues and adjacent beta strand glutamine residues that may prevent assembly of intact virions. Taken together, these data support that the BR4 domain is essential for virion assembly. Each BR was also found to be conserved in serotypes 1 to 11, suggesting that these regions are significant and function similarly in each serotype. This study establishes the importance of two BR motifs on the AAV2 capsid that are essential for infectivity and virion assembly.     

Structural studies on Rauscher murine leukemia virus: isolation and characterization of viral envelopes.

A preparative method for isolating pure viral envelopes from a type-C RNA tumor virus, Rauscher murine leukemia virus, is described. Fractionation of virions of Rauscher murine leukemia virus was studied after disruption of the virions with the detergents sodium dodecyl sulfate of Nonidet P-40 in combination with ether. Fractionation was performed through flotation in a discontinuous sucrose gradient and, as appeared from electron microscopic examination, a pure viral envelope fraction was obtained in this way. By use of sensitive competition radioimmunoassays or sodium dodecyl sulfate-polyacrylamide gel electrophoresis after immunoprecipitation with polyvalent and monospecific antisera directed against Rauscher murine leukemia virus proteins, the amount of the gag and env gene-encoded structural polypeptides in the virions and the isolated envelope fraction was compared. The predominant viral structural polypeptides in the purified envelope fraction were the env gene-encoded polypeptides gp70, p15(E), and p12(E), whereas, except for p15, there was only a relatively small amount of the gag gene-encoded structural polypeptides in this fraction.     

Essential role of the Vp2 and Vp3 DNA-binding domain in simian virus 40 morphogenesis.

Both a DNA-binding domain and a Vp1 interactive determinant have been mapped to the carboxy-terminal 40 residues of the simian virus 40 (SV40) minor capsid proteins, Vp2 and Vp3 (Vp2/3), with the last 13 residues being necessary for these activities. The role of this DNA-binding domain in SV40 morphogenesis and the ability to separate these two signals were investigated by mutagenesis and assessment of the activity and viability of the mutants. The carboxy-terminal 40 residues of Vp2/3 were expressed as a polyhistidine fusion protein, and five basic residues at the extreme carboxy terminus (Vp3 residues K226, R227, R228, R230, and R233) were mutagenized. The wild-type fusion protein bound DNA with a Kd of 3 x 10(-8) identical to that of the full-length Vp3. Mutant proteins containing either one to three or four amino acid substitutions bound DNA 4- to 7-fold or 20- to 30-fold less well, respectively, than the wild-type protein did. The most severe point mutants showed residual DNA binding similar to that of a truncated protein which lacks the entire 13 carboxy-terminal residues. All of the point mutants were able to interact with Vp1, indicating that the two signals within this region are mediated by different residues. When the mutations were placed into the context of the viral DNA and introduced into cells, all the structural proteins were expressed and localized correctly. Not all, however, were viable: mutant genomes whose Vp2/3 bound DNA with intermediate affinities formed plaques just as well as wild-type SV40 DNA did, but three mutants showing greatly reduced DNA binding failed to form plaques at all. These results are consistent with the hypothesis that Vp2/3 plays an essential role in SV40 virion assembly in the nucleus.     

Importance of calcium-binding site 2 in simian virus 40 infection

The exposure of molecular signals for simian virus 40 (SV40) cell entry and nuclear entry has been postulated to involve calcium coordination at two sites on the capsid made of Vp1. The role of calcium-binding site 2 in SV40 infection was examined by analyzing four single mutants of site 2, the Glu160Lys, Glu160Arg, Glu157Lys (E157K), and Glu157Arg mutants, and an E157K-E330K combination mutant. The last three mutants were nonviable. All mutants replicated viral DNA normally, and all except the last two produced particles containing all three capsid proteins and viral DNA. The defect of the site 1-site 2 E157K-E330K double mutant implies that at least one of the sites is required for particle assembly in vivo. The nonviable E157K particles, about 10% larger in diameter than the wild type, were able to enter cells but did not lead to T-antigen expression. Cell-internalized E157K DNA effectively coimmunoprecipitated with anti-Vp1 antibody, but little of the DNA did so with anti-Vp3 antibody, and none was detected in anti-importin immunoprecipitate. Yet, a substantial amount of Vp3 was present in anti-Vp1 immune complexes, suggesting that internalized E157K particles are ineffective at exposing Vp3. Our data show that E157K mutant infection is blocked at a stage prior to the interaction of the Vp3 nuclear localization signal with importins, consistent with a role for calcium-binding site 2 in postentry steps leading to the nuclear import of the infecting SV40.     

Isolation of coronavirus envelope glycoproteins and interaction with the viral nucleocapsid.

The two envelope glycoproteins and the viral nucleocapsid of the coronavirus A59 were isolated by solubilization of the viral membrane with Nonidet P-40 at 4 degrees C followed by sucrose density gradient sedimentation. Isolated E2 consisted of rosettes of peplomers, whereas E1, the membrane glycoprotein, was irregular and amorphous. Under certain conditions significant interactions occurred between components of Nonidet P-40-disrupted virions. Incubation of the Nonidet P-40-disrupted virus at 37 degrees C resulted in formation of a complex between one of the viral glycoproteins, E1, and the viral nucleocapsid. This was caused by a temperature-dependent conformational change in E1, resulting in aggregation of E1 and interaction with the viral RNA in the nucleocapsid. E1 also bound rRNA. The E1-nucleocapsid complexes can be distinguished on sucrose and Renografin density gradients from native viral nucleocapsids. The separation of the membrane glycoprotein E1 from the peplomeric glycoprotein E2 permitted preparation of antisera against these isolated proteins. A model is proposed for the arrangement of the three major structural proteins in the coronavirus A59 virion in relation to the viral envelope and RNA.     

Intracellular location of rabbit poxvirus nucleic acid within infected cells as determined by in situ hybridization.

The intracellular location of rabbit poxvirus DNA within cells during the course of infection has been determined by the hybridization in situ of labeled viral DNA probes to uninfected and infected cells under various conditions. Extensive control experiments were performed to demonstrate that DNA could be detected selectively and accurately within the cell. Our results suggest that rabbit poxvirus DNA is located only within the cytoplasm during the reproductive cycle, and we found no evidence that viral DNA enters the cell nucleus. The pattern of hybridization of viral DNA at early times (1 and 2 h postinfection) and in the presence of inhibitors of viral DNA synthesis suggests that there may be an association between the input viral DNA and some structural component of the host cell. A number of observations support the hypothesis that the host cell nucleus is required for a productive poxvirus infection. Our results are discussed in terms of the possible role of the nucleus in the replication of poxviruses.     

Cytoskeletal disruption during human cytomegalovirus infection of human lung fibroblasts

Human cytomegalovirus (HCMV) infection causes a rapid, progressive disruption of the host cell cytoskeleton that correlates with actin depolymerization. Whole-mount (3D) electron microscopy was used to analyze the cytoskeleton of uninfected and HCMV-infected human lung fibroblast cells. Within 2 min of HCMV infection, localized areas of cytoskeletal disruption were observed. Disruption extended throughout the cytoplasm during the ensuing 45 to 90 min of infection and resulted in generalized cytoskeletal disorganization. Actin depolymerization occurred, as indicated by an increase in DNase I inhibition and alteration in the fluorescence pattern with rhodamine-conjugated phalloidin. Thus, actin appears to be the primary cytoskeletal target involved during HCMV infection. Fractionation of the virus seed inoculum showed that development of DNase I inhibitory activity in infected cells was associated only with the virus-containing fractions. Cytochalasin B treatment at early times of HCMV infection stimulated progeny virus production. This study demonstrates that rapid cytoskeletal disruption occurs during early periods of HCMV infection and indicates that actin depolymerization facilitates viral infectivity.     

Microcompartmentation of glycolytic enzymes in cultured cells.

The microcompartmentation of aldolase and glyceraldehyde-3-phosphate-dehydrogenase (GAPDH) was investigated in four different cell types (3T3 cells, SV 40 transformed 3T3 cells, mouse fibroblasts, chick embryo cardiomyocytes) combining cell permeabilization and indirect immunofluorescence technique. Permeabilization of the cells prior to fixation released the soluble fractions, whilst the total amount of enzymes was preserved in nonpermeabilized cells. Both enzymes exist in a soluble as well as in a structure-bound form. The soluble fraction of aldolase and GAPDH is distributed homogeneously throughout the cytoplasm, excluding the nucleus and vesicles. The permeabilization-resistant form is associated with the actin cytoskeleton. A considerable amount of both enzymes is located in the perinuclear region and cannot be attributed to a definite structure. Comparing the staining patterns of aldolase and GAPDH in four different cell types we found that the distribution of the enzymes corresponds with diverse forms of actin cytoskeletal organization of these cells. The codistribution is maintained in cells treated with cytochalasin D.     

Pairs of Vp1 cysteine residues essential for simian virus 40 infection

Transient disulfide bonding occurs during the intracellular folding and pentamerization of simian virus 40 (SV40) major capsid protein Vp1 (P. P. Li, A. Nakanishi, S. W. Clark, and H. Kasamatsu, Proc. Natl. Acad. Sci. USA 99:1353-1358, 2002). We investigated the requirement for Vp1 cysteine pairs during SV40 infection. Our analysis identified three Vp1 double-cysteine mutant combinations that abolished viability as assayed by plaque formation. Mutating the Cys49-Cys87 pair or the Cys87-Cys254 pair led to ineffective nuclear localization and diminished accumulation of the mutant Vp1s, and the defect extended in a dominant-negative manner to the wild-type minor capsid proteins Vp2/3 and an affinity-tagged recombinant Vp1 expressed in the same cells. Mutating the Cys87-Cys207 pair preserved the nuclear localization and normal accumulation of the capsid proteins but diminished the production of virus-like particles. Our results are consistent with a role for Cys49, Cys87, and Cys254 in the folding and cytoplasmic-nuclear trafficking of Vp1 and with a role for Cys87 and Cys207 in the assembly of infectious particles. These findings suggest that transient disulfide bond formation between certain Vp1 cysteine residues functions at two stages of SV40 infection: during Vp1 folding and oligomerization in the cytoplasm and during virion assembly in the nucleus.     

Importance of Vp1 calcium-binding residues in assembly,cell entry,and nuclear entry of simian virus 40

For polyomaviruses, calcium ions are known to be essential for virion integrity and for the assembly of capsid structures. To define the role of calcium ions in the life cycle of the virus, we analyzed simian virus 40 (SV40) mutants in which structurally deduced calcium-binding amino acids of Vp1 were mutated singly and in combination. Our study provides evidence that calcium ions mediate not only virion assembly but also the initial infection processes of cell entry and nuclear entry. Mutations at Glu48, Glu157, Glu160, Glu216, and/or Glu330 are correlated with different extents of packaging defects. The low packaging ability of mutant E216R suggests the need to position the Glu216 side chain for proper virion formation. All other mutants selected for further analysis produced virus-like particles (VLPs) but were poorly infectious. The VLPs of mutant E330K could not attach to or enter the cell, and mutant E157A-E160A and E216K VLPs entered the cell but failed to enter the nucleus, apparently as a result of premature VLP dissociation. Our results show that five of the seven acidic side chains at the two calcium-binding sites-Glu48 and Glu330 (site 1), Glu157 and Glu160 (site 2), and Glu216 (both sites)-are important for SV40 infection. We propose that calcium coordination imparts not only stability but also structural flexibility to the virion, allowing the acquisition or loss of the ion at the two sites to control virion formation in the nucleus, as well as virion structural alterations at the cell surface and in the cytoplasm early during infection.     

Localization of viral structural proteins in the cytoplasm and nucleus of Rous-associated virus-2-infected chicken embryo fibroblasts

The cellular location of viral structural proteins was carried out by immunohistochemistry and by cell fractionation. Antibody against the structural protein p27 was used in immunohistochemical reactions to demonstrate the presence of viral proteins in the cytoplasm and nucleus of Rous-associated virus 2-infected chicken cells. Localization in the nucleus was found over heterochromatic regions; in the cytoplasm it was found in discrete particulate structures. These observations were extended in cell fractionation studies in which cytoplasmic and nuclear fractions were immunoprecipitated with antibody against the viral structural proteins.     

RNA-Dependent RNA Polymerase in Nuclei of Cells Infected with Influenza Virus

Nuclei purified from chicken embryo fibroblast cells infected with influenza (fowl plague) virus contain an RNA-dependent RNA polymerase. The in vitro activity of this enzyme is insensitive to actinomycin D, and is completely destroyed by preincubation with ribonuclease. Enzyme induction is prevented if cells are treated with actinomycin D or cycloheximide at the time of infection. RNA-dependent RNA polymerase activity increases rapidly in cell nuclei from 1 h postinfection, reaches a maximum at 3 to 4 h, then declines; a similar RNA polymerase activity in the microsomal cell fraction increases from 2 h postinfection and reaches a maximum at 5 to 6 h. The characteristics of the nuclear and microsomal enzymes in vitro are similar with respect to pH and divalent cation requirements. The in vitro products of enzyme activity present in the nuclear and microsomal fractions of cells infected for 3 and 5 h were characterized by sucrose density gradient analysis, and annealing to virion RNA. The microsomal RNA polymerase product contained 67 and 93% RNA complementary to virion RNA at 3 and 5 h, respectively; for the nuclear RNA polymerase product these values were 40% in each case.     

Intracellular localization of viral polypeptides during simian virus 40 infection.

African green monkey kidney cells infected by simian virus 40 were analyzed by immunofluorescence techniques for the nature and the time course of the appearance of viral polypeptides during infection. Reagents used in the study were anti-Vpl sera and affinity-purified anti-Vpl immunoglobulin G, anti-Vp3 sera, antivirus (anti-V) sera, and anti-tumor antigen sera. The results are summarized as follows. (i) Three types of staining, nuclear, perinuclear, and perinuclear accompanied by cytoplasmic staining, were observed in infected cells in reaction with anti-vpl antibody. In addition, a highly structured staining was observed at the periphery of nuclei of infected cells late in infection. (ii) In reaction with anti-Vp3 serum, the staining was confined within nuclei of cells throughout infection. (iii) Vp1 and Vp3 antigens seem to occupy different spacial regions of the nuclear area in cells. (iv) Vp1 and Vp3 antigens were expressed simultaneously during infection. (v) Centriolar staining observed early in infection paralleled the appearance of tumor (T-) antigen until 24 h after infection, after which time the frequency of positive centriolar staining decreased as infection progressed. (vi) T-antigen was first expressed at about 8 h after infection, and Vp1 and Vp3 antigens were first expressed at about 20 h after infection.