Disassembly of simian virus 40 during passage through the endoplasmic reticulum and in the cytoplasm

The nonenveloped polyomavirus simian virus 40 (SV40) is taken up into cells by a caveola-mediated endocytic process that delivers the virus to the endoplasmic reticulum (ER). Within the ER lumen, the capsid undergoes partial disassembly, which exposes its internal capsid proteins VP2 and VP3 to immunostaining with antibodies. We demonstrate here that the SV40 genome does not become accessible to detection while the virus is in the ER. Instead, the genome becomes accessible two distinct detection procedures, one using anti-bromodeoxyuridine antibodies and the other using a 5-ethynyl-2-deoxyuridine-based chemical reaction, only after the emergence of partially disassembled SV40 particles in the cytoplasm. These cytoplasmic particles retain some of the SV40 capsid proteins, VP1, VP2, and VP3, in addition to the viral genome. Thus, SV40 particles undergo discrete disassembly steps during entry that are separated temporally and topologically. First, a partial disassembly of the particles occurs in the ER, which exposes internal capsid proteins VP2 and VP3. Then, in the cytoplasm, disassembly progresses further to also make the genomic DNA accessible to immune detection.     

Assemblages of simian virus 40 capsid proteins and viral DNA visualized by electron microscopy

SV40 assembles in the nucleus by addition of capsid proteins to the minichromosome. The VP15VP2/3 capsomer is composed of a pentamer of the major protein VP1 complexed with a monomer of a minor protein, VP2 or VP3. In the capsid, the capsomers are bound together via their flexible carboxy-terminal arms. Our previous studies suggested that the capsomers are recruited to the packaging signal ses via avid interaction with Sp1. During assembly Sp1 is displaced, allowing chromatin compaction. Here we investigated the interactions in vitro of VP1(5)VP2/3 capsomers with the entire SV40 genome, using mutant VP1 deleted in the carboxy-arm that cannot assemble, but retains DNA-binding capacity. EM revealed that VP1(5)VP2/3 complexes bind non-specifically at random locations around the DNA. Sp1 was absent from mature virions. The findings suggest that multiple capsomers attach simultaneously to the viral genome, increasing their local concentration, facilitating rapid, concerted assembly reaction and removal of Sp1.     

SV40 VP2 and VP3 insertion into ER membranes is controlled by the capsid protein VP1: implications for DNA translocation out of the ER

Nonenveloped viruses such as Simian Virus 40 (SV40) exploit established cellular pathways for internalization and transport to their site of penetration. By analyzing mutant SV40 genomes that do not express VP2 or VP3, we found that these structural proteins perform essential functions that are regulated by VP1. VP2 significantly enhanced SV40 particle association with the host cell, while VP3 functioned downstream. VP2 and VP3 both integrated posttranslationally into the endoplasmic reticulum (ER) membrane. Association with VP1 pentamers prevented their ER membrane integration, indicating that VP1 controls the function of VP2 and VP3 by directing their localization between the particle and the ER membrane. These findings suggest a model in which VP2 aids in cell binding. After capsid disassembly within the ER lumen, VP3, and perhaps VP2, oligomerizes and integrates into the ER membrane, potentially creating a viroporin that aids in viral DNA transport out of the ER.     

Calcium Bridge Triggers Capsid Disassembly in the Cell Entry Process of Simian Virus 40

The calcium bridge between the pentamers of polyoma viruses maintains capsid metastability. It has been shown that viral infection is profoundly inhibited by the substitution of lysine for glutamate in one calcium-binding residue of the SV40 capsid protein, VP1. However, it is unclear how the calcium bridge affects SV40 infectivity. In this in vitro study, we analyzed the influence of host cell components on SV40 capsid stability. We used an SV40 mutant capsid (E330K) in which lysine had been substituted for glutamate 330 in protein VP1. The mutant capsid retained the ability to interact with the SV40 cellular receptor GM1, and the internalized mutant capsid accumulated in caveolin-1-mediated endocytic vesicles and was then translocated to the endoplasmic reticulum (ER) region. However, when placed in ER-rich microsome, the mutant capsid retained its spherical structure in contrast to the wild type, which disassembled. Structural analysis of the mutant capsid with cryo-electron microscopy and image reconstruction revealed altered pentamer coordination, possibly as a result of electrostatic interaction, although its overall structure resembled that of the wild type. These results indicate that the calcium ion serves as a trigger at the pentamer interface, which switches on capsid disassembly, and that the failure of the E330K mutant capsid to disassemble is attributable to an inadequate triggering system. Our data also indicate that calcium depletion-induced SV40 capsid disassembly may occur in the ER region and that this is essential for successful SV40 infection.     

The intranuclear location of simian virus 40 polypeptides VP2 and VP3 depends on a specific amino acid sequence.

A cDNA fragment coding for poliovirus capsid polypeptide VP1 was inserted into a simian virus 40 (SV40) genome in the place of the SV40 VP1 gene and fused in phase to the 3' end of the VP2-VP3 genes. Simian cells were infected with the resulting hybrid virus in the presence of an early SV40 mutant used as a helper. Indirect immunofluorescence analysis of the infected cells using anti-poliovirus VP1 immune serum revealed that the SV40/poliovirus fusion protein was located inside the cell nucleus. Deletions of various lengths were generated in the SV40 VP2-VP3 portion of the hybrid gene using BAL31 nuclease. The resulting virus genomes expressed spliced fusion proteins whose intracellular location was either intranuclear or intracytoplasmic, depending on the presence or absence of VP2 amino acid residues 317 to 323 (Pro-Asn-Lys-Lys-Lys-Arg-Lys). This was confirmed by site-directed mutagenesis of the Lys residue at position 320. Modification of Lys-320 into either Thr or Asn abolished the nuclear accumulation of the fusion protein. It is concluded that at least part of the sequence of VP2 amino acids 317 to 323 allows VP2 and VP3 to remain stably located inside the cell nucleus. The proteins are most probably transported from the cell cytoplasm to the cell nucleus by interaction, with VP1 acting as a carrier.     

Amino acid compositions of simian virus 40 structural proteins

The structural proteins of purified SV40 particles were isolated by preparative polyacrylamide gel electrophoresis and the amino acid composition of each protein was obtained. The amino acid composition of VP1 (the major coat protein) was significantly different to that of VP3 (the capsid protein most closely associated with SV40 DNA). The amino acid compositions of VP4, VP5 and VP6 indicated that these proteins were not exclusively histones.     

Simian virus 40 chromatin interaction with the capsid proteins

It has been established that both in virions and in infected cells, the cellular core histones fold the SV40 DNA into nucleosomes to form the SV40 chromosome or chromatin. We and others have begun to examine how the capsid proteins assemble the SV40 chromatin into virions and to investigate whether these proteins interact with the encapsidated chromatin. To follow the pathway of virus assembly, we have analyzed the nucleoproteins which accumulate in cells infected with the SV40 mutants temperature-sensitive in assembly: tsC, tsBC, and tsB. (The temperature-sensitivity of these mutants result from alterations in the amino acid sequence of the major capsid protein VP1). We have found that mutants belonging to the same class accumulate similar types of nucleoproteins at the nonpermissive temperature (40 degrees C) and thus, share characteristics in common. For example, the tsC mutants accumulate only the 75 S chromatin. Both tsBC and tsB mutants produce in addition to chromatin, nucleoprotein complexes which sediment broadly from 100-160 S and contain all the three capsid proteins VP1, VP2, and VP3. These nucleoproteins can be distinguished morphologically, however. Under the electron microscope, the tsBC 100-160 S nucleoproteins appear as chromatin to which a small cluster of the capsid proteins is attached; the tsB nucleoproteins appear as partially assembled virions. In addition, we find that the 220 S virions are assembled in cells coinfected with tsB and tsC mutants at 40 degrees C, in agreement with genetic analysis. Our observations favor the hypothesis that the VP1 protein contains three discrete domains. We speculate that each domain may play a specific function in SV40 assembly. To gain more insight into VP1-VP1 interactions, we have examined the nucleoproteins which result from treatment of the mature wild-type virions with increasing concentrations of the reducing agent DTT. In the presence of as low a concentration of DTT as 0.1 mM, the virion shell can be penetrated by micrococcal nuclease, which then cleaves the viral DNA. This result indicates that some of the disulfide bonds bridging the VP1 proteins are on the virion surface.     

The abundant nuclear enzyme PARP participates in the life cycle of simian virus 40 and is stimulated by minor capsid protein VP3

The abundant nuclear enzyme poly(ADP-ribose) polymerase (PARP) functions in DNA damage surveillance and repair and at the decision between apoptosis and necrosis. Here we show that PARP binds to simian virus 40 (SV40) capsid proteins VP1 and VP3. Furthermore, its enzymatic activity is stimulated by VP3 but not by VP1. Experiments with purified mutant proteins demonstrated that the PARP binding domain in VP3 is localized to the 35 carboxy-terminal amino acids, while a larger peptide of 49 amino acids was required for full stimulation of its activity. The addition of 3-aminobenzamide (3-AB), a known competitive inhibitor of PARP, demonstrated that PARP participates in the SV40 life cycle. The titer of SV40 propagated on CV-1 cells was reduced by 3-AB in a dose-dependent manner. Additional experiments showed that 3-AB did not affect viral DNA replication or capsid protein production. PARP did not modify the viral capsid proteins in in vitro poly(ADP-ribosylation) assays, implying that it does not affect SV40 infectivity. On the other hand, it greatly reduced the magnitude of the host cytopathic effects, a hallmark of SV40 infection. Additional experiments suggested that the stimulation of PARP activity by VP3 leads the infected cell to a necrotic pathway, characterized by the loss of membrane integrity, thus facilitating the release of mature SV40 virions from the cells. Our studies identified a novel function of the minor capsid protein VP3 in the recruitment of PARP for the SV40 lytic process.     

Engineering of SV40-based nano-capsules for delivery of heterologous proteins as fusions with the minor capsid proteins VP2/3

The capsid of SV40 is regarded as a potential nano-capsule for delivery of biologically active materials. The SV40 capsid is composed of 72 pentamers of the VP1 major capsid protein and 72 copies of the minor coat proteins VP2/3. We have previously demonstrated that, when expressed in insect Sf9 cells by the baculovirus system, VP1 self-assembles into virus-like particles (VP1-VLPs), which are morphologically indistinguishable from the SV40 virion and can be easily purified. Here, we show that heterologous proteins fused to VP2/3 can be efficiently incorporated into the VP1-VLPs. Using EGFP as a model protein, we have optimized this encapsulation system and found that fusion to the C-terminus of VP2/3 is preferable and that the C-terminal VP1-interaction domain of VP2/3 is sufficient for incorporation into VLPs. The VLPs encapsulating EGFP retain the ability to attach to the cell surface and enter the cells. Using this system, we have encapsulated yeast cytosine deaminase (yCD), a prodrug-modifying enzyme that converts 5-fluorocytosine to 5-fluorouracil, into VLPs. When CV-1 cells are challenged by the yCD-encapsulating VLPs, they become sensitive to 5-fluorocytosine-induced cell death. Therefore, proteins of interest can be encapsulated in VP1-VLPs by fusion to VP2/3 and successfully delivered to cells.     

Simian Virus 40 Chromatin Interaction with the Capsid Proteins

Abstract

It has been established that both in virions and in infected cells, the cellular core histones fold the SV40 DNA into nucleosomes to form the SV40 chromosome or chromatin. We and others have begun to examine how the capsid proteins assemble the SV40 chromatin into virions and to investigate whether these proteins interact with the encapsidated chromatin. To follow the pathway of virus assembly, we have analyzed the nucleoproteins which accumulate in cells infected with the SV40 mutants temperature-sensitive in assembly: tsC, tsBC, and tsB. (The temperature-sensitivity of these mutants result from alterations in the amino acid sequence of the major capsid protein VP1). We have found that mutants belonging to the same class accumulate similar types of nucleoproteins at the nonpermissive temperature (40°C) and thus, share characteristics in common. For example, the tsC mutants accumulate only the 75 S chromatin. Both tsBC and tsB mutants produce in addition to chromatin, nucleoprotein complexes which sediment broadly from 100–160 S and contain all the three capsid proteins VP1, VP2, and VP3. These nucleoproteins can be distinguished morphologically, however. Under the electron microscope, the tsBC 100–160 S nucleoproteins appear as chromatin to which a small cluster of the capsid proteins is attached; the tsB nucleoproteins appear as partially assembled virions. In addition, we find that the 220 S virions are assembled in cells coinfected with tsB and tsC mutants at 40°C, in agreement with genetic analysis. Our observations favor the hypothesis that the VP1 protein contains three discrete domains. We speculate that each domain may play a specific function in SV40 assembly. To gain more insight into VP1-VP1 interactions, we have examined the nucleoproteins which result from treatment of the mature wild-type virions with increasing concentrations of the reducing agent DTT. In the presence of as low a concentration of DTT as 0.1 mM, the virion shell can be penetrated by micrococcal nuclease, which then cleaves the viral DNA. This result indicates that some of the disulfide bonds bridging the VP1 proteins are on the virion surface.     

Simian virus 40 agnoprotein facilitates perinuclear-nuclear localization of VP1, the major capsid protein.

The agnoprotein of simian virus 40 (SV40) is a 61-amino-acid protein encoded in the leader of some late mRNAs. In indirect immunofluorescence studies with antisera against SV40 capsid proteins, we show that mutants which make no agnoprotein display abnormal perinuclear-nuclear localization of VP1, the major capsid protein, but not VP2 or VP3, the minor capsid proteins. In wild-type (WT) SV40-infected CV-1P cells, VP1 was found predominantly in the cytoplasm until 36 h postinfection (p.i.), approximately the time that high levels of agnoprotein became detectable under our infection conditions. Thereafter, VP1 localized rapidly to the perinuclear region and to the nucleus. In contrast, in agnoprotein-minus mutant-infected CV-1P cells, perinuclear-nuclear accumulation of VP1 occurred much less efficiently; a significantly greater fraction of cells with predominantly cytoplasmic fluorescence was observed up to 48 h p.i. At 48 and 60 h p.i., more cells with largely perinuclear and little nuclear staining were seen than in WT-infected controls. In similar analyses with stably transfected cell lines constitutively expressing the agnoprotein, VP1 localized to the nucleus before 30 h p.i., regardless of the infecting virus. Delayed nuclear entry of VP1 in a mutant which makes no agnoprotein was also overcome in a revertant which has a second site point mutation in VP1. This suggests that an alteration of VP1 can partially overcome the defect of the agnogene mutation by enhancement of the rate of its own nuclear localization. Taken together, these results indicate that at least one function of the agnoprotein is to enhance the efficiency of perinuclear-nuclear localization of VP1.     

Nuclear localization of poliovirus capsid polypeptide VP1 expressed as a fusion protein with SV40-VP1

The poliovirus cDNA fragment coding for capsid polypeptide VP1 was inserted between the EcoRI and BamHI sites of SV40 DNA, generating a chimaeric gene in which the sequence of the 302 amino acids (aa) of poliovirus capsid polypeptide VP1 was placed downstream from that of the 94 N-terminal aa of SV40 capsid polypeptide VP1. The resulting defective, hybrid virus, SV40-delta 1 polio, was propagated in CV1 cells using an early SV40 mutant, am404, as a helper. Cells doubly infected by SV40-delta 1 polio and am404 expressed a 50-kDal fusion protein which was specifically immunoprecipitated by polyclonal and/or monoclonal antibodies raised against poliovirus capsids or against poliovirus polypeptide VP1. Examination of the infected cells by immunofluorescence after staining with anti-poliovirus VP1 immune sera revealed that the fusion protein was mostly located in the intra- and perinuclear space of the cells, in contrast to the exclusively intracytoplasmic location of genuine poliovirus VP1 polypeptide that was observed in poliovirus-infected cells. This suggests that the N-terminal part of the SV40-VP1 polypeptide could contain an important sequence element acting as a migration signal for the transport of proteins from the cytoplasm to the nucleus.     

Identification of Virus-Induced Proteins in Cells Productively Infected with Simian Virus 40

The number and molecular weight of the structural polypeptides of highly purified simian virus 40 (SV40) were determined by polyacrylamide gel electrophoresis. Six different polypeptides were found, two of which (VP1 and VP2) comprise the bulk of the viral capsid proteins. The pattern of protein synthesis in productively infected CV-1 cells was studied by sodium dodecyl sulfate polyacrylamide gel electrophoresis. Identification of virus-induced proteins in the infected CV-1 cells was achieved in double-labeling experiments by electrophoresis with purified labeled SV40 capsid proteins. Four of these proteins (VP1 and VP4) could be classified as components of the virion because their synthesis occurred after the onset of viral deoxyribonucleic acid (DNA) replication and because they were inhibited by arabinofuranosylcytosine (ara-C). Appearance of two other virus-induced proteins was not prevented by ara-C; one of them did not comigrate in the electrophoresis with purified virion polypeptides, and both could be detected before the onset of viral DNA synthesis. These latter two proteins were classified on the basis of these criteria as nonvirion capsid proteins (NCVP1 and NCVP2).     

Role of JC virus agnoprotein in virion formation

JC virus (JCV) belongs to the polyomavirus family of double-stranded DNA viruses and causes progressive multifocal leukoencephalopathy in humans. JCV encodes early proteins (large T antigen, small T antigen, and T' antigen) and four late proteins (agnoprotein, and three viral capsid proteins, VP1, VP2, and VP3). In the current study, a novel function for JCV agnoprotein in the morphogenesis of JC virion particles was identified. It was found that mature virions of agnoprotein-negative JCV are irregularly shaped. Sucrose gradient sedimentation and cesium chloride gradient ultracentrifugation analyses revealed that the particles of virus lacking agnoprotein assemble into irregularly sized virions, and that agnoprotein alters the efficiency of formation of VP1 virus-like particles. An in vitro binding assay and immunocytochemistry revealed that agnoprotein binds to glutathione S-transferase fusion proteins of VP1 and that some fractions of agnoprotein colocalize with VP1 in the nucleus. In addition, gel filtration analysis of formation of VP1-pentamers revealed that agnoprotein enhances formation of these pentamers by interacting with VP1. The present findings suggest that JCV agnoprotein plays a role, similar to that of SV40 agnoprotein, in facilitating virion assembly.     

Opening and refolding of simian virus 40 and in vitro packaging of foreign DNA.

Simian virus 40 (SV40) can be disassembled under mild conditions by reducing disulfide bonds in the capsid and removing calcium ions. The nucleoprotein complexes formed, analyzed by electron microscopy, were circular and made up of 59 +/- 4 subunits, each with a diameter of about 10 nm. The complexes contained the viral DNA, histones, and the viral capsid proteins. The complexes had much-reduced infectivities compared with intact SV40. Addition of calcium ions to the disrupted virus caused the nucleoprotein complexes to refold into virus-like structures which sedimented at the same rate as intact SV40 and regained infectivity. Treatment of the disrupted SV40 with a high concentration of salt dissociated the viral proteins from the DNA. Lowering stepwise the salt concentration, removing the reducing agent, and adding calcium ions allowed structures to be reformed, and these structures sedimented, like SV40, at 240S and were infectious. The plaque-forming ability of the reconstituted particles was between that of the dissociated components and that of intact SV40. The addition of purified DNA of polyomavirus to the dissociated SV40 before the lowering of the salt concentration showed that virus-like structures could be formed from SV40 proteins and a foreign DNA.     

Nuclear localization of avian polyomavirus structural protein VP1 is a prerequisite for the formation of virus-like particles

Virions of polyomaviruses consist of the major structural protein VP1, the minor structural proteins VP2 and VP3, and the viral genome associated with histones. An additional structural protein, VP4, is present in avian polyomavirus (APV) particles. As it had been reported that expression of APV VP1 in insect cells did not result in the formation of virus-like particles (VLP), the prerequisites for particle formation were analyzed. To this end, recombinant influenza viruses were created to (co)express the structural proteins of APV in chicken embryo cells, permissive for APV replication. VP1 expressed individually or coexpressed with VP4 did not result in VLP formation; both proteins (co)localized in the cytoplasm. Transport of VP1, or the VP1-VP4 complex, into the nucleus was facilitated by the coexpression of VP3 and resulted in the formation of VLP. Accordingly, a mutant APV VP1 carrying the N-terminal nuclear localization signal of simian virus 40 VP1 was transported to the nucleus and assembled into VLP. These results support a model of APV capsid assembly in which complexes of the structural proteins VP1, VP3 (or VP2), and VP4, formed within the cytoplasm, are transported to the nucleus using the nuclear localization signal of VP3 (or VP2); there, capsid formation is induced by the nuclear environment.     

A domain of SV40 capsid polypeptide VP1 that specifies migration into the cell nucleus.

In order to identify the determinants responsible for the nuclear migration of simian virus 40 (SV40) polypeptide VP1, the 5'-terminal portion of the SV40 VP1 gene was fused with the complete cDNA sequence of poliovirus capsid polypeptide VP1 and the hybrid gene was inserted into an SV40 vector in place of the normal SV40 VP1 gene. Deletions of various length were generated in the SV40 VP1 portion of the hybrid gene, resulting in a set of truncated genes encoding 2-40 NH2-terminal amino acids from SV40 VP1, followed by poliovirus VP1. Monkey kidney cells were infected by the deleted hybrid viruses in the presence of an early SV40 amber mutant as helper, and the subcellular localization of the fusion proteins was determined by indirect immunofluorescence using an anti-poliovirus VP1 immune serum. The presence of the first 11 NH2-terminal amino acids from SV40 VP1 was found to be sufficient to target the fusion protein to the cell nucleus. Deletions extending from the NH2- towards the COOH-terminal end of the protein were next generated. Transport of the SV40 VP1-poliovirus VP1 fusion polypeptide to the nucleus was abolished when the first eight amino acids from SV40 VP1 were deleted. Thus the sequence of the first eight NH2-terminal amino acids of SV40 VP1 appears to contain a nuclear migration signal which is sufficient to target the protein to the cell nucleus.     

How viruses access the nucleus

Many viruses depend on nuclear proteins for replication. Therefore, their viral genome must enter the nucleus of the host cell. In this review we briefly summarize the principles of nucleocytoplasmic transport, and then describe the diverse strategies used by viruses to deliver their genomes into the host nucleus. Some of the emerging mechanisms include: (1) nuclear entry during mitosis, when the nuclear envelope is disassembled, (2) viral genome release in the cytoplasm followed by entry of the genome through the nuclear pore complex (NPC), (3) capsid docking at the cytoplasmic side of the NPC, followed by genome release, (4) nuclear entry of intact capsids through the NPC, followed by genome release, and (5) nuclear entry via virus-induced disruption of the nuclear envelope. Which mechanism a particular virus uses depends on the size and structure of the virus, as well as the cellular cues used by the virus to trigger capsid disassembly and genome release. This article is part of a Special Issue entitled: Regulation of Signaling and Cellular Fate through Modulation of Nuclear Protein Import.     

Low pH-dependent endosomal processing of the incoming parvovirus minute virus of mice virion leads to externalization of the VP1 N-terminal sequence (N-VP1), N-VP2 cleavage, and uncoating of the full-length genome

Minute virus of mice (MVM) enters the host cell via receptor-mediated endocytosis. Although endosomal processing is required, its role remains uncertain. In particular, the effect of low endosomal pH on capsid configuration and nuclear delivery of the viral genome is unclear. We have followed the progression and structural transitions of DNA full-virus capsids (FC) and empty capsids (EC) containing the VP1 and VP2 structural proteins and of VP2-only virus-like particles (VLP) during the endosomal trafficking. Three capsid rearrangements were detected in FC: externalization of the VP1 N-terminal sequence (N-VP1), cleavage of the exposed VP2 N-terminal sequence (N-VP2), and uncoating of the full-length genome. All three capsid modifications occurred simultaneously, starting as early as 30 min after internalization, and all of them were blocked by raising the endosomal pH. In particles lacking viral single-stranded DNA (EC and VLP), the N-VP2 was not exposed and thus it was not cleaved. However, the EC did externalize N-VP1 with kinetics similar to those of FC. The bulk of all the incoming particles (FC, EC, and VLP) accumulated in lysosomes without signs of lysosomal membrane destabilization. Inside lysosomes, capsid degradation was not detected, although the uncoated DNA of FC was slowly degraded. Interestingly, at any time postinfection, the amount of structural proteins of the incoming virions accumulating in the nuclear fraction was negligible. These results indicate that during the early endosomal trafficking, the MVM particles are structurally modified by low-pH-dependent mechanisms. Regardless of the structural transitions and protein composition, the majority of the entering viral particles and genomes end in lysosomes, limiting the efficiency of MVM nuclear translocation.