Role of simian virus 40 Vp1 cysteines in virion infectivity

We have developed a new nonoverlapping infectious viral genome (NO-SV40) in order to facilitate structure-based analysis of the simian virus 40 (SV40) life cycle. We first tested the role of cysteine residues in the formation of infectious virions by individually mutating the seven cysteines in the major capsid protein, Vp1. All seven cysteine mutants-C9A, C49A, C87A, C104A, C207S, C254A, and C267L-retained viability. In the crystal structure of SV40, disulfide bridges are formed between certain Cys104 residues on neighboring pentamers. However, our results show that none of these disulfide bonds are required for virion infectivity in culture. We also introduced five different mutations into Cys254, the most strictly conserved cysteine across the polyomavirus family. We found that C254L, C254S, C254G, C254Q, and C254R mutants all showed greatly reduced (around 100,000-fold) plaque-forming ability. These mutants had no apparent defect in viral DNA replication. Mutant Vp1's, as well as wild-type Vp2/3, were mostly localized in the nucleus. Further analysis of the C254L mutant revealed that the mutant Vp1 was able to form pentamers in vitro. DNase I-resistant virion-like particles were present in NO-SV40-C254L-transfected cell lysate, but at about 1/18 the amount in wild-type-transfected lysate. An examination of the three-dimensional structure reveals that Cys254 is buried near the surface of Vp1, so that it cannot form disulfide bonds, and is not involved in intrapentamer interactions, consistent with the normal pentamer formation by the C254L mutant. It is, however, located at a critical junction between three pentamers, on a conserved loop (G2H) that packs against the dual interpentamer Ca(2+)-binding sites and the invading C-terminal helix of an adjacent pentamer. The substitution by the larger side chains is predicted to cause a localized shift in the G2H loop, which may disrupt Ca(2+) ion coordination and the packing of the invading helix, consistent with the defect in virion assembly. Our experimental system thus allows dissection of structure-function relationships during the distinct steps of the SV40 life cycle.     

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.     

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.     

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.     

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.     

A structural rationale for SV40 Vp1 temperature-sensitive mutants and their complementation

Two groups of temperature-sensitive (ts) mutants, termed ts B and ts C, have mutations in the major capsid protein of SV40, Vp1. These mutants have virion assembly defects at the nonpermissive temperature, but can complement one another when two mutants, one from each group, coinfect a cell. A third group of mutants, termed ts BC, have related phenotypes, but do not complement other mutants. We found that the mutations fall into two structural and functional classes. All ts C and one ts BC mutations map to the region close to the Ca2+ binding sites, and are predicted to disrupt the insertion of the distal part of the C-terminal invading arm (C-arm) into the receiving clamp. They share a severe defect in assembly at the nonpermissive temperature, with few capsid proteins attached to the viral minichromosome. By contrast, all ts B and most ts BC mutations map to a contiguous region including acceptor sites for the proximal part of the C-arm and intrapentamer contacts. These mutants form assembly intermediates that carry substantial capsid proteins on the minichromosome. Thus, accurate virion assembly is prevented by mutations that disrupt interactions between the receiving pentamer and both the proximal and distal parts of the C-arms, with the latter having a greater effect. The distinct spatial localization and assembly defects of the two classes of mutants provide a rationale for their intracistronic complementation and suggest models of capsid assembly.     

The SV40 Capsid Is Stabilized by a Conserved Pentapeptide Hinge of the Major Capsid Protein VP1

The simian virus 40 (SV40) outer shell is composed of 72 pentamers of VP1. The core of the VP1 monomer is a β-barrel with jelly-roll topology and extending N- and C-terminal arms. A pentapeptide hinge, KNPYP, tethers the C-arm to the VP1 β-barrel core. The five C-arms that extend from each pentamer insert into the neighbouring pentamers, tying them together through different types of interactions. In the mature virion, this element adopts either of six conformations according to their location in the capsid. We found that the hinge is conserved among 16 members of the Polyomaviridae, attesting to its importance in capsid assembly and/or structure. We have used site-directed mutagenesis to gain an understanding into the structural requirements of this element: Y299 was changed to A, F, and T, and P300 to A and G. The mutants showed reduction in viability to varying degrees. Unexpectedly, assembly was reduced only to a small extent. However, the data showed that the mutants were highly unstable. The largest effect was observed for mutations of P300, indicating a role of the proline in the virion structure. P300G was more unstable than P300A, indicating a requirement for rigidity of the pentapeptide hinge. Y299T and Y299A were more defective in viability than Y299F, highlighting the importance of an aromatic ring at this position. Structural inspection showed that this aromatic ring contacts C-arms of neighbouring pentamers. Computational modelling predicted loss of stability of the Y mutants in concordance with the experimental results. This study provides insights into the structural details of the pentapeptide hinge that are responsible for capsid stability.     

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.     

Association of simian virus 40 vp1 with 70-kilodalton heat shock proteins and viral tumor antigens

Proper folding of newly synthesized viral proteins in the cytoplasm is a prerequisite for the formation of infectious virions. The major capsid protein Vp1 of simian virus 40 forms a series of disulfide-linked intermediates during folding and capsid formation. In addition, we report here that Vp1 is associated with cellular chaperones (HSP70) and a cochaperone (Hsp40) which can be coimmunoprecipitated with Vp1. Studies in vitro demonstrated the ATP-dependent interaction of Vp1 and cellular chaperones. Interestingly, viral cochaperones LT and ST were essential for stable interaction of HSP70 with the core Vp1 pentamer Vp1 (22-303). LT and ST also coimmunoprecipitated with Vp1 in vivo. In addition to these identified (co)chaperones, stable, covalently modified forms of Vp1 were identified for a folding-defective double mutant, C49A-C87A, and may represent a “trapped” assembly intermediate. By a truncation of the carboxyl arm of Vp1 to prevent the Vp1 folding from proceeding beyond pentamers, we detected several apparently modified Vp1 species, some of which were absent in cells transfected with the folding-defective mutant DNA. These results suggest that transient covalent interactions with known or unknown cellular and viral proteins are important in the assembly process.     

The VP2/VP3 minor capsid protein of simian virus 40 promotes the in vitro assembly of the major capsid protein VP1 into particles

The SV40 capsid is composed primarily of 72 pentamers of the VP1 major capsid protein. Although the capsid also contains the minor capsid protein VP2 and its amino-terminally truncated form VP3, their roles in capsid assembly remain unknown. An in vitro assembly system was used to investigate the role of VP2 in the assembly of recombinant VP1 pentamers. Under physiological salt and pH conditions, VP1 alone remained dissociated, and at pH 5.0, it assembled into tubular structures. A stoichiometric amount of VP2 allowed the assembly of VP1 pentamers into spherical particles in a pH range of 7.0 to 4.0. Electron microscopy observation, sucrose gradient sedimentation analysis, and antibody accessibility tests showed that VP2 is incorporated into VP1 particles. The functional domains of VP2 important for VP1 binding and for enhancing VP1 assembly were further explored with a series of VP2 deletion mutants. VP3 also enhanced VP1 assembly, and a region common to VP2 and VP3 (amino acids 119-272) was required to promote VP1 pentamer assembly. These results are relevant for controlling recombinant capsid formation in vitro, which is potentially useful for the in vitro development of SV40 virus vectors.     

Structural analysis of human immunodeficiency virus type 1 Gag protein interactions, using cysteine-specific reagents.

We have examined structural interactions of Gag proteins in human immunodeficiency virus type 1 (HIV-1) particles by utilizing cysteine mutagenesis and cysteine-specific modifying reagents. In immature protease-minus but otherwise wild-type (wt) particles, precursor Pr55Gag proteins did not form intermolecular cystines naturally but could be cross-linked at cysteines, and cross-linking appeared to occur across nucleocapsid (NC) domains. Capsid (CA) proteins in wt mature viruses possess cysteines near their carboxy termini at gag codons 330 and 350, but these residues are not involved in natural covalent intermolecular bonds, nor can they be intermolecularly cross-linked by using the membrane-permeable cross-linker bis-maleimido hexane. The cysteine at gag codon 350 (C-350) is highly reactive to thiol-specific modifying reagents, while the one at codon 330 (C-330) appears considerably less reactive, even in the presence of ionic detergent. These results suggest that the HIV-1 CA C terminus forms an unusually stable conformation. Mutagenesis of C-350 to a serine residue in the mutant C350S (C-350 changed to serine) virtually eliminated particle assembly, attesting to the importance of this region. We also examined a C330S mutant, as well as mutants in which cysteines were created midway through the capsid domain or in the C-terminal section of the major homology region. All such mutants appeared wt on the basis of biochemical assays but showed greatly reduced infectivities, indicative of a postassembly, postprocessing replicative block. Interestingly, capsid proteins of mature major homology region mutant particles could be cysteine cross-linked, implying either that these mutations permit cross-linking of the native C-terminal CA cysteines or that major homology regions on neighbor capsid proteins are in close proximity in mature virions.     

JC virus minor capsid proteins Vp2 and Vp3 are essential for virus propagation

Virus-encoded capsid proteins play a major role in the life cycles of all viruses. The JC virus capsid is composed of 72 pentamers of the major capsid protein Vp1, with one of the minor coat proteins Vp2 or Vp3 in the center of each pentamer. Vp3 is identical to two-thirds of Vp2, and these proteins share a DNA binding domain, a nuclear localization signal, and a Vp1-interacting domain. We demonstrate here that both the minor proteins and the myristylation site on Vp2 are essential for the viral life cycle, including the proper packaging of its genome.     

Interaction of a nuclear factor-1-like protein with the regulatory region of the human polyomavirus JC virus

We have initiated a study to identify host proteins which interact with the regulatory region of the human polyomavirus JC (JCV), which is associated with the demyelinating disease, progressive multifocal leukoencephalopathy. We examined the interaction of nuclear proteins prepared from different cell lines with the JCV regulatory region by DNA binding gel retardation assays. Binding was detected with nuclear extracts prepared from human fetal glial cells, glioma cells, and HeLa cells. Little or no binding was detected with nuclear extracts prepared from human embryonic kidney cells. Competitive binding assays suggest that the nuclear factor(s) which interacted with the JCV regulatory region was different from those which interacted with the regulatory region of the closely related polyomavirus SV40. We found three areas in the JCV regulatory region protected from DNase I digestion: site A, located just upstream from the TATA sequence in the first 98-base pair (bp) repeat; site B, located upstream from the TATA sequence in the second 98-bp repeat; and site C, located just following the second 98-bp repeat. There were some differences in the ability of the nuclear factor(s) from the two brain cell lines and HeLa cells to completely protect the nucleotides within the footprint region. The results from the DNase I protective studies and competitive DNA binding studies with specific oligonucleotides, suggest that nuclear factor-1 or a nuclear factor-1-like factor is interacting with all three sites in the JCV regulatory region. In addition, the results suggest that the nuclear factor which interacts with the JCV regulatory region from human brain cell lines is different from the factor found in HeLa cells.     

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.     

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 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 Role of Cysteine Residues in Redox Regulation and Protein Stability of Arabidopsis thaliana Starch Synthase 1

Starch biosynthesis in Arabidopsis thaliana is strictly regulated. In leaf extracts, starch synthase 1 (AtSS1) responds to the redox potential within a physiologically relevant range. This study presents data testing two main hypotheses: 1) that specific thiol-disulfide exchange in AtSS1 influences its catalytic function 2) that each conserved Cys residue has an impact on AtSS1 catalysis. Recombinant AtSS1 versions carrying combinations of cysteine-to-serine substitutions were generated and characterized in vitro. The results demonstrate that AtSS1 is activated and deactivated by the physiological redox transmitters thioredoxin f1 (Trxf1), thioredoxin m4 (Trxm4) and the bifunctional NADPH-dependent thioredoxin reductase C (NTRC). AtSS1 displayed an activity change within the physiologically relevant redox range, with a midpoint potential equal to -306 mV, suggesting that AtSS1 is in the reduced and active form during the day with active photosynthesis. Cys164 and Cys545 were the key cysteine residues involved in regulatory disulfide formation upon oxidation. A C164S_C545S double mutant had considerably decreased redox sensitivity as compared to wild type AtSS1 (30% vs 77%). Michaelis-Menten kinetics and molecular modeling suggest that both cysteines play important roles in enzyme catalysis, namely, Cys545 is involved in ADP-glucose binding and Cys164 is involved in acceptor binding. All the other single mutants had essentially complete redox sensitivity (98–99%). In addition of being part of a redox directed activity “light switch”, reactivation tests and low heterologous expression levels indicate that specific cysteine residues might play additional roles. Specifically, Cys265 in combination with Cys164 can be involved in proper protein folding or/and stabilization of translated protein prior to its transport into the plastid. Cys442 can play an important role in enzyme stability upon oxidation. The physiological and phylogenetic relevance of these findings is discussed.     

Isolation, propagation and characterization of replication requirements of reiteration mutants of Simian Virus 40.

We have identified five reiteration mutants from serially-propagated, defective stocks of Simian Virus 40 and DAR virus (an SV40³ variant of human origin). The genomes of these mutants contain tandem repeats of specific segments of the SV40 genome. In order to propagate individual reiteration mutants, the monomer DNA segments from the mutant genomes are separated from wild-type SV40 DNA after cleavage by certain bacterial restriction endonucleases which produce short cohesive termini at their cleavage sites. These monomer segments, which are one-third, one-fourth, or one-fifth the size of wild-type SV40 DNA, are then circularized in vitro using bacteriophage T4 polynucleotide ligase and used to infect African green monkey kidney cells in the presence of wild-type or temperature-sensitive mutant DNAs as helpers. While wild-type SV40 and late temperature-sensitive mutants can serve as helpers in the replication and amplification of these minicircular DNAs, early temperature-sensitive mutant genomes are unable to do so at the nonpermissive temperature. The minicircular DNAs are amplified in vivo through an arithmetic series of oligomers. Encapsidation of reiterated molecules between 70 and 100% the size of wild-type SV40 DNA is observed, although reiterated viral DNA molecules much larger than unit size are formed in vivo.     

A Structure-Guided Mutation in the Major Capsid Protein Retargets BK Polyomavirus

Viruses within a family often vary in their cellular tropism and pathogenicity. In many cases, these variations are due to viruses switching their specificity from one cell surface receptor to another. The structural requirements that underlie such receptor switching are not well understood especially for carbohydrate-binding viruses, as methods capable of structure-specificity studies are only relatively recently being developed for carbohydrates. We have characterized the receptor specificity, structure and infectivity of the human polyomavirus BKPyV, the causative agent of polyomavirus-associated nephropathy, and uncover a molecular switch for binding different carbohydrate receptors. We show that the b-series gangliosides GD3, GD2, GD1b and GT1b all can serve as receptors for BKPyV. The crystal structure of the BKPyV capsid protein VP1 in complex with GD3 reveals contacts with two sialic acid moieties in the receptor, providing a basis for the observed specificity. Comparison with the structure of simian virus 40 (SV40) VP1 bound to ganglioside GM1 identifies the amino acid at position 68 as a determinant of specificity. Mutation of this residue from lysine in BKPyV to serine in SV40 switches the receptor specificity of BKPyV from GD3 to GM1 both in vitro and in cell culture. Our findings highlight the plasticity of viral receptor binding sites and form a template to retarget viruses to different receptors and cell types.