Virus replication in engineered human cells that do not respond to interferons

The V protein of the paramyxovirus simian virus 5 blocks interferon (IFN) signaling by targeting STAT1 for proteasome-mediated degradation. Here we report on the isolation of human cell lines that express the V protein and can no longer respond to IFN. A variety of viruses, particularly slow-growing wild-type viruses and vaccine candidate viruses (which are attenuated due to mutations that affect virus replication, virus spread, or ability to circumvent the IFN response), form bigger plaques and grow to titers that are increased as much as 10- to 4,000-fold in these IFN-nonresponsive cells. We discuss the practical applications of using such cells in vaccine development and manufacture, virus diagnostics and isolation of newly emerging viruses, and studies on host cell tropism and pathogenesis.

The V proteins of simian virus 5 and other paramyxoviruses inhibit induction of interferon-beta

In this article we show that the paramyxovirus SV5 is a poor inducer of interferon-beta (IFN-beta). This inefficient induction is a consequence of the expression of an intact viral V protein. In the absence of the viral V protein cysteine-rich C-terminal domain, IFN-beta mRNA is strongly induced and the transcription factors NF-kappaB and IRF-3 are activated significantly. The V protein can work in isolation from SV5 to block intracellular dsRNA signaling. The mechanism of block to dsRNA signaling is distinct from that previously observed for blocking IFN signaling in that proteolysis of candidate factors cannot be detected, and furthermore, the respective blocks require distinct protein domains. Blocking of the induction of IFN-beta by dsRNA requires the C-terminal cysteine-rich domain, a feature that is highly conserved among paramyxoviruses. We demonstrate that the V proteins from other paramyxoviruses have equivalent functions and speculate that limiting the yield of IFN-beta during infection may be a general property of paramyxoviruses.

Recovery of paramyxovirus simian virus 5 with a V protein lacking the conserved cysteine-rich domain: the multifunctional V protein blocks both interferon-beta induction and interferon signaling

The V protein of the Paramyxovirus simian virus 5 (SV5) is a multifunctional protein containing an N-terminal 164 residue domain that is shared with the P protein and a distinct C-terminal domain that is cysteine-rich and which is highly conserved among Paramyxoviruses. We report the recovery from Vero cells [interferon (IFN) nonproducing cells] of a recombinant SV5 (rSV5) that lacks the V protein C-terminal specific domain (rSV5VDeltaC). In Vero cells rSV5VDeltaC forms large plaques and grows at a rate and titer similar to those of rSV5. In BHK or CV-1 cells rSV5VDeltaC forms small plaques and grows poorly. However, even when grown in Vero cells rSV5VDeltaC reverts to pseudo-wild-type virus in four to five passages, indicating the importance of the V protein for successful replication of SV5. Whereas rSV5 grows in many cell types with minimal cytopathic effect (CPE), rSV5VDeltaC causes extensive CPE in the same cell types. To overcome the antiviral state induced by IFN, many viruses have evolved mechanisms to counteract the effects of IFN by blocking the production of IFN and abrogating IFN signaling. Whereas rSV5 blocks IFN signaling by mediating the degradation of STAT1, rSV5VDeltaC does not cause the degradation of STAT1 and IFN signaling occurs through formation of the ISGF3 transcription complex. Furthermore, we find that rSV5 infection of cells prevents production of IFN-beta. The transcription factor IRF-3 which is required for transcription of the IFN-beta gene is not translocated from the cytoplasm to the nucleus in rSV5-infected cells. In contrast, in rSV5VDeltaC-infected cells IRF-3 is localized predominantly in the nucleus and IFN-beta is produced. By using ectopic expression of IRF-3, it was shown that after dsRNA treatment and expression of the V protein IRF-3 remained in the cytoplasm, whereas after dsRNA treatment and expression of the P protein (which lacks the C-terminal cysteine-rich domain) IRF-3 was localized predominantly in the nucleus. Thus, SV5 blocks two distinct pathways of the innate immune response, both of which require the presence of the C-terminal specific cysteine-rich domain of the multifunctional SV5 V protein.

The p127 subunit (DDB1) of the UV-DNA damage repair binding protein is essential for the targeted degradation of STAT1 by the V protein of the paramyxovirus simian virus 5

The V protein of simian virus 5 (SV5) blocks interferon signaling by targeting STAT1 for proteasome-mediated degradation. Here we present three main pieces of evidence which demonstrate that the p127 subunit (DDB1) of the UV damage-specific DNA binding protein (DDB) plays a central role in this degradation process. First, the V protein of an SV5 mutant which fails to target STAT1 for degradation does not bind DDB1. Second, mutations in the N and C termini of V which abolish the binding of V to DDB1 also prevent V from blocking interferon (IFN) signaling. Third, treatment of HeLa/SV5-V cells, which constitutively express the V protein of SV5 and thus lack STAT1, with short interfering RNAs specific for DDB1 resulted in a reduction in DDB1 levels with a concomitant increase in STAT1 levels and a restoration of IFN signaling. Furthermore, STAT1 is degraded in GM02415 (2RO) cells, which have a mutation in DDB2 (the p48 subunit of DDB) which abolishes its ability to interact with DDB1, thereby demonstrating that the role of DDB1 in STAT1 degradation is independent of its association with DDB2. Evidence is also presented which demonstrates that STAT2 is required for the degradation of STAT1 by SV5. These results suggest that DDB1, STAT1, STAT2, and V may form part of a large multiprotein complex which leads to the targeted degradation of STAT1 by the proteasome.

Bunyamwera bunyavirus nonstructural protein NSs counteracts the induction of alpha/beta interferon

Production of alpha/beta interferons (IFN-alpha/beta) in response to viral infection is one of the main defense mechanisms of the innate immune system. Many viruses therefore encode factors that subvert the IFN system to enhance their virulence. Bunyamwera virus (BUN) is the prototype of the Bunyaviridae family. By using reverse genetics, we previously produced a recombinant virus lacking the nonstructural protein NSs (BUNdelNSs) and showed that NSs is a nonessential gene product that contributes to viral pathogenesis. Here we demonstrate that BUNdelNSs is a strong inducer of IFN-alpha/beta, whereas in cells infected with the wild-type counterpart expressing NSs (wild-type BUN), neither IFN nor IFN mRNA could be detected. IFN induction by BUNdelNSs correlated with activation of NF-kappaB and was dependent on virally produced double-stranded RNA and on the IFN transcription factor IRF-3. Furthermore, both in cultured cells and in mice lacking a functional IFN-alpha/beta system, BUNdelNSs replicated to wild-type BUN levels, whereas in IFN-competent systems, wild-type BUN grew more efficiently. These results suggest that BUN NSs is an IFN induction antagonist that blocks the transcriptional activation of IFN-alpha/beta in order to increase the virulence of Bunyamwera virus.

Degradation of STAT1 and STAT2 by the V proteins of simian virus 5 and human parainfluenza virus type 2, respectively: consequences for virus replication in the presence of alpha/beta and gamma interferons

Human cell lines were isolated that express the V protein of either simian virus 5 (SV5) or human parainfluenza virus type 2 (hPIV2); the cell lines were termed 2f/SV5-V and 2f/PIV2-V, respectively. STAT1 was not detectable in 2f/SV5-V cells, and the cells failed to signal in response to either alpha/beta interferons (IFN-alpha and IFN-beta, or IFN-alpha/beta) or gamma interferon (IFN-gamma). In contrast, STAT2 was absent from 2f/PIV2-V cells, and IFN-alpha/beta but not IFN-gamma signaling was blocked in these cells. Treatment of both 2f/SV5-V and 2f/PIV2-V cells with a proteasome inhibitor allowed the respective STAT levels to accumulate at rates similar to those seen in 2fTGH cells, indicating that the V proteins target the STATs for proteasomal degradation. Infection with SV5 can lead to a complete loss of both phosphorylated and nonphosphorylated forms of STAT1 by 6 h postinfection. Since the turnover of STAT1 in uninfected cells is longer than 24 h, we conclude that degradation of STAT1 is the main mechanism by which SV5 blocks interferon (IFN) signaling. Pretreatment of 2fTGH cells with IFN-alpha severely inhibited both SV5 and hPIV2 protein synthesis. However, and in marked contrast, pretreatment of 2fTGH cells with IFN-gamma had little obvious effect on SV5 protein synthesis but did significantly reduce the replication of hPIV2. Pretreament with IFN-alpha or IFN-gamma did not induce an antiviral state in 2f/SV5-V cells, indicating either that the induction of an antiviral state is completely dependent on STAT signaling or that the V protein interferes with other, STAT-independent cell signaling pathways that may be induced by IFNs. Even though SV5 blocked IFN signaling, the addition of exogenous IFN-alpha to the culture medium of 2fTGH cells 12 h after a low-multiplicity infection with SV5 significantly reduced the subsequent cell-to-cell spread of virus. The significance of the results in terms of the strategy that these viruses have evolved to circumvent the IFN response is discussed.

Differences in interferon sensitivity and biological properties of two related isolates of simian virus 5: a model for virus persistence

CPI(+) and CPI(-) are two canine isolates of simian virus 5 (SV5). CPI(+) was originally isolated from the cerebrospinal fluid of a dog with temporary posterior paralysis and CPI(-) was recovered at 12 days p.i. from the brain tissue of a dog experimentally infected with CPI(+). We have previously shown that the V protein of SV5 blocks interferon (IFN) signalling by targeting STAT1 for degradation. Here we report that whilst CPI(+) targets STAT1 for degradation, CPI(-) fails to and as a consequence, CPI(+) blocks IFN signalling but CPI(-) does not. Three amino acid differences in the P/V N-terminal common domain of the V protein are responsible for the observed difference in the abilities of CPI(+) and CPI(-) to block IFN signalling. In cells persistently infected with CPI(-) the virus may become repressed in response to IFN, under which circumstances virus glycoproteins are lost from the surface of infected cells and virus nucleocapsid proteins accumulate in cytoplasmic inclusion bodies. We suggest that in vivo cells infected with IFN-resistant viruses (in which there would be continuous virus protein synthesis) may be more susceptible to killing by cytotoxic T cells than cells infected with IFN-sensitive viruses (in which virus protein synthesis was repressed), and a model of virus persistence is put forward in which there is alternating selection of IFN-resistant and IFN-sensitive viruses depending upon the state of the adaptive immune response.

Single amino acid substitution in the V protein of simian virus 5 differentiates its ability to block interferon signaling in human and murine cells

Previous work has demonstrated that the V protein of simian virus 5 (SV5) targets STAT1 for proteasome-mediated degradation (thereby blocking interferon [IFN] signaling) in human but not in murine cells. In murine BF cells, SV5 establishes a low-grade persistent infection in which the virus fluxes between active and repressed states in response to local production of IFN. Upon passage of persistently infected BF cells, virus mutants were selected that were better able to replicate in murine cells than the parental W3 strain of SV5 (wild type [wt]). Viruses with mutations in the Pk region of the N-terminal domain of the V protein came to predominate the population of viruses carried in the persistently infected cell cultures. One of these mutant viruses, termed SV5 mci-2, was isolated. Sequence analysis of the V/P gene of SV5 mci-2 revealed two nucleotide differences compared to wt SV5, only one of which resulted in an amino acid substitution (asparagine [N], residue 100, to aspartic acid [D]) in V. Unlike the protein of wt SV5, the V protein of SV5 mci-2 blocked IFN signaling in murine cells. Since the SV5 mci-2 virus had additional mutations in genes other than the V/P gene, a recombinant virus (termed rSV5-V/P N(100)D) was constructed that contained this substitution alone within the wt SV5 backbone to evaluate what effect the asparagine-to-aspartic-acid substitution in V had on the virus phenotype. In contrast to wt SV5, rSV5-V/P N(100)D blocked IFN signaling in murine cells. Furthermore, rSV5-V/P N(100)D virus protein synthesis in BF cells continued for significantly longer periods than that for wt SV5. However, even in cells infected with rSV5-V/P N(100)D, there was a late, but significant, inhibition in virus protein synthesis. Nevertheless, there was an increase in virus yield from BF cells infected with rSV5-V/P N(100)D compared to wt SV5, demonstrating a clear selective advantage to SV5 in being able to block IFN signaling in these cells.

Paramyxoviridae use distinct virus-specific mechanisms to circumvent the interferon response

STAT1 and STAT2 are cellular transcription factors involved in interferon (IFN) signaling and are thus critical for the IFN-induced antiviral state. We have previously shown that the paramyxovirus Simian Virus 5 (SV5) blocks both type I and type II interferon (IFN) signaling by targeting STAT1 for proteasome-mediated degradation. To determine whether this is a feature common to all Paramyxoviridae, we examined the abilities of SV5, Sendai virus (SeV), human respiratory syncytial virus (RSV), and human parainfluenza viruses types 2 and 3 (hPIV2 and hPIV3, respectively) to block interferon signaling. The results showed that in reporter assays SV5, SeV, and hPIV3 blocked both type I and type II IFN-signaling; hPIV2 blocked type I but not type II IFN-signaling; and RSV failed to block either type I or type II IFN-signaling. In agreement with these results, SV5 and SeV inhibited the formation of the ISGF3 and GAF transcription complexes (essential for type I and type II signaling, respectively). Surprisingly, although hPIV3 inhibited IFN-induction of the ISGF3 complex, GAF complexes were detected in hPIV3-infected cells. hPIV2 also blocked the formation of the ISGF3 complex but not the GAF complex, whereas RSV failed to block the induction of either complex. SV5 was the only virus that caused the degradation of STAT1. Indeed, in SeV- and hPIV3-infected cells STAT1 was phosphorylated on tyrosine 701 (Y701), a characteristic of IFN receptor activation. However, consistent with these viruses blocking IFN signaling downstream of receptor activation, there was a specific reduction in the levels of serine 727 (S727)-phosphorylated forms of STAT1alpha in SeV- and hPIV3-infected cells. In contrast both (Y701)- and (S727)-phosphorylated forms of STAT1 were detected in hPIV2-infected cells but there was a specific loss of STAT2. Both STAT1 (including Y701- and S727-phosphorylated forms) and STAT2 could readily be detected in RSV-infected cells. Despite not being able to block type I or type II IFN signaling, RSV was able to replicate in human cells that produce and respond to IFN, suggesting that RSV must have an alternative method(s) for circumventing the IFN response. These results demonstrate that, although interference with IFN signaling is a common strategy among Paramyxovirinae, distinct virus-specific mechanisms are used to achieve this end.

The V protein of simian virus 5 inhibits interferon signalling by targeting STAT1 for proteasome-mediated degradation

To replicate in vivo, viruses must circumvent cellular antiviral defense mechanisms, including those induced by the interferons (IFNs). Here we demonstrate that simian virus 5 (SV5) blocks IFN signalling in human cells by inhibiting the formation of the IFN-stimulated gene factor 3 and gamma-activated factor transcription complexes that are involved in activating IFN-alpha/beta- and IFN-gamma-responsive genes, respectively. SV5 inhibits the formation of these complexes by specifically targeting STAT1, a component common to both transcription complexes, for proteasome-mediated degradation. Expression of the SV5 structural protein V, in the absence of other virus proteins, also inhibited IFN signalling and induced the degradation of STAT1. Following infection with SV5, STAT1 was degraded in the absence of virus protein synthesis and remained undetectable for up to 4 days postinfection. Furthermore, STAT1 was also degraded in IFN-pretreated cells, even though the cells were in an antiviral state. Since pretreatment of cells with IFN delayed but did not prevent virus replication and protein synthesis, these observations suggest that following infection of IFN-pretreated cells, SV5 remains viable within the cells until they eventually go out of the antiviral state.

Fine mapping of the binding sites of monoclonal antibodies raised against the Pk tag

The monoclonal antibody (mAb) SV5-Pk is used widely in a variety of procedures to detect recombinant proteins tagged with the Pk tag, a 14 amino acid sequence derived from the P and V proteins of the paramyxovirus Simian Virus 5. Here we report on the isolation and characterisation of four additional SV5-Pk mAbs (termed SV5-Pk2 to 5) that bind the Pk tag. All the SV5-Pk mAbs can detect Pk tagged recombinant proteins in a variety of immunological procedures, including ELISA and immunofluorescence. Using SPOT technology, the minimal binding epitope of each SV5-Pk mAb was defined by one-sided terminal truncation analysis from either the amino- or carboxy-ends of the Pk peptide. Each mAb recognises slightly different epitopes within the Pk tag, ranging from 5 to 9 amino acids in length. The equilibrium dissociation constants (Kd) of the mAbs, as measured by surface plasmon resonance, ranged from approximately 20 to 60 pmol. Cysteine scanner mutations throughout the Pk tag revealed that some amino acids within the minimal binding epitopes were critical for mAb binding, while others could readily be substituted with little or no effect on antibody binding. The development of the Pk tag as a spacer arm for site-directed chemical coupling, and the use of the mAbs to monitor purification and coupling procedures, is discussed.

Sendai virus and simian virus 5 block activation of interferon-responsive genes: importance for virus pathogenesis

Sendai virus (SeV) is highly pathogenic for mice. In contrast, mice (including SCID mice) infected with simian virus 5 (SV5) showed no overt signs of disease. Evidence is presented that a major factor which prevented SV5 from productively infecting mice was its inability to circumvent the interferon (IFN) response in mice. Thus, in murine cells that produce and respond to IFN, SV5 protein synthesis was rapidly switched off. In marked contrast, once SeV protein synthesis began, it continued, even if the culture medium was supplemented with alpha/beta IFN (IFN-alpha/beta). However, in human cells, IFN-alpha/beta did not inhibit the replication of either SV5 or SeV once virus protein synthesis was established. To begin to address the molecular basis for these observations, the effects of SeV and SV5 infections on the activation of an IFN-alpha/beta-responsive promoter and on that of the IFN-beta promoter were examined in transient transfection experiments. The results demonstrated that (i) SeV, but not SV5, inhibited an IFN-alpha/beta-responsive promoter in murine cells; (ii) both SV5 and SeV inhibited the activation of an IFN-alpha/beta-responsive promoter in human cells; and (iii) in both human and murine cells, SeV was a strong inducer of the IFN-beta promoter, whereas SV5 was a poor inducer. The ability of SeV and SV5 to inhibit the activation of IFN-responsive genes in human cells was confirmed by RNase protection experiments. The importance of these results in terms of paramyxovirus pathogenesis is discussed.

Novel modifications to the C-terminus of LTB that facilitate site-directed chemical coupling of antigens and the development of LTB as a carrier for mucosal vaccines

To facilitate site-directed chemical coupling of antigens to the heat labile enterotoxin B subunit of Escherichia coli (LTB), a series of genetically modified fusion proteins of LTB were constructed. The LTB fusion proteins had modified versions of a short (14 amino acid) spacer epitope called the Pk tag attached at their C termini. The LTB-Pk.cys mutants differed from each other in the position of a single cysteine residue within the Pk tag. The presence of a cysteine residue at any position within the Pk spacer tag did not prevent the LTB-Pk.cys proteins from forming pentamers or binding to GM1 gangliosides, but the position of the cysteine had variable impact on the yield of the fusion proteins. Following site-directed chemical coupling of antigens to the cysteine residue within the Pk tag, the LTB antigen conjugates retained their ability to bind GM1 on the surface of eukaryotic cells. Intranasal immunisation of mice with an experimental antigen (HRP) chemically linked to LTB-Pk.cys induced high levels of anti-HRP antibodies that could be detected in the serum, saliva and nasal and lung washes. No antibody responses to HRP were detected when HRP was co-administered with, but not linked to, LTB-Pk.cys.

Vectors for the expression of tagged proteins in Schizosaccharomyces pombe

A series of vectors is described which enables the episomal expression of proteins fused to different tag sequences in Schizosaccharomyces pombe. Proteins can be expressed with their amino termini fused to GFP/EGFP, three copies of the HA or Pk epitopes or a combined tag which contains two copies of the myc epitope and six histidine residues (MH). Fusion of the carboxyl terminus of a protein to a tag is possible with GFP/EGFP or Pk. Expression of the fusion proteins is controlled by the medium strength mutant version of the regulatable nmt1 promoter.

Isolation of highly fusogenic variants of simian virus 5 from persistently infected cells that produce and respond to interferon

A series of experiments were undertaken to examine how interferon and neutralizing antibodies influence the ability of simian virus 5 (SV5) (strain W3) to establish and maintain persistent infections in murine cells. In contrast to the rapid decline in SV5 protein synthesis observed in murine BALB/c fibroblasts (BF cells), which produce and respond to interferon, between 24 and 48 h postinfection there was no inhibition of virus protein synthesis in MSFI- cells, skin fibroblasts derived from alpha/beta-interferon receptor knockout BALB/c mice. Furthermore, the addition of anti-interferon antibodies to the culture medium of infected BF cells significantly reduced the observed decline in virus protein synthesis. Following infection of untreated BF cells, the majority replicated virus but survived the infection and eventually cleared the virus after 8 to 15 days. However, not all the cells were cured, and the cultures became persistently infected. Upon passage of persistently infected cultures, the virus fluxed between active and repressed states as a consequence of interferon production. This resulted in a balance being reached in which only 5 to 20% of the cells were infected at any one time. After 30 passages of the persistently infected cells, highly fusogenic virus variants arose (one of which was isolated and termed W3-f). W3-f remained as sensitive to interferon as the parental W3 isolate but, in the absence of interferon, spread much more rapidly than the parental W3 strain through BF cell monolayers. Sequence analysis revealed no deduced amino acid differences between the F proteins of W3 and W3-f. BF cell cultures persistently infected with W3-f were rapidly cleared of virus by the addition of virus-neutralizing antibodies to the culture medium. In contrast, neutralizing antibodies had little effect on the numbers of cells persistently infected with W3 over several passages. These results suggest that the ability of paramyxoviruses to cause cell-cell fusion may be selected for in vivo as a consequence of their adaptation to the interferon response rather than their need to escape from neutralizing antibodies. The significance of these observations with regard to persistent parainfluenza virus infections in vivo is further discussed.

NP:P and NP:V interactions of the paramyxovirus simian virus 5 examined using a novel protein:protein capture assay

Using recombinant proteins extracted from mammalian cells, in a novel protein:protein binding assay, direct interaction of the nucleoprotein (NP) of simian virus 5 with the phosphoprotein (P) and V protein (V) was demonstrated. The amount of NP bound by V was found to be significantly less than that bound by P. Furthermore, preabsorption of NP with P removed the fraction of NP that could be bound by V, but preabsorption of NP with V did not remove all the NP that could be bound by P. These results suggested that V bound a subpopulation of the NP recognised by P. Further analysis revealed that P bound both soluble and homopolymeric forms of NP, while V bound only the soluble form; thus demonstrating that the binding sites on P and V, for soluble NP, are located within the N-terminal domain common to both P and V proteins. A monoclonal antibody, which recognised an epitope in the unique C-terminus of P, blocked the binding of P to polymeric NP but not to soluble NP. These results also suggest that there are two binding sites on NP for P, the site that interacts with the P/V common domain being either hidden or conformationally altered in polymeric NP.

Construction, purification and immunogenicity of antigen-antibody-LTB complexes

An oligonucleotide, encoding a short epitope peptide tag, termed Pk, was inserted at the 3'-end of the gene coding B-subunit of Escherichia coli heat-labile enterotoxin (LTB). The presence of the Pk epitope on LTB-Pk was used to construct novel macromolecular assemblies comprising LTB-Pk, an anti-Pk mAb, (mAb SV5-P-k) and Pk-linked recombinant SIV proteins. The 1:1:1 stoichiometry of such complexes was ensured by binding LTB-Pk to one arm of mAb SV5-P-k and an SIV-Pk antigen to the other arm of the antibody. Such SIV-mAb-LTB macromolecular complexes bound to GM1-ganglioside in vitro, and when immunized systemically into mice were highly immunogenic, inducing both humoral and cell-mediated responses to the recombinant SIV antigens.

Inducible expression of the P, V, and NP genes of the paramyxovirus simian virus 5 in cell lines and an examination of NP-P and NP-V interactions

The P, V, and NP genes of the paramyxovirus simian virus 5 (SV5) were cloned such that their expression was regulated by the tetracycline-controlled transactivator (M. Gossen and H. Bujard, Proc. Natl. Acad. Sci. USA 89:5547-5551, 1992), and mammalian cell lines that inducibly expressed individually the P, V, or NP protein or coexpressed the P plus NP or V plus NP proteins were isolated. A plasmid that expresses the tetracycline-controlled transactivator linked, via the foot-and-mouth disease virus 2A cleavage peptide sequence, to the neomycin aminoglycoside phosphotransferase gene was constructed. Cells were cotransfected with this plasmid, and the appropriate responder plasmids and clonies were selected on the basis of their resistance to Geneticin (via the neomycin aminoglycoside phosphotransferase gene). The properties of these cell lines, in terms of the induction of the P, V, and NP genes, are described in detail. Both the P and V proteins were phosphorylated when expressed alone. In immunoprecipitation studies using a monoclonal antibody that recognizes both the P and V proteins, a nonphosphorylated host cell protein with an estimated molecular weight of 150,000 was coprecipitated with V but not P. Immunofluorescence data demonstrated that when expressed separately, the P protein had a diffuse cytoplasmic distribution, but the related V protein had both a nuclear and cytoplasmic distribution. The NP protein had a granular cytoplasmic distribution, giving rise to punctate and granular fluorescence. Coexpression of the NP and P proteins resulted in the accumulation of large cytoplasmic inclusion aggregates, similar to those visualized at late times in SV5-infected cells. Coexpression of V with NP led to a partial redistribution of the NP protein in that the NP protein had both a diffuse cytoplasmic and nuclear distribution in the presence of V, but no NP-V aggregates or inclusion bodies were visualized. Direct binding studies also revealed that NP bound to both P and V. For SV5, these studies suggest that V may have a role in keeping NP soluble prior to encapsidation.

Attachment of an oligopeptide epitope to the C-terminus of recombinant SIV gp160 facilitates the construction of SMAA complexes while preserving CD4 binding

A small 14 amino acid oligopeptide tag (termed SV5-Pk) was fused onto the carboxy-terminus of simian immunodeficiency virus gp160 expressed from a recombinant baculovirus. The presence of the Pk tag had no obvious effect on the expression and glycosylation of gp160 and did not interfere either with CD4 binding or with cleavage at its maturation site by the protease furin. The presence of the Pk tag did, however, facilitate the simplified purification of full-length gp160 and its incorporation into immunogenic solid matrix-antibody-antigen (SMAA) complexes.

Evidence that the paramyxovirus simian virus 5 can establish quiescent infections by remaining inactive in cytoplasmic inclusion bodies

Following infection of BALB/c fibroblastic (BF) cells with simian virus 5 (SV5) only low levels of infectious virus were produced and the majority of cells survived the infection. However at 1 day post-infection (p.i.), near normal levels of all the virus proteins were synthesized and the virus genome was replicated. RNA analysis of the infected cells revealed that the levels of viral genomic RNA remained high over 5 days of infection, but that viral mRNA levels were significantly reduced by 3 days p.i. There was no evidence for the accumulation of defective genomes over this period. The reduction in mRNA levels was reflected by a concomitant decrease in the rate of ongoing viral protein synthesis. Despite the apparent decrease in viral transcription, comparative measurements of the relative levels of the different virus proteins at various times p.i. revealed that the levels of the P and NP proteins were similar at 1 and 5 days p.i. but the levels of V, M and F declined. Immunofluorescence analysis supported this data showing that at later times p.i., although there were some cells which were positive for all the viral proteins, a high proportion of cells were strongly positive for NP and P but negative for M, F and HN proteins. In these cells, NP and P were often located in discrete cytoplasmic foci. A series of cell lines were established from BF cells that had been infected at high multiplicity. Immunofluorescence studies showed that only a minority of cells in these cell lines were infected. This suggests that upon cell division, in a proportion of cells, virus replication was not taking place; otherwise it would be expected that all the daughter cells would remain infected. However, upon co-cultivation of these cells with Vero cells (cells that are fully permissive for SV5 replication), non-defective virus could be recovered. Virus cytoplasmic inclusion bodies could still be detected in a small proportion of BF cells that had been infected at high m.o.i. and passaged 10 times over a 12 week period, and again low levels of infectious virus could be recovered from these cells. It is proposed that in these persistently infected cells, the majority of virus genomes reside in an inactive form in cytoplasmic inclusion bodies but from which virus may occasionally be reactivated.(ABSTRACT TRUNCATED AT 400 WORDS)

Expression and purification of nonglycosylated SIV proteins, and their use in induction and detection of SIV-specific immune responses

Two commercially available expression vectors were modified to generate plasmids pGEXcPk and pQ9cPk. Proteins expressed from pGEXcPk and pQ9cPk had a short oligopeptide tag termed Pk at their carboxy termini and either glutathione S-transferase (GST) or a small histidine (His) tag, respectively, at their N termini. GST fusion proteins can be purified on immobilized glutathione and proteins coupled to the His tag selectively bind to Ni(2+)-NTA columns. The Pk tag is recognized by monoclonal antibody (MAb) SV5-P-k, previously produced in our laboratory. Thus proteins expressed from the pGEXcPk and pQ9cPk vectors can be purified in a two-step procedure, first via the N-terminal tag and second via the C-terminal tag. The combination of two affinity purification steps significantly improves the antigen purity and selects for full-size proteins. Moreover, by using the MAbSV5-P-k in the second purification step, Pk-linked antigens can be assembled directly into solid matrix-antibody-antigen (SMAA) complexes for use as vaccines. The genes for nef, endonuclease, p15, p17, p27, protease, Rev, reverse transcriptase (rt), tat, vif, vpr, and vpx of simian immunodeficiency virus (SIV mac 251) were cloned and expressed as both GST-SIV-Pk and His-SIV-Pk proteins. Multivalent SMAA complexes were made that contained His-p17-Pk, His-p27-Pk, His-rt-Pk, His-vpx-Pk, and His-vpr-Pk. Following two immunizations of mice with this mixture, antibodies could be detected to all five SIV antigens. When compared to single-protein immunizations, the immunogenicity of some of the proteins in this cocktail was either enhanced or decreased. Mice were also immunized with His-p17-Pk or His-p17-Pk-antibody complexes in the presence or absence of alum. The antibody-antigen complexes induced two- to four-fold higher antibody levels than antigen alone but did not appear to be more immunogenic in inducing lymphoproliferative responses. Sera from SIV-infected macaques were tested for the presence of antibodies reacting with the recombinant proteins by Western blot analysis. Antibodies to endonuclease, p15, p17, p27, rt, and vif were readily detected, antibodies against protease and vpx were present at much lower levels, but no antibodies were detected to nef, rev, tat, or vpr. Thus, we have developed a comprehensive range of reagents (available on request) that can be used to examine immune responses to SIV in both mice and monkeys.