Heterologous minor coat proteins of Citrus tristeza virus strains affect encapsidation, but the coexpression of HSP70h and p61 restores encapsidation to wild-type levels

The long flexuous bipolar virions of Citrus tristeza virus (CTV), a Closterovirus, are encapsidated with two capsid proteins at opposite ends: the minor coat protein (CPm) encapsidates the 5′ 630 nts of the genomic RNA and the major coat protein encapsidates the remainder of the genome. In this study, we found encapsidation of CTV CPm in the absence of other assembly-related proteins is highly specific in contrast to most plant viruses that allow virion assembly by a range of heterologous coat proteins. Heterologous CPms with 95-96% amino acid identity from related strains in CTV-CPm, a replicon with CPm as the only assembly-related ORF, either failed to initiate encapsidation or reduced encapsidation substantially. Substitution of subsets of amino acids revealed that the amino acids that differ between positions 121 and 180 of the VT strain, and 61 and 120 of the T3 strain were involved in specific encapsidation. We further mapped the specific encapsidation to a single amino acid: mutation of methionine₁₆₅ to threonine (VT type) or serine₁₀₅ to proline (T3 type) in CTV-CPm failed to form nucleocapsids. However, the heterologous CPm in combination with both HSP70h and p61 proteins, but not HSP70h or p61 alone, encapsidated at wild-type levels, suggesting that specific encapsidation by CPm was mitigated by the combination of HSP70h and p61. Thus, in addition to the previously described functions of HSP70h and p61 of greatly enhanced virion formation and restriction of CPm encapsidation to the 5′ 630 nts of the genomic RNA, these proteins facilitate encapsidation by heterologous CPms.     

Subcellular localization of the HSP70-homolog encoded by beet yellows closterovirus.

Closteroviridae is the only viral family coding for a homolog of HSP70 (HSP70h). Polyclonal antiserum to recombinant beet yellows closterovirus (BYV) HSP70h was generated and used for immunogold labeling of the leaf samples derived from the infected Nicotiana benthamiana plants. Ultrastructural analysis revealed the preferential accumulation of BYV in phloem, although occasional infection of the leaf mesophyll cells was also observed. The strongest HSP70h-specific labeling was associated with virion aggregates and vesicles harboring scattered virions. HSP70h was also observed in close proximity of plasmodesmata and inside the plasmodesmatal channels. The possible role of the BYV HSP70h in RNA encapsidation was tested in tobacco protoplasts. A BYV mutant possessing an inactivated HSP70h gene exhibited no detectable encapsidation defects. Collectively, the obtained results suggested that closteroviral HSP70h escorts the virions to their destinations inside the infected cells and possibly participates in the intercellular translocation of BYV.     

The Lettuce infectious yellows virus (LIYV)-encoded P26 is associated with plasmalemma deposits within LIYV-infected cells

Cytological, immunological, and mutagenesis approaches were used to identify the viral factors associated with the formation of plasmalemma deposits (PLDs) in whole plants and protoplasts infected by Lettuce infectious yellows virus (LIYV). Transmission electron microscopy and immunogold labeling using polyclonal antibodies to four of the five LIYV RNA 2-encoded large proteins, capsid protein (CP), minor capsid protein (CPm), HSP70 homolog (HSP70h), and P59, showed specific labeling of LIYV virions or virion aggregates around the vesiculated membranous inclusions, but not PLDs in LIYV-infected Nicotiana benthamiana, Nicotiana clevelandii, Lactuca sativa, and Chenopodium murale plants, and Nicotiana tabacum protoplasts. In contrast, antibodies to the RNA 2-encoded P26 showed specific labeling of PLDs but not virions in both LIYV-infected plants and protoplasts. Virion-like particles (VLPs) were seen in protoplasts infected by all LIYV RNA 2 mutants except for the CP (major capsid protein) mutant. PLDs were more difficult to find in protoplasts, but were seen in protoplasts infected by the CP and CPm mutants, but not in protoplasts infected by the P26, HSP70h, or P59 mutants. Interestingly, although the CPm mutant showed VLPs and PLDs, the PLDs did not show associated virions/virion-like particles as was always observed for PLDs seen in protoplasts infected by wild-type LIYV. Immunoblot analyses performed on purified LIYV virions showed that P26 was not detected with purified virions, but was detected in the cell wall, 1000 g and 30,000 g pellet fractions of LIYV-infected plants. These data suggest that P26 is associated with the LIYV-induced PLDs, and in contrast to the other RNA 2-encoded large proteins, P26 is not a virion protein.     

Interaction between HSP70 homolog and filamentous virions of the Beet yellows virus

An HSP70 homolog (HSP70h), encoded by the Closterovirus Beet yellows virus (BYV), functions in viral movement from cell to cell. A previous study revealed that in infected cells, HSP70h colocalizes with the masses of BYV filamentous virions. Here we demonstrate that HSP70h forms a physical complex with BYV virions. This conclusion is based on both the comigration of HSP70h with BYV virions in sucrose density gradients and the coimmunoprecipitation of the HSP70h and BYV capsid protein using anti-HSP70h serum. The HSP70h-virion complex is stable at high concentrations of sodium chloride; its dissociation using sodium dodecyl sulfate, lithium chloride, or alkaline pH was accompanied by virion disassembly. However, the complex formation does not involve covalent bonds between HSP70h and virion components. Each BYV virion contains approximately 10 molecules of HSP70h. The possible role of HSP70h interaction with the virions in cell-to-cell movement of BYV is discussed.     

Three genes of Citrus tristeza virus are dispensable for infection and movement throughout some varieties of citrus trees

Citrus tristeza virus (CTV), a member of the Closteroviridae, possesses a 19.3-kb positive-stranded RNA genome that is organized into twelve open reading frames (ORFs). The CTV genome contains two sets of conserved genes, which are characteristic of this virus group, the replication gene block (ORF 1a and 1b) and the quintuple gene block (p6, HSP70 h, p61, CPm, and CP). With the exception of the p6 gene, they are required for replication and virion assembly. CTV contains five additional genes, p33, p18, p13, p20 and p23, in the 3' half of the genome, some of which (p33, p18 and p13) are not conserved among other members of this virus group, and have been proposed to have evolved for specific interactions with the citrus host. In the present study, the requirements for systemic infection of citrus trees of p33, p6, p18, p13 and p20 were examined. Viral mutants with a deletion in the p6 or the p20 ORF failed to infect citrus plants systemically, suggesting their possible roles in virus translocation/systemic infection. However, we found that deletions within the p33, p18 or p13 ORF individually resulted in no significant loss of ability of the virus to infect, multiply, and spread throughout citrus trees. Furthermore, deletions in the p33, p18 and p13 genes in all possible combinations including deletions in all three genes allowed the virus to systemically invade citrus trees. Green fluorescent protein-tagged CTV variants with deletions in the p33 ORF or the p33, p18 and p13 ORFs demonstrated that the movement and distribution of these deletion mutants were similar to that of the wild-type virus.     

Transient gene expression of antisense RNA and coat protein-encoding sequences reduced accumulation of cherry leafroll virus in tobacco protoplasts

Cherry leafroll nepovirus (CLRV) is the causative agent of blackline disease, which results in a fatal necrosis of the graft union of English walnut scion on certain rootstocks. Tobacco suspension cell protoplasts were electroporated with plasmid constructions, bearing or not bearing RNA-derived sequences, and, subsequently, were electroporated with CLRV virions or virion RNA Replication of CLRV in protoplasts was demonstrated by accumulation of both positive- and negative-sense CLRV genomic RNAs 1 and 2, capsid antigen, and virions. Three plasmids were tested for antiviral action. These have inserts that were derived from the coat protein gene, inserted in both orientations, and from the 3' terminal sequence that is nearly identical in RNA 1 and RNA 2, oriented for expression of antisense RNA. Plasmids were introduced into protoplasts 12 hr prior to introducing the virions or virion RNA. CLRV accumulation was reduced significantly by prior electroporation of plasmids intended to express coat protein or 3' antisense RNA, but not by electroporation of plasmid without insert or plasmid with coat protein encoding sequences in the antisense orientation. These results demonstrate the utility of transient expression in a protoplast system for comparing the efficacy of a variety of virus-derived and other sequences for their potential application in virus control strategies.     

Association of HSP70 with the adenovirus type 5 fiber protein in infected HEp-2 cells

Although maximal synthesis of HSP70 is induced early (6-12 hr) after adenovirus type 5 (Ad5) infection of HEp-2 or HeLa cells, the total amount of HSP70 appears to be increased at late times of infection (18-24 hr). Since virion structural proteins also accumulate at these times, we investigated the possible interaction between Ad5 structural proteins and HSP70 by immunoprecipitation of infected cell extracts with antibodies to either ATP-affinity-purified HSP70 or to CsCl-gradient-purified Ad5 virions. We found that HSP70 and a 62-kDa Ad-specific protein coimmunoprecipitated from infected cell extracts. Antibody which recognizes one of these two proteins does not cross-react with the other. Thus, the association between HSP70 and the 62-kDa protein appears specific. Using different antisera to specific adenovirus structural proteins, we have identified the 62-kDa protein as the Ad5 fiber protein.     

In vivo particle polymorphism results from deletion of a N-terminal peptide molecular switch in brome mosaic virus capsid protein

The interaction between brome mosaic virus (BMV) coat protein (CP) and viral RNA is a carefully orchestrated process resulting in the formation of homogeneous population of infectious virions with T=3 symmetry. Expression in vivo of either wild type or mutant BMV CP through homologous replication never results in the assembly of aberrant particles. In this study, we report that deletion of amino acid residues 41-47 from the N-proximal region of BMV CP resulted in the assembly of polymorphic virions in vivo. Purified virions from symptomatic leaves remain non-infectious and Northern blot analysis of virion RNA displayed packaging defects. Biochemical characterization of variant CP by circular dichroism and MALDI-TOF, respectively, revealed that the engineered deletion affected the protein structure and capsid dynamics. Most significantly, CP subunits dissociated from polymorphic virions are incompetent for in vitro reassembly. Based on these observations, we propose a chaperon-mediated mechanism for the assembly of variant CP in vivo and also hypothesize that (41)KAIKAIA(47) N-proximal peptide functions as a molecular switch in regulating T=3 virion symmetry.     

Translation of eggplant mosaic virus RNA in wheat germ extracts and reticulocyte lysates

Eggplant mosaic virus (EMV) RNA extracted from virions (virion EMV RNA) is a good messenger in wheat germ extracts and reticulocyte lysates but directs surprisingly little synthesis of coat protein. Large amounts of coat protein, however, are synthesized when a low molecular weight RNA purified from virion RNA is used as messenger. Heavy virion RNA directs the synthesis of two proteins of high molecular weight in reticulocyte lysates. The larger of these proteins accounts for almost the entire coding potential of 2 × 10⁶ dalton viral RNA.     

Identification of heat shock protein 70 in the rabies virion.

We investigated a 73-kDa polypeptide (p73), a minor component of the rabies virion (HEP-Flury and ERA strains), accounting for as much as 1% of total virion proteins. Two-dimensional gel electrophoresis and immunoblotting with the antiserum against the heat shock protein 70 (hsp70) demonstrated that p73 was identical to a constitutive type of cellular hsp70. The antiserum also detected p73/hsp70 in the purified virions of other negative-stranded RNA viruses, such as vesicular stomatitis virus (New Jersey serotype), Newcastle disease virus (Miyadera strain), and influenza A virus (PR8 strain), among which, however, the contents were variable.     

Genetic analysis of the cell-to-cell movement of beet yellows closterovirus

A beet yellows closterovirus (BYV) variant expressing green fluorescent protein and leaves of BYV local lesion host Claytonia perfoliata were used to reveal genetic requirements for BYV cell-to-cell movement in leaf epidermis and mesophyll. A series of mutations targeting genes that are not involved in amplification of the viral positive-strand RNA was analyzed. The products of genes coding for a 6-kDa hydrophobic protein (p6) and a 64-kDa protein (p64), as well as for minor and major capsid proteins, were found to be essential for intercellular translocation of BYV. In a previous work, we have demonstrated that the BYV HSP70-homolog (HSP70h) also plays a critical role in viral movement (V. V. Peremyslov, Y. Hagiwara, and V. V. Dolja, 1999, Proc. Natl. Acad. Sci. USA, 96, 14771-14776). Altogether, a unique protein quintet including three dedicated movement proteins (p6, p64, and HSP70h) and two structural proteins is required to potentiate the cell-to-cell movement of a closterovirus. The corresponding BYV genes are clustered in a block that is conserved among diverse representatives of the family Closteroviridae.     

The p20 gene product of Citrus tristeza virus accumulates in the amorphous inclusion bodies

Citrus tristeza virus (CTV) has 10 3' open reading frames (ORFs) of unknown function except for the two coat proteins. The highest produced subgenomic RNAs are those of the major coat protein gene (p25) and the 3' most genes, p20 and p23. The proteins from three ORFs, p25, p27, and p20, were examined in the yeast two-hybrid assay for the interactions between themselves and to one another. The p20 protein exhibited a high affinity for itself, suggesting that it might aggregate in infected cells. The cytopathology of CTV infections includes characteristic paracrystalline and amorphous inclusions in the phloem elements of infected citrus. Polyclonal antiserum raised against the bacterial expressed p20 gene product detected a protein of approximately 22-23 kDa, which accumulated to relatively high levels in CTV-infected citrus, but not in healthy citrus. Immunogold localization using antibodies to p20 protein showed strong and specific labeling of the amorphous inclusion bodies present in CTV-infected cells. Mesophyll protoplasts of Nicotiana benthamiana transfected with a CTV mutant containing the green fluorescent protein (GFP) ORF fused in-frame to the 3' end of p20 protein ORF expressed high levels of GFP. The fusion protein was concentrated in one specific area in the cytoplasm and lacked an organized shape. Accumulation of high levels of p20 protein in infected tissue, specific localization of the p20-GFP fusion protein, immunolocalization of p20 protein into amorphous inclusions, and strong homologous p20 protein-p20 protein interactions in the yeast-two-hybrid assay suggest that the p20 protein of CTV is a major component of the amorphous inclusion bodies present in CTV-infected cells.     

Functional domains in the feline immunodeficiency virus nucleocapsid protein

Retroviral nucleocapsid (NC) proteins are small Gag-derived products containing one or two zinc finger motifs that mediate genomic RNA packaging into virions. In this study, we addressed the role of the feline immunodeficiency virus (FIV) NC protein in the late stages of virus replication by analyzing the assembly phenotype of FIV NC mutant viruses and the RNA binding activity of a panel of recombinant FIV NC mutant proteins. Substitution of serine for the first cysteine residue in the NC proximal zinc finger was sufficient to impair both virion assembly and genomic RNA binding. A similar defective phenotype with respect to particle formation and RNA binding was observed when the basic residues Lys28 and Lys29 in the region connecting both zinc fingers were replaced by alanine. In contrast, mutation of the first cysteine residue in the distal zinc finger had no effect on virion production and allowed substantial RNA binding activity of the mutant NC protein. Moreover, this NC mutant virus exhibited wild-type replication kinetics in the feline MYA-1 T-cell line. Interestingly, amino acid substitutions disrupting the highly conserved PSAP and LLDL motifs present in the C-terminus of the FIV NC abrogated virion formation without affecting the NC RNA binding activity. Our results indicate that the proximal zinc finger of the FIV NC is more important for virion production and genomic RNA binding than the distal motif. In addition, this study suggests that assembly domains in the FIV NC C-terminus may be functionally equivalent to those present in the p6 domain of the Gag polyprotein of primate lentiviruses.     

Frog virus 3 ORF 53R, a putative myristoylated membrane protein, is essential for virus replication in vitro

Although previous work identified 12 complementation groups with possible roles in virus assembly, currently only one frog virus 3 protein, the major capsid protein (MCP), has been linked with virion formation. To identify other proteins required for assembly, we used an antisense morpholino oligonucleotide to target 53R, a putative myristoylated membrane protein, and showed that treatment resulted in marked reductions in 53R levels and a 60% drop in virus titers. Immunofluorescence assays confirmed knock down and showed that 53R was found primarily within viral assembly sites, whereas transmission electron microscopy detected fewer mature virions and, in some cells, dense granular bodies that may represent unencapsidated DNA-protein complexes. Treatment with a myristoylation inhibitor (2-hydroxymyristic acid) resulted in an 80% reduction in viral titers. Collectively, these data indicate that 53R is an essential viral protein that is required for replication in vitro and suggest it plays a critical role in virion formation.     

RNA and capsid accumulation in cowpea protoplasts that are resistant to cowpea mosaic virus strain SB

Leaf protoplasts from the Arlington line of cowpea (Vigna unguiculata) support only a limited increase of cowpea mosaic virus strain SB (CPMV-SB), whereas cowpea severe mosaic virus, another member of the comovirus group, replicates efficiently in Arlington cowpea protoplasts. CPMV-SB replicates efficiently in protoplasts of cowpea line Blackeye 5. Some characteristics of the virus-specific resistance of Arlington protoplasts to CPMV-SB are reported. Differences between progeny CPMV-SB from Arlington and Blackeye 5 protoplasts were not detected. Inoculation with CPMV-SB RNA, rather than virions, did not make Arlington protoplasts fully susceptible. These results favor, for likely involvement in the CPMV-SB restriction phenomenon, events in the virus life cycle that occur after exposure of virion RNA to the cytoplasm and before assembly of particles is completed. The accumulation of CPMV-SB RNAs of both polarities was found to be depressed in inoculated Arlington protoplasts. However, (+)RNA (virion RNA polarity) accumulated to no lesser extent, per unit of (?)RNA, in Arlington protoplasts than in, Blackeye 5 protoplasts. Capsid antigen accumulation, per unit of (+)RNA, was reduced in Arlington protoplasts as compared to Blackeye 5 protoplasts. A working hypothesis consistent with the above and other observations is that Arlington protoplasts have an inhibitory substance that interferes with the production or/and function of CPMV-SB specified proteins.     

Polypeptides of feline leukaemia virus: identification of p15(E) and p12(E)

Antiserum to the p15(E) polypeptide of Rauscher murine leukaemia virus (R-MuLV) precipitated two proteins from purified virions of feline leukaemia virus (FeLV) with apparent mol. wt. of 18500 and 155000 on SDS-polyacrylamide gels. These proteins have been designated p15(E) and p12(E), in line with the nomenclature for MuLV proteins. Like the analogous protein of MuLV, FeLV p15(E) was found to be disulphide-linked to the virion glycoprotein, gp70. FeLV p15(E) was sensitive to digestion of intact virus particles with the proteolytic enzyme, bromelain, indicating that this protein is on the outer surface of the virion. An analysis of cat sera for precipitating activity for FeLV p12(E) showed this only in sera from cats which had recovered from FeLV infection and had virus-neutralizing activity.     

Electrophoretic and sedimentation heterogeneity of the virion antigen of the tick-borne encephalitis virus

Analysis of tick-borne encephalitis virus virion antigen by cross immunoelectrophoresis showed it to be separated into 2 subpopulations of virions differing by their mobility in the electric field. It was demonstrated that in immunoelectrophoresis the formation of precipitation bands typical of virion antigen occurred due to the movement of soluble immune complexes in the electric field. The immunoelectrophoretic characteristics of TBE virus virions are determined by the membrane E protein which was also found to be heterogeneous in its immunoelectrophoretic characteristics. The nucleocapsid of tick-borne encephalitis virus virions formed no precipitation bands in immunoelectrophoresis. The virion antigen not sedimenting in ultracentrifugation was represented by morphologically intact virions the structural protein composition of which differed from that of the structural proteins of virions sedimentable by ultracentrifugation. The possible causes of electrophoretic and sedimentation heterogeneity of tick-borne encephalitis virus virion antigen are discussed.     

Specific packaging of nodaviral RNA2 requires the N-terminus of the capsid protein.

Flock house virus (FHV), a member of the family Nodaviridae, is a nonenveloped, icosahedral insect virus whose capsids are assembled from 180 copies of a single type of coat protein. The viral genome is split between two segments of single-stranded positive-sense RNA, RNA1 and RNA2, which are packaged into a single virion. We previously demonstrated that synthesis of FHV coat protein in the baculovirus expression system results in assembly of virus-like particles whose capsids are indistinguishable from those of native virions, although the encapsidated RNA represents primarily cellular RNA. In contrast, expression of a deletion mutant lacking N-terminal residues 2-31 results in formation of multiple types of particles which differ in size, shape, and RNA contents. We postulated that the polymorphism was imposed by the type of RNA that the coat protein selected for packaging. In the current study we tested this hypothesis by analyzing the assembly of the mutant coat protein in Drosophila cells in the presence of replicating FHV RNAs. As anticipated, the resulting particles had the same shape and dimensions as wt virions. Surprisingly, however, they contained little RNA2 while packaging of RNA1 was not affected. Small amounts of defective interfering RNAs, which emerged rapidly in the presence of the mutant coat protein, were also detected. Taken together, these observations confirm our earlier hypothesis that selection of nonviral RNAs for packaging can significantly alter the assembly process. In addition, they demonstrate that the N-terminus of the FHV coat protein contains important determinants for recognition and packaging of RNA2. Our results provide the first evidence that encapsidation of the two genomic RNAs occurs independently and that the coat protein uses different regions for the recognition of RNA1 and RNA2.     

Inhibition by prostaglandin PGA1 on the multiplication of influenza virus is a dose-dependent effect

Cyclopentenone prostaglandins (PGs), are strong inhibitors of the multiplicative cycle of a wide variety of enveloped RNA and DNA viruses. Their antiviral activity is generally associated with alterations in the synthesis or maturation of specific virus proteins. In this report, we describe the effect of cyclopentenone PGA1 on the replication of influenza A virus Ulster 73 in LLC-MK2 cells. PGA1 was found to inhibit viral replication in a dose-dependent fashion and virus particle yield was reduced at a PGA1 concentration, which did not suppress protein synthesis in mock-infected cells. The kinetic of late viral protein synthesis was delayed in PGA1-treated cells till 10 h post-infection; after that period, viral polypeptide synthesis appeared to be similar in PGA1-treated as well as untreated cells both infected by Ulster 73 virus. This finding suggests that PGA1 might interfere with one or more events in the viral multiplicative cycle such as protein synthesis and assembly, correct insertion of virus polypeptides into the cell membrane and, or maturation of Ulster 73 virion particles. In particular, inhibition of viral replication in LLC-MK2 cells by PGA1 is accompanied by the induction of a cellular polypeptide of 70K molecular weight. We identified this cell protein as a heat shock protein (HSP) related to the inducible isoform of HSP 70, a polypeptide of 72K molecular weight. Induction of this polypeptide by PGA1 was found to be dose-dependent and a substantial accumulation could be seen at a PGA1 concentration that did not inhibit cell protein synthesis in uninfected cells. HSP 70 synthesis started after the beginning of PGA1 treatment and remained at the same level for at least 10 h, leading us to hypothesize that the delay of production of late Ulster 73 proteins could be the consequence of HSP 70 synthesis. These results suggest that HSP 70 could play a role in the antiviral activity of cyclopentenone PGA1 in LLC-MK2 cells.