- Volume 78, Issue 12, 1997

Binding of baculoviruses to insect cells and fusion of the virus envelope to cell membranes are early events suggested to be affected by baculovirus enhancins. The binding of Autographa californica nucleopolyhedrovirus (AcMNPV) to the Spodoptera frugiperda cell line Sf21 and the fusion of the virus envelope to cell membranes were characterized. Virus binding assays demonstrated that AcMNPV budded virus (BV) bound to specific binding sites on Sf21 cells with an avidity of 2·3 × 1010M 1. The cells displayed 3·1 × 103 specific binding sites per cell in a confluent monolayer. In addition, the effects of pH, buffer composition and cation concentration on the binding were examined. Using a fluorescent probe (R18) and fluorescence microscopy, the fusion of AcMNPV BV envelope to the cell membrane was directly visualized in living cells. It has been reported that Trichoplusia ni nucleopolyhedrovirus enters Sf21 cells by membrane fusion at the cell surface; however, the present studies confirmed the well established concept that adsorptive endo-cytosis is the major entry pathway for baculovirus BV infection. Membrane fusion kinetics and fluorescence microscopy demonstrated and verified that the envelope-cell membrane fusion was triggered by acidification. The effect of a T. ni granulovirus enhancin on virus binding and membrane fusion was examined, and no increase in activity was observed.

In nature, nuclear polyhedrosis viruses (NPV) are transmitted when susceptible insect larvae ingest viral occlusion bodies (OB). These dissociate in the alkaline environment of the midgut and release encapsulated virions (PDV) which bind to midgut epithelial cells and initiate an infection. A previous study showed that expression of the Autographa californica NPV (AcMNPV) p74 gene during replication is essential for the production of infectious OB. A set of p74 deletion and overexpression recombinants was used for the production and screening of monoclonal antibodies, and for an investigation of gross cytopathology and localization of p74. No differences in virus structure or morphogenesis were observed in infected cells when the p74 gene of AcMNPV was deleted, even though the infectivity of OB harvested from the cells was abolished when they were fed to Trichoplusia ni larvae. Mutant OB released virus particles and degraded insect peritrophic membrane as in infections with wild-type virus; in addition, virions purified from mutant OB were infectious when injected into the haemocoel of T. ni larvae. Western blot analysis confirmed that p74 was associated with the PDV and could not be detected in the budded form virion phenotype. The polypeptide was readily degraded by treatment of purified PDV with proteinase K, in the presence and absence of detergent, and could be extracted from PDV by a non-ionic detergent treatment. The data are consistent with p74 being a structural polypeptide of the PDV phenotype, most probably as a component associated with the outside surface of the virion envelope. Its presence is shown to be essential for primary infection of midgut cells of insect larvae.

Putative baculovirus helicases have been implicated as playing an important role in viral DNA replication and host specificity. The Spodoptera exigua multicapsid nucleopolyhedrovirus (SeMNPV) helicase is therefore of interest since the virus only infects the beet army worm. Sequence analysis of the SeMNPV lef5-p39 (mu 46·5–55·1) region, which is collinear with the 39K-lef5 area in Autographa californica MNPV (AcMNPV), revealed an open reading frame (ORF) of 3666 bp potentially encoding a protein with a molecular mass of 143 kDa. This protein had considerable amino acid sequence similarity (58%) to AcMNPV p143, including seven conserved motifs characteristic of helicases. In cultured insect cells, this SeMNPV ORF is expressed from 4 to 12 h postinfection and its major transcript of 4 kb starts 11 to 12 nt upstream of the putative translational initiation site (ATG). To study their possible role in the specificity of baculovirus DNA replication, the putative AcMNPV and SeMNPV helicase genes were tested for their ability to replicate homologous regions (hrs; putative origins of DNA replication) in a transient DNA replication assay in insect cells. All viral cis- and trans-acting factors were provided as plasmids using either Achr2 or Sehr1 as the DNA replication origin. SeMNPV p143 could not substitute for AcMNPV p143 in the transient assays supplemented with either hr. Similar results were obtained when the SeMNPV and AcMNPV ie1 genes were exchanged. None of the essential AcMNPV trans-acting factors could be complemented by SeMNPV infections to support DNA replication of hrs. These data suggest a specific interaction between baculovirus DNA replication factors to form the replisome and/or between the replisome and the origin of DNA replication.

The genome of Heliothis armigera entomopoxvirus (HaEPV) has been mapped with four restriction endonuclease enzymes (BamHI, HindIII, PstI and XhoI), and its length estimated at 233 kbp. An EcoRI- generated HaEPV genomic fragment hybridized to all fragments identified as genomic termini, providing the first experimental evidence for the presence of terminal repeat elements in an EPV genome. The HaEPV spheroidin and nucleoside triphosphate phosphohydrolase I (NPHI) genes have been cloned and sequenced, and their deduced products shown to possess high levels of identity with homologues from other Genus B entomopoxviruses (EPVs). The genomic locations of these and other HaEPV genes and open reading frames have been determined; comparison of their locations with those of homologues in the Amsacta moorei EPV genome largely supports an hypothesis that the Genus B EPVs share a conserved genomic organization which differs from that of chordopoxviruses. It is proposed that genes of EPVs can be assigned to five actual or predicted homology-based groups, a categorization which is useful for directing and interpreting investigations of EPV gene functions and relationships.

Cotesia congregata polydnavirus (CcPDV) is essential for successful parasitism of Manduca sexta larvae by the braconid wasp Cotesia congregata. To determine the molecular mechanisms for the vertical transmission of CcPDV in the wasps, we analysed the different forms of the virus sequences containing the gene encoding the early parasitism-specific protein 1 (EP1). By a detailed molecular analysis, we demonstrated that the EP1 sequences are present in wasp DNA in two forms: a circular form as seen in the virus particles and a form integrated into the wasp genome. Moreover, we showed that the integrated form of the EP1 sequences is able to excise in the ovary cells. A fragment corresponding to an EP1 ‘empty locus’(without the viral sequence) was PCR-amplified from ovarian DNA. Comparison of the sequences isolated from the EP1 circle, the integrated form and the empty locus revealed that the extremities of the EP1 genomic sequences constitute a direct repeat. Strikingly, these sequences contain a potential binding site for a recombinase of the Hin family located in close vicinity to the position where the DNA strand exchange occurs. Thus, the data bear upon the possibility that the bracovirus circles are excised via a mechanism related to the Hin mediated Conservative Specific-Specific Recombination (CSSR) of prokaryotes.

To study the morphogenesis and packaging of rice dwarf phytoreovirus (RDV), the interactions among multiple structural proteins were analysed using both the yeast two-hybrid system and far-Western blotting analysis. The following protein-protein interactions were observed. P3 (major core protein) bound to itself as well as to P7 (nucleic acid-binding protein) and P8 (major outer capsid protein). P7 bound to P1 (RNA-dependent RNA polymerase) and P8, in addition to P3. Based on these findings, we hypothesize that the core shell structure is based on P3-P3 interactions and that P7 has the ability to bind to multiple structural proteins as well as to genomic RNAs during viral particle assembly. Based on the observed protein-protein interactions and on computer-aided analysis of the numbers of structural proteins per particle, possible RDV assembly events are proposed.

A full-length cDNA clone of the potato virus Y (PVY) genome was obtained after cloning difficulties in Escherichia coli were overcome. These difficulties were mainly due to the expression of the CI gene from upstream prokaryotic promoter-like elements within the PVY genome. To overcome this problem, PVY cDNA was maintained in two subclones which were ligated before infection. A plasmid in which these two fragments were contained could be propagated in some E. coli strains but was unstable and yielded only low levels of plasmid DNA. Replacement of the 35S promoter by the SP6 promoter slightly increased the stability of the plasmid and its RNAtranscripts were infectious when capped with m7G(5′)ppp(5′)G. Using two inoculation methods (mechanical or biolistic) the cDNA and its RNA transcript proved infectious on three Nicotiana species and on Solanum tuberosum.

Full-length cDNAs of barley mild mosaic bymovirus RNA1 and RNA2 were cloned downstream of a modified cauliflower mosaic virus 35S promoter with double enhancer. Mechanical inoculation of barley seedlings with a mixture of both cDNAs resulted in systemic mosaic symptoms, typical of barley mild mosaic virus infection. The presence of both RNA species and their gene products in the systemically infected leaves was demonstrated by RT-PCR and Western blot analyses, respectively. Virions were detected by immunogold labelling, demonstrating that the RNAs are encapsidated. This is the first report of the 35S promoter used in successfully infecting a monocot plant host with cDNA from a strictly monocot plant RNA virus.

We have examined the molecular epidemiology of the leafhopper-borne maize rayado fino virus (MRFV) in Latin America. The coat protein gene and 3′ non-translated region of 14 isolates of MRFV collected from Latin America and the United States were sequenced and phylogenetic relationships examined. The nucleotide sequence revealed remarkable conservation, with a sequence similarity of 88–99 %. Phylogenetic analysis of sequence data obtained from a 633 bp fragment showed that MRFV has diverged into three main clusters, i.e. the geographically distinct northern and southern isolates and the Colombian isolates. Significant differences between the isolates collected from Colombia, previously named maize rayado colombiana virus, based upon differences in symptomatology and serological relationships to MRFV, and the other MRFV isolates, provides additional evidence supporting its designation as a unique strain of MRFV.

The complete sequence of the 5834 nucleotides of RNA 1 of beet soil-borne furovirus (BSBV, Ahlum isolate) was determined using a PCR product obtained with primers to highly conserved coding regions for helicase-like proteins in RNA 1 of furo-, hordei- and tobraviruses as a starting sequence. Unknown parts of the sequence upstream and downstream of this starting sequence were amplified by means of RT-PCR techniques using combinations of specific and random primers. BSBV RNA 1 contains one large ORF for a readthrough protein with a molecular mass of 204 kDa (204K protein) which is interrupted internally by a UAA stop codon terminating the coding region for a protein of 145 kDa (145K protein). The N- and C-terminal parts of the 145K protein and the readthrough domain of the 204K protein contain methyl- transferase, helicase and RNA-dependent RNA polymerase motifs, respectively. Unlike other furo- and tobraviruses BSBV contains no further genes on its RNA 1.

Tubular structures involved in the cell-to-cell movement of cowpea mosaic virus (CPMV) were partially purified from infected cowpea protoplasts to identify the structural components. A relatively pure fraction could be obtained by differential centrifugation and this was analysed by PAGE and immunoblotting. Besides the movement protein (MP) and capsid proteins (CP) of CPMV, no other major infection-specific proteins could be detected, suggesting that host proteins are not a major structural component of the movement tubule.

Alfalfa mosaic virus (AMV) and Prunus necrotic ringspot virus (PNRSV) are tripartite positive-strand RNA plant viruses that encode functionally similar translation products. Although the two viruses are phylogenetically closely related, they infect a very different range of natural hosts. The coat protein (CP) gene, the movement protein (MP) gene or both genes in AMV RNA 3 were replaced by the corresponding genes of PNRSV. The chimeric viruses were tested for heterologous encapsidation, replication in protoplasts from plants transformed with AMV replicase genes P1 and P2 (P12 plants) and for cell-to-cell transport in P12 plants. The chimeric viruses exhibited basic competence for encapsidation and replication in P12 protoplasts and for a low level of cell-to-cell movement in P12 plants. The potential involvement of the MP gene in determining host specificity in ilarviruses is discussed.

Hop stunt viroid (HSVd) is able to infect a number of herbaceous and woody hosts, such as grapevine, Citrus or Prunus plants. Previous phylogenetic analyses have suggested the existence of three major groups of HSVd isolates (plum-type, hop-type and citrus-type). The fact that these groups often contain isolates from only a limited number of isolation hosts prompted the suggestion that group-discriminating sequence variations could, in fact, represent host-specific sequence determinants which may facilitate or be required for replication in a given host. In an effort to further understand the relationships between HSVd and its different hosts, HSVd variants from eight naturally infected Prunus sources, including apricot, peach and Japanese plum have been cloned and sequenced. In total, ten molecular variants of HSVd have been identified, nine of which have not been described before. A detailed phylogenetic analysis of the existing HSVd sequences, including the new ones from Prunus determined in this work, points towards a redefinition of the grouping of variants of this viroid, since two new groups were identified, one of them composed of sequences described here. A bias for the presence of certain sequences and/or structures in certain hosts was observed, although no conclusive host-determinants were found. Surprisingly, our analysis revealed that a number of HSVd isolates probably derived from recombination events and thatthe previous hop-type group itself is likelyto be the result of a recombination between members of the plum-type and citrus-type groups.

The SBL-1 strain of mumps virus, grouping with genotype A on the basis of the small hydrophobic protein gene sequence, was grown in the presence of three different monoclonal antibodies. The monoclonal antibodies were directed against the haemagglutinin-neuraminidase (HN) protein and they inhibited haemagglutinating activity and infectivity of the virus. The HN genes of the nine neutralization-escape virus mutants were sequenced and the predicted amino acid sequences were compared with that of the parental virus. Amino acid substitutions were found at positions 269, 352 and 354, respectively, of the 582 amino acid long protein. The three monoclonal antibodies did not react with 35 virus strains isolated in Stockholm during the years 1970 to 1985. Thirteen and four of the strains were found to belong to the D and C genotypes, respectively. A type-specific neutralization antibody response was also found in sera of rabbits hyperimmunized with purified virions of genotype A and D. The genotype-specific difference in neutralizing activity in mice and rabbits was not corroborated by an overall difference in the amino acid sequence of the HN protein of the different genotypes. Further studies are needed to explore the efficacy of mumps virus vaccines for protection against homologous and heterologous genotypes of mumps virus.

The immunogenicity and protective efficacy of recombinant vaccinia viruses (rVV) encoding the F, G, N or M2 (22K) proteins of bovine respiratory syncytial virus (BRSV) were evaluated in calves, the natural host for BRSV. Calves were vaccinated either by scarification or intratracheally with rVV and challenged 6 to 7 weeks later with BRSV. Although replication of rVV expressing the F protein in the respiratory tract was limited after intratracheal vaccination, the levels of serum and pulmonary antibody were similar to those induced following scarification. The serum antibody response induced by the F protein was biased in favour of IgG1 antibody, whereas the G and the N proteins induced similar levels of IgG1:IgG2, and antibody was undetectable in calves primed with the M2 protein. The F protein induced neutralizing antibodies, but only low levels of complement-dependent neutralizing antibodies were induced by the G protein, and antibody induced by the N protein was not neutralizing. The F and N proteins primed calves for BRSV-specific lymphocyte proliferative responses, whereas proliferative responses were detected in calves primed with the G protein only after BRSV challenge. The M2 protein primed lymphocytes in only one out of five calves. Although there were differences in the immune responses induced by the rVVs, the F, G and N, but not the M2, proteins induced significant protection against BRSV infection and, in contrast with the enhanced lung pathology seen in mice vaccinated with rVV expressing individual proteins of human (H)RSV, there was a reduction in lung pathology in calves.

A field strain of Sendai virus (SeV) Ohita-M1 (M1) was isolated from an epidemic in an animal laboratory by passaging in mice. A mutant strain, Ohita- MVC11 (MVC11), was then obtained by passaging M1 in rhesus monkey (LLC-MK2) cells. MVC11 was adapted to LLC-MK2 cells and produced 20 times higher levels of infectious virus than M1. This increased production of infectious virus in LLC-MK2 cells was associated with enhanced viral gene expression. However, MVC11 could not replicate efficiently in mouse lung and was not lethal to mice even when inoculated at a titre of 8 × 105 cell-infecting units (CIU) per mouse. On the other hand, with an inoculum of only 4 × 101 CIU per mouse, corresponding to 1 LD50, M1 replicated well in mouse lung and was highly virulent to mice. Nucleotide and deduced amino acid sequence analyses of the entire genomes of M1 and MVC11 revealed that adaptation to LLC-MK2 cells and the attenuation of mouse pathogenicity of MVC11 were associated with only two amino acid substitutions; one on the C protein (Phe substituted by Ser at position 170) and the other on the RNA polymerase, the L protein (Glu substituted by Ala at position 2050).

Acute measles is associated with pronounced immunosuppression characterized both by leukopenia and impaired lymphocyte functions. In an earlier study, we found that mitogen-dependent proliferation of uninfected human peripheral blood lymphocytes (PBLs) and spontaneous proliferation of human cell lines of lymphocytic or monocytic origin was impaired after contact with UV- inactivated, measles virus (MV)-infected cells, UV- inactivated MV or with cells transfected with MV glycoproteins (gp) F and H. We now show that mitogen-stimulated PBLs and Jurkat cell clones either highly sensitive or resistant to CD95-induced apoptosis have a similar sensitivity to MV-induced inhibition and do not undergo apoptosis. Moreover, unimpaired mitogen-dependent upregulation of important activation markers, including IL-2R, was observed in PBL cultures after contact with MV- infected, UV-irradiated presenter cells. This indicates that the cells were indeed viable and acquire a state of activation. Less IL-2 was released from PBLs after contact with MV-infected presenter cells when compared with that released after contact with uninfected cells. However, mitogen-induced proliferation of PBLs was not restored by addition of IL- 2 under these conditions. It appeared that a higher fraction of mitogen-stimulated PBLs accumulated in the G0/G1 phase of the cell cycle after contact with MV-infected cells. Thus, the mitogen- unresponsiveness of PBLs seen after contact with MV-infected cells is due to cell cycle arrest rather than apoptosis.

A synthetic peptide representing residues 397–420 from the measles virus (MV) fusion (F) protein was tested for its structure, immunogenicity and protective capacity against intracerebral challenge with a neuroadapted strain of MV. Analysis of the peptide by mass spectrometry showed that it was linear, despite the presence of two cysteine residues in the sequence. Circular dichroism spectroscopy highlighted a weak preference for the peptide to adopt an α-helical conformation. The peptide was shown to be immunogenic in BALB/c and C57BL/6 mice after intraperitoneal immunization in Freund’s adjuvant, and anti-peptide antibodies from both strains of mice reacted with the MV as a solid phase antigen on an ELISA plate. When the fine specificity of the anti-peptide antibody response was examined using overlapping 8-mer peptides, serum antibodies from BALB/c mice recognized the region between residues 407 –417 whereas antibodies from C57BL/6 mice recognized the region 408 –420 of the 397–420 peptide sequence. Although anti-397–420 antibodies had no demonstrable neutralizing activity, protection against challenge with a neuroadapted strain of MV was demonstrated following active immunization with peptide in C57BL/6 mice or after passive transfer of anti-peptide antibodies in BALB/c mice. These findings highlight the importance of the 397–420 region in the induction of protective antibodies in the MV encephalitis mouse model, and suggest that this epitope might be a good candidate for inclusion in a future MV synthetic peptide vaccine.

Intracellular transport, glycosylation, tetrameriza- tion and enzymatic activity of the neuraminidase (NA) of fowl plague virus (FPV) were analysed in vertebrate cells after expression from a vaccinia virus vector. Tetramerization occurred with a halftime of 15 min, whereas passage through the medial Golgi apparatus and transport to the plasma membrane occurred with half-times of 2 and 3 h, respectively, suggesting a step in NA maturation beyond tetramerization that limits the rate of transport to the medial Golgi. NA transport rates were about fourfold slower than those of haemagglutinin (HA). Slow transport and processing of FPV NA was not altered by coexpression of FPV HA, nor was the transport rate of HA influenced by NA. The slow transport kinetics of NA were also observed in FPV- infected CV-1 cells. As deduced from the coding sequence, FPV NA has the shortest stalk of all naturally occurring NAs described to date and contains only three potential N-glycosylation sites, which are all located in the globular head domain. Elimination of each of the three N-glycosylation sites revealed that the two oligosaccharides at positions 124 and 66 are of the complex type, whereas the one at Asn-213 remains in mannose- rich form. The glycosylation mutants showed also that oligosaccharides at positions 124 and 213 of FPV NA modulate enzymatic activity. Transport of NA is not influenced by single elimination of any of the three oligosaccharide attachment sites. Mutational analysis of the three Cys residues not involved in intrachain disulfide pairing revealed that Cys-49 in the stalk of the NA molecule is responsible for the formation of disulfide-linked dimers. Analysis of cysteine mutants of FPV NA also demonstrated that disulfide-linked dimers are not absolutely necessary for the formation of enzymatically active tetramers but may stabilize the quaternary structure of NA.