Physical Maps of Autographa californica and Rachiplusia ou Nuclear Polyhedrosis Virus Recombinants

TN-368 cells were infected simultaneously with the closely related Autographa california (AcMNPV) and Rachiplusia ou (RoMNPV) nuclear polyhedrosis viruses. Progeny viral isolates were plaque purified, and their DNAs were analyzed with restriction endonucleases. Of 100 randomly cloned plaques, 7 were AcMNPV and RoMNPV recombinants, 5 were RoMNPV, and 88 were AcMNPV. The recombinants contained DNA sequences derived from both parental genomes. By comparing the restriction cleavage patterns of parental and recombinant DNAs, the crossover sites were mapped. A single double crossover was detected in each of the seven recombinant genomes. In addition, six of the seven recombinants revealed a crossover site mapping between 78 and 89% of the genome. The structural polypeptides of the seven recombinants and two parental viruses were analyzed by polyacrylamide gel electrophoresis, and their polyhedrins were identified by tryptic peptide mapping. An analysis of the segregation of three enveloped nucleocapsid proteins and of the polyhedrins among the recombinants located the DNA sequences coding for AcMNPV structural polypeptides with molecular weights of 37,000 (a capsid polypeptide), 56,000, and 90,000 and the RoMNPV structural polypeptides with molecular weights of 36,000 (a capsid polypeptide), 56,000, and 91,000. The AcMNPV and RoMNPV polypeptides of molecular weights 37,000 and 36,000, respectively, mapped within 78 to 89% or 1 to 29%, the polypeptides of molecular weights 55,000 and 56,000 mapped within 78 to 29%, and the polypeptides of molecular weights 90,000 and 91,000 mapped within 19 to 56% of the genome. The region of the parental DNAs that codes for polyhedrin was located within 70 to 89% of the genome.     

Restriction Map of Rachiplusia ou and Rachiplusia ou-Autographa californica Baculovirus Recombinants

The restriction sites of Rachiplusia ou nuclear polyhedrosis virus (RoMNPV) DNA were mapped for the endonucleases SmaI, KpnI, BamHI, SacI, XhoI, and EcoRI. Of the 60 DNA restriction sites of RoMNPV, 35 mapped in similar positions as compared to the restriction sites of Autographa californica nuclear polyhedrosis virus (AcMNPV) DNA. Two plaque-purified viruses, obtained from randomly picked plaques of a wild-type isolate of RoMNPV, were recombinants of RoMNPV and AcMNPV. The recombinants were shown to have RoMNPV and AcMNPV restriction fragments as well as structural polypeptides from each parental virus. Both recombinant viruses had a major RoMNPV capsid protein but were occluded in the AcMNPV polyhedrin protein.     

Persistence of an Occlusion-Negative Recombinant Nucleopolyhedrovirus in Trichoplusia ni Indicates High Multiplicity of Cellular Infection

We use data from the serial passage of co-occluded recombinant Autographa californica nuclear polyhedrosis virus (AcMNPV) to estimate the viral multiplicity of infection of cells within infected insects. Co-occlusion, the incorporation of wild-type and mutant virus genomes in the same occlusion body, has been proposed as a strategy to deliver genetically modified viruses as insecticides in a way that contains their spread in the environment. It may also serve as a means whereby naturally occurring mutant forms of NPVs can be maintained in a stable polymorphism. Here, a recombinant strain of AcMNPV was constructed with a deletion of its polyhedrin gene, rendering it incapable of producing occlusion bodies (i.e., occlusion negative). This was co-occluded with wild-type AcMNPV and used to infect fifth-instar Trichoplusia ni larvae. The fate of both genotypes was monitored over several rounds of insect infection. Levels of the occlusion-negative virus genome declined slowly over successive rounds of infection. We applied these data to a model of NPV population genetics to derive an estimate of 4.3 ± 0.3 viral genomes per occlusion body-producing cell.     

An RNA virus in Autographa californica nuclear polyhedrosis virus preparations: Incidence and influence on baculovirus activity

A small RNA virus infectious to Trichoplusia ni larvae (TRV) was observed as a contaminant of several Autographa californica nuclear polyhedrosis virus preparations (AcMNPV). The extent of contamination in various AcMNPV preparations was studied by means of serial enrichment passages through T. ni larvae and enzyme-linked immunosorbent assay (ELISA). TRV could not be detected by ELISA in the original preparation of AcMNPV polyhedra prepared in 1968 even after five enrichment passages. Antibody inactivation offers a possible prophylactic method against TRV but temperature inactivation (55°C) does not. Although TRV reduced larval weight, it had little or no effect on bioassays of AcMNPV to T. ni and Heliothis virescens.     

Integration of a transposable DNA sequence which mediates ampicillin resistance into Clo DF13 plasmid DNA: determination of the site and orientation of TnA insertions.

The isolation and characterization of Clo DF13 plasmids containing a transposable DNA sequence (TnA) that specifies for ampicillin resistance is described. The particular transposon is derived from the R plasmid pRI30, and is designated Tn901. In order to determine the site and orientation of Tn901 insertions into the Clo DF13 genome, we made use of restriction endonucleases and heteroduplex mapping. For this purpose, Clo DF13 plasmid DNA and DNA of Clo DF13::Tn901 plasmids were digested with endonucleases HincII, PstI, BamH-I, SalI, and HpaI or with a combination of two of these enzymes. By analysis of the resulting fragmentation patterns, the physical maps of Clo DF13 DNA and Tn901 DNA could be derived. Furthermore, the site and orientation of Tn901 insertions into the Clo DF13 genome could be determined by this approach. The data obtained were verified by heteroduplex mapping. Analysis of 33 independently isolated Clo DF13 recombinant plasmids showed that insertion of Tn901 had occurred at 31 different sites. No preference with respect to the orientation of Tn901 was observed. Insertion of Tn901 into a segment of about 20% of the Clo DF13 genome resulted in the loss of cloacin production, indicating that the structural gene coding for cloacin is located in this area. The sites of Tn901 insertions within Clo DF13 were more or less scattered; however, no Tn901 insertion sites were found in two distinct areas comprising 11 and 17%, respectively, of the Clo DF13 genome. Transposition of Tn901 DNA to the copy mutant Clo DF13-rep3 showed that the β-lactamase activity and the minimal inhibitory concentration of ampicillin were correlated to the number of plasmid copies per cell.     

Tn5-Induced Mutations in the Enterobacterial Phytopathogen Erwinia chrysanthemi

Escherichia coli (2492/pJB4JI) matings with Erwinia chrysanthemi produced kanamycin resistant (Km^r) transconjugants, a majority of which were gentamicin sensitive (Gm^s). A small proportion (about 0.8%) of the Km^r Gm^s clones were either auxotrophic or failed to catabolize galacturonate (Gtu⁻). The R plasmid (pJB4JI) DNA was detected in the parent E. coli strain and in a Km^r Gm^r transconjugant, but not in Km^r Gm^sE. chrysanthemi strains carrying Tn5-induced mutations. In Hfr crosses, Km^r (Tn5) was found linked with most mutations. A majority (>95%) of prototrophic recombinants were Km^s, except for Leu⁺ and Arg⁺ recombinants which were 30 to 50% Km^s. Spontaneous revertants were obtained for all markers except car, gtu, lys, thr, and trp. Prototrophic revertants, with the exception of Met⁺, Leu⁺, or His⁺ clones, were Km^s. We conclude from both genetic and physical data that Tn5 transposed from pJB4JI into different sites on the chromosome of E. chrysanthemi.     

Persistent Baculovirus Infection Results from Deletion of the Apoptotic Suppressor Gene p35

Infection with the wild-type baculovirus Autographa californica multiple nuclear polyhedrosis virus (AcMNPV) results in complete death of Spodoptera frugiperda (Sf) cells. However, infection of Sf cells with AcMNPV carrying a mutation or deletion of the apoptotic suppressor gene p35 allowed the cloning of surviving Sf cells that harbored persistent viral genomes. Persistent infection established with the virus with p35 mutated or deleted was blocked by stable transfection of p35 in the host genome or by insertion of the inhibitor of apoptosis (iap) gene into the viral genome. These artificially established persistently virus-infected cells became resistant to subsequent viral challenge, and some of the cell lines carried large quantities of viral DNA capable of early gene expression. Continuous release of viral progenies was evident in some of the persistently virus-infected cells, and transfection of p35 further stimulated viral activation of the persistent cells, including the reactivation of viruses in those cell lines without original continuous virus release. These results have demonstrated the successful establishment of persistent baculovirus infections under laboratory conditions and that their establishment may provide a novel continuous, nonlytic baculovirus expression system in the future.     

The location of four fimbrin-encoding genes,agfA, fimA,sefA and sefD,on the Salmonella enteritidis and/or S. typhimurium XbaI-BlnI genomic restriction maps

Four fimbrin-encoding genes, fimA (type-1 or SEF21 fimbriae), agfA (thin aggregative or SEF17 fimbriae), sefA (SEF14 fimbriae) and sefD (SEF18 fimbriae) from Salmonella enteritidis (Se) 27655-3b were located onto the XbaI-BlnI genomic restriction maps of Salmonella typhimurium (St) LT2 and Se strains SSU7998 and 27655-3b. The XbaI or BlnI genomic fragments carrying these genes were identified by hybridization with labeled oligodeoxyribonucleotides or fimbrin-encoding genes. The fimbrin-encoding genes were not encoded by the virulence plasmids, but were located on chromosomal DNA fragments. The position of each gene on a given XbaI fragment was determined by hybridization of a series of XbaI-digested genomic DNA samples from previously characterized Tn10 mutants of Se and St with its respective probe. The fimA gene mapped near 13 centisomes (Cs) between purE884::Tn10 at 12.6 Cs (11.8 min) and apeE2::Tn10 at 12.8 Cs (12.3 min) beside the first XbaI site at 13.0 Cs in St or between purE884::Tn10 at 12.6 Cs and the XbaI site at 13.6 Cs in Se. The agfA gene mapped near 26 Cs between putA::Tn10 and pyrC691::Tn10 in St, but near 40 Cs between pncX::Tn10 and the XbaI site at 43.3 Cs in Se. This difference in map position was due to the location of agfA near one end of the 815-kb chromosomal fragment inverted between Se and St. The sefA and sefD genes mapped precisely at 97.6 Cs in Se, but were absent from the genome of St LT2. To verify the mapping procedures used herein, tctC was also mapped in both Salmonella serovars. As expected, tctC mapped near 60 Cs in both St and Se, thereby confirming previous studies     

Effects of Substituting Granulin or a Granulin-Polyhedrin Chimera for Polyhedrin on Virion Occlusion and Polyhedral Morphology in Autographa californica Multinucleocapsid Nuclear Polyhedrosis Virus

Substitution of granulin from the Trichoplusia ni granulosis virus (TnGV) for polyhedrin of the Autographa californica multinucleocapsid nuclear polyhedrosis virus (AcMNPV) yielded a few very large (2 to 5 μm) cuboidal inclusions in the cytoplasm and nucleus of infected cells. These polyhedra lacked the beveled edges characteristic of wild-type AcMNPV polyhedra, contained fractures, and occluded few virions. Placing a nuclear localization signal (KRKK) in granulin directed more granulin to the nucleus and resulted in more structurally uniform cuboidal inclusions in which no virions were observed. A granulin-polyhedrin chimera produced tetrahedral occlusions with more virions than granulin inclusions but many fewer than wild-type polyhedra. Despite the unusual structure of the granulin and granulin-polyhedrin inclusions, they interacted with AcMNPV p10 fibrillar structures and electron-dense spacers that are precursors of the polyhedral calyx. The change in inclusion shape obtained with the granulin-polyhedrin chimera demonstrates that the primary amino acid sequence affects occlusion body shape, but the large cuboidal inclusions formed by granulin indicate that the amino acid sequence is not the only determinant. The failure of granulin or the granulin-polyhedrin chimera to properly occlude AcMNPV virions suggests that specific interactions occur between polyhedrin and other viral proteins which facilitate normal virion occlusion and occlusion body assembly and shape in baculoviruses.     

Mutational Analysis of the N-Linked Glycans on Autographa californica Nucleopolyhedrovirus gp64

gp64 is the major envelope glycoprotein in the budded form of Autographa californica multicapsid nucleopolyhedrovirus (AcMNPV). gp64 is essential for AcMNPV infection, as it mediates penetration of budded virus into host cells via the endocytic pathway. In this study, we used site-directed mutagenesis to map the positions of the N-linked glycans on AcMNPV gp64, characterize their structures, and evaluate their influence on gp64 function. We found that four of the five consensus N-glycosylation sites in gp64 are used, and we mapped the positions of those sites to amino acids 198, 355, 385, and 426 in the polypeptide chain. Endoglycosidase H sensitivity assays showed that N-linked glycans located at different positions are processed to various degrees. Lectin blotting analyses showed that each N-linked glycan on gp64 contains α-linked mannose, all but one contains α-linked fucose, and none contains detectable β-linked galactose or α2,6-linked sialic acid. The amounts of infectious progeny produced by AcMNPV mutants lacking one, two, or three N-linked glycans on gp64 were about 10- to 100-fold lower than wild-type levels. This reduction did not correlate with reductions in the expression, transport, or inherent fusogenic activity of the mutant gp64s or in the gp64 content of mutant budded virus particles. However, all of the mutant viruses bound more slowly than the wild type. Therefore, elimination of one or more N-glycosylation sites in AcMNPV gp64 impairs binding of budded virus to the cell, which explains why viruses containing these mutant forms of gp64 produce less infectious progeny.     

Studies of the Nucleopolyhedrovirus Infection Process in Insects by Using the Green Fluorescence Protein as a Reporter

A recombinant Autographa californica multicapsid nucleopolyhedrovirus (AcMNPV) expressing the green fluorescence protein (GFP) under the control of the AcMNPV polyhedrin promoter was constructed to study the spatial and temporal regulation of baculovirus infection in a permissive host. Larvae that ingested AcMNPV-GFP showed localized expression of GFP in the midgut epithelial cells, as well as hemocytes, at 24 h postinfection. The presence of fluorescence in these tissues indicated not only that the virus was replicating but also that the very late viral proteins were being synthesized. Secondary infection occurred within the tracheal cells throughout the body cavity, confirming earlier reports, and these foci of infection allowed entry of the virus into other tissues, such as the epidermis and the fat body.     

Bombyx mori Nucleopolyhedrovirus Encodes a DNA-Binding Protein Capable of Destabilizing Duplex DNA

A DNA-binding protein (designated DBP) with an apparent molecular mass of 38 kDa was purified to homogeneity from BmN cells (derived from Bombyx mori) infected with the B. mori nucleopolyhedrovirus (BmNPV). Six peptides obtained after digestion of the isolated protein with Achromobacter protease I were partially or completely sequenced. The determined amino acid sequences indicated that DBP was encoded by an open reading frame (ORF16) located at nucleotides (nt) 16189 to 17139 in the BmNPV genome (GenBank accession no. {"type":"entrez-nucleotide","attrs":{"text":"L33180","term_id":"3745835","term_text":"L33180"}}L33180). This ORF (designated dbp) is a homolog of Autographa californica multicapsid NPV ORF25, whose product has not been identified. BmNPV DBP is predicted to contain 317 amino acids (calculated molecular mass of 36.7 kDa) and to have an isoelectric point of 7.8. DBP showed a tendency to multimerization in the course of purification and was found to bind preferentially to single-stranded DNA. When bound to oligonucleotides, DBP protected them from hydrolysis by phage T4 DNA polymerase-associated 3′→5′ exonuclease. The sizes of the protected fragments indicated that a binding site size for DBP is about 30 nt per protein monomer. DBP, but not BmNPV LEF-3, was capable of unwinding partial DNA duplexes in an in vitro system. This helix-destabilizing ability is consistent with the prediction that DBP functions as a single-stranded DNA binding protein in virus replication.

Nucleopolyhedroviruses (NPVs) have large (80- to 180-kb) circular double-stranded DNA (dsDNA) genomes, which replicate in nuclei of infected cells. Despite the widespread use of NPVs for the expression of foreign genes and their potential for pest control, little is known about the mechanism of their replication and the properties of their replication factors. The most widely studied baculovirus, Autographa californica multicapsid NPV (AcMNPV), has the potential to encode about 150 proteins (3), including factors required for virus DNA replication. The products of nine viral genes (ie-1, ie-2, lef-1, lef-2, lef-3, dnahel, dnapol, p35, and lef-7 or pe-38) are necessary and sufficient for efficient replication of transfected plasmid DNAs containing a putative baculovirus replication origin (16, 22). It is likely that DNA polymerase and DNA helicase, which are encoded by the viral genes dnapol and dnahel, respectively (20, 35), form a core of the virus DNA replication machinery. The roles of other factors are less obvious. Single-stranded DNA binding (SSB) protein function was proposed for the protein LEF-3, which binds specifically single-stranded DNA (ssDNA) (10, 14). However, direct proof for the SSB function of LEF-3 in viral DNA replication is lacking. In addition, SSB function was also suggested for LEF-7 on the basis of its predicted amino acid sequence (22). It was recently demonstrated that LEF-1 forms a complex with LEF-2 and may serve as a DNA primase (9). The function of IE-1, IE-2, and PE-38 may result from their ability to activate in trans expression of other genes required for virus replication. The transactivator IE-1 may also participate in the initiation of DNA replication, due to its ability to bind putative replication origins (7, 13, 17, 33). P35 is an inhibitor of apoptosis and may not be involved directly in DNA replication. Its stimulatory effect in the transient-replication assay may result from inhibition of virus-induced apoptosis in cells transfected with the replication genes. Several genes required for DNA replication (six essential and three stimulatory) were also identified in the genome of Orgyia pseudotsugata NPV (1). Homology of these genes to those required for replication of AcMNPV suggests similar replication mechanisms for the two viruses. The genome organization of the Bombyx mori NPV (BmNPV) closely resembles that of AcMNPV. Nineteen homologs of the AcMNPV late expression factor genes (lef genes) were identified in BmNPV (12). At least three of these, ie-2, lef7, and p35, are not essential for virus DNA replication as demonstrated by deletion analysis (12). Because the daughter DNA molecules synthesized under control of the nine essential viral genes appear to be synthesized as concatemers (16, 22, 31, 32), factors required for maturation of nascent DNA and its further processing are still unknown. Although the nine AcMNPV factors were sufficient for efficient DNA replication in Sf cells, an additional viral gene, designated hcf-1, was essential for replication in TN-368 cells (21), indicating dependence of the transient assay on host cell-specific factors. Few proteins involved in NPV DNA replication have been purified from infected cells and characterized in cell-free systems. Among them are AcMNPV DNA polymerase (28, 37), BmNPV DNA polymerase (27), AcMNPV DNA helicase (19), and AcMNPV LEF-3 (10, 14). Isolation of other replication proteins of NPVs is still anticipated.In this report we describe the purification of a viral DNA-binding protein (designated DBP) from BmNPV-infected cells. DBP binds preferentially to ssDNA and is capable of unwinding duplex DNA. The BmNPV open reading frame (ORF) encoding DBP (dbp gene) is a homolog of AcMNPV ORF25, whose product has not been identified so far.     

In Vivo and In Vitro Analysis of Baculovirus ie-2 Mutants

Upon transient expression in cell culture, the ie-2 gene of Autographa californica nuclear polyhedrosis virus (AcMNPV) displays three functions: trans activation of viral promoters, direct or indirect stimulation of virus origin-specific DNA replication, and arrest of the cell cycle. The ability of IE2 to trans stimulate DNA replication and coupled late gene expression is observed in a cell line derived from Spodoptera frugiperda but not in a cell line derived from Trichoplusia ni. This finding suggested that IE-2 may exert cell line-specific or host-specific effects. To examine the role of ie-2 in the context of infection and its possible influence on the host range, we constructed recombinants of AcMNPV containing deletions of different functional regions within ie-2 and characterized them in cell lines and larvae of S. frugiperda and T. ni. The ie-2 mutant viruses exhibited delays in viral DNA synthesis, late gene expression, budded virus production, and occlusion body formation in SF-21 cells but not in TN-5B1-4 cells. In TN-5B1-4 cells, the ie-2 mutants produced more budded virus and fewer occlusion bodies but the infection proceeded without delay. Examination of the effects of ie-2 and the respective mutants on immediate-early viral promoters in transient expression assays revealed striking differences in the relative levels of expression and differences in responses to ie-2 and its mutant forms in different cell lines. In T. ni and S. frugiperda larvae, the infectivities of the occluded form of ie-2 mutant viruses by the normal oral route of infection was 100- and 1,000-fold lower, respectively, than that of wild-type AcMNPV. The reduction in oral infectivity was traced to the absence of virions within the occlusion bodies. The infectivity of the budded form of ie-2 mutants by hemocoelic injection was similar to that of wild-type virus in both species. Thus, ie-2 mutants are viable but exhibit cell line-specific effects on temporal regulation of the infection process. Due to its effect on virion occlusion, mutants of IE-2 were essentially noninfectious by the normal route of infection in both species tested. However, since budded viruses exhibited normal infectivity upon hemocoelic injection, we conclude that ie-2 does not affect host range per se. The possibility that IE-2 exerts tissue-specific effects has not been ruled out.     

Application of a novel radioimmunoassay to identify baculovirus structural proteins that share interspecies antigenic determinants

Immunological comparisons were made of baculovirus structural proteins by using a modification of the radioimmunological techniques described by Renart et al. (Proc. Natl. Acad. Sci. U.S.A. 76: 3116-3120, 1979) and Towbin et al. (Proc. Natl. Acad. Sci. U.S.A. 76: 4350-4354, 1979). Viral proteins were electrophoresed in polyacrylamide gels, transferred to nitrocellulose, and incubated with viral antisera, and the antibodies were detected with ¹²⁵I-labeled Staphylococcus aureus protein A. Antisera were prepared to purified and intact virions from five baculoviruses: Autographa californica, Porthetria dispar, Trichoplusia ni, and Heliothis zea nuclear polyhedrosis viruses (NPVs) and T. ni granulosis virus (GV). These antisera were tested against the virion structural polypeptides of 17 different species of baculoviruses. Specific multiple-nucleocapsid NPV (MNPV), single-nucleocapsid NPV (SNPV), and GV virion polypeptides were shown to have similar antigenic determinants and thus be immunologically related. The molecular weights of the virion polypeptides with cross-reacting antigenic determinants were identified. Antisera prepared to purified A. californica and H. zea MNPV polyhedrin (the occlusion body protein from NPVs) recognized antigenic determinants on all the polyhedrins and granulins (occlusion body protein from GVs) that were tested. No immunological relationship was detected between A. californica MNPV polyhedrin and any of the A. californica MNPV virion structural polypeptides present on either the virus isolated from occlusion bodies or A. californica MNPV extracellular virus from infected-cell cultures.     

Naturally Occurring Deletion Mutants Are Parasitic Genotypes in a Wild-Type Nucleopolyhedrovirus Population of Spodoptera exigua

A wild-type nucleopolyhedrovirus (NPV) isolate from Spodoptera exigua from Florida (Se-US2) is a variant of the SeMNPV type strain since it has a unique DNA profile but is closely related to other known geographical isolates of SeMNPV. It consists of several genotypic variants, of which seven were identified in a Se-US2 virus stock by a modification of the in vivo cloning method developed by Smith and Crook (Virology 166:240–244, 1988). The US2A variant was the most prevalent genotype, and it was designated the prototype Se-US2 variant, while four of the variants (US2B, US2D, US2F, and US2H) were found at low frequency. US2C and US2E were also very abundant, and their diagnostic bands were easily observed in wild-type isolate restriction endonuclease patterns. The analysis of each variant, compared to the prototype US2A, showed that US2B and US2H presented minor differences, while US2D and US2F contained slightly larger insertions or deletions. Variants US2C and US2E contained major deletions of 21.1 and 14 kb, respectively, mapping at the same genomic region (between 14.5 and 30.2 map units [m.u.] and between 12.8 and 23 m.u., respectively). This is the first report of such deletion mutants in a natural baculovirus population. Variants US2A, US2B, US2D, US2F, and US2H were isolated as pure genotypes, but we failed to clone US2C and US2E in vivo. When these two variants appeared without apparent contamination with any other variant, they lost their pathogenicity for Spodoptera exigua larvae. A further biological characterization showed evidence that these two naturally occurring deletion mutants act as parasitic genotypes in the virus population. Bioassay data also demonstrated that pure US2A is significantly more pathogenic against second-instar S. exigua larvae than the wild-type isolate. The need for precise genotypic characterization of a baculovirus prior to its development as a bioinsecticide is discussed.     

Localization of a Baculovirus-Induced Chitinase in the Insect Cell Endoplasmic Reticulum

Confocal immunofluorescence microscopy was used to demonstrate that the Autographa californica nucleopolyhedrovirus (AcMNPV) chitinase was localized within the endoplasmic reticulum (ER) of virus-infected insect cells. This was consistent with removal of the signal peptide from the chitinase and an ER localization motif (KDEL) at the carboxyl end of the protein. Chitinase release from cells, a prerequisite for liquefaction of virus-infected insect larvae, appears to be aided by synthesis of the p10 protein. Deletion of p10 from the AcMNPV genome delayed the appearance of chitinase activity in the medium of virus-infected cells by 24 h and also delayed liquefaction of virus-infected Trichoplusia ni larvae by the same period.     

Two Naturally Occurring Nuclear Polyhedrosis Virus Variants of Neodiprion sertifer Geoffr. (Hymenoptera; Diprionidae)

Two isolates of Neodiprion sertifer (Geoffr.) nuclear polyhedrosis virus from Britain and North America were compared using three biochemical techniques. Alkaline protease assays of polyhedra revealed the presence of endogenous enzyme activity in the British isolate but not in the North American isolate. Sodium dodecyl sulfate polyacrylamide gel electrophoresis of virus particle structural polypeptides revealed only minor differences, with the exception that the North American virus was contaminated with polyhedral protein. The restriction endonucleases SalI, HindIII, and HpaII were used as a definitive method of distinguishing the two variants, with all endonucleases achieving this to a greater or lesser extent. The possible significance of all of these observations is discussed in terms of their possible influence on the registration and field application of this virus.     

The Orf18 gene product from conjugative transposon Tn916 is an ArdA antirestriction protein that inhibits type I DNA restriction-modification systems

Gene orf18, which is situated within the intercellular transposition region of the conjugative transposon Tn916 from the bacterial pathogen Enterococcus faecalis, encodes a putative ArdA (alleviation of restriction of DNA A) protein. Conjugative transposons are generally resistant to DNA restriction upon transfer to a new host. ArdA from Tn916 may be responsible for the apparent immunity of the transposon to DNA restriction and modification (R/M) systems and for ensuring that the transposon has a broad host range. The orf18 gene was engineered for overexpression in Escherichia coli, and the recombinant ArdA protein was purified to homogeneity. The protein appears to exist as a dimer at nanomolar concentrations but can form larger assemblies at micromolar concentrations. R/M assays revealed that ArdA can efficiently inhibit R/M by all four major classes of Type I R/M enzymes both in vivo and in vitro. These R/M systems are present in over 50% of sequenced prokaryotic genomes. Our results suggest that ArdA can overcome the restriction barrier following conjugation and so helps increase the spread of antibiotic resistance genes by horizontal gene transfer.