Virus with a Multipartite Superhelical DNA Genome from the Ichneumonid Parasitoid Campoletis sonorensis

Cloning and expression of a gene encoding a Campoletis sonorensis polydnavirus structural protein

Polydnaviruses are the only known group of mutualistic viruses. They are required for successful parasitization in many braconid and ichneumonid parasitoids. The intimacy of this mutualistic association is indicated by the integration and vertical transmission of polydnaviruses in wasp genomes and by their asymptomatic, developmentally regulated replication. The evolution of this mutualism raises several interesting issues that require a better understanding of the viral genome and viral replication. To develop probes for virus replication and morphogenesis, we have begun to characterize several viral structural proteins. A 699 bp cDNA encoding the p12 viral structural protein was cloned and sequenced. The p12 gene localizes to viral segment Y and encodes a predicted protein of 92 amino acids that does not encode a signal peptide and is unrelated to known peptide or nucleic acid sequences. The p12 mRNA is detected at the onset of virus replication. mRNA titers increase with increasing rates of virus replication. Polyclonal antisera raised against histidine-tagged p12 protein expressed in bacteria reacted specifically with the p12 polypeptide in Western blots of CsPDV virions. The p12 polypeptide was not detected in non-replicative wasp or lepidopteran tissues by Western blot analyses but was readily detected in protein extracts of wasp ovaries. The data indicate that the p12 gene is a viral gene encoding a virion protein and provides a specific probe for virus replication that will be useful for studying the evolution of this group of mutualistic viruses.

Relationships between polydnavirus genomes and viral gene expression

Polydnavirus genomes and viral gene functions are atypical for viruses. Polydnaviruses are the only group of viruses with segmented DNA genomes and have an unusual obligate mutualistic association with parasitic Hymenoptera, in which the virus is required for survival of the wasp host and vice versa. The virus replicates asymptomatically in the wasp host but severely disrupts lepidopteran host physiology in the absence of viral DNA replication. It is not surprising then that viral gene expression is divergent in its two insect hosts and that differences in viral gene expression are linked to these divergent functions. Some viral genes are expressed only in the wasp host while other viral genes are expressed only in the lepidopteran host and are presumed to be involved in the disruption of host physiological systems. Our laboratory has described the expression and regulation of a family of viral genes implicated in suppressing the lepidopteran immune system, the cys-motif genes. In conjunction with these studies we have described the physical organization of additional viral gene segments. We have cloned, mapped and begun the sequence analysis of selected viral DNA segments. We have noted that some viral DNA segments are nested and that nested viral DNA segments encode the abundantly expressed, secreted cys-motif genes. Conversely, other viral segments are not nested, encode less abundantly expressed genes and may be targeted intra-cellularly. These results suggest that nesting of segments in polydnavirus genomes may be linked to the levels of gene expression. By extension, the unique, segmented organization of polydnavirus genomes may be associated, in part, with the requirement for divergent levels of viral gene expression in lepidopteran hosts in the absence of viral DNA replication.

Homologous sequences in the Campoletis sonorensis polydnavirus genome are implicated in replication and nesting of the W segment family

Polydnaviruses (PDVs) are double-stranded DNA viruses with segmented genomes that replicate only in the oviducts of some species of parasitic wasps and are required for the successful parasitization of lepidopteran insects. PDV DNA segments are integrated in the genomes of their associated wasp hosts, and some are nested; i.e., smaller segments are produced from and largely colinear with larger segments. To determine the internal structure of nested viral segments, the first complete nucleotide sequence of a PDV genome segment and its integration locus was determined. By restriction mapping, Southern blot, and sequence analyses, we demonstrated that the Campoletis sonorensis PDV segment W is integrated into wasp genomic DNA. DNA sequence analysis revealed that proviral segment W terminates in two 1,185-bp direct long terminal repeats (LTRs) in the wasp chromosome, while only one LTR copy is present in the extrachromosomal (viral) W. The results suggest that terminal direct repeats are a general feature of PDV DNA segment integration but that the homology and size of the repeats can vary extensively. Segment W contains 12 imperfect direct repeats of six different types between 89 bp and 1.9 kbp with 65 to 90% homology. The orientation and structure of the repeats suggest that W itself may have arisen through sequence duplication and subsequent divergence. Mapping, hybridization, and sequence analyses of cloned R and M demonstrated that these segments are nested within segment W and that internal imperfect direct repeats of one type are implicated in the homologous intramolecular recombination events that generate segments R and M. Interestingly, segment nesting differentially increases the copy number of genes encoded by segment W, suggesting that the unusual genomic organization of PDVs may be directly linked to the unique functions of this virus in its obligate mutualistic association with parasitic wasps.

Purification and analysis of a polydnavirus gene product expressed using a poly-histidine baculovirus vector

The VHv1.1 polydnavirus gene has been implicated in suppressing the encapsulation response in parasitized insects [Li and Webb (1994) J. Virol. 68, 7482-7489]. In order to characterize this gene product and to further our analysis of its immunosuppressive function, we expressed the VHv1.1 using a custom-designed C-terminal poly-histidine baculovirus vector which allows for high expression and single-step purification of the protein. The 34 kDa VHv1.1 protein was expressed in baculovirus-infected cell cultures and in H. virescens larvae. Highly enriched preparations of the secreted VHv1.1 protein were obtained after affinity chromatography using a NTA-(Ni2+) resin. Characterization with purified preparations of the VHv1.1 protein established that the protein is N-glycosylated, containing glycogroups which are PNGase F-sensitive but Endo H-resistant. The recombinant VHv1.1 protein bound to hemocytes in vitro and in vivo and was endocytosed in a manner similar to the native protein produced in CsPDV-infected larvae.

Expression and hemocyte-targeting of a Campoletis sonorensis polydnavirus cysteine-rich gene in Heliothis virescens larvae

The polydnavirus associated with the parasitic wasp Campoletis sonorensis is injected into the lepidopteran insect, Heliothis virescens, during parasitization, after which viral gene products suppress the cellular immune system of the hosts. Four related cysteine-rich polydnavirus gene have been identified in parasitized H. virescens larvae and grouped into a family. In this study, we investigated the expression and hemocyte targeting of the cysteine-rich VHv1.4 protein. Full-length and truncated VHv1.4 proteins were produced in a bacterial expression system, and the purified proteins were used to raise polyclonal antisera. In immunoblots the VHv1.4 protein was detected in parasitized insects as early as 6 h and throughout the entire course of parasitism. The VHv1.4 protein appeared predominantly in the plasma fraction of hemolymph from parasitized larvae, suggesting that this protein is secreted. The VHv1.4 protein expressed from a recombinant baculovirus was secreted in two lepidopteran cell lines and in larvae injected with the recombinant virus. Digestion with endoglycosidases suggests that the VHv1.4 protein is glycosylated at multiple N-glycosylation sites. Immunofluorescence assays showed that the VHv1.4 protein binds to the hemocytes, most notably the granulocytes, in H. virescens larvae. After binding, the VHv1.4 protein was internalized, probably by endocytosis. Specific binding of the VHv1.4 to granulocytes implies an important function in the suppression of host cellular encapsulation response.

Polydnavirus-facilitated endoparasite protection against host immune defenses

The polydnavirus of Campoletis sonorensis has evolved with an unusual life cycle in which the virus exists as an obligate symbiont with the parasite insect and causes significant physiological and developmental alterations in the parasite's host. The segmented polydnavirus genome consists of double-stranded superhelical molecules; each segment is apparently integrated into the chromosomal DNA of each male and female wasp. The virus replicates in the nucleus of calyx cells and is secreted into the oviduct. When the virus is transferred to the host insect during oviposition, gene expression induces host immunosuppression and developmental arrest, which ensures successful development of the immature endoparasite. In the host, polydnavirus expression is detected by 2 hr and during endoparasite development. Most of the abundantly expressed viral genes expressed very early after parasitization belong to multigene families. Among these families, the "cysteine-rich" gene family is the most studied, and it may be important in inducing host manifestations resulting in parasite survival. This gene family is characterized by a similar gene structure with introns at comparable positions within the 5' untranslated sequence and just 5' to a specific cysteine codon (*C) within a cysteine motif, C-*C-CC-C-C. Another unusual feature is that the nucleotide sequences of introns 2 in the subfamily WHv1.0/WHv1.6 are more conserved than those of the flanking exons. The structures of these viral genes and possible functions for their encoded protein are considered within the context of their endoparasite and virus strategy for genetic adaptation and successful parasitization.

Apparent functional role for a cysteine-rich polydnavirus protein in suppression of the insect cellular immune response

Polydnaviruses suppress the cellular immune response and inhibit growth and development in their lepidopteran host, allowing survival of their endoparasitic hymenopteran host. Characterization of genes disrupting insect physiological systems is a major objective in the study of polydnaviruses. Recently, a cysteine-rich gene family encoding a motif composed of invariable cysteine residues flanking hypervariable intercysteine amino acids was described (S.D. Dib-Hajj, B.A. Webb, and M.D. Summers, Proc. Natl. Acad. Sci. USA 90:3765-3769, 1993). They noted similarities to the positive selection pressure for mutations within the vertebrate major histocompatibility complex (MHC) class II genes and speculated that this class of polydnavirus genes may target and disrupt the insect immune system. To study the functional activity of this family of predicted cysteine-rich proteins, the VHv1.1 gene product was produced from bacterial and baculovirus expression systems. Polyclonal antiserum produced from the bacterial fusion protein reacted with a 30-kDa protein from hemocytes, cell-free plasma, and fat body of parasitized larvae. Immunofluorescence analysis of hemocytes from parasitized insects detected the 30-kDa protein bound to granulocytes and plasmacytes. To assay the functional activity of the 30-kDa VHv1.1 protein, a recombinant baculovirus was constructed allowing in vivo expression of the 30-kDa polydnavirus protein from infected insects. Expression of the VHv1.1 protein from the baculovirus system reduced the encapsulation response to washed wasp eggs relative to controls. The experimental evidence demonstrates that Campoletis sonorensis polydnavirus-infected cells secrete VHv1.1 into the hemolymph, where it binds to hemocytes and is associated with the inhibition of the cellular immune response.

Expression of polydnavirus genes from the parasitoid wasp Cotesia kariyai in two noctuid hosts

DNA purified from polydnavirus particles isolated from the parasitoid wasp Cotesia kariyai contained double-stranded closed circular molecules which were polydisperse in molecular weight. 2 days after viral injection into the host armyworm larvae viral DNA was detected in all tested larval tissues, including haemocytes, fat body, nerve cord and brain. Viral transcripts were also observed in all the tissues of virus-injected larvae. The most specific tissue was haemocytes because more viral DNA and RNA was detected than in the other tissues. Viral transcripts were not detected in haemocytes of virus-injected larvae of common cutworm. The present data suggest that C. kariyai virus (CkV) gene expression occurs species-specifically, although viral DNA can be detected in all tested tissues of the habitual host armyworm.

Evidence for an early immunosuppressive role for related Campoletis sonorensis venom and ovarian proteins in Heliothis virescens

Shared epitopes among venom, ovarian, and viral proteins may indicate that related proteins have similar functional roles during parasitization of Heliothis virescens by Campoletis sonorensis. Venom and ovarian proteins are introduced directly into the hemolymph during parasitization where they may target hemocytes or other components of the immune system. Polydnavirus expression has been detected in hemocytes, fat body, and other tissues but has not been detected earlier than 4 h after parasitization. Therefore, effects on hemocytes at times earlier than 4 h may not be caused by polydnavirus proteins synthesized in the parasitized insect. Visualization of hemocyte F-actin with fluorescently labeled phallicidin indicated that a dramatic alteration of plasmatocyte and granulocyte cytoskeletons occurred within 1.5 h after parasitization. The predominant non-viral proteins in the ovary introduced during parasitization were immunologically related to venom and viral envelope proteins. These ovarian proteins persist in the hemolymph. Antisera to the ovarian proteins bound to granulocytes and to plasmatocytes to a lesser degree, suggesting that ovarian proteins may be involved in early suppression of the host's immune response after parasitization.

Structure and evolutionary implications of a "cysteine-rich" Campoletis sonorensis polydnavirus gene family

For successful parasitization, the female Campoletis sonorensis endoparasitic wasp injects a polydnavirus into its host, Heliothis virescens, during oviposition. Viral gene expression induces immunosuppression and alters development of the host. We report here that three abundantly expressed genes, VHv1.1, WHv1.0, and WHv1.6, describes a polydnavirus "cysteine-rich" gene family which may be important in inducing these host manifestations. These genes have a similar primary gene structure and their proteins contain cysteine motifs characteristic of snail ion-channel ligands, the omega-conotoxins. Like the omega-conotoxins, the intercysteine amino acid residues are hypervariable with only three identical amino acids in all motifs. The conservation of this domain in the three viral genes may reflect an important functional role for these viral proteins in the parasitization of H. virescens. The three genes also contain introns similar in sequence at comparable positions in their 5' untranslated leaders and coding sequences. VHv1.1 contains two cysteine motifs, and each motif is interrupted by an intron at the same position as in the cysteine motifs of WHv1.0 and WHv1.6. Intron 2 sequences of WHv1.0 and WHv1.6 are 92% identical, while the immediately flanking exon sequences encoding the cysteine motifs are only 76% identical. This provides an example of nuclear pre-mRNA introns which are more conserved than flanking exons among members of a gene family.

Polydnavirus genome segment families in the ichneumonid parasitoid Hyposoter fugitivus

Sequences homologous to encapsidated polydnavirus genome segments are routinely detected in parasitoid chromosomal DNA; typically, each viral genome segment hybridizes to a single cognate chromosomal locus. In the present study, we show that in some cases, two or more viral genome segments may hybridize to the same chromosomal locus. Genome segments of this type invariably share a majority of restriction enzyme sites, a fact suggesting derivation from a common template. Families of viral genome segments appear to be relatively common in the Hyposoter fugitivus polydnavirus genome.

Generation and analysis of defective genomes of Autographa californica nuclear polyhedrosis virus

We have generated defective genomes of Autographa californica nuclear polyhedrosis virus (AcNPV) by serial, undiluted passage in IPLB-SF-21 cell culture in an attempt to identify potential cis-acting sequences important for AcNPV DNA replication. Viral DNA isolated from some of the 81 serial passages was analyzed by pulsed-field gel electrophoresis, restriction endonuclease analysis, and Southern blot hybridization. AcNPV-defective genomes appeared to be generated through a series of successively smaller and transiently stable intermediates. Although the defective genomes at passages later than passage 65 (P65) were somewhat heterogeneous in size, those of the majority of the population had a mean size estimated to be 50 kb, or 40% of that of standard virus. Defective genomic DNA at P81 hybridized strongly only to a 2.8-kb region mapping within 85.0 to 87.2 map units of AcNPV DNA (most of HindIII-K and a small part of HindIII-B), suggesting that the majority of P81-defective genomes were missing most of the 128-kb wild-type DNA sequence, except for this small 2.8-kb fragment. Furthermore, our results indicated that the defective genomes of P81 were composed largely of reiterations of this sequence. We suggest that the 2.8-kb DNA segment retained by the defective AcNPV genomes of P81 contains an important cis-acting element(s) sufficient for viral DNA replication in AcNPV-infected cells.

Polydnavirus DNA is integrated in the DNA of its parasitoid wasp host

The polydnavirus Campoletis sonorensis virus (CsV) is present in the oviducts of all adult C. sonorensis female wasps and appears to be required for these wasps to parasitize hosts successfully. Physical mapping, Southern blot analysis, and nucleotide sequence analysis demonstrate that the viral DNA B-specific sequences in cloned wasp DNA are colinear with viral genomic segment DNA B from nucleocapsids and are covalently linked to nonviral wasp sequences. Integrated DNA B terminates in 59-nucleotide imperfect direct repeats, but a single repeat exists in the extrachromosomal superhelical viral DNA B. Sequences near each junction form imperfect inverted repeats with sequences near the ends of an internal viral 540-base-pair repeat element gene. CsV appears to be the first documented integrated, nonretroviral DNA virus of insects and probably is vertically transmitted as a provirus.

Parasitoid virus-like particles destroy Drosophila cellular immunity

Parasitoid wasps must avoid the destructive effects of the host's cellular defense system in order to exploit the host hemocoel as a suitable environment for their survival. To protect their eggs from encapsulation by Drosophila melanogaster blood cells, Leptopilina heterotoma females inject a factor that selectively destroys lamellocytes, the type of Drosophila blood cell involved in recognition and encapsulation of large foreign objects. Other types of host blood cells, including the phagocytic plasmatocytes, remain functional. This report demonstrates that the destructive factor for lamellocytes is a virus-like particle (VLP) stored in the reservoir of an accessory gland associated with the female wasp reproductive system. We show that VLPs enter Drosophila blood cells in vitro. VLPs are found free in the cytoplasm of lamellocytes but are confined to phagocytic vesicles of plasmatocytes. As lamellocytes are susceptible to the VLP infection and plasmatocytes are not, we conclude that the mode of VLP entry and its disposition in the cytoplasm determine the fate of the infected host blood cell.

Venom and viral expression products of the endoparasitic wasp Campoletis sonorensis share epitopes and related sequences

Endoparasitic wasps of lepidopteran insects must induce changes in host immunity and development to survive. Depending on the species, this may require wasp venom proteins and/or a polydnavirus. We describe an immunological and genetic relationship between the Campoletis sonorensis polydnavirus and the wasp's venom gland. Monoclonal antibodies raised against venom glands recognized epitopes conserved on several polydnavirus proteins and on multiple wasp oviduct and venom proteins. The viral envelope proteins had molecular masses of 16, 20, 45, and 50 kDa, while a complex of at least five immunoreactive venom-gland and soluble oviduct proteins ranged in size from 24 to 36 kDa. Since the conserved epitopes were present on the viral envelope, neutralization assays were performed. Monoclonal antibodies added to purified virus blocked the normal viral inhibition of host growth and development. To determine whether venom mRNA and viral genes were also related, venom-related cDNA clones were isolated from the wasp oviduct with a venom-gland cDNA probe. Venom-related viral clones were then identified and selected from a viral genomic library and from a parasitized Heliothis virescens cDNA library. Venom-related mRNAs were expressed in the venom gland, the oviduct, and the parasitized host. We propose that the immunological relationship between venom and viral proteins, and the hybridization of venom and viral genes, may reflect an evolutionary relationship in which venom gene homologs were incorporated into the viral genome, thereby allowing viral expression of venom-related genes and enhancing parasite survival.

Cloning and expression of NDV hemagglutinin-neuraminidase cDNA in a baculovirus expression vector system

The hemagglutinin-neuraminidase (HN) gene of the Hitchner B1 strain of Newcastle disease virus (NDV) was cloned as a cDNA and inserted into a baculovirus expression vector. The recombinant HN (recHN) expressed in Spodoptera frugiperda cells had both hemagglutinating and neuraminidase activities both of which were inhibited by polyclonal anti-NDV sera or a monoclonal antibody (MAb) against HN. Infected insect cells could hemadsorb chicken red blood cells suggesting that the recHN is properly glycosylated and transported to the cell surface. A 67-kDa recHN precursor and a 74-kDa, presumably mature, recHN from infected cells were detected by Western blot analysis and were found to comigrate with similar proteins from NDV-infected chick embryo fibroblast cells. The kinetics of synthesis of recHN was similar to that for polyhedrin and some HN appeared in the extracellular medium. HN was copurified with extracellular virus (ECV) from the extracellular medium and was used to immunize chickens. The anti recHN serum was specific to NDV in both ELISA and Western blot analysis.

Segment W of Campoletis sonorensis virus: expression, gene products, and organization

Campoletis sonorensis virus (CsV, Polydnaviridae) is a segmented double-stranded DNA virus which has an apparently symbiotic relationship with the parasitic wasp, Campoletis sonorensis. CsV replicates in the oviducts of the parasitic wasp and is injected into the wasp's host, Heliothis virescens (Lepidoptera; Noctuiidae), during oviposition. In the parasitized lepidopteran host, the virus has a dramatic effect on host physiology and viral gene products are believed to play an essential role in the survival of the parasitic wasp's egg and larva. In the current study, we used Northern blot analyses to examine expression from segment W in the parasitized host and in the parasitic wasp. Segment W hybridized primarily to two relatively abundant mRNAs (1.6 and 1.0 kb) from the parasitized host. These 1.6- and 1.0-kb mRNAs, which were previously shown to be transcribed from two closely related genes (WHv1 and WHv2) on segment W (G. W. Blissard, O. P. Smith, and M. D. Summers, 1987, Virology 160, 120-134) increased in relative abundance between 2 and 24 hr postparasitization (pp) and were detected throughout parasitization (8 days). To study the proteins encoded by these closely related genes, the open reading frame from each of the related genes was cloned into a baculovirus expression vector. By pulse labeling in the presence and absence of tunicamycin, we examined secretion and glycosylation of these CsV proteins in infected lepidopteran cells (Spodoptera frugiperda). Expression of segment W in the oviducts of the female wasp was also examined. Segment W hybridized to at least five CsV mRNAs on Northern blots of poly(A) mRNA from C. sonorensis oviducts. To identify specific CsV mRNAs and map putative viral genes expressed in wasp oviduct tissues, segment W was used to screen a cDNA library of C. sonorensis oviduct mRNAs. Three cDNAs were used to identify CsV mRNAs by Northern blot analyses and to map the locations of three putative CsV genes on segment W. Cross-hybridization within the CsV genome was examined with cloned segment W and with the three cloned cDNAs.

Interference with function of plasmatocytes of Heliothis virescens in vivo by calyx fluid of the parasitoid Campoletis sonorensis

Immature stages of the ichneumonid parasitoid, Campoletis sonorensis, develop within the haemocoel of its noctuid host, Heliothis virescens. The host cannot encapsulate the parasitoid egg owing to the suppressive effect of the polydnavirus-laden calyx fluid injected by the female parasitoid during oviposition. We have examined the effects of injection of calyx fluid on the following haemocytic manifestations of the immune system of 5th-instar larvae of H. virescens: encapsulation, nodulation, phagocytosis, erythrocyte rosetting and coagulation. Of these phenomena, only those requiring the formation of a multicellular sheath of plasmatocytes were affected. In general, encapsulation was fully suppressed; all of the C. sonorensis eggs and most of the glass rods implanted as targets were devoid of attached haemocytes 3 days after implantation although a few of the latter were coated by a sparsely distributed layer of granulocytes. Plasmatocytes also appeared to be present in thicker depositions of haemocytes. In nodulation, only the second, encapsulation-like phase was inhibited. The resistant first stage, involving the entrapment of particles by haemocytes, only resulted in the formation of amorphous, disorganized nodules. Granulocyte-dependent aspects of the immune system (phagocytosis, rosetting and possibly coagulation and the first stage of encapsulation and nodulation) occurred normally. The data suggest that in 5th-instar hosts injection of calyx fluid acts specifically on plasmatocyte function.

An unusual virus from the parasitic wasp Cotesia melanoscela

Certain strains of the braconid parasitoid Cotesia melanoscela carry two different viruses within their ovaries, one of which (here designated CmV2) is apparently not a polydnavirus. Virus replication occurs in the ovarian calyx and in some other tissues of both male and female parasitoids; as yet, no replication has been observed in the testis, however. In addition, CmV2 is one of only two parasitoid viruses known to replicate in host insect larvae, and we not show that this virus is also capable of replicating in vitro; the virus is nevertheless nonpathogenic for gypsy moth larvae. The virus is not transmissible per os, either to host animals or to larvae of parasitoid strains lacking it. CmV2 is stably maintained within strains carrying it apparently by a vertical transmission mode involving the maternal line; transmission via the male germ line could not be demonstrated. While purification of the virus was not achieved, preliminary work allows us to suggest the genome consists of a single double-stranded DNA molecule of approximately 125 kb.

Two related viral genes are located on a single superhelical DNA segment of the multipartite Campoletis sonorensis virus genome

Campoletis sonorensis virus (CsV) (Polydnaviridae) is a large eucaryotic DNA virus with a structurally complex genome consisting of 28 or more superhelical (SH) DNA segments. Little is known of the relationship between different SH DNAs, but some SH DNAs do cross hybridize, indicating a relatedness between certain SH DNAs. In a previous study of viral expression in parasitized Heliothis virescens larvae, several partially homologous viral mRNAs were also identified (G. W. Blissard, S. B. Vinson, and M. D. Summers, 1986, J. Virol. 57, 318-327). To study the organization of the viral genome and the relationship between two partially homologous viral mRNAs, we analyzed cDNA clones and a cloned SH DNA segment of the CsV genome. Of the two CsV mRNAs examined (1.6 and 1.0 kb), both mRNAs were abundant at 48 hr after parasitization and the 1.6-kb mRNA was detected as early as 2 hr after parasitization. Nucleotide sequence analyses of cDNA clones representing the two partially homologous CsV mRNAs (1.6 and 1.0 kb) show that the two CsV mRNAs share five regions of imperfect homology (68 to 88%) which include a large part of each mRNA. These data indicate that the two mRNAs are transcribed from two separate but closely related CsV genes. Comparison of predicted amino acid sequences shows that the two related viral genes encode proteins with divergent amino acid sequences. Northern and Southern hybridization analyses using cloned cDNAs as probes showed that one CsV mRNA (1.6 kb) is homologous to CsV SH DNAs W, R, and M, while the other mRNA (1.0 kb) shows strong homology only to SH DNA W. By cloning and Southern hybridization mapping of the 15.8-kbp SH DNA W, we demonstrate that the genes for the related 1.6- and 1.0-kb mRNAs are located on different regions of this single 15.8-kbp SH DNA. Alignment of nucleotide sequences from a cloned viral genomic DNA and a cDNA demonstrates that the CsV gene encoding the 1.6-kb mRNA is a spliced gene containing at least two introns. Conservation of splice junctions between the two mRNAs suggests that the 1.0-kb mRNA is also spliced. These data represent the detailed analysis of two closely related CsV mRNAs abundantly expressed in parasitized H. virescens larvae, the first observation of related viral genes in a eucaryotic DNA virus, the demonstration of splicing in the Polydnaviridae, and the cloning and mapping of one of the largest SH DNA segments of the CsV genome.

Physical Analysis of the Campoletis sonorensis Virus Multipartite Genome and Identification of a Family of Tandemly Repeated Elements

This report is an analysis of cross-hybridizing sequences found within the 28 superhelical (SH) DNAs of the multipartite genome of the polydnavirus Campoletis sonorensis virus (CsV). A Southern cross-blot hybridization analysis showed that the majority of CsV Eco RI restriction fragments cross-hybridize to multiple Eco RI fragments. These sequence homologies were analyzed by hybridizing recombinant clones of the CsV SH DNAs B, H, M, and O 1 to Southern blots of undigested CsV DNA, using different hybridization stringencies. The results indicated that homologous regions among the SH DNAs include closely related sequences that are detectable under stringent conditions and related but more diverged sequences which are only detectable under reduced stringencies. A sequence that hybridized to the majority of the CsV SH DNAs was identified and subcloned from the SH DNAs O 1 , H, and B. Nucleotide sequence data revealed that these homologous regions contained a family of imperfectly conserved repeated elements. These repeat elements were arranged singly or in direct tandem arrays and had an average length of 540 base pairs. Within the sequenced regions that contained the repeated elements six putative open reading frames were identified. These results show that the CsV genome consists of SH DNAs with complex sequence interrelationships that may have arisen due to multiple recombinational events.

Studies on polydnavirus transmission

Polydnaviruses are thought to replicate only in the ovaries of certain hymenopteran species. Nevertheless, in the present study, polydnaviral DNA was found to exist in males of the braconid parasitoid species Cotesia melanoscela and in both male and female non-ovarian tissue of an ichneumonid, Hyposoter fugitivus; preliminary results suggest that viral DNA may be present in an unintegrated form, but whether or not it is encapsidated is unknown. Using interstrain genetic crosses, we demonstrated that C. melanoscela males can apparently transmit at least some viral DNA to female progeny. We suggest that polydnavirus DNAs may be present in most if not all tissues of certain parasitoid species, and are probably maintained within parasitoid populations by vertical transmission through the germ line. In parallel experiments, manually injected eggs of the ichneumonid parasitoid (H. fugitivus) survived and hatched in Malacosoma americanum larvae in the apparent absence of exogenous polydnavirus; female parasitoids reared in this manner nevertheless carried virus in their ovaries. Experiments utilizing different strains of C. melanoscela also suggest that per os transmission of polydnaviruses (to parasitoid larvae) does not occur, despite the fact that inoculum viral DNA can be shown to persist for several days in the tissues of parasitized host larvae.

Campoletis sonorensis Endoparasitic Wasps Contain Forms of C. sonorensis Virus DNA Suggestive of Integrated and Extrachromosomal Polydnavirus DNAs

Campoletis sonorensis virus (CsV) ( Polydnaviridae ) previously was detected only in the calyx epithelial cells and lumen of the oviducts from female C. sonorensis (Ichneumonidae) endoparasitic wasps (Norton et al., Cell Tissue Res. 162:195-208, 1975). Using dot-blot hybridizations, we detected low amounts of CsV DNA in male and female wasp head and thorax tissues and in male abdominal tissues. Low amounts of extrachromosomal viral DNA were detected in Southern blots of undigested male wasp DNA and in male DNA purified by isopycnic centrifugation. High-molecular-weight male wasp DNA digested with any of several restriction endonucleases and hybridized with cloned viral DNAs from CsV superhelices B and Q under stringent conditions contained CsV-specific DNA fragments that differed significantly in size and number from the hybridizing fragments detected in comparably digested viral DNA. Identical offsize restriction fragments were detected in digested female head and thorax DNA. These data suggest that at least CsV DNAs B and Q are integrated in C. sonorensis cellular DNA and that the virus may be transmitted through the germline.

Identification, Mapping, and In Vitro Translation of Campoletis sonorensis Virus mRNAs from Parasitized Heliothis virescens Larvae

Expression of Campoletis sonorensis virus (CsV) in parasitized Heliothis virescens larvae was investigated by Northern blot analysis of poly(A) + mRNAs isolated from H. virescens larvae at various times after parasitization by C. sonorensis. At least 12 CsV mRNAs were detected in parasitized H. virescens larvae. Injection of nonparasitized H. virescens larvae with purified CsV resulted in a pattern of viral mRNAs similar to that observed in naturally parasitized larvae. With CsV DNA restriction fragments which contained expressed sequences, individual CsV mRNAs were mapped to the superhelical DNAs of the viral genome. Two gene-specific probes, which consisted of cloned S1 nuclease-protected restriction fragments, each hybridized to several CsV superhelical DNAs, suggesting that some CsV genes may be shared on several superhelical DNAs. Cloned restriction fragments containing sequences which flank the expressed sequences also hybridized to numerous CsV superhelical DNAs. Some CsV proteins were identified by in vitro translation of hybrid-selected CsV mRNAs.

Metabolic integration during the host associations of multicellular animal endoparasites

The nature of metabolic interaction during parasitic infection was discussed and the concept of metabolic integration outlined. The subjective nature of the integrative argument was noted. The parasite-host relationships of larval trematodes of the genus Schistosoma with their intermediate molluscan hosts, the nematode Trichnella spiralis and cestode Hymenolepis diminuta, with their definitive hosts, as well as the hymenopterous insect parasite, Hyposoter exiguae, with its insect host, Trichoplusia ni, were examined. The significance of the immune system in the establishment of the parasite-host association and the means by which parasites evade host defense were discussed. The involvement of microorganisms or "hyperparasites" during the host associations of multicellular parasites was described. The importance of evolutionary considerations in assessing the nature of metabolic interaction and its significance to the success of the parasite-host relationship was emphasized. The use of teleological assessment and anthropomorphic description was discussed.

Expression of Campoletis sonorensis Virus in the Parasitized Host, Heliothis virescens

Polyadenylated mRNA transcripts of the virus of Campoletis sonorensis were detected in Heliothis virescens host larvae 2 h after the larvae had been parasitized by C. sonorensis females and continued to be present in host larvae through 9 days postparasitization while C. sonorensis developed endoparasitically. cDNAs of viral transcripts present in H. virescens hybridized with only certain C. sonorensis viral DNAs.