The nucleocapsid domain is responsible for the ability of spleen necrosis virus (SNV) Gag polyprotein to package both SNV and murine leukemia virus RNA.
(1/112)
Murine leukemia virus (MLV)-based vector RNA can be packaged and propagated by the proteins of spleen necrosis virus (SNV). We recently demonstrated that MLV proteins cannot support the replication of an SNV-based vector; RNA analysis revealed that MLV proteins cannot efficiently package SNV-based vector RNA. The domain in Gag responsible for the specificity of RNA packaging was identified using chimeric gag-pol expression constructs. A competitive packaging system was established by generating a cell line that expresses one viral vector RNA containing the MLV packaging signal (Psi) and another viral vector RNA containing the SNV packaging signal (E). The chimeric gag-pol expression constructs were introduced into the cells, and vector titers as well as the efficiency of RNA packaging were examined. Our data confirm that Gag is solely responsible for the selection of viral RNAs. Furthermore, the nucleocapsid (NC) domain in the SNV Gag is responsible for its ability to interact with both SNV E and MLV Psi. Replacement of the SNV NC with the MLV NC generated a chimeric Gag that could not package SNV RNA but retained its ability to package MLV RNA. A construct expressing SNV gag-MLV pol supported the replication of both MLV and SNV vectors, indicating that the gag and pol gene products from two different viruses can functionally cooperate to perform one cycle of retroviral replication. Viral titer data indicated that SNV cis-acting elements are not ideal substrates for MLV pol gene products since infectious viruses were generated at a lower efficiency. These results indicate that the nonreciprocal recognition between SNV and MLV extends beyond the Gag-RNA interaction and also includes interactions between Pol and other cis-acting elements. (+info)
Mutational analysis of the v-Rel dimerization interface reveals a critical role for v-Rel homodimers in transformation.
(2/112)
The v-rel oncogene encoded by reticuloendotheliosis virus strain T is the acutely transforming member of the Rel/NF-kappaB family of transcription factors. In v-Rel-transformed cells, v-Rel exists as homodimers or heterodimers with the endogenous Rel/NF-kappaB proteins c-Rel, NF-kappaB1, NF-kappaB2, and RelA. To examine the contribution of these complexes to v-Rel-mediated transformation, mutations were introduced into the dimerization interface of v-Rel to generate v-Rel mutants with selective dimerization properties. Nine mutants are described in this study that are defective in homodimer and/or heterodimer formation with specific Rel/NF-kappaB family members. Viruses expressing mutants that failed to homodimerize but were able to form heterodimeric complexes were unable to transform splenic lymphocytes in vitro, indicating that the dimerization of v-Rel with endogenously expressed Rel/NF-kappaB proteins is not in itself sufficient for transformation. In addition, two partially transforming mutants were identified that exhibited an impaired ability to form homodimers. Sequence analysis of the proviral DNA from cells transformed by these mutants revealed the presence of multiple secondary mutations in sequences responsible for dimerization and DNA binding. Two of these mutations either enhanced or restored the ability of these proteins to bind DNA as a homodimer. Viruses expressing these proteins transformed cells at levels comparable to or slightly less than v-Rel, suggesting that a threshold level of DNA binding by v-Rel homodimers is required for transformation. (+info)
Reticuloendotheliosis virus sequences within the genomes of field strains of fowlpox virus display variability.
(3/112)
Nine field strains of fowlpox virus (FPV) isolated during a 24-year span from geographically diverse outbreaks of fowlpox in the United States were screened for the presence of reticuloendotheliosis virus (REV) sequences in their genomes by PCR. Each isolate appeared to be heterogeneous in that either a nearly intact provirus or just a 248- or 508-nucleotide fusion of portions of the integrated REV 5' and 3' long terminal repeats (LTRs) was exclusively present at the same genomic site. In contrast, four fowlpox vaccines of FPV origin and three originating from pigeonpox virus were genetically homogeneous in having retained only the 248-bp LTR fusion, whereas two other FPV-based vaccines had only the larger one. These remnants of integrated REV presumably arose during homologous recombination at one of the two regions common to both LTRs or during retroviral excision from the FPV genome. Loss of the provirus appeared to be a natural event because the tripartite population could be detected in a field sample (tracheal lesion). Moreover, the provirus was also readily deleted during propagation of FPV in cultured cells, as evidenced by the detection of truncated LTRs after one passage of a plaque-purified FPV recombinant having a "genetically marked" provirus. However, the deletion mutants did not appear to have a substantial replicative advantage in vitro because even after 55 serial passages the original recombinant FPV was still prevalent. As to the in vivo environment, retention of the REV provirus may confer some benefit to FPV for infection of poultry previously vaccinated against fowlpox. (+info)
Characterization of reticuloendotheliosis virus-transformed avian T-lymphoblastoid cell lines infected with Marek's disease virus.
(4/112)
The expression of Marek's disease virus (MDV) transcripts and protein products was investigated in reticuloendotheliosis virus-transformed avian T-lymphoblastoid cell line RECC-CU91, which was superinfected with MDV. The presence of MDV in the superinfected cell line, renamed RECC-CU210, was demonstrated by Southern hybridization with 32P-labeled BamHI-H and -B fragments of the BamHI MDV DNA library. Examination of RECC-CU210 for the expression of MDV-specific RNA transcripts encoded by the internal repeat long (IRL), internal repeat short (IRS), and unique short (US) regions of the MDV genome revealed two small transcripts of 0.6 and 0.7 kb. These transcripts were mapped to the IRL and IRS regions, respectively. In contrast, RECC-CU211, which was developed through transfection of CU210 with the BamHI-A fragment of MDV, expressed an additional nine transcripts from the IRL, IRS, and US regions. CU211 but not CU210 also expressed a complex of polypeptides of 40, 38, and 24 kDa, identified by monoclonal antibodies as MDV-specific phosphoproteins. The 38-kDa phosphoprotein is likely to be pp38, an early viral protein that maps within the IRL region of the MDV genome. These findings suggest that genes located within the transfected BamHI-A fragment transactivated a number of genes located in the IRL region of the MDV genome. (+info)
Retrovirus insertion into herpesvirus in vitro and in vivo.
(5/112)
Retroviruses and herpesviruses are naturally occurring pathogens of humans and animals. Coinfection of the same host with both these viruses is common. We report here that a retrovirus can integrate directly into a herpesvirus genome. Specifically, we demonstrate insertion of a nonacute retrovirus, reticuloendotheliosis virus (REV), into a herpesvirus, Marek disease virus (MDV). Both viruses are capable of inducing T lymphomas in chickens and often coexist in the same animal. REV DNA integration into MDV occurred in a recently attenuated strain of MDV and in a short-term coinfection experiment in vitro. We also provide suggestive evidence that REV has inserted into pathogenic strains of MDV in the past. Sequences homologous to the REV long terminal repeat are found in oncogenic MDV but not in nononcogenic strains. These results raise the possibility that retroviral information may be transmitted by herpesvirus and that herpesvirus expression can be modulated by retroviral elements. In addition, retrovirus may provide a useful tool to characterize herpesviral function by insertional mutagenesis. (+info)
Unusually high frequency of reconstitution of long terminal repeats in U3-minus retrovirus vectors by DNA recombination or gene conversion.
(6/112)
Recently, we described a retrovirus vector system with which to study formation of cDNA genes (R. Dornburg and H. M. Temin, Mol. Cell. Biol. 6:2328-2334, 1988; Mol. Cell. Biol. 8:64-72, 1990; J. Virol. 64:886-889, 1990). For these studies, retrovirus vectors were constructed in which the U3 region of the 3' long terminal repeat (LTR) was deleted. After one round of retrovirus replication, such vectors formed a provirus with two U3-minus LTRs. However, the insertion of some additional sequences into such vectors promoted vector rearrangements with an efficiency greater than 95%. Such rearranged vectors behaved like vectors with two wild-type LTRs. Proviruses derived from such vectors were investigated by Southern blot analysis, polymerase chain reaction, and DNA sequencing. We found that the U3 region was reconstituted, resulting in vectors with LTRs like wild-type virus. The sequences that reconstituted the U3 region of the vector LTR were derived from LTR sequences present in the helper cell. Since no retroviral protein coding sequences were detected in infected target cells, recombination of vector sequences with coencapsidated helper cell sequences during reverse transcription seems very unlikely. Thus, it appears that the recombination (or gene conversion) events leading to a vector with reconstituted LTRs occurred at the DNA level. The high frequency of this recombination (or gene conversion) was dependent on internal vector sequences. (+info)
Spleen necrosis virus, an avian immunosuppressive retrovirus, shares a receptor with the type D simian retroviruses.
(7/112)
The reticuloendotheliosis viruses (REV) are a family of highly related retroviruses isolated from gallinaceous birds. On the basis of sequence comparison and overall genome organization, these viruses are more similar to the mammalian type C retroviruses than to the avian sarcoma/leukemia viruses. The envelope of a member of the REV family, spleen necrosis virus (SNV), is about 50% identical in amino acid sequence to the envelope of the type D simian retroviruses. Although SNV does not productively infect primate or murine cells, the receptor for SNV is present on a variety of human and murine cells. Moreover, interference assays show that the receptor for SNV is the same as the receptor for the type D simian retroviruses. We propose that adaptation of a mammalian type C virus to an avian host provided the REV progenitor. (+info)
Transcriptional interaction between retroviral long terminal repeats (LTRs): mechanism of 5' LTR suppression and 3' LTR promoter activation of c-myc in avian B-cell lymphomas.
(8/112)
Chicken syncytial viruses induce bursal lymphomas by integrating into the c-myc locus and activating myc expression by 3' long terminal repeat (LTR) promoter insertion. In contrast to wild-type proviruses, in which transcription initiates predominantly in the 5'LTR, these myc-associated proviruses exhibit a predominance of transcription from the 3' LTR and little transcription from the 5' LTR. Most of these proviruses contain deletions within the 5' end of their genome that spare the 5' LTR. We report the identification of a 0.3-kb viral leader sequence that modulates 5' and 3' LTR transcriptional activities. In the presence of this sequence, transcription from the 5' LTR predominates, but in its absence, the 3' LTR promoter becomes activated, resulting in a high level of myc expression. This viral sequence does not behave like a classical enhancer; it activates transcription only when located downstream from the promoter and in the sense orientation. In this regard, it resembles the recently described human immunodeficiency virus RNA enhancer. This study suggests that retroviruses contain internal sequences which directionally activate the 5' LTR promoter to facilitate transcription of the viral genome and that deletion of these sequences is one step in the activation of the 3' LTR of myc-associated proviruses in avian bursal lymphomas. (+info)