Effects of Reticuloendotheliosis virus on TLR-3/IFN-Β pathway in specific pathogen-free chickens.

Birds infected by Reticuloendotheliosis virus (REV) are vulnerable to other microorganisms. This immunosuppression is related to the immune organs (thymus, bursa of Fabricius, and spleen) damaged by REV. The regulation of IFN-ß greatly depends on pattern recognition receptor TLR-3 and nuclear factors IRF-7, NF-κB. To address if and how the TLR-3/IFN-ß pathway is disturbed by REV, 60 one-day-old specific-pathogen-free chickens were intraperitoneally injected with RE virus dilution (n = 30) or stroke-physiological saline solution (n = 30). At 1, 3, 7, 21, and 28 days post-infection, after collecting thymuses, bursas, and spleens, we monitor the kinetics of TLR-3, IFN-ß, NF-κB p65, and IRF-7 at transcriptional and translational levels using qPCR, Western blotting, and ELISA separately. As a result, compared with control chickens, the mRNA levels of TLR-3, IRF-7, and NF-κB p65 showed increasingly differences in the early period of REV infection. Synchronal changes occurred at translation levels. In the latter infection period, a decrease of NF-κB p65 was contemporaneous with a fall in IFN-ß at both transcriptional and translational levels in the thymuses and bursas. These data suggest that the changes of IFN-ß content are closely related to NF-κB p65 when REV invades chicken central immune organs. That reveals new insights into the immunosuppression mechanism of REV in avian.

RIOK3-Mediated Akt phosphorylation facilitates synergistic replication of Marek's disease and reticuloendotheliosis viruses.

Co-infection of Marek's disease virus (MDV) and reticuloendotheliosis virus (REV) synergistically drives disease progression, yet little is known about the mechanism of the synergism. Here, we found that co-infection of REV and MDV increased their replication via the RIOK3-Akt pathway. Initially, we noticed that the viral titres of MDV and REV significantly increased in REV and MDV co-infected cells compared with single-infected cells. Furthermore, tandem mass tag peptide labelling coupled with LC/MS analysis showed that Akt was upregulated in REV and MDV co-infected cells. Overexpression of Akt promoted synergistic replication of MDV and REV. Conversely, inhibition of Akt suppressed synergistic replication of MDV and REV. However, PI3K inhibition did not affect synergistic replication of MDV and REV, suggesting that the PI3K/Akt pathway is not involved in the synergism of MDV and REV. In addition, we revealed that RIOK3 was recruited to regulate Akt in REV and MDV co-infected cells. Moreover, wild-type RIOK3, but not kinase-dead RIOK3, mediated Akt phosphorylation and promoted synergistic replication of MDV and REV. Our results illustrate that MDV and REV activated a novel RIOK3-Akt signalling pathway to facilitate their synergistic replication.

Analysis of the spleen proteome of chickens infected with reticuloendotheliosis virus.

Infection with reticuloendotheliosis virus (REV), a gammaretrovirus in the family Retroviridae, can result in immunosuppression and subsequent increased susceptibility to secondary infections. In the present study, we identified differentially expressed proteins in the spleens of chickens infected with the REV-A HLJ07I strain, using two-dimensional gel electrophoresis on samples from time points coinciding with different phases of the REV life cycle. Differentially expressed proteins were identified using one-dimensional liquid chromatography electrospray ionization tandem mass spectrometry (1D LC ESI MS/MS). Comparative analysis of multiple gels revealed that the majority of changes occurred at early stages of infection. In total, 60 protein spots representing 28 host proteins were detected as either quantitatively (false discovery rate [FDR] ≤0.05 and fold change ≥2) or qualitatively differentially expressed at least once during different sampling points. The differentially expressed proteins identified in this study included antioxidants, molecular chaperones, cellular metabolism, formation of the cytoskeleton, signal transduction, cell proliferation and cellar aging. The present findings provide a basis for further studies to elucidate the role of these proteins in REV-host interactions. This could lead to a better understanding of REV infection mechanisms that cause immune suppression.

[Prokaryotic expression, purification and identification of the recombinant gp90 protein of Reticuloendotheliosis virus].

OBJECTIVE: To obtain the recombinant gp90 protein of Reticuloendotheliosis virus (REV) and the anti-gp90 serum with high titer. METHODS: Using the plasmid pMD18T-env as template, we amplified the gp90 gene and then cloned it into pET-28a(+). The recombinant plasmid pET28a-gp90 was transformed into Escherichia coli BL21 (DE3), which was induced with isopropylthio-beta-D-galactoside(IPTG). After identification by SDS-PAGE and Western blotting, the purified gp90 protein was injected into Balb/c mice to prepare anti-gp90 serum. The specificity and titer of the antiserum were evaluated by IFA and the enzyme-linked immunosorbant assay (ELISA). RESULTS: SDS-PAGE and Western blotting showed that the gp90 protein was expressed successfully in the form of inclusion body in the recombinant E coli. ELISA showed the mouse anti-gp90 serum had a titer of 1:12800. Successful expression of recombinant gp90 protein and preparation of its antiserum laid the foundation for the development of diagnostic reagent of REV.

The v-Rel oncoprotein complexes with new Rel- and RelA-related proteins in transformed cells.

The v-Rel oncoprotein of the Rev-T retrovirus interacts with a number of cellular proteins in transformed chicken spleen cells including p40/I kappa B alpha, p68c-Rel, hsc70, and the p124 and p115 precursors for the p50 and p52 subunits of NF kappa B. Here we report that v-Rel associates with at least three other cellular proteins of 75-85 kDa in these cells, as well as with a protein related to human RelA. Western blot analysis of v-Rel immune complexes showed cross-reactivity between all of these factors and antibodies raised against Rel sequences, but none appeared to represent isoforms of c-Rel. Synchronization experiments revealed that the expression and/or association of these proteins with v-Rel varied throughout the cell cycle. Combined with the previously described interaction of v-Rel with known members of the Rel family, these studies strengthen the hypothesis that the interaction of v-Rel with multiple Rel-related proteins may be important for the transformation of lymphoid cells.

Analytical study of avian reticuloendotheliosis virus dimeric RNA generated in vivo and in vitro.

The retroviral genome consists of two identical RNA molecules associated at their 5' ends by a stable structure called the dimer linkage structure. The dimer linkage structure, while maintaining the dimer state of the retroviral genome, might also be involved in packaging and reverse transcription, as well as recombination during proviral DNA synthesis. To study the dimer structure of the retroviral genome and the mechanism of dimerization, we analyzed features of the dimeric genome of reticuloendotheliosis virus (REV) type A and identified elements required for its dimerization. Here we report that the REV dimeric genome extracted from virions and infected cells, as well as that synthesized in vitro, is more resistant to heat denaturation than avian sarcoma and leukemia virus, murine leukemia virus, or human immunodeficiency virus type 1 dimeric RNA. The minimal domain required to form a stable REV RNA dimer in vitro was found to map between positions 268 and 452 (KpnI and SalI sites), thus corresponding to the E encapsidation sequence (J. E. Embretson and H. M. Temin, J. Virol. 61:2675-2683, 1987). In addition, both the 5' and 3' halves of E are necessary in cis for RNA dimerization and the extent of RNA dimerization is influenced by viral sequences flanking E. Rapid and efficient dimerization of REV RNA containing gag sequences in addition to the E sequences and annealing of replication primer tRNA(Pro) to the primer-binding site necessitate the nucleocapsid protein.

The v-rel oncogene product is complexed with cellular proteins including its proto-oncogene product and heat shock protein 70.

The oncogene product, pp59v-rel, of avian reticuloendotheliosis virus (REV-T) is complexed in the cytosol of REV-T transformed lymphoid cells with cellular proteins. Monoclonal antibodies and antisera directed against different regions of pp59v-rel coimmunoprecipitate five cellular proteins (p124, p115, p75, p70, and p40) in addition to pp59v-rel. Cellular proteins with the same apparent molecular mass also copurify with pp59v-rel during sequential Sephacryl S200 and immunoaffinity chromatography. Antisera directed against the most abundant cellular protein in the complex, pp40, coimmunoprecipitate pp59v-rel and several cellular proteins with the same apparent molecular mass. The 75-kDa protein in the pp59v-rel complex is the product of c-rel proto-oncogene and is weakly phosphorylated. In MSB-1 cells this protein is not detectably phosphorylated or associated with cellular proteins. The 70-kDa protein in the pp59v-rel containing cytosolic complex is the constitutive form of avian heat shock protein 70 (HSC70). The p70 protein coimmunoprecipitates and copurifies with pp59v-rel using antisera directed against pp59v-rel and coimmunoprecipitates with antisera specific for pp40. The p70 isolated from immune complexes containing pp59v-rel shares V8 protease fragments with HSC70.

Viral rel and cellular rel associate with cellular proteins in transformed and normal cells.

The rel oncogene from the avian reticuloendotheliosis virus strain T is a 59 kd phosphoprotein localized primarily to the cytoplasm of transformed cells. Recently, the v-rel protein was shown to associate with several cellular proteins with molecular weights of 124 kd, 115 kd, and 36 kd. We have analysed the subcellular distribution of v-rel protein complexes after biochemical fractionation of [35S]methionine and [32P]orthophosphate labeled cells. Our results demonstrate that the v-rel protein coprecipitates with a characteristic set of proteins, some of which are distinct to nuclear or cytoplasmic fractions. We also demonstrate that the normal cellular homolog of the viral rel protein, c-rel, coprecipitates with several cellular proteins from normal chick hematopoietic tissue. These cellular proteins have apparent molecular weights similar to those which are coprecipitated with v-rel from cytoplasmic fractions. Our results demonstrate that both v-rel and c-rel interact with a variety of cellular proteins and suggest that this association is important for the function or regulation of the rel protein.

Novel glycosylation pathways of retroviral envelope proteins identified with avian reticuloendotheliosis virus.

Previously, we identified two mature glycoproteins, gp90, the surface glycoprotein, and gp20, the transmembrane protein, from avian reticuloendotheliosis virus and an avian reticuloendotheliosis virus env gene-encoded intracellular polyprotein gPr77env, but the precise relationship of gPr77env to the mature envelope proteins was not determined (W.-P. Tsai, T.D. Copeland, and S. Oroszlan, Virology 155:567-583, 1986). In the present study, using metabolic labeling of viral proteins with [35S]cysteine, radioimmunoprecipitation, and carbohydrate structure analysis, we have identified a higher-molecular-weight endo-H-resistant env gene-encoded polyprotein designated gPr115env in addition to the endo-H-sensitive gPr77env. It appears that gPr77env is the primary polyprotein precursor, modified with mannosyloligosaccharides that are processed into sialic-acid-rich extraordinarily large complex-type carbohydrates (up to 17 kilodaltons for each N-linked site) on the gp90 domain but not on the gPr22 domain. In this process, gPr77env is converted into the apparently endo-H-resistant secondary polyprotein, gPr115env, which is rapidly processed into gp90 and gPr22. The proteolytic processing which occurs only after the appearance of an endo-H resistant precursor is now clearly demonstrated for a retrovirus. Some important aspects of carbohydrate structure, including the site-specific glycosylation, as well as the intracellular location and nature of the potential enzyme involved in the proteolytic cleavage of gPr115env are discussed.

Biosynthesis and chemical and immunological characterization of avian reticuloendotheliosis virus env gene-encoded proteins.

Two glycosylated proteins designated gp90 and gp20 were purified from replication-competent avian reticuloendotheliosis associated virus (REV-A). The N-terminal sequences of gp90 and gp20 were determined and found to match the REV-A-env-gene sequence. The alignments of the determined amino acid sequences with the predicted sequence indicate that gp20 and gp90 are the REV-A-encoded viral transmembrane and surface glycoprotein, respectively, and predict a signal peptide of 36 residues on the 5' end of the env-gene. Furthermore, gp90 of REV-A was detected by Western blot analysis with antibodies to a tridecapeptide corresponding to an env-gene nucleotide segment immediately preceding gp20 and thus representing the C-terminal portion of gp90. The env-gene precursor polyprotein gPr75-79env and Pr22(E), the precursor to gp20 and p2(E) were identified in the infected cells by monospecific antibodies raised against purified gp20. Thus the organization of gPR75-79env is likely to be N-gp90-gp20-p2(E), resembling that of M-MuLV gp85env. Sequence comparisons showed that the env gene of REV-A is highly related to both baboon endogenous virus and Type D retroviruses. In Western blot analyses, antibodies to REV-A gp20 cross-reacted with a panel of mammalian Type C and Type D viruses. Evolutionary aspects of these findings are discussed.

Detection and characterization of the protein encoded by the v-rel oncogene.

To identify the protein encoded by v-rel, the oncogene of reticuloendotheliosis virus (REV-T), antisera have been raised to three synthetic peptides derived from the translation of our previously published v-rel DNA sequence [R.M. Stephens, N.R. Rice, R.R. Hiebsch, H.R. Bose, Jr., and R.V. Gilden, Proc. Natl. Acad. Sci. USA 80, 6229-6233 (1983)]. Sera to all three peptides precipitate a 59,000 Da protein from REV-T-transformed chicken lymphoid cells. This protein is not detectable in uninfected chick embryo fibroblasts, and its observed size is in good agreement with the 56,000 Da predicted by the DNA sequence. We conclude that this protein is the v-rel product and designate it p59rel. To search for evidence of post-translational processing of this protein, cells were grown in the presence of glycosylation inhibitors. These resulted in no detectable difference in the size of p59rel. Nor was its size detectably altered during the course of a pulse-chase experiment. Growth of cells in the presence of [32P] orthophosphate, however, revealed that p59rel is a phosphoprotein. It is also closely associated with a protein kinase activity, for precipitation with one of the peptide antisera (but not the other two) resulted in strong kinase activity in the immune complex pellet. During this reaction, p59rel itself becomes phosphorylated. Kinase activity was retained in the immune complex following detergent and high salt washes, leaving open the possibility that p59rel is itself a kinase.

Oncogene expression in reticuloendotheliosis virus-transformed lymphoid cell lines and avian tissues.

The genome of reticuloendotheliosis virus (REV-T) contains a unique oncogene, designated v-rel, which is inserted into the env region. Employing a cloned rel DNA probe, a single 2.9- to 3.0-kilobase v-rel mRNA was identified in poly(A)+ RNA from REV-T-transformed lymphoid cell lines. A 4.0-kilobase rel-specific transcript corresponding to the cellular homolog of the v-rel oncogene was identified in MSB-1 cells, a herpesvirus-transformed lymphoid cell line. Cytodot hybridization was used to quantitate the levels of rel, c-rel, c-myc, c-myb, c-abl, c-fms, c-Ha-ras, c-Ki-ras, c-src, c-yes, c-mos, and c-sis mRNA in REV-T-transformed cells. The levels of rel transcription in REV-T-transformed cells were elevated only two to eightfold over levels found in the transformed immature avian lymphoid cell line MSB-1. The relatively modest levels of rel transcription in REV-T-transformed cells and the significant differences between the lengths of the v-rel and c-rel mRNA suggest that REV-T transformation is the result of the production of an altered rel protein. The c-rel proto-oncogene is expressed in all avian hematopoietic tissues but is not expressed at significant levels in brain and muscle. The transcription of other proto-oncogenes is not enhanced in REV-T-transformed lymphoid cell lines.

Assembly of avian reticuloendotheliosis virus: association of the core precursor polypeptide with the intracellular ribonucleoprotein complex.

A virus-specific ribonucleoprotein complex is present in the cytoplasm of reticuloendotheliosis virus-transformed chicken bone marrow cells. This ribonucleoprotein complex contains viral reverse transcriptase activity and may represent a precursor to the budding virion. The major viral polypeptide associated with the ribonucleoprotein complex was a polypeptide with a molecular weight of 63,000. This protein exhibited a precursor-product relationship with the major reticuloendotheliosis virus structural core protein p29. Core polypeptides were not associated with the intracellular ribonucleoprotein complex. Thus, p29 was incorporated into the virion in the form of its precursor Pr63. The cleavage of Pr63 in the ribonucleoprotein complex was accomplished either during the budding process of shortly after the release of particles from the cell.

Low-molecular-weight RNAs and initiation of RNA-directed DNA synthesis in avian reticuloendotheliosis virus.

The small RNAs of avian reticuloendotheliosis virus (REV) were analyzed by two-dimensional polyacrylamide gel electrophoresis and compared with those of murine leukemia virus and avian sarcoma virus. Although there were some similarities among the three virus types, the patterns of small RNAs were distinct. By characterizing the small RNA which is most tightly associated with REV genome RNA and which can be labeled in limited DNA synthesis reactions, the primer for REV reverse transcription was identified as tRNAPro. This is consistent with previous reports that REV is more closely related to retroviruses of mammalian origin than to other avian viruses. In contrast, REV strong-stop complementary DNA is longer than any previously characterized strong-stop products of avian or mammalian retroviruses. The REV group may, therefore, have been derived from an as yet unidentified mammalian type C virus.

Cell killing by spleen necrosis virus is correlated with a transient accumulation of spleen necrosis virus DNA.

Spleen necrosis virus productively infects avian and rat cells. The average number of molecules of unintegrated and integrated viral DNA in cells at different times after infection was determined by hybridization and transfection assays. Shortly after infection, there was a transient accumulation of an average of about 150 to 200 molecules of unintegrated linear spleen necrosis virus DNA per chicken, turkey, or pheasant cell. No such accumulation was seen in infected rat cells. Soon after infection there was in chicken cells, but not inturkey, pheasant, or rat cells, also a transient integration of an average of 35 copies of viral DNA per cell. By 10 days after infection, the majority of this integrated viral DNA was lost from the population of infected chicken cells. At the same time, the majority of the unintegrated viral DNA was also lost from infected chicken, turkey, and pheasant cells. The transient cytopathic effect seen in these infected cells also occurred at this time. Late after infection about five copies of apparently nondefective spleen necrosis proviruses were stably integrated at multiple sites in chicken, turkey, pheasant, and rat DNA. These results demonstrate a correlation between the transient accumulation of large numbers of spleen necrosis virus DNA molecules and the transient occurrence of cytopathic effects.

Infectious DNA of spleen necrosis virus is integrated at a single site in the DNA of chronically infected chicken fibroblasts.

The infectious DNAs of a number of avian leukosis-sarcoma and reticuloendotheliosis viruses were digested with six nucleotide-specific restriction endonucleases, and the digests were tested for infectivity. All of the enzymes inactivated the viral infectivities except for EcoRI, which did not inactivate the infectivity of the DNA of two of the reticuloendotheliosis viruses, spleen necrosis and chick syncytial viruses. The infectious DNA of spleen necrosis virus after digestion with EcoRI had a buoyant density in CsCl solution greater than the density of the high-molecular-weight infectious viral DNA. The infectious EcoRI-digested spleen necrosis virus DNA from chronically infected chicken cells was uniform in size, 10 megadaltons, which indicated a single site of integration. The infectious EcoRI-digested spleen necrosis virus DNA from acutely infected cells was heterogeneous in size, ranging from 8-14 megadaltons, which indicated multiple sites of integration. These results are consistent with the hypothesis that cells that integrate infectious spleen necrosis virus DNA at a single site survive and multiply, whereas cells that integrate infectious viral DNA at additional sites either die or selectively lose or inactivate the DNA in the additional sites.

Effect of medium of lowered NaCl concentration on virus release and protein synthesis in cells infected with reticuloendotheliosis virus.

When cultures producing reticuloendotheliosis virus were incubated for 24 h in medium of lowered NaCl concentration, virus production was inhibited. The extent of inhibition increased as the salt concentration of the medium was decreased. The inhibition was rapidly reversed by replacement of low-salt medium with normal medium. During the first hour after the inhibited cultures were returned to normal medium, virus was released at an accelerated rate, making the total amount of virus released by inhibited and control cultures the same. After 1 h in normal medium, the rate of virus production in the previously inhibited cultures was the same as in the control cultures. Incubation of infected cells in low-salt medium resulted in a 60% decrease in the overall rate of protein synthesis. Although returning the cells to normal medium rapidly reversed the inhibition of virus production, it did not rapidly increase the rate of protein synthesis. These results suggest that host cell-directed protein synthesis is preferentially inhibited by the low-ionic-strength medium, whereas that required for virus production continues.

Infectious DNA from cells infected with Rous sarcoma virus, reticuloendotheliosis virus or Rous-associated virus-O.

We have described an efficient and quantitative assay for infectious DNA of the avian ribodeoxyviruses and have applied this method to study the possible existence of infectious viral DNAs in uninfected cells. Infectious DNA from cells infected with RSV or REV consisted of a single unit of DNA with a specific infectivity of 10(-5)-10(-6). The minimum molecular weight of RSV DNA required for infection of chicken cells was about 6 million, while the minimum molecular weight of infectious REV DNA was about 20 million. This difference may reflect complementation of the RSV DNA by endogenous avian leukosis virus-related DNA in uninfected chicken cells. Uninfected chicken cells do not contain infectious DNA for an REV, nor for a strongly transforming or a nontransforming avian leukosis virus.