Analysis of translational products of Friend strain of spleen focus-forming virus.

We have analyzed normal rat kidney cells nonproductively infected with the Friend strain of spleen focus-forming virus (SFFV) for the presence of murine leukemia virus-specific type C viral proteins. SFFV was found to code for the p15 and p12 proteins of Friend-murine leukemia virus as determined by immunological typing of their antigenic determinants. Molecular-size analysis of p15 and p12 proteins in SFFV nonproductively infected normal rat kidney cells indicated that these proteins are translated as parts of polyprotein molecules. The apparent molecular weights of the polypeptides bearing p12 antigenic determinants revealed the presence of translational products of the SFFV genome that could not be accounted for by know type C virus helper structural proteins.     

Sequence comparisons of the anemia- and polycythemia-inducing strains of Friend spleen focus-forming virus.

A nucleotide sequence analysis carried out on the envelope gene of the anemia-inducing strain of the Friend spleen focus-forming virus (F-SFFVA) reveals that its product has some unique features in common with previously described polycythemia-inducing strains of F-SFFV (F-SFFVP). (i) It contains an amino terminus that is highly related to the gp70 of mink cell focus-inducing viruses, (ii) it is a fusion protein containing the amino terminus of gp70 and the carboxy terminus of p15E, and (iii) it lacks the R-peptide normally found at the carboxy end of the p15E region. Although the envelope genes of F-SFFVA and F-SFFVP are quite similar overall, they do show sequence variation, particularly at the 3' end in the p15E-related region. These variations may contribute to previously observed differences in the response of F-SFFVP- and F-SFFVA-infected erythroid cells to regulatory hormone or to differences in the way the envelope glycoproteins are processed. The long terminal repeat regions of F-SFFVA and the Lilly-Steeves strain of F-SFFVP were also sequenced and compared with each other and with a previously published sequence of another F-SFFVP long terminal repeat. The sequences were found to be reasonably similar to each other but different from their ecotropic parent, Friend murine leukemia virus, as a result of a deletion of one copy of the direct tandem repeat in the enhancer regions. The observation that all SFFVS have this common change in the long terminal repeat enhancer region raises the possibility that it is required for pathogenicity.     

Membrane association and defective transport of spleen focus-forming virus glycoproteins

The gp52 glycoprotein of the spleen focus-forming virus found in the Friend and Rauscher complexes of murine leukemia viruses (MuLV) has been previously identified as a recombinant molecule involving substitutions and deletions of the MuLV env gene. Unlike the MuLV structural glycoproteins, gp52 is defective in its transport to the cell surface. We have studied aspects of the intracellular transport and membrane association of gp52 to investigate the possible mechanisms underlying the defective transport process. It was found that a panel of monoclonal antibodies to different epitopes of p 15E, as well as an antiserum to a synthetic peptide corresponding to the carboxy terminus of MuLV envelope precursors, failed to react with gp52. Despite the possible absence of membrane-anchoring regions of MuLV envelope proteins known to reside on p 15E, gp52 was not found to be secreted into the culture fluids. Detergent extraction studies indicated that gp52 is associated with the membranes and not the contents of microsomal vesicles in speen focus-forming virus-infected cells. gp65, the processed form of gp52, could be labeled with [3H]palmitic acid, suggesting a membrane association. To determine whether a spontaneous denaturation occurs leading to aggregation and defective transport of gp52, we studied the surface expression of gp52 in cells grown at different temperatures, as well as the solubility of gp52 in low concentrations of Triton X-100. No evidence of aggregation or of a temperature-dependent difference in transport was obtained. gp52 appears to be a monotopic integral membrane protein, unlike MuLV envelope proteins which are bitopic integral membrane proteins; proteolytic digestion of intact microsomal vesicles did not reveal a detectable cytoplasmic tail under conditions where this could be demonstrated on MuLV envelope precursors. We suggest that a loss of putative signals involved in mediating intracellular transport is a likely cause for the defective transport of the spleen focus-forming virus glycoproteins.     

Heteroduplex analysis of molecular clones of the pathogenic Friend virus complex: Friend murine leukemia virus, Friend mink cell focus-forming virus, and the polycythemia- and anemia-inducing strains of Friend spleen focus-forming virus.

The pathogenic Friend virus complex is of considerable interest in that, although members of this group are genetically related, they differ markedly in biochemical and biological properties. Heteroduplex mapping of molecular clones of the Friend virus complex, which includes the replication-competent ecotropic Friend murine leukemia virus (F-MuLV) and mink cell focus-forming virus (F-MCF) and replication-defective polycythemia- and anemia-inducing strains of spleen focus-forming virus (SFFVp and SFFVa, respectively), was employed to provide insight into the molecular basis of their relationships. In heteroduplexes of F-MuLV X F-MCF, a major substitution of 0.89 kilobases in the env gene of F-MCF was discerned. Heteroduplexes of SFFVp X F-MuLV or F-MCF and SFFVa X F-MuLV or F-MCF showed several major deletions in the pol gene region and a single major deletion in the 3' half of the env gene region of SFFVp and SFFVa. A major substitution of 0.89 kilobases was mapped to the 5' end of the env deletion of SFFVp and SFFVa in heteroduplexes with F-MuLV, similar to that seen in F-MuLV X F-MCF heteroduplexes. In contrast, this env gene region was totally homologous in F-MCF X SFFVp or SFFVa and SFFVp X SFFVa heteroduplexes. Our results suggest that (i) both SFFVp and SFFVa lack part of the env gene at its 3' end, corresponding to the p15(E) coding region, (ii) major deletions occur in the pol and env genes which account for the replication defectiveness of SFFVp and SFFVa, (iii) minor substitutions occur in the gag gene region of SFFVa that are not present in SFFVp, F-MuLV, or F-MCF, (iv) a major substitution exists in the gp70 region of the env gene between F-MuLV and F-MCF that probably accounts for the differences in their host range specificities, (v) this substitution in F-MCF is identical to the gp70 part of the gp52 coding region of SFFVp and SFFVa, and (vi) heteroduplexes to F-MCF show unambiguously that no additional large substitutions are present in SFFVp or SFFVa that could account for differences in their leukemogenicity.     

Glycosylation pattern and processing of envelope gene products encoded by glycosylation mutants of Friend spleen focus-forming virus

The protein encoded by the envelope gene of Friend spleen focus-formingvirus is responsible for the acute leukaemogenicity of thisvirus. In order to correlate glycosylation and intracellularprocessing of this protein with viral pathogenicity, envelopegene products of pathogenic and apathogenic glycosylation mutantswere expressed in Rat-1 cells and metabolically labelled with[6-³H] glucosamine. Following immunoprecipitation, primary andsecondary gene products (gp55, gp65) were separated by preparativepolyacrylamide gel electrophoresis. Oligosaccharides were releasedfrom tryptic glycopeptides by treatment with endo-ß-N-acetylglucosaminidaseH (gp55), peptide-N⁴-(N-acetyl-ß-glucosaminyl)asparagineamidase F (gp65) or by reductive ß-elimination. Resultingglycans were characterized by cochromatography with authenticoligosaccharide standards using different HPLC systems and digestionwith exoglycosidases. The results revealed that the primaryenvelope gene products of pathogenic glycosylation mutants were,in part, further processed in Rat-1 cells similar to wild-typeglycoprotein, resulting in polypeptides carrying complex-typeN-glycans as well as partially sialylated O-linked oligosaccharides.In contrast, corresponding glycoproteins encoded by apathogenicmutants were found to remain at the level of the primary translationproduct exclusively comprising high-mannose-type N-glycans.Hence, intracellular maturation of the envelope gene productsin this model cell line seems to correlate with the in vivopathogenicityof the glycosylation mutants studied. carbohydrate structure glycoprotein murine leukaemia virus oligosaccharide processing SFFV     

Deregulation of erythropoiesis by the Friend spleen focus-forming virus

The proliferation and differentiation of erythroid cells is a highly regulated process that is controlled primarily at the level of interaction of erythropoietin (Epo) with its specific cell surface receptor (EpoR). However, this process is deregulated in mice infected with the Friend spleen focus-forming virus (SFFV). Unlike normal erythroid cells, erythroid cells from SFFV-infected mice are able to proliferate and differentiate in the absence of Epo, resulting in erythroid hyperplasia and leukemia. Over the past 20 years, studies have been carried out to identify the viral genes responsible for the pathogenicity of SFFV and to understand how expression of these genes leads to the deregulation of erythropoiesis in infected animals. The studies have revealed that SFFV encodes a unique envelope glycoprotein which interacts specifically with the EpoR at the cell surface, resulting in activation of the receptor and subsequent activation of erythroid signal transduction pathways. This leads to the proliferation and differentiation of erythroid precursor cells in the absence of Epo. Although the precise mechanism by which the viral protein activates the EpoR is not yet known, it has been proposed that it causes dimerization of the receptor, resulting in constitutive activation of Epo signal transduction pathways. While interaction of the SFFV envelope glycoprotein with the EpoR leads to Epo-independent erythroid hyperplasia, this is not sufficient to transform these cells. Transformation requires the viral activation of the cellular gene Sfpi-1, whose product is thought to block erythroid cell differentiation. By understanding how SFFV can deregulate erythropoiesis, we may gain insights into the causes and treatment of related diseases in man.     

Roles of helper and defective retroviral genomes in murine erythroleukemia: studies of spleen focus-forming virus in the absence of helper.

Retroviruses that cause acute oncogenesis are generally complexes of a replication-competent helper virus and a replication-defective component. However, the pure defective components have not been previously available. We prepared the defective spleen focus-forming virus component of Rauscher erythroleukemia virus (R-SFFV) by transfecting a colinear R-SFFV DNA clone into a retroviral packaging cell line (psi 2 cells). The transfected cells released virus (psi 2/SFFV) that was free of helper virus and that induced erythropoietin-dependent erythroid burst formation in bone marrow cultures. When injected into normal adult NIH/Swiss mice in moderate doses, psi 2/SFFV caused a rapid splenic erythroblastosis that regressed. Extensive erythroblastosis could be maintained by repeated injections of psi 2/SFFV into anemic mice or by the addition of a helper virus. We conclude that R-SFFV alone causes proliferation but not immortalization of a population of erythroblasts that is normally replenished from a precursor stem cell pool. Because these precursor cells are inefficiently infected, a single moderate inoculum of psi 2/SFFV causes a wave of erythroblastosis. The properties of the proliferating erythroblasts are substantially determined by the R-SFFV viral component.     

Biological activity of Friend spleen focus-forming virus after cold storage

Two stocks of Friend spleen focus-forming virus (SFFV) were prepared, one in saline and the other in Eagle's medium with 2% fetal calf serum, and the effects of different freezing, storage and thawing temperatures were determined for the recovery of infectious virus from each diluent. Once frozen, virus maintained its titer at ?70 and at ?170 °C for up to 13 weeks, while it lost titer at ?13 °C more rapidly if it had been prepared in saline than in medium. However, during the freezing process lower ambient temperatures (?70 and ?170 °C) gave lower virus yields than a higher temperature (?13 °C) did. Similarly, rapid thawing (in a 37 °C water bath) was less efficient than slow thawing (in 4 or 20 °C air) for the recovery of infectious SFFV, This study illustrates the importance, for efficient recovery of leukemogenic activity from stored murine leukemia virus stocks, of the temperature used for freezing or thawing, as well as for storage.     

Integration of spleen focus-forming virus proviruses in Friend tumor cells.

Using the Southern blot procedure, we studied the presumed spleen focus-forming virus (SFFV) provirus integration sites in the genome of the premalignant and the malignant cells isolated during the course of Friend erythroleukemia. Two restriction endonucleases, PstI and BamHI, discriminated the presumed integrated SFFV proviruses from the endogenous xenotropic-mink cell focus-forming viral sequences. No SFFV integration sites were detectable in the premalignant cells, suggesting a random integration of SFFV proviruses in the genome of these cells. In contrast, SFFV proviruses were detected at a single or very few sites in the genome of all malignant cells we analyzed. These results indicate that the event leading to the malignant transformation in acute Friend leukemia is clonal. In two of the six animals examined, tumors cells isolated from the spleens and the livers of individual mice showed identical SFFV integration patterns. This last result suggests that in some cases different tumors in a same leukemic animal could be derived from a unique clonal event.     

Loss of pathogenicity of spleen focus-forming virus after pseudotyping with Akv.

Friend virus complex (FV), which comprises replication-competent Friend murine leukemia virus (FMuLV) plus replication-defective spleen focus-forming virus (SFFV), induces a multistage erythroleukemia. We have examined the role of replication-competent helper virus in the early and late stages of FV disease by replacing FMuLV, the native helper, with Akv, the endogenous ecotropic MuLV of AKR mice. SFFVP/FRE, an established fibroblast line nonproductively infected with the polycythemic strain of SFFV, was superinfected with FMuLV or with Akv. Although supernatants from these cells showed similar titers in the XC plaque assay, supernatants from Akv-infected SFFVP/FRE cells showed 100- to 5,000-fold less activity than did those from FMuLV-infected cells with respect to spleen focus induction in vivo. Since virions isolated from these two supernatants contained similar ratios of SFFV to helper virus genomic RNA, it did not appear that the difference was due to a relative inability of Akv to package SFFV. Although FMuLV- and Akv-rescued SFFV are equally infectious in a mouse fibroblast cell line (NIH 3T3), FMuLV-rescued SFFV was far more efficient in inducing erythroid bursts in cultured primary bone marrow cells. Adding Akv to preparations of FMuLV-rescued SFFV did not significantly interfere with burst induction. Helper-free SFFV induced 50- to 500-fold more spleen foci when coinjected with FMuLV than it did with Akv. Helper virus also affected mortality rates that reflect the late stage of the disease. When FMuLV- or Akv-rescued SFFV was injected into NIH Swiss mice at dosage levels adjusted to give equal numbers of spleen foci, all mice receiving FMuLV-rescued SFFV developed splenomegaly and died, whereas no mice receiving Akv-rescued SFFV died or developed detectable splenomegaly. When FMuLV was coinjected with Akv-rescued SFFV, the mortality rate rose from 0 to 100%. Injection of helper-free SFFV alone did not induce mortality, but coinjection of helper-free SFFV with FMuLV resulted in 100% mortality. Thus, the helper virus used to rescue SFFV plays at least a quantitatively important role in the early stage of FV disease and a crucial role in the late stage of the disease in vivo.     

Cas spleen focus-forming virus. II. Further biological and biochemical characterization.

A new isolate of a murine erythroblastosis-inducing spleen focus-forming virus (Cas SFFV), derived from the wild mouse ecotropic murine leukemia virus Cas-Br-M, was further characterized after the production of a nonproducer cell line. When rescued from the nonproducer cells with a helper murine leukemia virus, the Cas SFFV induced rapid splenic enlargement and focus formation when inoculated into adult NFS/N mice. The Cas SFFV nonproducer cell line was also utilized to compare the envelope-related glycoprotein of Cas SFFV with gp52s from three strains of Friend SFFV. Cas SFFV was found to encode a 50,500-dalton glycoprotein (gp50) distinct in size to the envelope-related glycoproteins of the Friend SFFVs. The Cas SFFV was also compared in RNA blot hybridization studies. The genomic viral RNA of Cas SFFV was found to be slightly larger than two polycythemia-inducing strains of Friend SFFV and markedly larger than the anemia-inducing strain. Further comparisons between the SFFVs were made by examining their transforming capabilities in an in vitro erythroid burst assay. The erythroid bursts induced by Cas SFFV and the anemia-inducing strain of Friend SFFV showed similarities in their erythropoietin requirements. This study supports our recent observations that Cas SFFV is biologically similar to the anemia-inducing strain of Friend SFFV yet biochemically distinct from all Friend SFFVs.     

Phylogenetic comparison of Epstein-Barr virus genomes

Technologies used for genome analysis and whole genome sequencing are useful for us to understand genomic characterization and divergence. The Epstein-Barr virus (EBV) is an oncogenic virus that causes diverse diseases such as Burkitt’s lymphoma (BL), nasopharyngeal carcinoma (NPC), Hodgkin’s lymphoma (HL), and gastric carcinoma (GC). EBV genomes found in these diseases can be classified either by phases of EBV latency (type-I, -II, and -III latency) or types of EBNA2 sequence difference (type-I EBV, type-II EBV or EBV-1, EBV-2). EBV from EBV-transformed lymphoblastoid cell line (LCL) establishes type-III latency, EBV from NPC establishes type-II latency, and EBV from GC establishes type-I latency. However, other important factors play key roles in classifying numerous EBV strains because EBV genomes are highly diverse and not phylogenetically related to types of EBV-associated diseases. Herein, we first reviewed previous studies to describe molecular characteristics of EBV genomes. Then, using comparative and phylogenetic analyses, we phylogenetically analyzed molecular variations of EBV genomes and proteins. The review of previous studies and our phylogenetic analysis showed that EBV genomes and proteins were highly diverse regardless of types of EBV-associated diseases. Other factors should be considered in determining EBV taxonomy. This review will be helpful to understand complicated phylogenetic relationships of EBV genomes.     

Specific neutralization of defective spleen focus-forming virus in Friend virus complex by rat antiserum.

The spleen focus-forming virus (SFFV), a rapidly transforming, replication-defective virus in Friend virus (FV) complex that is readily neutralized by antisera directed against its helper virus, was examined for the presence of SFFV-specific antigens. Antisera prepared in Fisher rats against an SFFV-infected Fisher rat embryo fibroblast line (SFFV-FRE) neutralized SFFV effectively, but not Friend-associated murine leukemia virus (F-MuLV) whether the latter was tested alone or was mixed with SFFV in the FV complex. In contrast, serum from mice immunized with SFFV-infected nonproducer mouse cells had little or no neutralizing activity against SFFV. Both absorption and immunoprecipitation studies indicate that the SFFV-specific antigen is immunologically related to xenotropic murine leukemia virus antigens. The role of both SFFV- and F-MuLV-specific antigens in the neutralization of SFFV suggests that this defective virus could be an antigenic mosaic and that viruses in the FV complex may participate in a undirectional form of phenotypic mixing.     

Recovery of biologically active spleen focus-forming virus from molecularly cloned spleen focus-forming virus-pBR322 circular DNA by cotransfection with infectious type C retroviral DNA.

The genome of the Lilly-Steeves strain of spleen focus-forming virus (SFFV) was molecularly cloned in the plasmid vector pBR322. Infectious SFFV could be recovered by releasing the SFFV DNA from the vector, transfecting the released DNA onto NIH 3T3 cells, and rescuing the SFFV either by superinfection with helper virus or by cotransfection with molecularly cloned infectious helper viral DNA. By using transfections with SFFV DNA still attached to the plasmid vector, infectious SFFV activity could also be recovered with either method of rescue. Studies performed with these latter types of transfections indicated that only a portion of the SFFV genome was required for biological activity. Since gp52, a marker protein for SFFV, could be detected in all cultures from which adequate titers of biologically active SFFV were recovered, the results are consistent with the hypothesis that gp52 is necessary for SFFV-induced erythroblastosis and polycythemia.     

Conversion of Friend mink cell focus-forming virus to Friend spleen focus-forming virus by modification of the 3'' half of the env gene.

The 3' half of the env gene of the dualtropic Friend mink cell focus-forming virus was modified by replacing the restriction enzyme fragment of the genome DNA with the corresponding fragment of the acutely leukemogenic, polycythemia-inducing strain of Friend spleen focus-forming virus (F-SFFVP) genome DNA. Replacement with the fragment of F-SFFVP env containing the 585-bp deletion, the 6-bp duplication, and the single-base insertion converted the resulting chimeric genome so that the mutant had a pathogenic activity like that of F-SFFVP. Replacement with the fragment containing only the 585-bp deletion did not result in a pathogenic virus. However, when this virus pseudotyped by Friend murine leukemia virus was passaged in newborn DBA/2 mice, we could recover weakly pathogenic viruses with a high frequency. Molecular analysis of the genome of the recovered virus revealed the presence of a single-base insertion in the same T5 stretch where the wild-type F-SFFV env has the single-base insertion. These results provided evidence that the unique genomic structures present in the 3' half of F-SFFV env are the sole determinants that distinguish the pathogenicity of F-SFFV from that of Friend mink cell focus-forming virus. The importance of the dualtropic env-specific sequence present in the 5' half of F-SFFV env for the pathogenic activity was evaluated by constructing a mutant F-SFFV genome in which this sequence was replaced by the ecotropic env sequence of Friend murine leukemia virus and by examining its pathogenicity. The results indicated that the dualtropic env-specific sequence was essential to pathogenic activity.     

Intracellular transport and leukemogenicity of spleen focus-forming virus envelope glycoproteins with altered transmembrane domains.

Friend murine spleen focus-forming virus (SFFV) encodes a glycoprotein designated gp52, which is responsible for the leukemogenic properties of the virus. gp52 lacks a cytoplasmic domain and is defective in its transport to the cell surface. We constructed a chimeric envelope gene which codes for a molecule with an external domain derived from the SFFV envelope gene and membrane-spanning and cytoplasmic domains derived from the Friend murine leukemia virus envelope gene. Like gp52, the chimeric protein was defective in its transport to the cell surface, indicating that the absence of a cytoplasmic tail is not responsible for the defective intracellular transport of SFFV gp52. However, unlike wild-type SFFV, the chimeric SFFV genome failed to induce erythroleukemia in adult mice. The results indicate that the altered membrane-spanning domain, lack of a detectable cytoplasmic tail in gp52, or both factors are prerequisites for the erythroleukemia-inducing properties of SFFV but are not responsible for the block in intracellular transport of the glycoprotein.     

Identification of a spleen focus-forming virus in erythroleukemic mice infected with a wild-mouse ecotropic murine leukemia virus

An NFS/N mouse inoculated at birth with an ecotropic murine leukemia virus (MuLV) obtained from wild mice (Cas-Br-M MuLV) developed a lymphoma after 18 weeks. An extract prepared from the lymphomatous spleen was inoculated into newborn NFS/N mice, and these mice developed erythroleukemia within 9 weeks. Spleens from the erythroleukemic mice contained ecotropic and mink cell focus-inducing (MCF) MuLVs; however, when these viruses were biologically cloned and reinoculated into newborn NFS/N mice, no erythroleukemia was induced. In contrast, cell-free extracts prepared from the erythroleukemic spleens induced erythroleukemia within 5 weeks. Analysis of cell-free extracts prepared from the erythroleukemic spleens showed that they contained a viral species that induced splenomegaly and spleen focus formation in adult mice, with susceptibility controlled by alleles at the Fv-2 locus. The spleen focus-forming virus coded for a 50,000-dalton protein precipitated by antibodies specific to MCF virus gp70. RNA blot hybridization studies showed the genomic viral RNA to be 7.5 kilobases and to hybridize strongly to a xenotropic or MCF envelope-specific probe but not to hybridize with an ecotropic virus envelope-specific probe. The virus described here appears to be the fourth independent isolate of a MuLV with spleen focus-forming activity.     

Glycosylation of glycoprotein 55 encoded by the anaemia-inducing strain of Friend spleen focus-forming virus

Normal rat kidney cells, non-productively infected with the anaemia-inducing variant of Friend spleen focus-forming virus (F-SFFV_A), were metabolically labelled with [2-³H]mannose. The primary translation product of the viral envelope gene (env), representing a glycoprotein with an apparent molecularM _r of 55 000 (gp55), was isolated from cell lysates by immunoaffinity chromatography and purified by preparative SDS/PAGE. Radiolabelled oligosaccharides, released from tryptic glycopeptides by treatment with endo--N-acetylglucosaminidase H, were characterized chromatographically, by enzymic digestion and by acetolysis. The results revealed that F-SFFV_A gp55 obtained from this source carried predominantly oligomannose type sugar chains with five to nine mannoses. As a characteristic feature, glycans with seven to nine mannoses contained, in part, an additional glucose residue. Although the amount of glucosylated species found was higher in F-SFFV_A gp55 (about 25% of total endo-H-sensitive oligosaccharides) than in gp55 of the corresponding polycythaemia-inducing variant (F-SFFV_P, 16.3%), the overall glycosylation pattern of the F-SFFV_A env product closely resembled that of F-SFFV_P gp55 [Strubeet al. (1988)J Biol Chem 263:3762–71]. Hence, our results demonstrate that the different intracellular processing and transport of the primary F-SFFV_A env product cannot be attributed to aberrant trimming of its oligomannose type glycans.Abbreviations endo H endo--N-acetylglucosaminidase H fromStreptomyces griseus - env envelope gene - Env protein translation product ofenv - F-SFFV Friend spleen focus-forming virus - F-SFFV_A anaemia-inducing variant of F-SFFV - F-SFFV_P polycythaemia-inducing variant of F-SFFV - Hex hexose - NRK normal rat kidney - PNGase F peptide-N ⁴-(N-acetyl--glucosaminyl)asparagine amidase F fromFlavobacterium meningosepticum