Mink Cell Focus-forming Virus Research Articles

The Prostate Cancer-Associated Human Retrovirus XMRV Lacks Direct Transforming Activity but Can Induce Low Rates of Transformation in Cultured Cells

The human retrovirus XMRV (xenotropic murine leukemia virus-related virus) is associated with prostate cancer, but a causal relationship has not been established. Here, we have used cultured fibroblast and epithelial cell lines to test the hypothesis that XMRV might have direct transforming activity but found only rare transformation events, suggestive of indirect transformation, even when the target cells expressed the human Xpr1 cell entry receptor for XMRV. Characterization of cells from three transformed foci showed that all were infected with and produced XMRV, and one produced a highly active transforming virus, presumably generated by recombination between XMRV and host cell nucleic acids. Given the sequence similarity of XMRV to mink cell focus-forming (MCF) viruses and the enhanced leukemogenic activity of the latter, we tested XMRV for related MCF-like cytopathic activities in cultured mink cells but found none. These results indicate that XMRV has no direct transforming activity but can activate endogenous oncogenes, resulting in cell transformation. As part of these experiments, we show that XMRV can infect and be produced at a high titer from human HT-1080 fibrosarcoma cells that express TRIM5alpha (Ref1), showing that XMRV is resistant to TRIM5alpha restriction. In addition, XMRV poorly infects NIH 3T3 cells expressing human Xpr1 but relatively efficiently infects BALB 3T3 cells expressing human Xpr1, showing that XMRV is a B-tropic virus and that its infectivity is regulated by the Fv1 mouse locus.

Up-regulation of a cellular protein at the translational level by a retrovirus

Mink cell focus-forming (MCF) murine leukemia viruses (MLVs) are the etiologic agent of thymic lymphoma in mice. We have observed previously that superinfection by MCF13 MLV of certain cell types, such as preleukemic thymic lymphocytes and cultured mink epithelial cells, results in the accumulation of the viral envelope precursor polyprotein, leading to the induction of endoplasmic reticulum (ER) stress. In this study, we demonstrate that the induction of ER stress by MCF13 MLV infection results in an increase in the phosphorylation of the alpha-subunit of eukaryotic initiation factor 2. In cells in which this occurs, we have detected an up-regulation of the cellular inhibitor of apoptosis protein 1 (c-IAP1). The results of real-time RT-PCR quantification of message levels and protein turnover assays indicate that up-regulation of c-IAP1 occurs at the translational level. Elevation of c-IAP1 levels at a posttranscriptional step was detectable in MCF13 MLV-induced thymic lymphomas and chronically infected mink epithelial cells. The ability of a simple retrovirus to regulate cellular gene expression at the translational level may be an important mechanism that contributes to pathogenesis.

Induction of Endoplasmic Reticulum Stress in Thymic Lymphocytes by the Envelope Precursor Polyprotein of a Murine Leukemia Virus during the Preleukemic Period

Infection of thymic lymphocytes by a mink cell focus-forming murine leukemia virus induces apoptosis during the preleukemic period of lymphomagenesis. In this study, we observed that during this period, the viral envelope precursor polyprotein accumulated to high levels in thymic lymphocytes from mice inoculated with virus. Envelope accumulation occurred with the same kinetics as the induction of endoplasmic reticulum (ER) stress, which resulted in the upregulation of the 78-kDa glucose-regulated protein (GRP78). In thymic lymphomas, GRP78 levels were higher than those in virus-infected preleukemic cells, and GRP58 was upregulated. These results suggest that Env precursor accumulation induces ER stress, which participates in thymic lymphocyte apoptosis. The subsequent upregulation of ER chaperone proteins GRP78 and GRP58 may contribute to rescuing cells from virus-induced apoptosis.

Differential Cell Killing by Lymphomagenic Murine Leukemia Viruses Occurs Independently of p53 Activation and Mitochondrial Damage

Upon inoculation into AKR mice, mink cell focus-forming murine leukemia virus (MCF MLV) accelerates thymic lymphoma formation. During the preleukemic phase of disease, we observed the induction of apoptosis in thymic lymphocytes. A similar induction of apoptosis was observed for cultured mink epithelial cells after MCF13 MLV infection. In this study, the relevance of viral pathogenicity to cell killing was determined by testing the susceptibility of various cell types from different species to lymphomagenic MLVs. We observed that the cytopathic effect of lymphomagenic MLVs was restricted to mink cells. Southern blot analysis of MLV-infected cells revealed an accumulation of the linear form of unintegrated viral DNA, particularly in mink cells after MCF13 MLV infection. Thus, a strong correlation was observed between viral superinfection, which results in the accumulation of high levels of unintegrated viral DNA, and cell killing. Immunoblot analysis for MCF13 MLV-infected mink epithelial cells did not show a significant change in total p53 levels or its phosphorylated form at Ser-15 compared with that in mock-treated cells. Moreover, a time course analysis for mink epithelial cells infected with MCF13 MLV did not reveal mitochondrial depolarization or a significant change in Bax levels. These results demonstrate that MCF13 MLV induces apoptosis preferentially in cells in which superinfection occurs, and the mechanism involved is independent of p53 activation and mitochondrial damage.

Mink cell focus-forming murine leukemia virus killing of mink cells involves apoptosis and superinfection.

Induction of apoptosis by different types of pathogenic retroviruses is an important step in disease development. We have observed that infection of thymic lymphocytes by the mink cell focus-forming murine leukemia virus (MCF MLV) during the preleukemic period resulted in an enhancement of apoptosis of these cells. To further study the ability of MCF MLVs to induce apoptosis and the role of this process in viral pathogenesis, we have developed an in vitro system of virus-induced apoptosis. MCF13 MLV infection of mink epithelial cells resulted in the production of cytopathic foci. In contrast, infection of mink cells with the 4070A amphotropic MLV did not produce any cytopathic effects. Staining of MCF13 MLV-infected cells with propidium iodide and annexin V-fluorescein isothiocyanate indicated that virus-induced cell death was due to apoptosis. At 6 days postinfection, the percentage of apoptotic MCF13 MLV-infected cells was 27% compared with 2 to 3% for mock- or amphotropic MLV-infected cells, representing a 9- to 14-fold difference. Assays for caspase-3 activation confirmed the detection by flow cytometry of apoptosis of MCF13 MLV-infected cells. Large amounts of unintegrated linear viral DNA were detectable by Southern blot analysis during the acute phase of infection, which indicated that MCF13 MLV is able to superinfect mink cells. Unintegrated viral DNA of only the linear form was detectable in thymic lymphocytes isolated from MCF13 MLV-inoculated mice during the preleukemic period. These results indicated that the ability of MCF13 MLV to induce apoptosis is correlated with its ability to superinfect cells and that this occurs as an early step in thymic lymphoma development.

Role of the LTR Region between the Enhancer and Promoter in Mink Cell Focus-Forming Murine Leukemia Virus Pathogenesis

Long terminal repeat (LTR) sequences are important determinants of mink cell focus-forming (MCF) murine leukemia virus pathogenesis. These sequences include the enhancer and sequences between the enhancer and promoter (DEN). In a previous study we showed that a virus missing the DEN region in its LTR was severely attenuated in its ability to induce thymic lymphoma. In this study we observed that a virus with an LTR consisting of DEN but no enhancer sequences was pathogenic. We compared the pathogenicity of this DEN virus with other LTR mutant MCF13 viruses that contained a single enhancer (1R) or a single enhancer plus DEN (1R + DEN). All LTR mutant viruses generated thymic lymphoma, however, at a much lower incidence and with a longer latency compared with wild-type (WT) MCF13 virus. DEN virus replication in the thymus was the lowest compared with the 1R and 1R + DEN viruses. Viral replication in a different thymic subpopulation could not explain the decreased pathogenicity of the LTR mutant viruses compared with WT virus. However, lower levels of mutant virus replication in the thymus compared with WT during the preleukemic period may contribute to the attenuation of pathogenicity. The phenotype of tumors induced by the mutant viruses was similar and differed from tumors induced by WT virus by the presence of CD3−CD4−CD8− cells. Analysis of LTR sequences of infectious virus rescued from tumors induced by the 1R and 1R + DEN viruses showed that amplification of enhancer sequences had occurred during tumor development. The lack of DEN virus expression by tumor cells led us to propose that DEN sequences may play a role at an early step in tumorigenesis.

Moloney murine leukemia virus-induced preleukemic thymic atrophy and enhanced thymocyte apoptosis correlate with disease pathogenicity.

Moloney murine leukemia virus (M-MuLV) is a replication-competent, simple retrovirus that induces T-cell lymphoma with a mean latency of 3 to 4 months. During the preleukemic period (4 to 10 weeks postinoculation) a marked decrease in thymic size is apparent for M-MuLV-inoculated mice in comparison to age-matched uninoculated mice. We were interested in studying whether the thymic regression was due to an increased rate of thymocyte apoptosis in the thymi of M-MuLV-inoculated mice. Neonatal NIH/Swiss mice were inoculated subcutaneously (s.c.) with wild-type M-MuLV (approximately 10(5) XC PFU). Mice were sacrificed at 4 to 11 weeks postinoculation. Thymic single-cell suspensions were prepared and tested for apoptosis by two-parameter flow cytometry. Indications of apoptosis included changes in cell size and staining with 7-aminoactinomycin D or annexin V. The levels of thymocyte apoptosis were significantly higher in M-MuLV-inoculated mice than in uninoculated control animals, and the levels of apoptosis were correlated with thymic atrophy. To test the relevance of enhanced thymocyte apoptosis to leukemogenesis, mice were inoculated with the Mo+PyF101 enhancer variant of M-MuLV. When inoculated intraperitoneally, a route that results in wild-type M-MuLV leukemogenesis, mice displayed levels of enhanced thymocyte apoptosis comparable to those seen with wild-type M-MuLV. However, in mice inoculated s.c., a route that results in attenuated leukemogenesis, significantly lower levels of apoptosis were observed. This supported a role for higher levels of thymocyte apoptosis in M-MuLV leukemogenesis. To examine the possible role of mink cell focus-forming (MCF) recombinant virus in raising levels of thymocyte apoptosis, MCF-specific focal immunofluorescence assays were performed on thymocytes from preleukemic mice inoculated with M-MuLV and Mo+PyF101 M-MuLV. The results indicated that infection of thymocytes by MCF virus recombinants is not required for the increased level of apoptosis and thymic atrophy.

Receptors for polytropic and xenotropic mouse leukaemia viruses encoded by a single gene at Rmc1.

The onset of leukaemia caused by type C retroviruses (MLV) in mice is accelerated by the emergence of recombinant polytropic or mink cell focus-forming (MCF) viruses. Susceptibility to infection by polytropic/MCF and also by closely related xenotropic MLV has been mapped to Rmc1 on mouse chromosome 1 (refs 5-7). To identify this gene, we introduced an expression cDNA library prepared from mouse NIH3T3 fibroblasts into nonpermissive hamster cells and screened these cells for acquired susceptibility to MCF viruses encoding beta-galactosidase and G418 resistance. From hamster cell clones identified in the screen, we recovered a mouse cDNA that maps to Rmc1 and confers MCF MLV infection when expressed in nonpermissive cell lines. It encodes a membrane protein related to Syg1p (suppressor of yeast G alpha deletion; ref. 8). The receptor-binding domain of the MCF MLV envelope protein binds specifically to Xenopus laevis oocytes that express mouse Syg1, suggesting it functions as a receptor that mediates virus entry. We also obtained the cDNA encoding human SYG1. When expressed in hamster cells, it establishes infectivity by MCF MLV as well as xenotropic MLV, which do not infect laboratory mice.

FMEV vectors: both retroviral long terminal repeat and leader are important for high expression in transduced hematopoietic cells.

FMEV retroviral vectors combine the long terminal repeat of Friend mink cell focus-forming viruses with the 5' untranslated leader region of the murine embryonic stem cells virus. These modules were connected to achieve high transgene expression in hematopoietic progenitor and stem cells. Here, we report the cloning of safety-improved and versatile FMEV vectors allowing module-wise exchange of crucial elements for comparative studies. By transfer and expression of four different marker genes (neomycin phosphotransferase, lacZ, enhanced green fluorescent protein and truncated low affinity nerve growth factor receptor), we formally demonstrate that both the long terminal repeat and the leader contribute to the high expression of FMEV in transduced hematopoietic cells. Most prominent are the data recorded in the absence of selection in myelo-erythroid progenitor cells. Here, FMEV vectors mediate up to two orders of magnitude increased transgene expression levels when compared with vectors based on the Moloney murine leukemia virus.

Genetic and immunological parameters governing in vivo susceptibility/resistance to retrovirally induced murine malignant histiocytosis

Malignant histiocytosis sarcoma virus (MHSV) arose as a recombinant of c-Harvey-ras murine sarcoma virus (Ha-MuSV) and Friend mink cell focus-forming virus (F-MCFV). It is a defective acute transforming retrovirus that, along with Friend murine leukemia helper virus (F-MuLV), induces malignant histiocytosis (MH) in susceptible adult mice. We have assessed the in vivo susceptibility to MHSV in inbred homozygous, F1 hybrid, congenic, and recombinant inbred (RI) mice. We have shown that: (1) in vivo resistance to MHSV is multigenic, regulated by MHC and non-MHC genes in a different fashion than with F-MCFV, F-MuLV, or Ha-MuSV; (2) using BXD RI mice, the resistance phenotype is linked with 95.8% probability to two linked loci, Pmv-9 and Iapls3-14, on chromosome 13 (homologous to the area of human chromosome 5 for which a chromosomal break point at position 5q35 is associated with human MH); and (3) CD4+ T cells are critical for MHSV resistance.

Spacing between the enhancer and promoter of the long terminal repeat of a murine leukaemia retrovirus is required for transcriptional activation in T cells.

In T cells, transcriptional activation by the long terminal repeat (LTR) of the mink cell focus-forming murine leukaemia virus requires some spacing between the enhancer and promoter. A large size-range of intervening sequences (11-93 bp) is able to activate transcription efficiently. Neither a specific nucleotide sequence nor stereospecific alignment of the spacer is important.

Nucleotide sequence of the murine leukaemia virus amphotropic strain 4070A integrase (IN) coding region and comparative structural analysis of the inferred polypeptide.

The complete nucleotide sequence of the integrase (IN) protein coding region of the murine leukaemia virus (MLV) amphotropic strain 4070A is presented. The sequence comprises 1,224 nucleotides, encoding a 408-residue polypeptide of M(r) 46,312. Alignment of the inferred 4070A IN amino acid sequence with the IN proteins of other MLV showed that substitutions are confined largely to segments within the N- and C-terminal domains. In the N-terminal domain the majority of substitutions occur as contiguous 2- to 6-residue blocks, whereas in the C-terminal domain they occur as isolated entities except within a short segment characterized by deletions/insertions. Selection appears to act on the C-terminal 19 residues of IN rather than on the N-terminal residues of ENV (encoded by overlapping reading frames), suggesting a functional role for this segment. Phylogenetic analyses grouped the sequences into two clusters, one comprising IN from the amphotropic strain 4070A and three ecotropic MLV (CAS-BR-E, Moloney and Friend), the other consisting of IN from three ecotropic MLV (two radiation-induced viruses and AKV) and a mink cell focus-forming (MCF) MLV virus. The same dichotomy and cluster composition was obtained from analysis of the long terminal repeat (LTR) regions from these viruses (consistent with the functional interrelationship of IN and LTR) but not from analysis of envelope protein sequences (consistent with the functional independence of ENV proteins from both IN and LTR). Secondary structure predictions supported features determined from the catalytic domain of human immunodeficiency virus and avian sarcoma virus IN, and identified probable structures within the relatively long N- and C-terminal domains of MLV IN proteins.

Identification of nucleotide sequences that regulate transcription of the MCF13 murine leukemia virus long terminal repeat in activated T cells.

The region downstream of the enhancer (DEN) of the long terminal repeat of the mink cell focus-forming murine leukemia virus is important for viral pathogenicity. Another important activity of DEN is its control of transcription in activated T cells, and we have determined that an NF-kappaB site is critical for this activity.

Characterization of the AKR thymic microenvironment and its influence on thymocyte differentiation and lymphoma development

The thymic stroma has long been implicated in AKR thymic leukaemia. In this study an extensive panel of monoclonal antibodies was used to investigate changes in the AKR thymic microenvironment, in parallel with thymocyte differentiation of normal (2 month), preleukaemic (5–7 month) and leukaemic (>7 month) mice. We found select alterations in the thymic stroma, including a loss of isolated medullary antigens and changes in MTS 32, a mAb detecting an antigen on both thymocytes and stroma in the thymic cortex. Stromal alterations were accompanied by shifts in thymocyte differentiation and the appearance of the leukaemogenic mink cell focus-forming (MCF) murine leukaemia virus.

Resistance to murine AIDS in offspring of mice infected with LP-BM5. Role of CD8 T cells.

The murine-acquired immunodeficiency syndrome (MAIDS) is caused by a mixture of murine leukemia viruses (LP-BM5 MuLV). The influence of perinatal contact with retroviruses or their Ags on the response to infection was tested by infecting with LP-BM5 (MuLV) the adult offspring of mice with MAIDS. These offspring were resistant to disease after virus challenge. Most of them were free of defective viral DNA, and even those with molecular evidence of infection had lymphoid cells with a lower infectious capacity to cause MAIDS in naive recipients. No ecotropic, xenotropic, or mink cell focus-forming (MCF) virus expression was found at the age of 5 wk, which is the time of LP-BM5 (MuLV) challenge. However, at 22 wk of age, one-half of the offspring from MAIDS mothers had ecotropic virus-expressing cells in their spleens. At the time of suckling, offspring from infected mothers had enhanced percentages of B cells and CD4 and CD8 T cells in the spleen, possibly followed by a slight persistent splenomegaly. These results suggest that immune reactivity, rather than tolerance to the virus, is responsible for resistance to disease after challenge. The offspring of MAIDS mice could clear the virus after challenge. This clearance was mediated by CD8 T cells, as continuous CD8 T cell depletion initiated at the time of viral challenge abrogated the resistance of these mice to MAIDS.

Genetic basis for resistance to polytropic murine leukemia viruses in the wild mouse species Mus castaneus.

Cultured cells derived from the wild mouse species Mus castaneus were found to be uniquely resistant to exogenous infection by polytropic mink cell focus-forming (MCF) murine leukemia viruses (MuLVs). This MCF MuLV resistance is inherited as a genetically recessive trait in the progeny of F1 crosses between M. castaneus and MCF MuLV-susceptible laboratory mice. Examination of the progeny of backcrosses demonstrated that susceptibility is inherited as a single gene which maps to chromosome 1. The map location of this gene places it at or near the locus Rmc1, the gene encoding the receptor for MCF/xenotropic MuLVs, suggesting that resistance is mediated by the M. castaneus allele of this receptor.

Novel retroviral vectors for efficient expression of the multidrug resistance (mdr-1) gene in early hematopoietic cells.

We present data that retroviral gene expression in early hematopoietic cells is subjected to transcriptional controls similar to those previously described for embryonic stem cells. Transient transfection experiments revealed that both the viral enhancer region in the U3 region of the long terminal repeat as well as a repressor element coincident with the primer binding site of Moloney leukemia viruses are limiting for expression in hematopoietic cells in a differentiation-dependent manner. Within the group of Moloney leukemia virus-related viruses, only the myeloproliferative sarcoma virus showed high enhancer activity in myeloid (including erythroid) cells. In contrast, enhancer regions related to the Friend mink cell focus-forming viruses mediate much higher gene expression levels in both multipotent and lineage-committed myeloid cells. In addition, transcriptional repression related to sequences in the primer binding site of Moloney leukemia virus-derived vectors is also found in early hematopoietic cells and can be overcome by using the corresponding sequences of the murine embryonic stem cell virus. On the basis of these results, two types of novel retroviral hybrid vectors were developed; they combine the U3 regions of either the Friend mink cell focus-forming virus family or the myeloproliferative sarcoma virus with the primer binding site of the murine embryonic stem cell virus. When used to express the human multiple drug resistance gene, these vectors substantially improve protection to cytostatic drugs in transduced hematopoietic cell lines FDC-Pmix, TF-1, and K-562 in comparison with Moloney leukemia virus-derived vectors presently used for the stem cell protection approach in somatic gene therapy.

Spontaneous mutation of cell oncogenes plays a minor role in neoplastic transformation of virus-induced murine T-cell lymphomas.

Mink cell focus-forming viruses (MCF) are slow-transforming retroviruses that are able to accelerate the appearance of T-cell lymphomas when injected in newborn AKR mice. Activation of proto-oncogenes by proviral insertion is thought to be the major mechanism by which these viruses exert their oncogenic potential. However, molecular phenomena not strictly virus-determined, such as mutations in cellular oncogenes/tumor suppressor genes or chromosome aberrations, have been hypothesized to contribute to the achievement of the fully neoplastic phenotype in MCF-infected mice. To evaluate the role of spontaneous mutagenesis phenomena in murine virus-induced lymphomagenesis, we analyzed a series of 18 MCF247-induced thymic lymphomas and derived cell lines for the presence of p53 and c-ras gene mutations. Only 1 mutation at the p53 gene and 1 mutation at the ki-ras gene were detected in our study. Our results suggest that spontaneous mutagenesis plays a minor role in virus-induced lymphomagenesis and support the notion that multiple proviral insertions could be the prevalent mechanism of transformation in this experimental system.

Replacement of interleukin-2 (IL-2)-generated mitogenic signals by a mink cell focus-forming (MCF) or xenotropic virus-induced IL-9-dependent autocrine loop: implications for MCF virus-induced leukemogenesis

In earlier studies, we have shown that superinfection of an interleukin-2 (IL-2)-dependent, Moloney murine leukemia virus (MoMuLV)-induced rat T-cell lymphoma line (4437A) with mink cell focus-forming (also called polytropic) murine retroviruses induces rapid progression to IL-2-independent growth. In this report, we present evidence that the vast majority (> 90%) of the IL-2-independent lines established from polytropic or xenotropic virus-infected 4437A cells carry provirus insertions in the 3' untranslated region of the IL-9 receptor gene (Gfi-2 [for growth factor independence-2]/IL-9R). Prior to superinfection, the cells express neither IL-9 nor IL-9R. Following superinfection and provirus insertion in the Gfi-2/IL-9R locus, the cells express high levels of mRNA transcripts with a truncated 3' untranslated region which are predicted to encode the normal IL-9R protein product. The same IL-2-independent cells also express IL-9 which is induced by an insertional mutagenesis-independent mechanism. The establishment of an IL-9-dependent autocrine loop was sufficient to render the cells IL-2 independent, as suggested by the finding that 4437A cells, expressing a stably transfected Gfi-2/IL-9R construct, do not require IL-2 when maintained in IL-9-containing media. Additional experiments designed on the basis of these results showed that IL-9 gene expression is induced rapidly following the infection of 4437A cells by polytropic or xenotropic viruses and occurs in the absence of selection for IL-2-independent growth. Taken together, these data suggest that infection of 4437A cells by mink cell focus-forming or xenotropic viruses induces the expression of IL-9, which in turn rapidly selects the cells expressing the IL-9 receptor through an insertional mutagenesis-dependent mechanism. Given that both the polytropic and xenotropic viruses can induce the IL-9-dependent autocrine loop, the reduced ability of the xenotropic viruses to rapidly induce IL-2 independence in culture and tumors in animals is likely to be the result of their lower growth rates.

Identification of an H-2 Kb-presented Moloney murine leukemia virus cytotoxic T-lymphocyte epitope that displays enhanced recognition in H-2 Db mutant bm13 mice.

Upon infection with the Moloney murine sarcoma virus-murine leukemia virus (MuLV) complex, H-2b C57BL/6 (B6) mice respond with a class I Db-restricted cytotoxic T-lymphocyte (CTL) response, which protects against virus-induced tumorigenesis. In the B6-derived Db mutant B6.CH-2bm13 (bm13) strain, part of the class I Db antigen-presenting groove is shaped by a class I Kb-encoded sequence. Like B6 mice, bm13 mice reject Moloney virus-induced tumors, but the protective CTL response is Kb restricted. In this study we show enhanced levels of Moloney MuLV-specific CTLp with a restriction for Kb in bm13 mice. Through the use of CTL clones from Moloney virus-immunized bm13 mice, the class I Kb-presented CTL epitope was identified. The epitope is located in the Moloney virus gp70 envelope protein region (Moloney envelope, amino acids 189 to 196 [Mol env (189-196)]), SSWDFITV and has the Kb allele-specific binding motif. The Dbm13 molecule does not present the env(189 to 196) epitope to Kb-restricted bm13 CTL. In B6 mice, Mol env(189-196)-specific CTL could be induced by peptide vaccination. B6 mice thus have CTL precursors specific for this epitope but at considerably lower levels than do bm13 mice. We hypothesize that additional positive selection of Kb-restricted CTL on the Dbm13 molecule in bm13 mice explains this difference in precursor frequencies. We examined related strains of MuLV for the presence of Mol env(189-196) sequence equivalents. Rauscher, Friend, and AKV MuLV-encoded Mol env(189-196) epitope equivalents were properly recognized in cytotoxicity assays, both as synthetic and as endogenously expressed (Rauscher MuLV) peptides. In contrast, the mink cell focus-forming virus MuLV-encoded epitope equivalent, lacking a Kb anchor residue, was not presented for CTL recognition and hence can be excluded as an important CTL epitope for mink cell focus-forming viruses.