MCF-specific murine monoclonal antibodies made against AKR-247 MCF virus recognize a unique determinant associated with the gp70-p-15(E) complex

Analysis of two monoclonal antibodies reactive with envelope proteins of murine retroviruses: one pan specific antibody and one specific for Moloney leukemia virus

Many monoclonal antibodies (MAbs) reactive with various proteins of murine leukemia viruses (MuLVs) have been developed. In this report two additional MAbs with differing and unusual specificities are described. MAb 573 is reactive with the envelope protein of all MuLVs tested including viruses in the ecotropic, xenotropic, polytropic and amphotropic classes. Notably, MAb 573 is one of only two reported MAbs that react with the envelope protein of amphotropic MuLVs. This MAb appears to recognize a conformational epitope within the envelope protein, as it reacts strongly with live virus and live infected cells, but does not react with formalin-fixed or alcohol-fixed infected cells or denatured viral envelope protein in immunoblots. In contrast, Mab 538 reacts only with an epitope unique to the envelope protein of the Moloney (Mo-) strain of MuLV, a prototypic ecotropic MuLV that is the basis for many retroviral tools used in molecular biology. MAb 538 can react with live cells and viruses, or detergent denatured or fixed envelope protein. The derivation of these antibodies as well as their characterization with regard to their isotype, range of reactivity with different MuLVs and utility in different immunological procedures are described in this study.

Expression of infectious murine leukemia viruses by RAW264.7 cells, a potential complication for studies with a widely used mouse macrophage cell line

The mouse macrophage-like cell line RAW264.7, the most commonly used mouse macrophage cell line in medical research, was originally reported to be free of replication-competent murine leukemia virus (MuLV) despite its origin in a tumor induced by Abelson MuLV containing Moloney MuLV as helper virus. As currently available, however, we find that it produces significant levels of ecotropic MuLV with the biologic features of the Moloney isolate and also MuLV of the polytropic or MCF class. Newborn mice developed lymphoma following inoculation with the MuLV mixture expressed by these cells. These findings should be considered in interpretation of increasingly widespread use of these cells for propagation of other viruses, studies of biological responses to virus infection and use in RNA interference and cell signalling studies.

In vivo interactions of ecotropic and polytropic murine leukemia viruses in mixed retrovirus infections

Mixed retrovirus infections are the rule rather than the exception in mice and other species, including humans. Interactions of retroviruses in mixed infections and their effects on disease induction are poorly understood. Upon infection of mice, ecotropic retroviruses recombine with endogenous proviruses to generate polytropic viruses that utilize different cellular receptors. Interactions among the retroviruses of this mixed infection facilitate disease induction. Using mice infected with defined mixtures of the ecotropic Friend murine leukemia virus (F-MuLV) and different polytropic viruses, we demonstrate several dramatic effects of mixed infections. Remarkably, inoculation of F-MuLV with polytropic MuLVs completely suppressed the generation of new recombinant viruses and dramatically altered disease induction. Co-inoculation of F-MuLV with one polytropic virus significantly lengthened survival times, while inoculation with another polytropic MuLV induced a rapid and severe neurological disease. In both instances, the level of the polytropic MuLV was increased 100- to 1,000-fold, whereas the ecotropic MuLV level remained unchanged. Surprisingly, nearly all of the polytropic MuLV genomes were packaged within F-MuLV virions (pseudotyped) very soon after infection. At this time, only a fractional percentage of cells in the mouse were infected by either virus, indicating that the co-inoculated viruses had infected the same small subpopulation of susceptible cells. The profound amplification of polytropic MuLVs in coinfected mice may be facilitated by pseudotyping or, alternatively, by transactivation of the polytropic virus in the coinfected cells. This study illustrates the complexity of the interactions between components of mixed retrovirus infections and the dramatic effects of these interactions on disease processes.

Precise identification of endogenous proviruses of NFS/N mice participating in recombination with moloney ecotropic murine leukemia virus (MuLV) to generate polytropic MuLVs

Polytropic murine leukemia viruses (MuLVs) are generated by recombination of ecotropic MuLVs with env genes of a family of endogenous proviruses in mice, resulting in viruses with an expanded host range and greater virulence. Inbred mouse strains contain numerous endogenous proviruses that are potential donors of the env gene sequences of polytropic MuLVs; however, the precise identification of those proviruses that participate in recombination has been elusive. Three different structural groups of proviruses in NFS/N mice have been described and different ecotropic MuLVs preferentially recombine with different groups of proviruses. In contrast to other ecotropic MuLVs such as Friend MuLV or Akv that recombine predominantly with a single group of proviruses, Moloney MuLV (M-MuLV) recombines with at least two distinct groups. In this study, we determined that only three endogenous proviruses, two of one group and one of another group, are major participants in recombination with M-MuLV. Furthermore, the distinction between the polytropic MuLVs generated by M-MuLV and other ecotropic MuLVs is the result of recombination with a single endogenous provirus. This provirus exhibits a frameshift mutation in the 3' region of the surface glycoprotein-encoding sequences that is excluded in recombinants with M-MuLV. The sites of recombination between the env genes of M-MuLV and endogenous proviruses were confined to a short region exhibiting maximum homology between the ecotropic and polytropic env sequences and maximum stability of predicted RNA secondary structure. These observations suggest a possible mechanism for the specificity of recombination observed for different ecotropic MuLVs.

A small region of the ecotropic murine leukemia virus (MuLV) gag gene profoundly influences the types of polytropic MuLVs generated in mice

The vast majority of recombinant polytropic murine leukemia viruses (MuLVs) generated in mice after infection by ecotropic MuLVs can be classified into two major antigenic groups based on their reactivities to two monoclonal antibodies (MAbs) termed Hy 7 and 516. These groups very likely correspond to viruses formed by recombination of the ecotropic MuLV with two distinct sets of polytropic env genes present in the genomes of inbred mouse strains. We have found that nearly all polytropic MuLVs identified in mice infected with a substrain of Friend MuLV (F-MuLV57) are reactive with Hy 7, whereas mice infected with Moloney MuLV (Mo-MuLV) generate major populations of both Hy 7- and 516-reactive polytropic MuLVs. We examined polytropic MuLVs generated in NFS/N mice after inoculation with Mo-MuLV-F-MuLV57 chimeras to determine which regions of the viral genome influence this difference between the two ecotropic MuLVs. These studies identified a region of the MuLV genome which encodes the nucleocapsid protein and a portion of the viral protease as the only region that influenced the difference in polytropic-MuLV generation by Mo-MuLV and F-MuLV57.

A multistep process of leukemogenesis in Moloney murine leukemia virus-infected mice that is modulated by retroviral pseudotyping and interference

Mixed retroviral infections frequently exhibit pseudotyping, in which the genome of one virus is packaged in a virion containing SU proteins encoded by another virus. Infection of mice by Moloney murine leukemia virus (M-MuLV), which induces lymphocytic leukemia, results in a mixed viral infection composed of the inoculated ecotropic M-MuLV and polytropic MuLVs generated by recombination of M-MuLV with endogenous retroviral sequences. In this report, we describe pseudotyping which occurred among the polytropic and ecotropic MuLVs in M-MuLV-infected mice. Infectious center assays of polytropic MuLVs released from splenocytes or thymocytes of infected mice revealed that polytropic MuLVs were extensively pseudotyped within ecotropic virions. Late in the preleukemic stage, a dramatic change in the extent of pseudotyping occurred in thymuses. Starting at about 5 weeks, there was an abrupt increase in the number of thymocytes that released nonpseudotyped polytropic viruses. A parallel increase in thymocytes that released ecotropic M-MuLV packaged within polytropic virions was also observed. Analyses of the clonality of preleukemic thymuses and thymomas suggested that the change in pseudotyping characteristics was not the result of the emergence of tumor cells. Examination of mice infected with M-MuLV, Friend erythroleukemia virus, and a Friend erythroleukemia virus-M-MuLV chimeric virus suggested that the appearance of polytropic virions late in the preleukemic stage correlated with the induction of lymphocytic leukemia. We discuss different ways in which pseudotypic mixing may facilitate leukemogenesis, including a model in which the kinetics of thymic infection, modulated by pseudotyping and viral interference, facilitates a stepwise mechanism of leukemogenesis.

Characterization of epitopes defining two major subclasses of polytropic murine leukemia viruses (MuLVs) which are differentially expressed in mice infected with different ecotropic MuLVs

Polytropic murine leukemia viruses (MuLVs) arise in mice by recombination of ecotropic MuLVs with endogenous retroviral envelope genes and have been implicated in the induction of hematopoietic proliferative diseases. Inbred mouse strains contain many endogenous sequences which are homologous to the polytropic env genes; however, the extent to which particular sequences participate in the generation of the recombinants is unknown. Previous studies have established antigenic heterogeneity among the env genes of polytropic MuLVs, which may reflect recombination with distinct endogenous genes. In the present study, we have examined many polytropic MuLVs and found that nearly all isolates fall into two mutually exclusive antigenic subclasses on the basis of the ability of their SU proteins to react with one of two monoclonal antibodies, termed Hy 7 and MAb 516. Epitope-mapping studies revealed that reactivity to the two antibodies is dependent on the identity of a single amino acid residue encoded in a variable region of the receptor-binding domain of the env gene. This indicated that the two antigenic subclasses of MuLVs arose by recombination with distinct sets of endogenous genes. Evaluation of polytropic MuLVs in mice revealed distinctly different ratios of the two subclasses after inoculation of different ecotropic MuLVs, suggesting that individual ecotropic MuLVs preferentially recombine with distinct sets of endogenous polytropic env genes.

Human immunodeficiency virus infection elicits early antibody not detected by standard tests: implications for diagnostics and viral immunology

The FDA-approved tests for diagnosis of HIV exposure depend on detection of specific antibody in serum. HIV infection is missed in some individuals because they score seronegative by the standard clinical EIA and Western blot assays. This apparent immunological "silent" period following infection may last for months and has been reported to be as long as 3 years in rare cases. Is there truly a lack of an immune response or is there a more subtle, narrowly focused antibody response in these HIV-infected individuals which is not detected by the current tests? Using a nondenaturing serological assay (immunofluorescence of live infected T-cells), we found that each of four infected individuals "seronegative" by the standard tests did possess antibody against native HIV proteins expressed on infected cells. These antibodies reacting with native HIV antigenic epitopes were of the IgG isotype, they cross-reacted with many, but not all, of seven random HIV-1 isolates, and one of the sera immunoprecipitated HIV gp160 from NP-40-solubilized infected cells. These results show that seronegative, high-risk, infected individuals can actually be seropositive and that different types of assays using native antigenic epitopes may be required for screening. Implementation of these findings thus may decrease HIV transmission. These results also highlight the importance of protein conformation for many natural viral antigenic epitopes.

A neutralizable epitope common to the envelope glycoproteins of ecotropic, polytropic, xenotropic, and amphotropic murine leukemia viruses

An epitope common to all classes of murine leukemia viruses (MuLVs) was detected by reactivity of MuLVs with a rat monoclonal antibody (MAb) termed 83A25. The antibody is of the immunoglobulin G2a isotype and was derived after fusion of NS-1 myeloma cells with spleen cells from a Fischer rat immunized with a Friend polytropic MuLV. The antibody reacted with nearly all members of the ecotropic, polytropic, xenotropic, and amphotropic classes of MuLVs. Unreactive viruses were limited to the Friend ecotropic MuLV, Rauscher MuLV, and certain recombinant derivatives of Friend ecotropic MuLV. The presence of an epitope common to nearly all MuLVs facilitated a direct quantitative focal immunofluorescence assay for MuLVs, including the amphotropic MuLVs for which no direct assay has been previously available. Previously described MAbs which react with all classes of MuLVs have been limited to those which react with virion core or transmembrane proteins. In contrast, protein immunoblot and immunoprecipitation analyses established that the epitope reactive with MAb 83A25 resides in the envelope glycoproteins of the viruses. Structural comparisons of reactive and nonreactive Friend polytropic viruses localized the epitope near the carboxyl terminus of the glycoprotein. The epitope served as a target for neutralization of all classes of MuLV with MAb 83A25. The efficiency of neutralization varied with different MuLV isolates but did not correlate with MuLV interference groups.

Primary virus-induced lymphomas evade T cell immunity by failure to express viral antigens

T lymphoma induction by the mink cell focus-inducing murine leukemia virus MCF 1233 in C57BL/10 and C57BL/6 mice is influenced by a strongly Th-dependent, H-2I-A-restricted antiviral immune response (25). We compared the MHC class I as well as viral env and gag antigenic cell surface profiles of frequent T lymphomas of H-2I-A nonresponder-type mice to that of rare T lymphomas of H-2I-A responder-type mice. Membrane immunofluorescence studies, with a panel of anti-env mAbs (reactive with the highly conserved gp70f epitope, the p15Ec epitope, and the gp70-p15E complex), a polyclonal anti-p30 serum, and anti-H-2 class I mAbs, showed that all 17 nonresponder tumors tested expressed high levels of both env and gag viral proteins, and 15 of these 17 nonresponder tumors expressed high levels of H-2 class I K and D antigens. In contrast, 10 of 11 responder lymphomas lacked env and/or gag determinants. The only responder lymphoma with both strong env and gag expression failed to express H-2K and -D antigens. Preferential loss of env or gag expression did not correlate with H-2 class I allelic specificities. Both responder and nonresponder T lymphoma DNA contained multiple, predominantly MCF-like, newly acquired proviral integrations. Differences in viral antigen cell surface expression were confirmed at cytoplasmic and RNA levels. The amounts of 8.2- and 3.2-kb viral RNA were greatly reduced in two responder lymphomas when compared with four nonresponder lymphomas. In both responder lymphomas, aberrantly sized viral RNA species were found. Upon in vivo passage of these responder lymphomas in either immunocompetent or T cell-deficient nu/nu mice, it was found that various molecular mechanisms may underlie the lack of viral antigen expression at the cell surface of these lymphomas. One lymphoma re-expressed viral antigens when transplanted with nu/nu mice, whereas the other remained stably gag negative. The combined findings indicate that an H-2I-A-regulated antiviral immune response not only strongly reduces T lymphoma incidence, but also forces T lymphomas that still arise to poorly express viral antigens, thus explaining their escape from immunosurveillance.

Major histocompatibility complex class II-regulated immunity to murine leukemia virus protects against early T- but not late B-cell lymphomas

We studied the relative importance of class I and class II major histocompatibility complex (MHC) immunoregulation in the control of T- and B-cell lymphomas induced by murine leukemia virus. Previously, we have described a mink cell focus-inducing (MCF) murine leukemia virus, MCF 1233, which induces not only lymphoblastic T-cell lymphomas but also follicle center cell or lymphoblastic B-cell lymphomas. We now report that the outcome of neonatal infection with MCF 1233 in H-2-congenic C57BL/10 and C57BL/6 mice is decisively influenced by the H-2 I-A locus. A total of 64% of H-2 I-Ak, d mice [B10.BR, B10.D2, B10.A(2R), B10.A(4R), and B10.MBR] developed T-cell lymphomas after MCF 1233 infection (mean latency, 37 weeks). In contrast, H-2 I-Ab [B10, B10.A(5R), B6], H-2 I-Ab/k [(B10.A x B10)F1 and (B10 x B10.A)F1], and H-2 I-Abm12 (bm12) mice were resistant against T-cell lymphomagenesis, but 65% of these H-2 I-Ab, b/k, bm12 animals developed B-cell lymphomas (mean latency, 71 weeks). Animals of T-cell lymphoma-susceptible strains that escaped from T-cell lymphomagenesis developed B-cell lymphomas with similar frequency as animals of T-cell lymphoma-resistant strains, but with a shorter latency. H-2 class II-determined regulation of antiviral immunity was reflected in the presence of high titers of antiviral envelope antibodies in T-cell lymphoma-resistant B-cell lymphoma-susceptible H-2 I-Ab, b/k, bm12 mice, whereas in T-cell lymphoma-susceptible H-2 I-Ak,d mice no antiviral antibodies were found. At week 4 after neonatal MCF 1233 infection, a high percentage of thymocytes were virally infected in both T-cell lymphoma-susceptible and -resistant mice. However, T-cell lymphoma-resistant animals cleared the thymic infection between weeks 4 and 10 of age, coinciding with a sharp rise in serum levels of antiviral antibodies. We conclude that the pleiotropic effects of MCF 1233 infection in H-2-congenic mice result from MHC class II I-A-determined T-cell response differences.

Heterogeneity of human immunodeficiency virus cell-associated antigens and demonstration of virus type specificities of human antibody responses

We examined the antigens of human immunodeficiency viruses (HIV) expressed on infected H9 cells using live-cell membrane immunofluorescence and immunofluorescence absorption. Application of this nondenaturing serological method permitted analysis of HIV antigenic determinants maintained in their native configurations on the cell surface. Sera from infected individuals were found to react variably with H9 cells productively infected with nine different HIV isolates, and certain sera were completely unreactive with some isolates. Absorption of the sera prior to use in immunofluorescence revealed extensive heterogeneity of HIV cell-surface antigens and multiple type-specific antibodies in patients' sera. Immunoprecipitation and SDS-PAGE analysis of radiolabeled cell-surface proteins indicated that the predominant serological reactions were to env-encoded proteins. The observed antigenic and antibody heterogeneity likely reflects env sequence heterogeneity which has been previously reported for different HIV isolates. The demonstration of antigenic diversity among HIVs and the importance of defining the native antigenic epitopes, particularly those most widely shared, are important issues that must be considered in vaccine development.

Class II polytropic murine leukemia viruses (MuLVs) of AKR/J mice: possible role in the generation of class I oncogenic polytropic MuLVs

We examined the frequency of occurrence of polytropic murine leukemia viruses (MuLVs) in the spleens and thymuses of preleukemic AKR/J mice from 1 week to 6 months of age and analyzed the genomic RNAs of several polytropic isolates by RNase T1 oligonucleotide fingerprinting. Polytropic MuLVs were first detected in the spleens of 3-week-old mice and preceded the appearance of polytropic MuLVs in the thymus by over 1 month. At 4 months of age and older, nearly all mice expressed polytropic MuLVs in both organs. In contrast to previous studies which have identified class I polytropic MuLVs in AKR/J mice, fingerprint analysis of polytropic MuLVs from both young (3- to 4-week-old) and older (5- to 6-month-old) preleukemic mice indicated that a large proportion of viruses at both ages were class II polytropic MuLVs. All polytropic viruses (five isolates) analyzed from 3- to 4-week-old mice were recovered from spleen cells and were class II polytropic MuLVs. In older preleukemic mice, five of seven isolates were class II polytropic MuLVs and two were class I polytropic viruses. Class I and class II polytropic MuLVs were recovered from both the spleens and thymuses of older preleukemic mice. A detailed comparison of the class I and class II polytropic MuLVs from 5- to 6-month-old mice revealed that the nonecotropic gp70 sequences of most of the class I and class II MuLVs were identical, consistent with a common origin for these sequences. In contrast, the nonecotropic p15E sequences of class I MuLVs were clearly derived from different endogenous sequences than the nonecotropic p15E sequences of the class II MuLVs. The in vitro host ranges of class I and class II polytropic viruses were clearly distinguishable. Examination of the in vitro host range of several isolates suggested that the predominant polytropic viruses initially identified in the thymus (2 to 3 months of age) were class II polytropic viruses. The order of appearance of the class I and class II polytropic MuLVs and the identity of the gp70 oligonucleotides of these MuLVs suggested a model for the stepwise generation of class I polytropic MuLVs involving a class II polytropic MuLV intermediate.

Characterization of polytropic MuLVs from three-week-old AKR/J mice

An immunological focus assay using monoclonal antibodies on live adherent in vitro cell lines was employed to detect and isolate different types of murine leukemia viruses (MuLVs) from spleen and thymus cells of young (less than 1 month of age) AKR/J mice. In agreement with earlier studies, ecotropic viruses were detected from cells of both tissues in all mice tested, although only trace levels of ecotropic MuLV infectious centers were found with thymus cells from mice of this age. Polytropic MuLVs were not detected in mice less than 3 weeks of age; however, between the ages of 3 and 4 weeks, polytropic viruses were detectable in assays of spleen cells from 50% of the mice. No polytropic MuLVs were detected in assays of thymocytes from any mice of this age. Several polytropic MuLVs obtained from spleens of young mice were further characterized. All of the isolates were infectious for both mink and SC-1 (feral mouse) cells, and exhibited interference properties typical of polytropic MuLVs. However, none of the viruses induced obvious cytopathic effects (CPE) on mink cells. All of the viruses appeared antigenically similar with regard to their reactivities to a panel of 12 monoclonal antibodies directed at envelope antigens of polytropic MuLVs. RNase T1-resistant oligonucleotide analysis of a polytropic MuLV from a 26-day-old mouse indicated that its entire env gene was derived from nonecotropic sequences while the remainder of its genome was indistinguishable from the ecotropic parent. The isolate thus exhibited a genome structure typical of Class II polytropic MuLVs and is the first example of this type of MuLV isolated from AKR/J mice. Examination of polytropic MuLVs derived from the spleens and thymuses of 5- to 6-month-old mice indicated that only 2 of 10 isolates examined induced CPE on mink cells. Furthermore, most of the CPE-negative viruses isolated from spleen and thymus cells of these mice exhibited in vitro host ranges and antigenic reactivities similar to isolates from young mice, suggesting that this type of polytropic MuLV may originate in the spleen, subsequently spread to other tissues, and persist throughout the preleukemic period. The detection of polytropic viruses in a large proportion of very young mice is in contrast to previous studies which have not detected polytropic virus production in AKR mice less than 5 to 6 months of age.(ABSTRACT TRUNCATED AT 250 WORDS)

A new class of retrovirus present in many murine leukemia systems

A new class of MuLV has been detected and isolated from normal and leukemic AKR, C58, SJL, and NFS.AKV mice as well as from NFS mice inoculated with Friend or Moloney ecotropic viruses. These new viruses are XC negative and serologically cross-react with MCF env antigens but are ecotropic in host range, being able to only infect mouse cells to varying degrees and unable to infect mink or other cells infectable by MCF or xenotropic viruses. Viruses of this type from AKR mice cross-interfere with Moloney ecotropic and MCF viruses in SC-1 cells and appear to have properties similar to those of the SL3-2, GPA-V2, and R-XC- isolates. Analysis of their genomes by restriction endonuclease mapping of proviral DNA indicates structures similar to class II MCFs with the 5' half of the genome being like ecotropic viruses and the env region exhibiting restriction sites characteristic of MCF viruses. In normal AKR mice, these ecotropic recombinant-like viruses are found in spleen and bone marrow as early as 1 week of age, but first appear in the thymus at 3-4 months of age. These viruses have not been detected in mice with no or low expression of ecotropic viruses (NFS, NZB, DBA/2, BALB/c, C57BL/6). Because of their apparent recombinant structure and ecotropic host range we have provisionally designated them ecotropic recombinant virus (ERV) to distinguish them from the MCF class of recombinant MuLV.

Differences in oncogenicity among murine leukemia virus isolates are not correlated with the magnitude of H-2 regulated anti-viral envelope antibody responses

The antibody response against the envelope proteins of a variety of cloned highly and poorly oncogenic dualtropic mink cell focus-inducing (MCF) murine leukemia viruses (MuLV) was studied and compared with the antibody response against ecotropic isolates. MCF viruses evoke stronger antibody responses than ecotropic MuLV isolates. Although these MCF viruses are highly polymorphic with respect to their gp70 and p15(E) envelope proteins, generally a similar H-2-linked immune response gene control of anti-viral antibody responses is observed. Neonatally infected BALB/c (H-2d) and C57BL/10 (B10,H-2b) mice are high responders and B10.A (H-2a) mice, congenic at the major histocompatibility complex (H-2) with B10, low responders. No correlation was found between the expression of any single gp70 or p15(E) epitope of the infecting MCF virus and the magnitude of the antibody response. This indicates that the level of the H-2 regulated anti-MuLV envelope antibody response is most likely determined by a MuLV antigen shared by all MuLV isolates examined. The magnitude of the antibody response against highly oncogenic and against poorly oncogenic MCF virus does not differ significantly. The combined data indicate that the intrinsic oncogenic potency encoded by the viral genome is a more important feature of oncogenesis than the level of antiviral envelope antibody response evoked by the MCF virus. However, the oncogenic properties of a single murine leukemia virus may vary among H-2 congenic mice, correlated with their H-2-dependent capacity to produce antiviral antibodies.

Monoclonal antibodies against Aleutian disease virus distinguish virus strains and differentiate sites of virus replication from sites of viral antigen sequestration

Monoclonal antibodies (mAbs) were used to study antigenic differences among strains of Aleutian disease virus (ADV) and to characterize viral proteins in vitro and in vivo. A number of ADV field strains could be discriminated, and highly virulent Utah I ADV was clearly delineated from the tissue culture-adapted avirulent ADV-G strain. This specificity could be demonstrated by indirect immunofluorescence against infected cultures of Crandell feline kidney cells or against tissues of Utah I ADV-infected mink. Viral antigens were demonstrated in both the nuclei and the cytoplasm of infected tissue culture cells. However, in mink mesenteric lymph node, spleen, and liver, viral antigen was observed only in the cytoplasm. Absence of nuclear fluorescence suggested that the detected antigen represented phagocytized viral antigens rather than replicating virus. This conclusion was supported by the finding that mAbs reactive only against low-molecular-weight polypeptides derived from intact viral proteins gave the same pattern of in vivo fluorescence as mAbs with broad reactivity for large or small (or both) viral polypeptides. The distribution of infected cells was the same as that described for macrophages in these tissues and suggested that cells of the reticuloendothelial system had sequestered viral antigens.

Different murine cell lines manifest unique patterns of interference to superinfection by murine leukemia viruses

Interference to superinfection by murine leukemia viruses (MuLV) was analyzed in cells chronically infected with other MuLVs. A new sensitive focal immunofluorescence assay employing monoclonal antibodies was used to detect foci of virus infection in live cell monolayers. Monoclonal antibodies were chosen which reacted with the challenge virus but not with the interfering virus. The results obtained confirmed some of the findings of previous workers using Moloney sarcoma virus pseudotypes as challenge viruses on mouse and nonmouse cells. In addition, SC-1 mouse cells nonproductively infected with defective spleen focus-forming virus were found to be resistant to superinfection by recombinant dual-tropic viruses. Furthermore, results indicated that interference patterns between some pairs of viruses differed in different cell types. Thus, xenotropic MuLV blocked superinfection by recombinant dual-tropic viruses in SC-1 feral mouse cells, but not in two lines of NZB mouse cells. Also, in a Mus dunii tail fibroblast cell line some unique patterns of interference were observed. One ecotropic MuLV blocked infection by two xenotropic viruses and three recombinant dual-tropic viruses. Two other ecotropic viruses blocked infection by only one of the two xenotropic viruses tested. These two ecotropic viruses also differed from each other in their ability to block the three recombinant viruses. In addition, two strains of amphotropic MuLV also differed in their interference capacity. As expected, strain 1504A did not block any viruses tested, whereas strain 4070A surprisingly blocked one xenotropic and one ecotropic MuLV. The lack of homogeneity in interference patterns seen in the Mus dunii cells suggested either that a large number of heterogeneous virus receptors were present on this cell line or that interference in these cells might operate through a mechanism other than blocking of virus receptors by the envelope protein of the interfering virus.

Friend and Moloney murine leukemia viruses specifically recombine with different endogenous retroviral sequences to generate mink cell focus-forming viruses

A group of mink cell focus-forming (MCF) viruses was derived by inoculation of NFS/N mice with Moloney murine leukemia virus (Mo-MuLV 1387) and was compared to a similarly derived group of MCF viruses from mice inoculated with Friend MuLV (Fr-MuLV 57). Antigenic analyses using monoclonal antibodies specific for MCF virus and xenotropic MuLV envelope proteins and genomic structural analyses by RNase T1-resistant oligonucleotide finger-printing indicated that the Moloney and Friend MCF viruses arose by recombination of the respective ecotropic MuLVs with different endogenous retrovirus sequences of NFS mice.

Ecotropic and dualtropic mink cell focus-inducing murine leukemia viruses can induce a wide spectrum of H-2 controlled lymphoma types

Neonatal infection of C57BL and BALB/c mice by cloned ecotropic and dualtropic mink cell focus-inducing (MCF) murine leukemia viruses (MuLV) induces a wide spectrum of different lymphomas of T, B, and non-T/non-B cell types. Oncogenic dualtropic MCF viruses and poorly oncogenic ecotropic MuLV act synergistically in lymphomagenesis. Within one mouse strain virus-induced T-cell lymphomas arise earlier than B-cell lymphomas after neonatal inoculation of a single-cloned MuLV. The host genetic constitution, notably the H-2 complex has a marked influence on lymphoma type. This H-2 influence can be explained by an H-2-linked difference in penetration of the thymus early in life by oncogenic thymotropic MuLV, which in turn is correlated with, but not necessarily due to the magnitude of the anti-MuLV antibody response.

Neutralizing antibodies detect a disulfide-linked glycoprotein complex within the envelope of human cytomegalovirus

The specificity of neutralizing antibodies for human cytomegalovirus (CMV) envelope proteins was studied by comparing the reactivity of human CMV immune sera with that of a group of CMV-specific monoclonal antibodies. Characterization of this group of monoclonal antibodies revealed that six antibodies bound intact virions, and four of these antibodies neutralized infectious virus in vitro. All of the monoclonal antibodies, as well as human immune sera, precipitated three virion glycoproteins of estimated molecular weights of 160-K 116K, and 55K. Human immune sera also precipitated proteins of estimated molecular weights of 200K, 145K, 100K, 66K, and 34K. The three envelope glycoproteins detected by both the neutralizing monoclonal antibodies and immune human sera were shown to exist as a covalently linked, disulfide-bonded protein complex within virions. This result provided an explanation for the reactivity with multiple proteins of such highly specific reagents as monoclonal antibodies. Furthermore, these findings suggested that determinant(s) detected by CMV-neutralizing antibodies were expressed by this complex of envelope proteins.

An immunological focus assay for murine leukemia viruses on viable attached cell lines

An assay is described for the detection and isolation of murine leukemia virus (MuLV)-infected cells in viable monolayers. The procedure utilizes antisera or monoclonal antibodies which specifically bind cell surface viral antigens of infected cells. Bound antibodies are subsequently detected by binding with 125I-labeled Staphylococcus aureus protein A followed by autoradiography of the tissue culture vessel. Focal areas of infection can be identified from the autoradiograph and infected cells can subsequently be isolated and subcultured as MuLV-producing cell lines. With appropriate antibodies the procedure should be useful for the direct isolation of minor components, including mutants, in complex virus mixtures.

Characterization of monoclonal antibodies reactive with murine leukemia viruses: use in analysis of strains of friend MCF and Friend ecotropic murine leukemia virus

Sixteen mouse and rat monoclonal antibodies reactive with gag or env proteins of Friend murine leukemia virus (F-MuLV) or recombinant MCF viruses related to F-MuLV were derived. Specificity of these was determined by immunofluorescence, immunoprecipitation, and reactivity with viral proteins blotted onto nitrocellulose paper. Seven antibodies reacted with envelope protein antigens of certain nonecotropic viruses only. Nine antibodies reacted with both ecotropic and nonecotropic viruses. Of this latter group, three were antienvelope, four were anti-p15, one was anti-p12, and one was anti-p30 in specificity. When tested as a panel against 10 strains of F-MuLV, these antibodies could distinguish seven different antigenic patterns. However, all 10 strains retained reactivity for three anti-gp70 antibodies uniquely specific for Friend and Rauscher MuLVs. Our antibody panel could also identify MCF viruses isolated from mice neonatally inoculated with F-MuLV as recombinants related to a particular F-MuLV strain based on identity of p15 gag antigenic profiles. However, recombinant viruses lacked several envelope antigens always associated with F-MuLV and instead had new envelope reactivities. These anti-MCF monoclonal antibodies detected no shared envelope antigens between MCF and xenotropic viruses isolated from mice inoculated with F-MuLV, however many of them did react with MCF viruses derived from AKR mice and NFS mice congenic for endogenous ecotropic virus loci.

Monoclonal antibodies derived during graft-versus-host reaction. II. Antibodies detect unique determinants common to many MCF viruses

Hybridoma cell lines were recovered from the spleens of 6-week-old (B6 X D2)F1 mice undergoing graft-versus-host reaction induced by the transfer of 5-week-old B6 parental spleen cells. These cell lines produced antibodies reactive with envelope polypeptides of a variety of MuLV. The viral specificity assessed by membrane immunofluorescence and virus-binding radioimmunoassay indicated that the reactivity of these antibodies was distinctly different from monoclonal antibodies recovered from (B6 X D2)F1 recipients of D2 spleen cells reported previously (Portis et al., Virology 118, 181-190, 1982). Ten out of 17 monoclonal antibodies in the current study reacted exclusively with MCF viruses and three of these antibodies detected envelope determinants which were shared by a broad panel of MCF viruses of diverse origin. These common MCF determinants were expressed by the gp70 molecule as determined by Western blot analysis. The production of these antibodies by young mice in the absence of exogenous virus inoculation suggests that these antigens may be encoded by endogenous MCF-like sequences.

Naturally occurring leukemia viruses in H-2 congenic C57BL mice. III. Characterization of C-type viruses isolated from lymphomas induced by milk transmission of B-ecotropic virus

The prevalence of different host-range classes of murine leukemia virus (MuLV) was studied in C57BL mice with (V+) and without (V-) milk transmission of a naturally occurring B-tropic ecotropic MuLV. Virus isolates were studied with respect to growth properties, XC-plaque formation, antigen profiles of their envelope proteins (gp70 and P15(E)), gp70 tryptic-peptide maps, and their potential to induce lymphomas after inoculation into newborn mice. B-tropic ecotropic MuLV with the capacity to cause plaques in XC cells was isolated from almost all lymphomas of both V+ and V- sublines. The reaction patterns of these ecotropic isolates with monoclonal antibodies reactive with MuLV-env proteins and the tryptic-peptide maps of the gp70 molecule indicate that they are similar to each other and differ only slightly from the ecotropic MuLV in the spleens of young V+ animals, which is identical to the milk-transmitted virus. XC-, B-tropic dualtropic mink cell focus-inducing (MCF) viruses were isolated from the majority of different types of lymphoma (B cell, T cell, or neither B nor T cell derived), but not from the spleens or milk of young V+ or V- animals. The env proteins of the MCF isolates are highly heterogeneous, but most isolates originating from B10.AV + T-cell lymphomas share MCF-related epitopes in their gp85 envelope precursor with AKR MCF-247 virus. Most MCF viruses isolated from non-T lymphomas do not possess these epitopes. The results indicate that also in this model the generation of dualtropic MCF viruses might be important in lymphoma induction, although only some of the cloned MCF viruses show enhanced oncogenic properties in comparison with ecotropic isolates. A cloned oncogenic MCF virus induced different lymphoma types in C57BL/10 (= B10, H-2b) and B10.A (H-2a) mice, similar to what was found earlier with the milk-transmitted virus. Hence, the lymphoma-type differences are not due to differences in the B-tropic ecotropic viruses transmitted through the milk in these strains, but reflect an influence of the H-2 complex on the phenotype of the virus-induced lymphomas.

Characterization of target cells for MCF viruses in AKR mice

The recombinant (MCF) class of murine leukemia virus appears to play an important role in lymphomagenesis in AKR and other mice. Although much effort has been extended in characterizing MCF viruses, relatively little is known about the cells they infect. I examined what cells were targets in AKR mice for both lymphomagenic and nonlymphomagenic MCF viruses. Lymphomagenic MCF viruses of thymic origin (AKR-247 and C58L1) were found to infect and replicate selectively in immature lymphocytes only present in thymic cortex, whereas nonlymphomagenic MCF viruses of splenic origin (C58v-1-C77 and C58v-2-C45) selectively infected and replicated in cells that appeared to B lymphocytes. Virus-binding studies suggested that neither T- nor B-lymphocyte tropisms were determined by selective attachment of virus to the respective cells. These findings demonstrate that in contrast with ecotropic viruses, which can infect many types of cells in the mouse, specific cellular tropisms can exist for MCF viruses, and that MCF infection, and therefore oncogenicity, is closely linked to cellular differentiation.