Fv-1 determinants in xenotropic murine leukemia viruses studied with biological assay systems: Isolation of xenotropic virus with N-tropic Fv-1 activity in the cryptic form.

By a biological assay system using phenotypically mixed ecotropic and xenotropic murine leukemia viruses, we investigated whether in the virions of a xenotropic virus there is N- or B-tropic Fv-1 determinant in active form. The existence of N-tropic Fv-1 determinant was demonstrated in SL-XT-1 xenotropic virus isolated from the spleen of a 3-month-old SL mouse, and the N-tropic Fv-1 tropism was confirmed by analysis of the phenotypically mixed viruses harvested from clonal SC-1 cells doubly infected with the SL-XT-1 and B-tropic ecotropic viruses. However, neither N- nor B-tropic Fv-1 determinant was demonstrated in any xenotropic viruses isolated from embryo cells of BALB/c, NZB, or DBA/2 mice, or Cas E #1-IU, and xenotropic-like virus isolated from a wild mouse.     

Chromosome breakage and xenotropic C-type virus in embryonic cultures from New Zealand black mice.

A considerable increase in chromatid and chromosome breaks, as well as excessive fragmentation and "pulverization" of whole metaphase plates was observed in embryonic fibroblast cultures from New Zealand black mice. A C-type RNA virus with a xenotropic host range was isolated from the supernatant fluid of co-cultures of NZB cells and heterologous permissive cells (SIRC cell line). One of the NZB cultures produced this virus without amplification by co-cultivation after spontaneous transformation of the cells. NZB cells are supposed to lack normal restriction of complete xenotropic virus expression and to release this endogenous virus spontaneously at a high level. It is hypothesized that the excessive chromosome damage observed in these cell cultures is related to the permanent production of virus, thus indicating a chromosome breaking effect of endogenous viruses.     

Genetics of xenotropic virus expression in mice. I. Evidence for a single locus regulating spontaneous production of infectious virus in crosses involving NZB/B1NJ and 129/J strains of mice.

The extent of infectious xenotropic virus expression in homogenized splenic tissues from the high-virus-expressing NZB/BINJ mice and the non-virus-expressing 129/J mice and their crosses has been examined. The data suggest that a single autosomal "dominant-like" gene controls the spontaneous production and release of infectious xenotropic virus in NZB mice. Analysis of infectious virus production in second-backcross families [(F1 X 129) X 129] confirmed this conclusion. Variations in the amount of X-tropic virus released were evident in all genetic crosses. Virus titers (expressed as focus-forming units per milliliter) of supernatant fluid ranged from high levels in the NZB mice to somewhat lower levels in crosses involving the 129 mice. In the absence of a definite pattern in the titers observed in the genetic crosses studied, the term dominant-like is proposed for the single gene regulating the expression of X-tropic virus in NZB mice.     

Susceptibility of wild mouse cells to exogenous infection with xenotropic leukemia viruses: control by a single dominant locus on chromosome 1.

Although xenotropic murine leukemia viruses cannot productively infect cells of laboratory mice, cells from various wild-derived mice can support replication of these viruses. Although the virus-sensitive wild mice generally lack all or most of the xenotropic proviral genes characteristic of inbred strains, susceptibility to exogenous infection is unrelated to inheritance of these sequences. Instead, susceptibility is controlled by a single dominant gene, designated Sxv, which maps to chromosome 1. Sxv is closely linked to, but distinct from Bxv-1, the major locus for induction of xenotropic murine leukemia viruses in laboratory mice. Genetic experiments designed to characterize Sxv show that this gene also controls sensitivity to a wild mouse virus with the interference properties of mink cell focus-forming murine leukemia viruses, and that Sxv-mediated susceptibility to xenotropic murine leukemia viruses is restricted by the mink cell focus-forming virus resistance gene Rmcf. These data, together with genetic mapping of the mink cell focus-forming virus cell surface receptor locus to this same region of chromosome 1, suggest that Sxv may encode a wild mouse variant of the mink cell focus-forming virus receptor that allows penetration by xenotropic murine leukemia viruses.     

In vitro studies of the mechanism of leukemogenesis. II. Characterization of endogenous murine leukemia viruses isolated from AKR thymic epithelial reticulum cell lines

Thymic epithelial reticulum (TER) cell lines were established from thymuses of a young healthy AKR mouse (A2T), a preleukemic AKR mouse (A6T), and two lymphoma-bearing AKR/Ms mice (ASLT-1 and ASLT-2). Numerous type-C virus particles with occasional budding forms were observed in all cell lines. Expression of XC-detectable, N-tropic, ecotropic virus was observed in every cell line, whereas the presence of xenotropic and mink cell focus-inducing (MCF) viruses could be detected only in TER cells derived from preleukemic and leukemic mice. Expression of xenotropic virus in various cells of newborn and young AKR mice could readily be induced by IUdR treatment, whereas MCF virus was never detected in these cells, with the exception of the A2T cell line after more than 20 passages, in which MCF virus with dual-tropic infectivity emerged in addition to ecotropic and xenotropic viruses. These spontaneous and induced MCF viruses were purified, and their virological properties were characterized. The cloned MCF viruses (MCFs AT1, AT2, AT3, and AT4-IU) showed dual tropism and produced cytopathic effect-like foci in mink lung cells. Preinfection with either ecotropic or xenotropic virus interfered with the infectivity of MCF viruses. Spontaneous leukemogenesis in AKR mice was accelerated by the inoculation of MCF viruses. These findings indicate that TER cells could serve as the host cells for the genetic recombination of the endogenous MuLV; the recombinant MuLV, MCF virus, appears to be most closely associated with leukemogenesis in AKR mice.     

Innate immunity against HIV: a priority target for HIV prevention research

The xenotropic/polytropic subgroup of mouse leukemia viruses (MLVs) all rely on the XPR1 receptor for entry, but these viruses vary in tropism, distribution among wild and laboratory mice, pathogenicity, strategies used for transmission, and sensitivity to host restriction factors. Most, but not all, isolates have typical xenotropic or polytropic host range, and these two MLV tropism types have now been detected in humans as viral sequences or as infectious virus, termed XMRV, or xenotropic murine leukemia virus-related virus. The mouse xenotropic MLVs (X-MLVs) were originally defined by their inability to infect cells of their natural mouse hosts. It is now clear, however, that X-MLVs actually have the broadest host range of the MLVs. Nearly all nonrodent mammals are susceptible to X-MLVs, and all species of wild mice and several common strains of laboratory mice are X-MLV susceptible. The polytropic MLVs, named for their apparent broad host range, show a more limited host range than the X-MLVs in that they fail to infect cells of many mouse species as well as many nonrodent mammals. The co-evolution of these viruses with their receptor and other host factors that affect their replication has produced a heterogeneous group of viruses capable of inducing various diseases, as well as endogenized viral genomes, some of which have been domesticated by their hosts to serve in antiviral defense.     

Phenotypic alteration in retroviral gene expression by leukemia-resistant thymocytes differentiating in leukemia-susceptible recipients

(AKR x NZB)F1 mice possess the dominant genes, Akv-1, Akv-2, Nzv-1a and Nzv-2a, which determine the expression of ecotropic and xenotropic viruses. Nevertheless, their thymic lymphocytes fail to produce these agents, and these mice are resistant to leukemia. We investigated the mechanism of this cell-specific restriction in radiation chimeras. (AKR x NZB)F1 thymocytes that had differentiated in lethally irradiated AKR recipients produced high levels of ecotropic and xenotropic viruses and showed marked amplification of MuLV antigen expression. Polytropic viruses could also be isolated from such thymocytes. These virological changes in chimeric thymocytes were donor- and host-specific and occurred only when (AKR x NZB)F1 bone marrow cells were inoculated into AKR recipients. This inductive capacity of the host environment could be detected in irradiated AKR recipients as early as age 2 months. The phenotypic changes brought about in leukemia-resistant (AKR x NZB)F1 thymocytes by the leukemia-susceptible AKR thymic microenvironment may be the result of a three-component inductive system.     

Laboratory and wild-derived mice with multiple loci for production of xenotropic murine leukemia virus.

Mendelian segregation analysis was used to define genetic loci for the induction of infectious xenotropic murine leukemia virus in several laboratory and wild-derived mice. MA/My mice contain two loci for xenotropic virus inducibility, one of which, Bxv -1, is the only induction locus carried by five other inbred strains. The second, novel MA/My locus, designated Mxv -1, is unlinked to Bxv -1 and shows a lower efficiency of virus induction. The NZB mouse carries two induction loci; both are distinct from Bxv -1 since neither is linked to the Pep-3 locus on chromosome 1. Finally, one partially inbred strain derived from the wild Japanese mouse, Mus musculus molossinus, carries multiple (at least three) unlinked loci for induction of xenotropic virus. Although it is probable that inbred strains inherited xenotropic virus inducibility from Japanese mice, our data suggest that none of the induction loci carried by this particular M. m. molossinus strain are allelic with Bxv -1.     

Tryptic peptide analysis of avian oncovirus gag and pol gene products.

Tryptic digests of the internal proteins p30, p15, p12, and p10 of mouse xenotropic, ecotropic, and amphotropic type C viruses were subjected to cation-exchange chromatography. Analysis of these maps revealed that the p30 proteins from representative isolates of all three viral subgroups were distinguishable. The p15 proteins were all unique. The p12 proteins of NZB xenotropic and wild-mouse amphotropic viruses were not identical and yielded peptide maps remarkably different from that of the ecotropic virus. The p10 proteins of xenotropic and ecotropic viruses were identical and were dissimilar to that of the wild-mouse amphotropic virus.     

Natural immunity in mice to the envelope glycoprotein of endogenous ecotropic type C viruses: neutralization of virus infectivity.

The ability of naturally immune mouse sera to neutralize ecotropic AKR murine leukemia virus (MuLV) was examined by using unfrozen virus preparations harvested for 1 h. In this assay several mouse sera significantly and consistently neutralized MuLV infectivity. The ability of these sera to neutralize was correlated with the presence of antibodies against MuLV detectable in a radioimmune precipitation assay using radioactively labeled intact virions. This neutralization was specific, in that either N- or B-tropic viruses, but not Friend MuLV, were neutralized. In addition, neutralization could be abrogated with purified AKR MuLV gp71 at concentrations that do not interfere with virus infectivity but could not be abrogated with Rauscher MuLV gp71. Neutralizing activity could be removed by absorption with intact AKR MuLV, but not by absorption with Friend MuLV, a BALB/c xenotropic virus, or with NZB xenotropic virus. All the neutralizing activity of (B6C3)F1 mouse sera was associated with the immunoglobulin G fraction.     

Amphotropic host range of naturally occuring wild mouse leukemia viruses.

Seven murine leukemia virus field isolates (uncloned) from wild mice (Musmusculus) of four widely separated areas in southern California show an unusually wide in vitro host range. They replicate well in human, feline, canine, guinea pig, rabbit, rat, and mouse cells, whereas bovine, hamster, and avian cells are resistant. Since this host range includes that of both mouse tropic (ecotropic) and xenotropic murine leukemia viruses, they are designated as "amphotropic". No purely xenotropic virus component is detectable in these field isolates. They may represent the "wild" or ancestral viruses from which the ecotropic and xenotrophic murine leukemia virus strains of laboratory mice have been derived.     

Differential expression of murine leukemia virus loci in chemically induced hybrid cells.

The time course of murine leukemia virus production after chemical induction was determined in hamster-mouse somatic cell hybrids containing the xenotropic murine leukemia virus induction locus Bxv-1 or the ecotropic locus Akv-2. By using these hybrids, induction could be studied in the absence of secondary virus spread because xenotropic viruses cannot infect hybrid cells and ecotropic viruses cannot infect hybrids which have lost mouse chromosome 5. After induction, hybrids with Bxv-1 produced only a transient burst of virus, whereas those with Akv-2 continued to produce virus for periods in excess of 3 months. The presence or absence of other mouse chromosomes in the hybrid lines did not alter these induction patterns. Thus, endogenous murine leukemia virus loci differ in their response to induction, and both inducibility and the kinetics of virus expression are controlled at or near these proviral loci.     

Stimulation of mouse migration inhibitory factor (MIF) production form MSV-immune lymphocytes by soluble tumor-associated antigen: requirement for histocompatible macrophages.

Spleen cells from C57BL/6 mice immunized with murine sarcoma virus (MSV) are capable of producing migration inhibition factor (MIF) in response to stimulation with a specific tumor-associated antigen prepared by solubilization with 3 M KCL. We have previously demonstrated that this response is T cell-dependent. Further investigations into the effector cells involved in the production of MIF have revealed that spleen cells from mice immunized with MSV cannot produce MIF when stimulated with tumor extract if the population has been previously depleted of macrophages. However, the response can be restored by adding nonimmune syngeneic macrophages but not by allogeneic macrophages. The inability of allogeneic macrophages to provide this function was not due to their increased suppressor activity since in mixing experiments they did not interfere with the ability of immune spleen cells to produce MIF. Furthermore, they were not defective since they could supply this "cooperative function" to appropriate F1 mice. The results indicate that macrophages are required for stimulation of MIF by soluble tumor antigens and that for efficient interaction the macrophages and lymphocytes must share some genetic similarities.     

Genetics of xenotropic virus expression in mice. II. Expression of major virus structural proteins in crosses involving NZB/B1NJ, SWR/J, and 129/J strains of mice

The expression of viral structural polypeptides and the production of infectious xenotropic virus were found to segregate together in NZB, 129/J, and SWR/J mice and in crosses between these strains. The viral p30 protein segregation pattern, as measured by competition radioimmunoassay using extracts of frozen spleens from backcross progeny, indicate that xenotropic murine leukemia virus expression is controlled by two dominant genes.     

Expression and detection of endogenous mouse C-type RNA viruses

Summary Many naturally occurring C-type RNA viruses are of endogenous origin. The genetic information for synthesizing these RNA viruses is present in the DNA of normal mouse cells, probably as part of their chromosomal DNA. Some C-type viruses infect mouse cells (homotropic virus), while others infect certain tissue culture cells from other species but not mouse fibroblasts (xenotropic virus). All mouse strains studied appear to contain endogenous xenotropic viral genomes. However, based on the regularity with which homotropic virus is detected, inbred mice can be divided into high, low, and nonvirus-yielding strains. Nucleic acid hybridization studies have shown that DNA from high virus strains contains several copies of the homotropic virus genome, while that from low virus strains contains fewer copies, and DNA from nonvirus strains lacks a significant portion of the homotropic virus genome. In vivo and in vitro genetic studies support the nucleic acid hybridization results. In addition, high virus mouse strains are more likely than low virus strains to release virus that will replicate efficiently in their own cells. Methods for the activation and detection of endogenous C-type virus in tissue culture are discussed. Presented at the Session in Depth on Endogenous Viruses in Cell Culture at the Twenty-fifth Annual Meeting of the Tissue Culture Association, June 1974.     

Characterization of recombinant nonecotropic murine leukemia viruses from the wild mouse species Mus spretus

The wild mouse species most closely related to the common laboratory strains contain proviral env genes of the xenotropic/polytropic subgroup of mouse leukemia viruses (MLVs). To determine if the polytropic proviruses of Mus spretus contain functional genes, we inoculated neonates with Moloney MLV (MoMLV) or amphotropic MLV (A-MLV) and screened for viral recombinants with altered host ranges. Thymus and spleen cells from MoMLV-inoculated mice were plated on Mus dunni cells and mink cells, since these cells do not support the replication of MoMLV, and cells from A-MLV-inoculated mice were plated on ferret cells. All MoMLV-inoculated mice produced ecotropic viruses that resembled their MoMLV progenitor, although some isolates, unlike MoMLV, grew to high titers in M. dunni cells. All of the MoMLV-inoculated mice also produced nonecotropic virus that was infectious for mink cells. Sequencing of three MoMLV- and two A-MLV-derived nonecotropic recombinants confirmed that these viruses contained substantial substitutions that included the regions of env encoding the surface (SU) protein and the 5' end of the transmembrane (TM) protein. The 5' recombination breakpoint for one of the A-MLV recombinants was identified in RNase H. The M. spretus-derived env substitutions were nearly identical to the corresponding regions in prototypical laboratory mouse polytropic proviruses, but the wild mouse infectious viruses had a more restricted host range. The M. spretus proviruses contributing to these recombinants were also sequenced. The seven sequenced proviruses were 99% identical to one another and to the recombinants; only two of the seven had obvious fatal defects. We conclude that the M. spretus proviruses are likely to be recent germ line acquisitions and that they contain functional genes that can contribute to the production of replication-competent virus.     

Oncogenicity of AKR endogenous leukemia viruses.

Four biologically distinct groups of endogenous murine leukemia virus (MuLV) have been isolated from AKR mice. These viruses included (i) ecotopic XC+ MuLV that occur in high titer in normal tissues and serum of AKR mice throughout their life span, (ii) ecotropic XC- MuLV that are produced in high titers by leukemia cells, (iii) xenotropic MuLV that are readily demonstrable only in aged mice, and (iv) polytropic MuLV thatarise in the thymuses of aged mice as a consequence of genetic recombination between ecotropic and xenotropic MuLV. Virus of each of these biological classes were assayed in AKR mice for their ability to accelerate the occurrence of spontaneous leukemia. Certain isolates of ecotropic XC- MuLV and polytropic MuLV were found to have high oncogenic activity. These viruses induced 100% leukemias within 90 days of inoculation. In contrast, ecotropic XC+ MuLV that were obtained from AKR embryo fibroblasts and xenotropic MuLV that were obtained from the lymphoid tissues of aged AKR mice did not demonstrate oncogenic activity. These findings demonstrate fundamental differences between XC- and XC+ ecotropic MuLV that are found in leukemic and normal tissues, respectively. Furthermore, these findings point to the role of ecotropic XC- and polytropic MuLV in the spontaneous leukemogenesis of AKR mice.     

Isolation and Characterization of Mink Cell Focus-Inducing Murine Leukemia Viruses with Xenotropic Host Range from Mouse Strain SL

A new type of mink cell focus-inducing virus was persistently isolated from the leukemic tissues of SL mice. In contrast to the dual tropic mink cell focus-inducing viruses reported to date, the new virus has the host range of the xenotropic murine leukemia virus. Analysis of RNase T(1) fingerprints of genomic RNAs suggested that the mink cell focus-inducing virus with the xenotropic host range isolated from SL mice is a recombinant virus deriving from xenotropic murine leukemia virus.     

Rescue of Murine Sarcoma Virus from a Sarcoma-Positive Leukemia-Negative Cell Line: Requirement for Replicating Leukemia Virus

The nature of murine sarcoma virus (MSV) "defectiveness" was investigated by employing an MSV-transformed mouse 3T3 cell line which releases noninfectious virus-like particles. Rescue kinetics of MSV, observed after murine leukemia virus (MuLV) superinfection of these "sarcoma-positive leukemia-negative (S + L -)" mouse 3T3 cells, consisted of a 9- to 12-hr eclipse period followed by simultaneous release of both MSV and MuLV with no evidence for release of infectious MSV prior to the production of progeny MuLV. Addition of thymidine to the growth medium of MuLV-superinfected S + L - cells at a concentration suppressing deoxyribonucleic acid synthesis inhibited the replication of MuLV and the rescue of MSV. MSV production closely paralleled MuLV replication under a variety of experimental conditions. These results suggest that replication of MuLV is required for the rescue of infectious MSV from S + L - cells and that one (or more) factor, produced late in the MuLV replicative cycle, is utilized by both viruses during virion assembly. During the course of these experiments, virus stocks were recovered which contained infectious MSV in apparent excess over MuLV. These stocks were used for generating new S + L - cell lines by simple end point dilution procedures.