Effect of the Fv-1 locus on the titration of murine leukemia viruses.

Titration of N- and B-tropic murine leukemia viruses on sensitive and resistant cell lines has been studied by direct XC plaque assay and infective center assay. The titration of cloned B-tropic virus by infective center assay on BALB/3T3 (Fv-1b/b) and NIH/3T3 (Fv-1n/n) cells gave one-hit patterns, with 100-fold less infected NIH/3T3 cells than BALB/3T3 cells. The titration of B-tropic virus on DBA/2 cells (Fv-1n/n) was also a one-hit. The titration of a one-hit curve, and there were about 100-fold less infected BALB/3T3 cells than NIH/3T3 cells. Comparable results were obtained by titrating the cloned N-tropic virus on congenic SIM (Fv-1n/n) and SIM.R (Fv-1b/b) cells or the Gross N-tropic virus on BALB/3T3 cells. Therefore, our data indicate that the multiple-hit phenomenon described previously may not be an essential part of the Fv-1 gene restriction.     

Phenotypic mixing between N- and B-tropic murine leukemia viruses: infectious particles with dual sensitivity to Fv-1 restriction.

In effort to understand how N or B tropism is determined in murine leukemia virus (MuLV) particles, we analyzed the MuLV produced after dual infection of mouse cells by N- and B-tropic MuLV. The progeny MuLV from such a mixed infection are sensitive to Fv-1 restriction in both N- and B-type cells, but are still highly infectious for mouse cells which do not exhibit Fv-1 restriction. This dual sensitivity to Fv-1 restriction is a phenotypic property of MuLV produced by mixedly infected cells, since individual virus clones derived from this MuLV are either N- or B-tropic. In further experiments, we superinfected murine sarcoma virus (MSV)-transformed cells with mixtures of N- and B-tropic MuLVs. The rescued MSV is restricted in its ability to transforms both N- and B-type cells. The results suggest that N- and B-tropic MuLVs specify different determinants, which are incorporated into virions along with the viral genome and which are the recognition sites for Fv-1 restriction. The presence of a given determinant in a virion renders the virus sensitive to restriction in cells of the opposite Fv-1 type.     

Retrovirus-induced murine acquired immunodeficiency syndrome: natural history of infection and differing susceptibility of inbred mouse strains.

C57BL mice (Fv-1b) develop a severe immunodeficiency disease following inoculation as adults with LP-BM5 murine leukemia virus (MuLV), a derivative of Duplan-Laterjet virus which contains B-tropic ecotropic and mink cell focus-inducing MuLVs and a putative defective genome which may be the proximal cause of disease. The stages of development of this disease were defined for C57BL mice on the basis of lymphadenopathy and splenomegaly; histopathological changes consistent with B-cell activation; and alterations in expression of cell surface antigens affected by proliferation of T cells, B cells, and macrophages. By using this disease profile as a standard, the response of adult mice of various inbred strains and selected F1 hybrids was compared. We show that although the strains which are highly sensitive are of the Fv-1b genotype (i.e., permissive for B-tropic MuLVs), certain Fv-1b strains, e.g., BALB/c and A/J, are resistant to murine acquired immunodeficiency syndrome, whereas certain Fv-1n strains (permissive for N-tropic MuLVs but restrictive for B-tropic MuLVs), notably P/N, BDP, and AKR, show moderate sensitivity and (C57BL/6 x CBA/N)F1 mice (Fv-1n/b and thus dually restrictive) are of relatively high susceptibility. The results of virus recovery tests suggest that apparently anomalous sensitivity, based on predicted Fv-1 restriction, may reflect MuLV induction and/or mutation to provide a helper virus for which the host is permissive.     

Effect of Fv-1 gene product on synthesis of linear and supercoiled viral DNA in cells infected with murine leukemia virus.

Levels of unintegrated viral DNA made in Fv-1b/b (SIM.R, JLS-V9) and Fv-1n/n (NIH/3T3) cell lines after infection with N- or B-tropic murine leukemia virus (MuLV) have been measured. Different forms of viral DNA were sedimented on neutral sucrose or ethidium bromide-cesium chloride density gradients and detected by hybridization with complementary DNA. It was found that the major viral DNA species made in Fv-1 permissive or resistant cells was sedimenting at 20S on neutral sucrose gradient. Levels of this 20S viral DNA species were not significantly different in both systems. However levels of closed circular (form I) viral DNA separated on ethidium bromide-cesium chloride gradients were found to be decreased in Fv-1 resistant cells. Various species of viral DNA were also analyzed by the agarose gel-DNA transfer procedure of Southern. The major viral DNA species was found to migrate as a double-stranded linear DNA of 5.7 x 10(6) daltons. The molecular weight of linear viral DNA molecules extracted from Fv-1 permissive or resistant cells appeared to be the same. Levels of this linear viral DNA were almost identical in both systems except in B-tropic MuLV-infected resistant NIH/3T3 cells in which a moderate decrease has been measured. Two closed circular viral DNA species were observed by this technique. Their levels were markedly decreased in Fv-1 resistant cells. Our results indicate that the Fv-1 restriction does not grossly affect the formation of linear double-stranded viral DNA, but prevents the accumulation of closed circular viral DNA. Therefore the Fv-1 gene product could allow the synthesis of a normal linear viral DNA but interfere with the formation of supercoiled viral DNA. Alternatively, it could promote the synthesis of a faulty linear viral DNA whose defect (yet undetected) would prevent its circularization. In any case, the Fv-1 restriction mechanism appears to occur before the integration event itself.     

Genetic evidence for a product of the Fv-1 locus that transfers resistance to mouse leukemia viruses.

Extracts of mouse cells have been shown to transfer to N- or B-trophic host range types of mouse leukemia viruses. The genetic specificity of the inhibition was tested in two ways: (i) by correlating the Fv-1 genotype of a number of mouse strains with the restriction-transferring activity of extracts of the respective embryo cell cultures, and (ii) by correlating the Fv-1 genotype of BLC3F2 (C57BL/6 female [Fv-1bb] by C3H male [Fv-1nn] parental strains) mouse embryos, which segregate the Fv-1 alleles in a 12:1 ratio, with the inhibitor activity of extracts of the cells from each embryo. Five independent matings, totaling 45 individual embryos, were tested. Each embryo was cultured, and the Fv-1 genotype was determined independently by titration of N- and B-tropic viruses; the extracts of replicate secondary cultures were tested for their effect on infection of permissive cells by N- and B-tropic viruses. The specific-restriction-transferring activity of the embryos was found to segregate with the appropriate Fv-1 genotype. These res-lts confirm the suggestion that the inhibitor of the leukemia virus host range types in the cellular extracts is a product of the Fv-1 locus.     

Evidence for recombination between N- and B-tropic murine leukemia viruses.

After co-infection of Sc-1 cells with N- and B-tropic murine leukemia viruses that differ in their XC plaque morphology, Hopkins et al. (1976) obtained viruses, designated XLP-N, that appeared to be recombinants, since they possess the N-tropism of one parent and the XC plaque morphology of the other (the B-tropic virus) parent. Here we present evidence, based on antigenicity and electrophoretic mobility, that some clonal isolates of XLP-N have inherited gp70 gene of their B-tropic virus parent. In addition to providing evidence that XLP-N viruses are recombinants, the fact that an N-tropic virus may apparently possess a gp70 derived from a B-tropic virus provides evidence, which is in agreement with the findings of others (Huang et al., 1973; Krontiris et al., 1973) that the N- or B-tropism of murine leukemia virus does not reside in gp70.     

Genetic transmission of endogenous N- and B-tropic murine leukemia viruses in low-leukemic strain C57BL/6.

Spontaneous expression of endogenous N- and B-tropic murine leukemia viruses was stu1bb), DDD (Fuv-1nn), DDD-Fvr (fv-1nn), (DDD or DDD-Fvr times C57BL/6)F1, and 16 partially inbredlines with either the Fv-1nn or Fv-1bb genotype, which had been established from hybrids between C57BL/6 and DDD-Fvr. When tested at middle age, virus-positive mice were found in C57BL/6, F1 hybrids, and 9 out of 16 partially inbred lines. N-tropic viruses were isolated from Fv-1nn, Fv-1bb mice, whereas B-tropic viruses, except for one isolate, were from Fv-1bb mice only. C57BL/6 mice were positive for both N- and B-tropic viruses, whereas DDD-Fvr mice were negative. With respect to the Fv-1 genotype and the presence of endogenous murine leukemia viruses, the partially inbred lines were grouped into five types: (i) Fv-1bb, both N- and B-tropic virus positive, like C57BL/6; (ii) Fv-1nn, virus negative, like DDD-Fvr; (iii) Fv-1bb, virus negative; (iv) Fv-1nn, only N-tropic virus positive; and (v) less convincingly, Fv-1bb, only B-tropic virus positive. These findings indicate that the transmission of N- and B-tropic viruses in C57BL/6 is genetically controlled and that the expression of B-tropic virus, but not of N-tropic virus, is closely associated with the Fv-1 genotype.     

Fv-1 host restriction of Friend leukemia virus: analysis of unintegrated proviral DNA.

The murine gene Fv-1 predominantly controls the outcome of infection by murine ecotropic retroviruses. The inhibition of virus replication by the Fv-1 gene product has been determined to be at an early stage in virus replication. Mechanistically, its effect appears to be on the accumulation of unintegrated proviral DNA or its integration or both. We investigated the synthesis of unintegrated proviral DNA, using several clones of B-, N-, or NB-tropic Friend murine leukemia virus. Our results indicate that the accumulation of B-tropic proviral DNA in NIH cells may be inhibited at either the level of linear (form III) or covalently closed circular DNA (form I), depending upon the degree of restriction of the clone of virus used. We confirmed that there is an effect of the Fv-1 gene on the accumulation of form I DNA of either B- or N-tropic Friend murine leukemia virus. However, the decrease in infectious centers effected by the Fv-1 gene did not correlate quantitatively with the effect on form I proviral DNA produced by N-tropic Friend murine leukemia virus in nonpermissive cells. Lastly, we demonstrated in nonpermissively infected NIH cells that a rapidly migrating doublet of viral DNA is formed.     

Genetic studies of the Fv-1 locus of mice: linkage with Gpd-1 in recombinant inbred lines.

Multiple recombinant inbred lines, derived from crosses between strains permissive to N-tropic murine leukemia viruses (Fv-1n) and strains permissive to B-tropic murine leukemia viruses (Fv-1b), have been characterized as to Fv-1 genotype and other chromosome 4 markers, including the closely linked hexose-6-phosphate dehydrogenase isozyme locus (Gpd-1). Only one recombinant between Fv-1 and Gpd-1 was found among 45 lines tested. On this basis, the distance between Fv-1 and Gpd-1 is estimated to be 0.6 centimorgans. None of the lines was either resistant or susceptible to both N- and B-tropic viruses. Nineteen other inbred strains, previously untested, were characterized as either Fv-1n or Fv-1b.     

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.     

Development and characterization of an Fv-1-sensitive retrovirus-packaging system: single-hit titration kinetics observed in restrictive cells.

We have constructed an RNA-packaging-deficient mutant of N-tropic murine leukemia virus WN1802N by removal of 330 nucleotides located between the upstream long terminal repeat and the start of the gag gene region. Transfection into mink CCL64 cells produced a cell line capable of packaging retrovirus vectors into ecotropic, Fv-1 N-tropic virions. Using retrovirus vectors that confer resistance to the antibiotic G418, we demonstrated that the magnitude of restriction in BALB/3T3 and SIM.R cells (both Fv-1b/b) and in RFM/3T3 cells (Fv-1nr/nr) is approximately 100-fold compared with that in AKR or NIH 3T3 cells (both Fv-1n/n). Furthermore, titration kinetics were single hit in restrictive cells. Colonies of antibiotic-resistant cells recovered after infection of genotypically restrictive cultures were phenotypically restrictive when reinfected, ruling out selection of stably nonrestrictive subpopulations. These results suggest that the ability to infect some fraction of cells in a genotypically restrictive culture does not require specific abrogation and that multihit kinetics may not be an essential feature of Fv-1 restriction.     

Donation of N- or B-tropic phenotype to NB-tropic murine leukemia virus during mixed infections.

The IC isolate of Moloney murine leukemia virus (MuLV), which is NB-tropic, was grown in cells producing conditionally defective or defective virus particles derived from N- or B-tropic MuLV. The infectious MuLV that was then released was found to be sensitive to Fv-1 restriction but produced NB-tropic progeny upon passage. These results indicate that this NB-tropic MuLV can acquire sensitivity to Fv-1 restriction by phenotypic mixing with N- or B-tropic MuLV. It is thus suggested that NB-tropic MuLV is insensitive to Fv-1 restriction simply because it lacks the determinants of tropism.     

Unstable resistance of G mouse fibroblasts to ecotropic murine leukemia virus infection.

G mouse cells were resistant to N- and NB-tropic Friend leukemia viruses and to B-tropic WN 1802B. Though the cells were resistant to focus formation by the Moloney isolate of murine sarcoma virus, they were relatively sensitive to helper component murine leukemia virus. To amphotropic murine leukemia virus and to focus formation by amphotropic murine sarcoma virus, G mouse cells were fully permissive. When the cell lines were established starting from the individual embryos, most cell lines were not resistant to the murine leukemia viruses. Only one resistant line was established. Cloning of this cell line indicated that the resistant cells constantly segregated sensitive cells during the culture; i.e., the G mouse cell cultures were probably always mixtures of sensitive and resistant cells. Among the sensitive cell clones, some were devoid of Fv-1 restriction. Such dually permissive cells, and also feral mouse-derived SC-1 cells, retained glucose-6-phosphate dehydrogenase-1 and apparently normal number 4 chromosomes. The loss of Fv-1 restriction in these mouse cells was not brought about by any gross structural changes in the vicinity of Fv-1 on number 4 chromosomes.     

Transfer of Fv-1 locus-specific resistance to murine N-tropic and B-tropic retroviruses by cytoplasmic RNA.

A standardized bioassay for transfer of Fv-1 gene-specific resistance to N-tropic and B-tropic murine retroviruses was developed using X plaque reduction in SC-1 (Fv-1-) cells inoculated with virus. Testing of subcellular fractions of restrictive cells showed that the resistance transfer activity was present in the cytoplasmic (microsomal and cytosol) fractions. The activity of the cytoplasmic extract was destroyed by treatment with ribonuclease, but not with deoxyribonuclease or proteases. RNA prepared by phenol-chloroform extraction of mouse tissues, including embryos and livers of weanling mice, transferred Fv-1 locus-specific resistance into DEAE-dextran-treated SC-1 cells. The activity of isolated RNA preparations against virus of the appropriate host-range type has been demonstrated to correspond to the Fv-1 genotypes of the cell sources. The specific transfer of resistance with cellular RNA was effective within a 5- to 6-h period from 2 h before to 4 to 5 after virus infection. Sucrose gradient centrifugation of the RNA showed that the activity sedimented as a broad peak, with an apparent maximum in the 22S region. Affinity chromatography of whole-cell RNA on polyuridylic acid-Sepharose tended to separate more activity into the polyadenylic acid RNA fraction than the non-polyadenylic acid RNA fraction. Except for the reciprocal inhibitory activity for the two host-range virus types, the RNAs of Fv-1n and Fv-1b specificities showed similar properties in all aspects studied.     

Reversal of Fv-1 host range by in vitro restriction endonuclease fragment exchange between molecular clones of N-tropic and B-tropic murine leukemia virus genomes.

We molecularly cloned unintegrated viral DNA of the BALB/c endogenous N-tropic and B-tropic murine leukemia retroviruses and in vitro passaged N-tropic Gross (passage A) murine leukemia retroviruses. Recombinant genomes were constructed in vitro by exchanging homologous restriction enzyme fragments from N- or B-tropic parents and subsequent recloning. Infectious virus was recovered after transfection of these recombinant genomes into NIH-3T3 cells and cocultivation with the Fv-1 nonrestrictive SC-1 cells. XC plaque assays of recombinant virus progeny on Fv-ln and Fv-lb cells indicated that the Fv-l host range was determined by sequences located between the BamHI site in the p30 region of the gag gene (1.6 kilobase pairs from the left end of the map) and the HindIII site located in the pol gene (2.9 kilobase pairs from the left end of the map).     

Studies with aphidicolin on the Fv-1 host restriction of Friend murine leukemia virus.

The murine gene Fv-1 exerts a major control over the replication of Friend murine leukemia virus (F-MuLV). An effect of the gene product has been determined to be at the level of accumulation and integration of viral DNA. Aphidicolin, an inhibitor of eucaryotic DNA polymerase alpha, was studied in murine cells infected either permissively or nonpermissively with regard to the Fv-1 genotype. Results indicated that inhibition of DNA polymerase alpha did not affect the accumulation of form III viral DNA in either permissive or nonpermissive cells. However, the normal accumulation of circular form I DNA in permissive cells was inhibited. The block in the accumulation of form I DNA resembled that occurring in some F-MuLV Fv-1-nonpermissive infections. Additionally, aphidicolin treatment resulted in the accumulation of novel low-molecular-weight viral DNA species, normally detectable in a nonpermissive infection of NIH cells with B-tropic F-MuLV. These data suggest that the Fv-1 gene product may interact with host DNA polymerase alpha to prevent viral replication.     

N-Tropic variants obtained after co-infection with N- and B-tropic murine leukemia viruses.

Sc-1 cells co-infected with small XC plaque-forming N-tropic and large XC plaque-forming B-tropic murine leukemia viruses produced, in addition to parental types, progeny with the phenotype, large XC plaque morphology, and N-tropism. This phenotype remained stable through end point titration and plaque purification on NIH/3T3 cells and growth on BALB/3T3 cells. These N-tropic viruses (XLP-N virus) grow to unusually high titer and make very large XC plaques.     

Characterization of N-type and dually permissive cells segregated from mouse fibroblasts whose Fv-1 phenotype could be modified by another independently segregating gene(s).

Though the inbred DDD mouse strain is essentially of the N type, the primary culture of this strain was about 100-fold more sensitive to B-tropic WN1802B virus than were the typical N-type strains (C3H/He, C57L, etc.). After cloning, DDD mouse cells segregated two types of cells, typical N-type cells and cells lacking in Fv-1 restriction. As both types of cells so far tested retained glucose-6-phosphatase-1 coded by a locus closely linked to Fv-1 and genetic cross experiments indicated the presence of a gene(s) modifying the Fv-1 phenotype, variation in Fv-1 restriction could presumably be brought about by genetic changes in a gene(s) other than Fv-1 itself. N-type and dually permissive cell clones were similarly established from the inbred G mouse. Compositions of polypeptides labeled with [35S]methionine in the N-type and dually permissive cells of DDD and G mouse origins were compared by two-dimensional gel electrophoresis. The polypeptide maps of these cells were similar except for a few spots. Among these dissimilar spots, a spot of about 20,000 daltons with a pI of about 5.5 was always present in N-type cells, whereas it was absent in dually permissive cells. In DDD mouse-derived clones, a proportional relation was observed between the intensity of the spot and the restriction to the B-tropic virus.     

Fate of Unintegrated Viral DNA in Fv-1 Permissive and Resistant Mouse Cells Infected with Murine Leukemia Virus

We have found that levels of unintegrated linear viral DNA were nearly identical in several Fv-1 resistant cell lines, whereas levels of closed circular viral DNA are markedly reduced in these resistant cells, to the same extent as virus production (P. Jolicoeur and E. Rassart, J. Virol. 33:183-195, 1980). To determine the fate of linear viral DNA made in resistant cells we performed pulse-chase experiments, labeling viral DNA with 5-bromodeoxyuridine and following it with a thymidine chase. 5-Bromodeoxyuridine-labeled viral DNA (HH) recovered by banding on cesium chloride gradients was sedimented on neutral sucrose density gradients or separated by the agarose gel-DNA transfer procedure and detected by hybridization with complementary DNA. Levels of linear viral DNA made in Fv-1^b/b (JLS-V9 and SIM.R) and Fv-1^n/n (NIH/3T3 and SIM) cells were found to decrease during the chase period at about the same rate in permissive and nonpermissive conditions, indicating that linear viral DNA is not specifically degraded in Fv-1 resistant cells. Levels of the two species of closed circular viral DNA made in Fv-1 permissive cells increased relative to the levels of linear DNA during the chase period. This confirmed the precursor-product relationship between linear DNA and the two species of circular DNA. In Fv-1 resistant cells, this apparent conversion of linear viral DNA into circular forms was not seen, and no supercoiled viral DNA could be detected. To determine whether the transport of linear viral DNA from the cytoplasm into the nucleus was prevented by the Fv-1 gene product, SIM.R cells were fractionated into cytoplasmic and nuclear fractions, and viral DNA was detected in each fraction by the agarose gel-DNA transfer procedure. Levels of linear viral DNA were nearly identical in both cytoplasmic and nuclear fractions of permissive or resistant cells. Circular viral DNA could be detected in the nuclear fraction of permissive cells, but not in that of resistant cells. A pulse-chase experiment was also performed with SIM.R cells. During the thymidine chase period, linear viral DNA was seen to accumulate in nuclei of both permissive and resistant cells, whereas supercoiled viral DNA accumulated only in nuclei of permissive cells. These results indicate that the Fv-1 gene product does not interfere with the transport of linear viral DNA into the nucleus. Our data also suggest that the Fv-1 restriction does not operate through a degradation process. Therefore, the Fv-1 gene product could either block the circularization of linear viral DNA directly or promote the synthesis of a faulty linear viral DNA whose defect (yet undetected) would prevent its circularization.