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.     

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.     

Physical mapping of the Fv-1 tropism host range determinant of BALB/c murine leukemia viruses

The murine leukemia viruses (MuLVs) have different host ranges and were originally designated N-tropic and B-tropic if they replicated preferentially in vitro on NIH and BALB/c fibroblasts, respectively. It was later found that N-tropic MuLVs were in fact restricted in BALB/c cells, that B-tropic MuLVs were restricted in NIH cells, and that both viruses were restricted in (BALB X NIH) F1 cells. A single gene, Fv-1, with two alleles, Fv-1b and Fv-1n, determines this dominant restriction. A virus-encoded protein seems to carry the viral host range determinant which is recognized by the Fv-1 gene product. To map the viral DNA sequences encoding this determinant, we constructed viral DNA recombinants in vitro between the cloned infectious viral DNA genomes from BALB/c N-tropic and B-tropic MuLVs. Infectious recombinant MuLVs were recovered by microinjecting these recombinant DNAs into murine Fv-1- SC-1 cells and were subsequently tested in vitro for their host ranges (N- or B-tropic). We found that a short 302-base pair 5'-end fragment was necessary and sufficient to confer a specific host range to a recombinant. Our sequencing data revealed that this fragment codes for amino acid sequences in gag p30. They also showed that only two consecutive amino acid differences, Gln-ArgN- and Thr-GluB-, in p30 are responsible for the N- and B-tropic host ranges of the BALB/c MuLVs, respectively. Therefore, it appears that the Fv-1b and Fv-1n gene products can discriminate between these two p30 amino acid sequences.     

Host restriction of friend leukemia virus; fate of input virion RNA

Host restriction of oncogenesis by RNA tumor viruses may be studied in vitro by measuring the replication of the lymphatic leukemia component of the Friend Virus Complex (LLV-F) in either NIH-Swiss or Balb/C mouse embryo cells. These cells derive from mice differing at the Fv-1 locus, which controls the replication of all murine RNA leukemia viruses. Studies of early events in the replication of LLV-F were carried out by following the infection of permissive and restrictive mouse embryo cells by ³²P labeled LLV-F. ³²P labeled viral genome RNA rapidly becomes associated with cell nuclei and may be found integrated to the same extent with high molecular weight host DNA of either permissive or restrictive cells. These results suggest that Fv-1 mediated host restriction of LLV-F occurs at a step following integration of viral genome RNA into host DNA.Two other conclusions are suggested by these data. The nucleus appears to be the site of activation and synthesis of DNA of the infecting virus; and the “provirus”, at least transiently, is represented as an RNA-DNA hybrid molecule covalently integrated with host cell DNA.     

Fv-1 restriction and its effects on murine leukemia virus integration in vivo and in vitro.

We have investigated the mechanisms by which alleles at the mouse Fv-1 locus restrict replication of murine leukemia viruses. Inhibition of productive infection is closely paralleled by reduced accumulation of integrated proviral DNA as well as by reduced levels of linear viral DNA in a cytoplasmic fraction. Nevertheless, viral DNA is present at nearly normal levels in a nuclear fraction, and total amounts of viral DNA are only mildly affected in restrictive infections, suggesting a block in integration to account for reduced levels of proviral DNA. However, integrase (IN)-dependent trimming of 3' ends of viral DNA occurs normally in vivo during restrictive infections, demonstrating that not all IN-mediated events are prevented in vivo. Furthermore, viral integration complexes present in nuclear extracts of infected restrictive cells are fully competent to integrate their DNA into a heterologous target in vitro. Thus, the Fv-1-dependent activity that restricts integration in vivo may be lost in vitro; alternatively, Fv-1 restriction may prevent a step required for integration in vivo that is bypassed in vitro.     

Abrogation of Fv-1 restriction by genome-deficient virions produced by a retrovirus packaging cell line.

The Fv-1b-mediated restriction of N-tropic retrovirus vector infection of BALB/3T3 cells was partially abrogated by prior infection with N-tropic murine leukemia virus. Likewise, abrogation of the Fv-1b restriction of N-tropic murine leukemia virus replication was accomplished by prior infection with genome-deficient virions produced by an N-tropic murine leukemia virus packaging cell line. The latter observation suggests that the Fv-1 target in genome-deficient virions abrogates Fv-1 restriction in the absence of any viral genome-directed processes.     

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).     

Loss of Fv-1 restriction in Balb/3T3 cells following infection with a single N tropic murine leukemia virus particle.

The ability of various murine leukemia viruses (MuLVs) to replicate in mouse cells exhibiting Fv-1 restriction was analyzed by quantitative dose-response assays. In particular, the effect of infection with N, B, or NB tropic MuLVs on Fv-1b restriction in Balb/3T3 cells was measured with an infection center technique in which pseudotypes of murine sarcoma virus (MSV), which have been shown to exhibit Fv-1 dependence of expression, were used to quantitate the degree of restriction. The resulting dose-response curves indicate that productive infection of a single Balb/3T3 cell with N tropic MSV requires co-infection with two MuLV particles. These two MuLV particles are functionally distinguishable. One of them must be N tropic and must be added less than 18 hr after infection with N tropic MSV. The second MuLV particle, on the other hand, need not be N tropic and may be added at any time. Balb/3T3 cultures infected with sufficient N tropic MuLV become fully permissive to transformation by N tropic MSV and to productive infection by N tropic MuLV. This effect, termed "abrogation" of Fv-1 restriction, results from infection of a Balb/3T3 cell with a single N tropic MuLV particle, but apparently occurs without viral replication. It seems probable that a requirement for abrogation of Fv-1b restriction by a single infectious particle of N tropic MuLV, which does not itself replicate, is responsible for the two-hit dose-response relationship observed in infectivity titrations of N tropic MuLV in Balb/3T3 cells. The requirements that N tropic MuLV be added within a specified time period with regard to N tropic MSV in order for abrogation to occur suggests that in the absence of N tropic MuLV, the cellular Fv-1b restriction mechanism inactivates N tropic MSV by 9 hr after infection.     

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.     

Inherited resistance to N- and B-tropic murine leukemia viruses in vitro: titration patterns in strains SIM and SIM.R congenic at the Fv-1 locus.

We have investigated the titration patterns of murine leukemia viruses on mouse embryo cultures derived from a pair of congenic strains differing at the Fv-1 locus. XC plaque and infectious center assays carried out with N- and B-tropic viruses on both SIM (Fv-1nn) and SIM.R(Fv-1bb) host cells yielded results that were best approximated by Poisson one-hit curves. Titration curves of N-tropic virus by direct XC plaque assay were linear and parallel on the different hosts, with titers 1.8 to 2.7 log10 lower on SIM.R and on (SIM X SIM.R)F1 than on SIM cells; similar linear and parallel curves were found for B-tropic virus, with titers 1.4 to 2.0 log10 lower on SIM and (SIM XSIM-R)F1 than on SIM-R cells. In the infectious center assays, the proportion of infected cells was linearly related to multiplicity of infection on both permissive (N- on SIM and B- on SIM.R) restrictive (B- on SIM and N- on SIM.R) genotypes at multiplicities of infection below 0.5; the line relating the variables was about 1 log10 lower in the restrictive than in the permissive situations. At multiplicities of infection where the proportion of infected cells reached a plateau, differences between the results on permissive and restrictive genotypes were considerably reduced. This appeared to be due to the action of non-Fv-1 factors in permissive host. We conclude that the major action of the restrictive allele at the Fv-1 locus in this system is to reduce the probability of successful murine leukemia virus infection without a change in hitness.     

Host restriction of Friend Leukemia virus coat protein synthesis.

Fv-1 gene-mediated host restriction of Friend leukemia virus replication was investigated in terms of coat protein synthesis. By using the assay of pseudotype formation with vesicular stomatitis virus. it was shown that under restricting growth conditions the availablity of leukemia virus coat protein for pseudotype formation was decreased. These studies appear to eliminate a pure assembly defect as the mechanism of Fv-1 host restriction.     

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.     

Helper-Dependent Properties of Friend Spleen Focus-Forming Virus: Effect of the Fv-1 Gene on the Late Stages in Virus Synthesis

Co-infection of neonatal BALB/c mice with Friend virus (FV) complex (containing defective spleen focus-forming virus [SFFV] and endogenous N-tropic leukemia-inducing helper virus [LLV-F]) and B-tropic Tennant leukemia virus (TenLV) resulted in the inhibition of LLV-F by the Fv-1(b) gene and recovery of a TenLV pseudotype of SFFV, abbreviated SFFV(TenLV). The host range of this pseudotype was B-tropic, since SFFV(TenLV) was 10 to 100 times more infectious for B-type (Fv-1(bb)) than for N-type (Fv-1(nn)) mice. The similar patterns of neutralization of N-tropic and B-tropic SFFV by type-specific murine antisera suggested that the difference in infectivity between these two SFFV preparations did not reside in envelope determinants. Rather, helper control of SFFV's host range was only apparent and dependent upon the ability of associated virus to provide a helper function for late stages in SFFV synthesis. Early stages in SFFV's infectious cycle were shown to be helper independent. The Fv-1 gene did not act at the level of the cell membrane to effectively restrict SFFV infection, since SFFV-induced transformed cells could be detected in the absence of spleen focus formation and SFFV synthesis. Further, the generation of these transformed cells by SFFV followed a one-hit, dose-response pattern, suggesting that SFFV-induced cell transformation is helper independent. Finally, restriction of helper function by Fv-1 may be an intracellular event, because both SFFV and its associated LLV-F helper share common envelope determinants and presumably adsorb onto and penetrate target cells with equal efficiency.     

Molecular characterization of the Akvr-1 restriction gene: a defective endogenous retrovirus-borne gene identical to Fv-4r.

A dominant restriction allele, Akvr-1r, from California wild mice (Mus musculus domesticus) confers resistance to exogenous ecotropic murine leukemia virus (MuLV) infection. The presence of an ecotropic MuLV envelope-related glycoprotein in uninfected virus-resistant cells suggests that viral interference is a possible mechanism for this resistance. We molecularly cloned the ecotropic MuLV envelope-related sequence from the genomic DNA of a wild mouse homozygous for the Akvr-1r locus. The cloned provirus was defective and contained a C-terminal end of the pol gene, a complete envelope gene, and a 3' long terminal repeat. The presence of this provirus was directly correlated with Akvr-1r-mediated virus resistance in cell cultures and hybrid mice. The Akvr-1r provirus restriction map and partial DNA sequence were identical to those of the Fv-4r allele, an ecotropic MuLV resistance locus from Japanese feral mice (M. musculus molossinus), which was previously shown to be allelic with the Akvr-1r gene. The 3' host flanking sequences of Fv-4r and Akvr-1r also had identical restriction maps. These findings indicate that Akvr-1r and Fv-4r are the same gene. It was probably acquired by interbreeding of these feral species in recent times. Conservation of this locus might be favored by the useful function that it performs in protection against ecotropic MuLV infection endemic in both populations of wild mice.     

A replication-defective variant of Moloney murine leukemia virus. I. Biological characterization.

We have studied the virus produced by a clone, termed 8A, that was isolated from a culture of murine sarcoma virus-transformed mouse cells after superinfection with Moloney murine leukemia virus (MuLV-M). Clone 8A produced high levels of type C virus particles, but only a low titer of infectious murine sarcoma virus and almost no infectious MuLV. When fresh cultures of mouse cells were infected with undiluted clone 8A culture fluids, they released no detectable pogeny virus for several weeks after infection. Fully infectious MuLV was then produced in these cultures. This virus was indistinguishable from MuLV-M by nucleic acid hybridization tests and in its insensitivity to Fv-1 restriction. It also induced thymic lymphomas in BALB/c mice. To explain these results, we propose that cone 8A is infected with a replication-defective variant of MuLV-M. Particles produced by clone 8A, containing this defective genome, can establish an infection in fresh cells but cannot produce progency virus at detectable levels. Several weeks after infection, the defect in the viral genome is corrected by back-mutation or by recombination with endogenous viral genomes, resulting in the formation of fully infectious progeny MuLV. The progeny MuLV'S that arose in two different experiments were found to be genetically different from each other. This is consistent with the hypothesis that, in each experiment, the progeny virus is formed clone 8A cells and assayed for infectivity by the calcium phosphate transfection technique. No detectable MuLV was produced by cells treated with this DNA. This finding, along with positive results obtained in control experiments, indicates that clone 8A cells do not contain a normal MuLV provirus.     

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 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.