Six-NB-tropic murine leukemia viruses derived from a B-tropic virus of BALB/c have altered p30

Capsid-dependent lentiviral restrictions

Host antiviral proteins inhibit primate lentiviruses and other retroviruses by targeting many features of the viral life cycle. The lentiviral capsid protein and the assembled viral core are known to be inhibited through multiple, directly acting antiviral proteins. Several phenotypes, including those known as Lv1 through Lv5, have been described as cell type-specific blocks to infection against some but not all primate lentiviruses. Here we review important features of known capsid-targeting blocks to infection together with several blocks to infection for which the genes responsible for the inhibition still remain to be identified. We outline the features of these blocks as well as how current methodologies are now well suited to find these antiviral genes and solve these long-standing mysteries in the HIV and retrovirology fields.

Patterns of Coevolutionary Adaptations across Time and Space in Mouse Gammaretroviruses and Three Restrictive Host Factors

The classical laboratory mouse strains are genetic mosaics of three Mus musculus subspecies that occupy distinct regions of Eurasia. These strains and subspecies carry infectious and endogenous mouse leukemia viruses (MLVs) that can be pathogenic and mutagenic. MLVs evolved in concert with restrictive host factors with some under positive selection, including the XPR1 receptor for xenotropic/polytropic MLVs (X/P-MLVs) and the post-entry restriction factor Fv1. Since positive selection marks host-pathogen genetic conflicts, we examined MLVs for counter-adaptations at sites that interact with XPR1, Fv1, and the CAT1 receptor for ecotropic MLVs (E-MLVs). Results describe different co-adaptive evolutionary paths within the ranges occupied by these virus-infected subspecies. The interface of CAT1, and the otherwise variable E-MLV envelopes, is highly conserved; antiviral protection is afforded by the Fv4 restriction factor. XPR1 and X/P-MLVs variants show coordinate geographic distributions, with receptor critical sites in envelope, under positive selection but with little variation in envelope and XPR1 in mice carrying P-ERVs. The major Fv1 target in the viral capsid is under positive selection, and the distribution of Fv1 alleles is subspecies-correlated. These data document adaptive, spatial and temporal, co-evolutionary trajectories at the critical interfaces of MLVs and the host factors that restrict their replication.

Expression levels of Fv1: effects on retroviral restriction specificities

BACKGROUND

The mouse protein Fv1 is a factor that can confer resistance to retroviral infection. The two major Fv1 alleles from laboratory mice, Fv1 (n) and Fv1 (b) , restrict infection by different murine leukaemia viruses (MLVs). Fv1(n) restricts B-tropic MLV, but not N-tropic MLV or NB-tropic MLV. In cells expressing Fv1(b) at natural levels, only N-MLV is restricted, however restriction of NB-MLV and partial restriction of B-MLV were observed when recombinant Fv1(b) was expressed from an MLV promoter in Fv1 null Mus dunni tail fibroblast cells. To investigate the relationship between expression level and restriction specificity we have developed new retroviral delivery vectors which allow inducible expression of Fv1, and yet allow sufficient production of fluorescent reporter proteins for analysis in our FACS-based restriction assay.

RESULTS

We demonstrated that at concentrations close to the endogenous expression level, Fv1(b) specifically restricts only N-MLV, but restriction of NB-MLV, and to a lesser extent B-MLV, could be gained by increasing the protein level of Fv1(b). By contrast, we found that even when Fv1(n) is expressed at very high levels, no significant inhibition of N-MLV or NB-MLV could be observed. Study of Fv1 mutants using this assay led to the identification of determinants for N/B tropism at an expression level close to that of endogenous Fv1(n) and Fv1(b). We also compared the recently described restriction activities of wild mice Fv1 proteins directed against non-MLV retroviruses when expressed at different levels. Fv1 from M. spretus restricted N-MLV, B-MLV and equine infectious anaemia virus equally even at low concentrations, while Fv1 from M. macedonicus showed even stronger restriction against equine infectious anaemia virus than to N-MLV. Restriction of feline foamy virus by Fv1 of M. caroli occurred at levels equivalent to MLV restriction.

CONCLUSIONS

Our data indicate that for some but not all Fv1 proteins, gain of restriction activities could be achieved by increasing the expression level of Fv1. However such a concentration dependent effect is not seen with most Fv1s and cannot explain the recently reported activities against non-MLVs. It will be interesting to examine whether overexpression of other capsid binding restriction factors such as TRIM5α or Mx2 result in novel restriction specificities.

Antiretroviral restriction factors in mice

One of the most exciting areas in contemporary retrovirus research is the discovery of "restriction factors". These are cellular proteins that act after virus entry to inhibit infection by or replication of retroviruses (and other viruses and intracellular pathogens). We briefly discuss here three antiretroviral restriction factors in mice: Fv1, APOBEC3, and tetherin, touching on both biological and molecular aspects of these restriction systems.

Evolution of the retroviral restriction gene Fv1: inhibition of non-MLV retroviruses

Fv1 is the prototypic restriction factor that protects against infection by the murine leukemia virus (MLV). It was first identified in cells that were derived from laboratory mice and was found to be homologous to the gag gene of an endogenous retrovirus (ERV). To understand the evolution of the host restriction gene from its retroviral origins, Fv1s from wild mice were isolated and characterized. Most of these possess intact open reading frames but not all restricted N-, B-, NR-or NB-tropic MLVs, suggesting that other viruses could have played a role in the selection of the gene. The Fv1s from Mus spretus and Mus caroli were found to restrict equine infectious anemia virus (EIAV) and feline foamy virus (FFV) respectively, indicating that Fv1 could have a broader target range than previously thought, including activity against lentiviruses and spumaviruses. Analyses of the Fv1 sequences revealed a number of residues in the C-terminal region that had evolved under positive selection. Four of these selected residues were found to be involved in the novel restriction by mapping studies. These results strengthen the similarities between the two capsid binding restriction factors, Fv1 and TRIM5α, which support the hypothesis that Fv1 defended mice against waves of retroviral infection possibly including non-MLVs as well as MLVs.

We have followed the evolution of the retroviral restriction gene, Fv1, by functional analysis. We show that Fv1 can recognize and restrict a wider range of retroviruses than previously thought including examples from the gammaretrovirus, lentivirus and foamy virus genera. Nearly every Fv1 tested showed a different pattern of restriction activity. We also identify several hypervariable regions in the coding sequence containing positively selected amino acids that we show to be directly involved in determining restriction specificity. Our results strengthen the analogy between Fv1 and another capsid-binding, retrovirus restriction factor, TRIM5α. Although they share no sequence identity they appear to share a similar design and appear likely to recognise different targets by a mechanism involving multiple weak interactions between a virus-binding domain containing several variable regions and the surface of the viral capsid. We also describe a pattern of constant genetic change, implying that different species of Mus have evolved in the face of ever-changing retroviral threats by viruses of different kinds.

Viral and cellular requirements for the nuclear entry of retroviral preintegration nucleoprotein complexes

Retroviruses integrate their reverse transcribed genomes into host cell chromosomes as an obligate step in virus replication. The nuclear envelope separates the chromosomes from the cell cytoplasm during interphase, and different retroviral groups deal with this physical barrier in different ways. Gammaretroviruses are dependent on the passage of target cells through mitosis, where they are believed to access chromosomes when the nuclear envelope dissolves for cell division. Contrastingly, lentiviruses such as HIV-1 infect non-dividing cells, and are believed to enter the nucleus by passing through the nuclear pore complex. While numerous virally encoded elements have been proposed to be involved in HIV-1 nuclear import, recent evidence has highlighted the importance of HIV-1 capsid. Furthermore, capsid was found to be responsible for the viral requirement of various nuclear transport proteins, including transportin 3 and nucleoporins NUP153 and NUP358, during infection. In this review, we describe our current understanding of retroviral nuclear import, with emphasis on recent developments on the role of the HIV-1 capsid protein.

Capsid-binding retrovirus restriction factors: discovery, restriction specificity and implications for the development of novel therapeutics

The development of drugs against human immunodeficiency virus type 1 infection has been highly successful, and numerous combinational treatments are currently available. However, the risk of the emergence of resistance and the toxic effects associated with prolonged use of antiretroviral therapies have emphasized the need to consider alternative approaches. One possible area of investigation is provided by the properties of restriction factors, cellular proteins that protect organisms against retroviral infection. Many show potent viral inhibition. Here, we describe the discovery, properties and possible therapeutic uses of the group of restriction factors known to interact with the capsid core of incoming retroviruses. This group comprises Fv1, TRIM5α and TRIMCypA: proteins that all act shortly after virus entry into the target cell and block virus replication at different stages prior to integration of viral DNA into the host chromosome. They have different origins and specificities, but share general structural features required for restriction, with an N-terminal multimerization domain and a C-terminal capsid-binding domain. Their overall efficacy makes it reasonable to ask whether they might provide a framework for developing novel antiretroviral strategies.

SUMO-interacting motifs of human TRIM5α are important for antiviral activity

Human TRIM5α potently restricts particular strains of murine leukemia viruses (the so-called N-tropic strains) but not others (the B- or NB-tropic strains) during early stages of infection. We show that overexpression of SUMO-1 in human 293T cells, but not in mouse MDTF cells, profoundly blocks N-MLV infection. This block is dependent on the tropism of the incoming virus, as neither B-, NB-, nor the mutant R110E of N-MLV CA (a B-tropic switch) are affected by SUMO-1 overexpression. The block occurred prior to reverse transcription and could be abrogated by large amounts of restricted virus. Knockdown of TRIM5α in 293T SUMO-1-overexpressing cells resulted in ablation of the SUMO-1 antiviral effects, and this loss of restriction could be restored by expression of a human TRIM5α shRNA-resistant plasmid. Amino acid sequence analysis of human TRIM5α revealed a consensus SUMO conjugation site at the N-terminus and three putative SUMO interacting motifs (SIMs) in the B30.2 domain. Mutations of the TRIM5α consensus SUMO conjugation site did not affect the antiviral activity of TRIM5α in any of the cell types tested. Mutation of the SIM consensus sequences, however, abolished TRIM5α antiviral activity against N-MLV. Mutation of lysines at a potential site of SUMOylation in the CA region of the Gag gene reduced the SUMO-1 block and the TRIM5α restriction of N-MLV. Our data suggest a novel aspect of TRIM5α-mediated restriction, in which the presence of intact SIMs in TRIM5α, and also the SUMO conjugation of CA, are required for restriction. We propose that at least a portion of the antiviral activity of TRIM5α is mediated through the binding of its SIMs to SUMO-conjugated CA.

Ordered assembly of murine leukemia virus capsid protein on lipid nanotubes directs specific binding by the restriction factor, Fv1

The restriction factor Fv1 confers resistance to murine leukemia virus (MLV), blocking progression of the viral life cycle after reverse transcription, but before integration into the host chromosome. It is known that the specificity of restriction is determined by both the restriction factor and the viral capsid (CA), but a direct interaction between Fv1 and MLV CA has not yet been demonstrated. With the development of a previously unexplored method for in vitro polymerization of MLV CA, it has now been possible to display a binding interaction between Fv1 and MLV CA. C-terminally His-tagged CA molecules were assembled on Ni-chelating lipid nanotubes, and analysis by electron microscopy revealed the formation of a regular lattice. Comparison of binding data with existing restriction data confirmed the specificity of the binding interaction, with multiple positions of both Fv1 and CA shown to influence binding specificity.

Host restriction factors blocking retroviral replication

Retroviruses are highly successful intracellular parasites, and as such they are found in nearly all branches of life. Some are relatively benign, but many are highly pathogenic and can cause either acute or chronic diseases. Therefore, there is tremendous selective pressure on the host to prevent retroviral replication, and for this reason cells have evolved a variety of restriction factors that act to inhibit or block the viruses. This review is a survey of the best-characterized restriction factors capable of inhibiting retroviral replication and aims to highlight the diversity of strategies used for this task.

Genetic control of retrovirus susceptibility in mammalian cells

Host cellular genes can have profound effects on retrovirus replication. Many of these genes encode restriction factors that block virus infection; others encode positive factors that are exploited by the viruses. Recently, a number of such genes have been cloned and characterized, bringing into sharper focus the mechanisms and pathways exploited by these viruses. The major host factors involved in the early phase of the viral life cycle are discussed.

Retroviral capsid determinants of Fv1 NB and NR tropism

The specificity determinants for susceptibility to resistance by the Fv1 n and b alleles map to amino acid 110 of the murine leukemia virus CA protein. To study the interaction between Fv1 and CA, we examined changes in CA resulting in the loss of susceptibility to Fv1 resistance in naturally occurring NB- and NR-tropic viruses. A variety of amino acid changes affecting Fv1 tropism were identified, at CA positions 82, 92 to 95, 105, 114, and 117, and they all were mapped to the apparent exterior of virion-associated CA. These amino acids may form a binding surface for Fv1.

Early steps of retrovirus replicative cycle

During the last two decades, the profusion of HIV research due to the urge to identify new therapeutic targets has led to a wealth of information on the retroviral replication cycle. However, while the late stages of the retrovirus life cycle, consisting of virus replication and egress, have been partly unraveled, the early steps remain largely enigmatic. These early steps consist of a long and perilous journey from the cell surface to the nucleus where the proviral DNA integrates into the host genome. Retroviral particles must bind specifically to their target cells, cross the plasma membrane, reverse-transcribe their RNA genome, while uncoating the cores, find their way to the nuclear membrane and penetrate into the nucleus to finally dock and integrate into the cellular genome. Along this journey, retroviruses hijack the cellular machinery, while at the same time counteracting cellular defenses. Elucidating these mechanisms and identifying which cellular factors are exploited by the retroviruses and which hinder their life cycle, will certainly lead to the discovery of new ways to inhibit viral replication and to improve retroviral vectors for gene transfer. Finally, as proven by many examples in the past, progresses in retrovirology will undoubtedly also provide some priceless insights into cell biology.

Consensus structural models for the amino terminal domain of the retrovirus restriction gene Fv1 and the murine leukaemia virus capsid proteins

Background

The mouse Fv1 (friend virus) susceptibility gene inhibits the development of the murine leukaemia virus (MLV) by interacting with its capsid (CA) protein. As no structures are available for these proteins we have constructed molecular models based on distant sequence similarity to other retroviral capsid proteins.

Results

Molecular models were constructed for the amino terminal domains of the probable capsid-like structure for the mouse Fv1 gene product and the capsid protein of the MLV. The models were based on sequence alignments with a variety of other retrovirus capsid proteins. As the sequence similarity of these proteins with MLV and especially Fv1 is very distant, a threading method was employed that incorporates predicted secondary structure and multiple sequence information. The resulting models were compared with equivalent models constructed using the sequences of the capsid proteins of known structure.

Conclusions

These comparisons suggested that the MLV model should be accurate in the core but with significant uncertainty in the loop regions. The Fv1 model may have some additional errors in the core packing of its helices but the resulting model gave some support to the hypothesis that it adopts a capsid-like structure.

Characterization of Moloney murine leukemia virus p12 mutants blocked during early events of infection

Mutations affecting either the N- or C-terminal regions of the Gag protein p12 block replication of Moloney murine leukemia virus (M-MuLV). Viruses carrying mutations in this portion of gag can mediate the assembly and release of virions but are unable to successfully carry out the early phase of the M-MuLV life cycle. Wild-type and mutant viruses were found to synthesize similar levels of linear viral DNA in both cytoplasmic and nuclear fractions, and there were no significant differences in either the density or sedimentation of the viral protein-nucleic acid complexes. Analysis of the termini of the linear viral DNAs showed that the 3' ends of the mutant viral DNA were processed normally by the integrase. Further, the preintegration complexes extracted from the cytoplasm of cells infected with the mutant viruses were competent for integration into target DNA in vitro. Nevertheless, no circular viral DNAs were detected in cells infected by the mutants, and functional proviruses were not formed. These results suggest that p12 has an unexpected role in the early phase of the life cycle and is needed after viral DNA synthesis to deliver the incoming DNA to the correct location and in the appropriate state to permit either circularization or integration of the viral DNA in vivo.

Intracellular trafficking of retroviral genomes during the early phase of infection: viral exploitation of cellular pathways

Retroviruses enter cells through specific cell-surface receptors and then embark on a journey that ultimately leads to the establishment of the integrated proviral DNA. The steps of the journey include the reverse transcription of the viral RNA into DNA, the trafficking of the viral protein-DNA complex through the cytoplasm, the entry of the complex into the nucleus, and the insertion of the linear viral DNA into the host genome. All these steps are likely to involve specific interactions of viral proteins with host machinery. Our knowledge of the details of these interactions is very limited but is rapidly expanding, and should provide a deeper understanding of the pathways and components used by the different classes of retroviruses. This knowledge in turn should enable the development of better and more efficient retroviral vectors for use in gene therapy protocols in vivo.

Identification of the regions of Fv1 necessary for murine leukemia virus restriction

The Fv1 gene restricts murine leukemia virus replication via an interaction with the viral capsid protein. To study this interaction, a number of mutations, including a series of N-terminal and C-terminal deletions, internal deletions, and a number of single-amino-acid substitutions, were introduced into the n and b alleles of the Fv1 gene and the effects of these changes on virus restriction were measured. A significant fraction of the Fv1 protein was not required for restriction; however, retention of an intact major homology region as well as of domains toward the N and C termini was essential. Binding specificity appeared to be a combinatorial property of a number of residues within the C-terminal portion of Fv1.

A single amino acid change in the murine leukemia virus capsid gene responsible for the Fv1(nr) phenotype

The nr allele at the mouse Fv1 restriction locus governs resistance to B-tropic and some N-tropic murine leukemia viruses (MLVs). Sequence analysis and site-specific mutagenesis of N-tropic MLVs identified a single amino acid difference responsible for this restriction that is distinct from the site that governs N or B tropism. Viruses with other substitutions at this site were evaluated for altered replication patterns.

Human immunodeficiency virus type 1 Gag protein binds to cyclophilins A and B

Retroviral Gag protein is capable of directing the assembly of virion particles independent of other retroviral elements and plays an important role early in the infection of a cell. Using the GAL4 two hybrid system, we screened a cDNA expression library and identified two host proteins, cyclophillins (CyPs) A and B, which interact specifically with the human immunodeficiency virus type 1 (HIV-1) Gag polyprotein Pr55gag. Glutathione S-transferase-CyP fusion proteins bind tightly to Pr55gag in vitro, as well as to the HIV-1 capsid protein p24. Cyclosporin A efficiently disrupts the Gag-CyPA interaction and less efficiently disrupts the Gag-CyPB interaction. The Gag-CyP interaction may be important for the HIV-1 life cycle and may be relevant to the pathology caused by this immunosuppressive virus.

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.

Fv-1 restriction of endogenous feline C-type RD114 virus genome phenotypically mixed with ecotropic murine leukemia viruses

Endogenous feline leukemia RD114 virus genome rendered capable of infecting mouse cells by phenotypic mixing with an ecotropic murine leukemia virus (MuLV) exhibited the Fv-1 restriction pattern of the ecotropic murine virus. However, RD114 genomes phenotypically mixed with ecotropic MuLV showed one-hit dose-response kinetics, even when titrated with murine cells with the restricted Fv-1 phenotype.

In vivo generation of antigenic variants of murine retroviruses

Inoculation of adult BALB/c-H-2k (BALB.K) mice with both Gross murine leukemia virus (GV) and a biological clone derived from this virus resulted in the recovery of variant viruses which differ from GV with respect to the expression of specific epitopes associated with the env gene product, gp70. The loss of these epitopes correlated with the failure of antiserum raised in BALB.K mice against GV to neutralize variant virus although this antiserum neutralized GV. In contrast, BALB/c-H-2b (BALB.B) mice, immunized with GV, produced antibodies which neutralized both GV and the variant virus, indicating that BALB.B mice respond to epitopes distinct from those recognized by BALB.K mice. These results suggest that the selection of variant viruses resulting from in vivo passage may be related to the immunoselective pressures exerted in mice which express particular alleles of certain major histocompatibility complex (MHC)-linked genes.

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.

Biochemical and immunological characterization of murine leukemia viruses that are paralysis-inducing in rats

The molecular size and pI of the viral structural proteins of four PVC viruses (PVC111, PVC211, PVC321 and PVC441) were compared by single or two-dimensional polyacrylamide gel electrophoresis. PVC111 had slightly larger p15E and gPr85 molecules (about 0.5 kilodalton) than did the other PVC viruses. On the other hand, the virion structural proteins p30, p15, p12E and p12 from all the viruses had the same molecular sizes and pIs. The gp70s and p10s from all the viruses showed the same molecular sizes. A monoclonal antibody to gp70 of PVC321 virus recognized the gp70s of all PVC viruses, but not the gp70s of four clones of the wild mouse ecotropic viruses, Friend murine leukemia viruses (F-MuLV), AKR ecotropic MuLV, dual-tropic F-MuLV or NZB endogenous xenotropic MuLV, revealing that these four PVC viruses are homologous with each other, but distinct from the known mouse retroviruses.

Mutants of murine leukemia viruses and retroviral replication

The analysis of retroviral mutants has played a critical role in the development of our understanding of the complex viral life cycle. The most fundamental result of that analysis has been the definition of the replication functions encoded by the viruses. From a biochemical examination of a particular step in the life cycle it is difficult to determine, for example, whether that step is catalyzed by a viral or a host enzyme; but the isolation of a viral mutant defective in that step can firmly establish that a viral function is involved. In this way many facts about the viruses have been established. We know that reverse transcriptase is encoded by the virus; that RNAase H and DNA polymerase activities reside on the same gene product; that processing of many precursor proteins is mediated by a viral proteinase; and that establishment of the integrated provirus requires a viral protein. The list of functions mediated by viral enzymes has largely been defined by the mutants isolated and studied in various laboratories. The second significant result of the studies of viral mutants has been the assignation of the replication functions to particular viral genes, and then more specifically to particular domains of these genes. Mutants and viral variants have been essential in the determination, for example, that the gag protein is the critical gene product for the assembly of a virion particle; that the env protein is the determinant of species specificity of infection; or that the LTR is a major determinant of tissue tropism and leukemogenicity. The subdivisions of functions within a given gene have similarly hinged on mutants. Genetic mapping was needed to establish that P30 is the most important region for assembly; that the proteinase and integrase functions reside, respectively, in the 5' and 3' portions of the pol gene; and that the glycosylated gag protein is dispensable for replication. A third important area of knowledge has depended heavily on viral mutants: the determination of host functions and proteins that interact with viral proteins. Variant viruses with altered or restricted host ranges serve to define differences between pairs of different host cells, and the mapping of the viral mutations serves to define the viral protein important in that interaction with the host. These studies are only in their infancy, but it is clear that substantial efforts will be made to further analyze these host functions.(ABSTRACT TRUNCATED AT 400 WORDS)

Production of acquired immunodeficiency syndrome-associated retrovirus in human and nonhuman cells transfected with an infectious molecular clone

We constructed an infectious molecular clone of acquired immunodeficiency syndrome-associated retrovirus. Upon transfection, this clone directed the production of infectious virus particles in a wide variety of cells in addition to human T4 cells. The progeny, infectious virions, were synthesized in mouse, mink, monkey, and several human non-T cell lines, indicating the absence of any intracellular obstacle to viral RNA or protein production or assembly. During the course of these studies, a human colon carcinoma cell line, exquisitely sensitive to DNA transfection, was identified.

Analysis of structural polypeptides of the lymphoproliferative disease virus (LPDV) of turkeys

The polypeptide composition of the lymphoproliferative disease virus (LPDV) of turkeys was shown to comprise several polypeptides with apparent molecular weights of 76, 31, 28, 20 and 15 kDa. This polypeptide pattern is distinctly different from the protein profiles of avian leukosis viruses, reticuloendotheliosis virus, or murine leukemia viruses. Moreover, LPD virions contain 2 major structural proteins (p31 and p28), in contrast to only one major internal protein present in most other retroviruses. The 76 kDa protein was established as the major viral envelope glycoprotein. The uniqueness of the LPDV polypeptide pattern is consistent with the lack of genetic relatedness of LPDV genome to other retroviruses, establishing LPDV as a representative of a distinct group of retroviridae.

The pathophysiology of murine retrovirus-induced leukemias

Murine leukemia viruses (MuLVs) are retroviruses which induce a broad spectrum of hematopoietic malignancies. In contrast to the acutely transforming retroviruses, MuLVs do not contain transduced cellular genes, or oncogenes. Nonetheless, MuLVs can cause leukemias quickly (4 to 6 weeks) and efficiently (up to 100% incidence) in susceptible strains of mice. The molecular basis of MuLV-induced leukemia is not clear. However, the contribution of individual viral genes to leukemogenesis can be assayed by creating novel viruses in vitro using recombinant DNA techniques. These genetically engineered viruses are tested in vivo for their ability to cause leukemia. Leukemogenic MuLVs possess genetic sequences which are not found in nonleukemogenic viruses. These sequences control the histologic type, incidence, and latency of disease induced by individual MuL Vs.

Isolation from cats of an endogenous type C virus with a novel envelope glycoprotein

A search for variant endogenous cat viruses led to a novel isolate. Although the major envelope glycoprotein of this virus was similar in size to that of an RD-114-like virus that was coisolated, it was unrelated to RD-114 or feline leukemia virus by immunological and biological criteria. This degree of dissimilarity suggests a different evolutionary progenitor from that for the RD-114 and feline leukemia virus viral envelopes. The novel virus did, however, code for gag gene polypeptides which are closely related to RD-114 virus. Neither the novel isolate nor the RD-114-like coisolate induced foci in S+L- cat cells which restrict focus induction by RD-114 virus. This suggests that the two viruses share a common genomic target of restriction which resides outside of the env region.

Construction and analysis of deletion mutations in the pol gene of Moloney murine leukemia virus: a new viral function required for productive infection

We have used in vitro mutagenesis to explore the functions of the gene products encoded by the pol gene of Moloney murine leukemia virus (M-MuLV). Deletions were constructed at a variety of positions in the gene, and the altered DNA copies of the viral genome were introduced into mouse cells by cotransformation. The mutants could be divided into two classes depending on the phenotype and map position of the deletion within the pol gene. Mutants with deletions mapping in the 5' portion of the gene were found to be completely deficient in reverse transcriptase activity. Mutants mapping in the 3' portion of the gene, however, assembled and released virions with normal levels of reverse transcriptase and RNAase H activities. When applied to permissive cells, these virions directed the synthesis of all three forms of unintegrated viral DNA: full-length, double-stranded linear DNA and the two circular forms with one and two copies of the long terminal repeat sequences. The infection was arrested at this point and the infected cells did not become producers of virus. Thus the 3' portion of the pol gene encodes a polypeptide with a function distinct from that of reverse transcriptase, which is not required for synthesis of viral DNA but is essential for establishment of that DNA in a stable, active form in the infected cell. We suggest that this function may be the integration of the proviral DNA.

Nucleotide sequences of gag-pol regions that determine the Fv-1 host range property of BALB/c N-tropic and B-tropic murine leukemia viruses

Previously, in vitro recombinant DNA studies demonstrated that genetic determinants of N-tropism and B-tropism, or Fv-1-related host range properties of murine leukemia viruses, were located in a BamHI-HindIII DNA segment derived from the 5' portion of the cloned viral genome. We sequenced this segment and its immediate 5' region from cloned DNA of two BALB/c mouse C-type viruses (WN1802N and WN1802B) and found base differences at 12 positions out of the otherwise identical 1,390-base-pair sequences. Analysis of the most likely reading frame showed that 6 of the 12 base differences would result in four encoded amino acid changes, three of which occur at positions 109 (glutamine in WN1802N versus threonine in WN1802B), 110 (arginine in WN1802N versus glutamic acid in WN1802B), and 159 (glutamic acid in WN1802N versus glycine in WN1802B) of the p30 protein. The remaining one is located at position 36 (threonine in WN1802N versus isoleucine in WN1802B) of the viral polymerase protein. Significant conformational alteration of the p30 protein could be predicted from these amino acid changes.

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.

Ecotropic MuLV expression in radiation-induced lymphomas of the RF, BALB/c and (BALB/c X RF)F1 mouse strains

Endogenous ecotropic viruses isolated from radiation-induced lymphomatous tissue of BALB/c mice have been shown to consist of a collection of variants as assayed by the mobility of virion structural proteins p30, p15, p12 and gp70 on SDS-polyacrylamide gel electrophoresis (SDS-PAGE) (Ellis et al., 1980 a). In this study we show that a similar phenomenon occurs in RF mice, but only with regard to p15 and gp70, and not p30 and p12. Using the distinct and unvarying mobility of the RF viral p12 protein on SDS-PAGE as a marker, we show that the RF-derived ecotropic murine leukemia virus (MuLV) is expressed to the exclusion of the BALB/c-derived ecotropic MuLV in F1 hybrid mice of the BALB/c X RF cross, and that variant viruses expressed in F1 radiation-induced lymphomatous tissue display the pattern of variation characteristic of the RF, and not of the BALB/c, strain.

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).

Variants of type-C retroviruses from DBA/2 mice: protein-structural and biological properties

Ecotropic murine leukemia viruses isolated from normal and carcinogen-treated DBA/2 mice can be classified into three main groups that differ in structure and biology. Two groups, called Ea and Eb, consist of N-tropic viruses related to the standard endogenous ecotropic virus of AKR mice. Ea viruses replicate with reduced efficiency in cell lines derived from C3H mice, while Eb viruses essentially replicate normally in these cells. As elsewhere reported, Ea viruses appear apathogenic in C3H mice, while Eb viruses cause a moderate incidence of late leukemias. The biological differences are associated with modulations of the fine structure of the gag gene-encoded proteins. A third group of viruses, called Ec, is clearly more diverged. They differ extensively from Ea and Eb viruses in the products of the gag and env gene, and are related to Rauscher leukemia virus. Ec viruses are NB-ecotropic; they replicate efficiently in all mouse cells tested, and induce leukemias in C3H mice with shorter latency periods than Eb viruses. Since published nucleic acid hybridization data indicate that DBA/2 mice only carry one ecotropic provirus, we assume that the DBA/2 viruses represent a developmental series of variants evolving during the life of the animals.

Temperature-sensitive mutants of influenza A/Udorn/72 (H3N2) virus. III. Genetic analysis of temperature-dependent host range mutants

One hundred thirty-three ts mutants of influenza A/Udorn/72 virus were arranged into eight complementation groups, A-H, on Madin-Darby canine kidney (MDCK) monolayer cultures at the restrictive temperature of 40 degrees. The eight complementation groups, A-H, on MDCK cells corresponded to the eight recombination groups, A-H, on rhesus monkey kidney (RMK) cells, respectively, and this suggested that each MDCK complementation group represented one of the eight influenza A RNA gene segments. These ts viruses were used to identify the locus of the ts mutation in temperature-dependent host range (td-hr) mutants of the A/Udorn/72 virus. Sixteen of the 133 ts mutants exhibited distinct host (MDCK)-dependent restriction of plaque formation at 40 degrees but not at 34 degrees and were referred to as td-hr mutants. These 16 td-hr mutants were ts+ (not ts) on RMK cells but ts on MDCK cells. The td-hr mutants did not share a common lesion and the ts lesions were distributed among the eight complementation groups, A-H, when tested on MDCK cells. An analysis of one of the td-hr mutants indicated that an extrageneic RMK-dependent suppressor mutation did not account for the td-hr phenotype. These data suggested that a host-dependent ts mutation was responsible for the td-hr restriction of this mutant. Representation of td-hr mutations in each of the eight complementation groups indicates that the influenza A virus genome can undergo mutation leading to an altered host range in any of its eight RNA segments.

Control of RFM strain endogenous retrovirus in RFM mouse cells

RFM/Un mice express an endogenous type C retrovirus throughout their life span in many tissues; primary or established embryo fibroblast cell cultures do not express a virus but can be induced by exposure to 5-iodo-2'-deoxyuridine. All of our sources yielded a single ecotropic virus (RFV) which appeared to be related more closely to the endogenous N-tropic virus (WN1802N) of BALB/c mice than to Gross leukemia virus on the basis of two-dimensional gel electropherograms of virion proteins. No xenotropic or recombinant viruses were isolated by cocultivation techniques. RFV is N-tropic, and RFM/Un cells possess the Fv-1n allele, as indicated by restriction of B-tropic virus and susceptibility to Gross strain N-tropic virus. However, RFM cells are highly resistant to RFV and other endogenous N-tropic viruses. This resistance is expressed by two-hit titration kinetics and by inhibition of viral linear duplex DNA formation. This is similar to the effects of the Fv-1 locus, but preliminary work has shown no apparent genetic linkage between the two restrictions. The relative strength of the restriction, the presence of a single class of ecotropic virus, and the absence of recombinant viruses suggest that in RFM mice virus is expressed only in cells in which it is induced and not by cell-to-cell transmission.

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.

Comparison of the restriction endonuclease maps of unintegrated proviral DNAs from four xenotropic murine leukemia viruses

From purified linear and superhelical DNAs, the restriction endonuclease maps of four xenotropic murine leukemia virus DNAs from NFS, NZB, BALB/c, and AKR mice were determined with ten restriction endonucleases. Each xenotropic proviral DNA was found to be a unique restriction endonuclease map, with differences in the gag, pol, env, and terminal repeated sequence regions. However, type-specific SacI and EcoRI sites in the env region were identical in all four xenotropic murine leukemia virus DNAs and were not found in ecotropic murine leukemia virus DNA. Comparison of the xenotropic murine leukemia virus DNA maps with maps of ecotropic murine leukemia virus DNA showed that the pol and terminal repeated sequence regions were highly conserved. Other similarities in ecotropic and some xenotropic viral DNAs suggest common origins.

Biochemical analysis of the p30's of N-, B-, and B leads to NB-tropic murine leukemia viruses of BALB/c origin

Previous analysis of the virion proteins of an N- and a B-tropic type C virus of BALB/c mice, of 16 N-tropic recombinants (XLPN viruses) between these viruses, and of eight NB-tropic viruses derived from the B-tropic virus suggested that among these closely related viruses N-, B-, or NB-tropism was associated with the electrophoretic mobility of p30 on sodium dodecyl sulfate-polyacrylamide gels, and thus that p30 might determine this phenotype. To obtain further evidence for the association of structural markers of p30 with N-, B-, or NB-tropism, we have analyzed the p30's of these same viruses by using two-dimensional tryptic peptide mapping and slab gel isoelectric focusing. The results of these analyses suggest that (i) a single peptide unique to the N-tropic virus p30- is present in the p30 of all N-tropic recombinants; (ii) a single peptide unique to the B virus p30 is not present in p30's of the N-tropic recombinants, and this peptide is also absent in p30's of NB-tropic viruses derived from the B-tropic virus; and (iii) p30's of NB-tropic viruses possess a new tryptic peptide not found in the p30 of their B-tropic virus progenitors, and this new peptide is not found in the p30 of the N-tropic virus of BALB/c or the XLPN viruses. These results are consistent with the possibility that p30 may determine the N-, B-, or NB-tropism of murine leukemia viruses. In addition, these studies indicate that some of the N-tropic recombinants have experienced recombination within the p30 gene.

Efficient production of xenotropic murine leukemia virus unintegrated proviral DNA by cocultivation

Cocultivation of virus-producing cells and homologous uninfected cells yielded greater than a 10-fold increase in linear and superhelical proviral DNAs as compared with previously published techniques.