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

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

Simple, Quantitative Assay for Both Xenotropic Murine Leukemia and Ecotropic Feline Leukemia Viruses

A cat cell line carrying the genome of a murine sarcoma virus developed discrete foci in linear response to infection with feline leukemia virus or xenotropic murine C-type virus.     

Host-Range Restrictions of Murine Leukemia Viruses in Mouse Embryo Cell Cultures

Murine leukemia virus strains fall into three categories with respect to their ability to propagate in cells of National Institutes of Health (NIH) Swiss and BALB/c mouse embryos. Cultures of NIH cells are 100- to 1,000-fold more sensitive to "N-tropic" strains than BALB/c cell cultures, but are 30- to 100-fold less sensitive to "B-tropic" strains. Some virus strains (dually tropic or "NB-tropic") propagate equally well in both cells. M-MSV pseudotypes show the host-range characteristics of the virus supplying the envelope, both in vitro and in vivo. The host-range characteristics appear to be genetically determined and could not be explained by host-induced modification or virus mixtures. There was no correlation between host range and Gross-AKR or FMR serotype.     

Expression of the mammalian Xenotropic Polytropic Virus Receptor 1 (XPR1) in tobacco leaves leads to phosphate export

Phosphate homeostasis in multicellular eukaryotes depends on both phosphate influx and efflux. The mammalian Xenotropic Polytropic Virus Receptor 1 (XPR1) shares homology to the Arabidopsis PHO1, a phosphate exporter expressed in roots. However, phosphate export activity of XPR1 has not yet been demonstrated in a heterologous system. Here, we demonstrate that transient expression in tobacco leaves of XPR1-GFP leads to specific phosphate export. Like PHO1-GFP, XPR1-GFP is localized predominantly to the endomembrane system in tobacco cells. These results show that tobacco leaves are a good heterologous system to study the transport activity of members of the PHO1/XPR1 family.     

Polymorphisms in Toll-Like Receptor 4 Underlie Susceptibility to Tumor Induction by the Mouse Polyomavirus

PERA/Ei (PE) mice are susceptible to tumor induction by polyomavirus (Py), while C57BR/cdJ (BR) mice are resistant. Antigen-presenting cells from BR mice respond to the virus with interleukin-12 (IL-12) and those from PE mice with IL-10. These polarized cytokine responses underlie the development of effective antitumor immunity in BR mice and the lack thereof in PE mice. An ex vivo cytokine production assay using spleen cells from infected [PE × BR] F2 mice together with a genome-wide SNP (single-nucleotide polymorphism)-based QTL (quantitative trait locus) analysis was used to map the determinant of cytokine production to a region of chromosome 4 carrying the Toll-like receptor 4 (TLR4) gene. Genotyping of infected F2 mice showed concordance of TLR4 allele-specific DNA sequences with the cytokine profile. Cytokine responses elicited by Py are MyD88 dependent. Bacterial lipopolysaccharide (LPS), a known TLR4 ligand, induced the same polarized responses as the virus in these host strains. Spleen cells from C3H/HeJ and C57BL/10ScNJ LPS-nonresponsive mice challenged in vitro with Py showed an impaired IL-12 response but were unaffected in IL-10 production. TLR4s of strains PE and BR differ by 3 amino acid substitutions, 2 in the extracellular domain and 1 in the intracellular domain. cDNAs encoding the TLR4s signaled equally to an NF-κB reporter in 293 cells in a ligand-independent manner. When introduced into TLR2/TLR4 double-knockout macrophages, the TLR4 cDNA from BR mice conferred a robust IL-12 response to Py and no IL-10 response. The TLR4 cDNA from PE mice failed to confer a response with either cytokine. These results establish TLR4 as a key mediator of the cytokine response governing susceptibility to tumor induction by Py.     

Genetic Polymorphisms Affect Mouse and Human Trace Amine-Associated Receptor 1 Function

Methamphetamine (MA) and neurotransmitter precursors and metabolites such as tyramine, octopamine, and β-phenethylamine stimulate the G protein-coupled trace amine-associated receptor 1 (TAAR1). TAAR1 has been implicated in human conditions including obesity, schizophrenia, depression, fibromyalgia, migraine, and addiction. Additionally TAAR1 is expressed on lymphocytes and astrocytes involved in inflammation and response to infection. In brain, TAAR1 stimulation reduces synaptic dopamine availability and alters glutamatergic function. TAAR1 is also expressed at low levels in heart, and may regulate cardiovascular tone. Taar1 knockout mice orally self-administer more MA than wild type and are insensitive to its aversive effects. DBA/2J (D2) mice express a non-synonymous single nucleotide polymorphism (SNP) in Taar1 that does not respond to MA, and D2 mice are predisposed to high MA intake, compared to C57BL/6 (B6) mice. Here we demonstrate that endogenous agonists stimulate the recombinant B6 mouse TAAR1, but do not activate the D2 mouse receptor. Progeny of the B6XD2 (BxD) family of recombinant inbred (RI) strains have been used to characterize the genetic etiology of diseases, but contrary to expectations, BXDs derived 30–40 years ago express only the functional B6 Taar1 allele whereas some more recently derived BXD RI strains express the D2 allele. Data indicate that the D2 mutation arose subsequent to derivation of the original RIs. Finally, we demonstrate that SNPs in human TAAR1 alter its function, resulting in expressed, but functional, sub-functional and non-functional receptors. Our findings are important for identifying a predisposition to human diseases, as well as for developing personalized treatment options.     

Evolution of Functional and Sequence Variants of the Mammalian XPR1 Receptor for Mouse Xenotropic Gammaretroviruses and the Human-Derived Retrovirus XMRV

Genetic conflicts between retroviruses and their receptors result in the evolution of novel host entry restrictions and novel virus envelopes, and such variants can influence trans-species transmission. We screened rodents and other mammals for sequence variation in the Xpr1 receptor for the mouse xenotropic or polytropic mouse leukemia viruses (X-MLVs or P-MLVs, respectively) of the gammaretrovirus family and for susceptibility to mouse-derived X/P-MLVs and to XMRV (xenotropic murine leukemia virus-related virus), an X-MLV-like virus isolated from humans with prostate cancer and chronic fatigue syndrome. We identified multiple distinct susceptibility phenotypes; these include the four known Xpr1 variants in Mus and a novel fifth Xpr1 gene found in Mus molossinus and Mus musculus. We describe the geographic and species distribution of the Mus Xpr1 variants but failed to find the X-MLV-restrictive laboratory mouse allele in any wild mouse. We used mutagenesis and phylogenetic analysis to evaluate the functional contributions made by constrained, variable, and deleted residues. Rodent Xpr1 is under positive selection, indicating a history of host-pathogen conflicts; several codons under selection have known roles in virus entry. All non-Mus mammals are susceptible to mouse X-MLVs, but some restrict other members of the X/P-MLV family, and the resistance of hamster and gerbil cells to XMRV indicates that XMRV has unique receptor requirements. We show that the hypervariable fourth extracellular XPR1 loop (ECL4) contains three evolutionarily constrained residues that do not contribute to receptor function, we identify two novel residues important for virus entry (I579 and T583), and we describe a unique pattern of ECL4 variation in the three virus-restrictive Xpr1 variants found in MLV-infected house mice; these mice carry different deletions in ECL4, suggesting either that these sites or loop size affects receptor function.The XPR1 receptor mediates entry for the mouse leukemia viruses (MLVs) with xenotropic and polytropic host ranges (X-MLVs and P-MLVs, respectively). X-MLVs and P-MLVs can be isolated from laboratory mice and are capable of infecting cells of nonrodent species; these viruses are distinguished by the ability of P-MLVs, but not X-MLVs, to infect cells of the laboratory mouse and by the cytopathic and leukemogenic properties of P-MLVs, also termed MCF MLVs (mink cell focus-inducing MLVs) (11, 16, 24). XPR1 is also the receptor for several wild mouse isolates with an atypical host range (6, 48, 49) and for the recently described virus XMRV (xenotropic murine leukemia virus-related virus) (8), isolated from human patients with prostate cancer or chronic fatigue syndrome (27, 37, 43). Studies on the XPR1 receptor have identified residues critical for virus entry and described functionally distinct variants of XPR1 in human and rodent species that differ in their abilities to mediate entry of various virus isolates (18, 29, 31, 48, 49).In Mus, four receptor variants of Xpr1 are found in different taxonomic groups. Xpr1ⁿ was originally described in strains of the laboratory mouse (1, 41, 51), which are largely derived from Mus domesticus (50). Xpr1^c was identified in the Asian species Mus castaneus (29, 31); Xpr1^p is in the Asian species Mus pahari (48); and Xpr1^sxv was found in several Eurasian species (18, 31). These variants are distinguished by their differential susceptibilities to prototype X-MLVs and P-MLVs as well as to two wild mouse isolates, CasE#1 and Cz524 (49); only Xpr1^sxv encodes a receptor that is fully permissive for all isolates. The host range differences of these various virus isolates are due to sequence polymorphisms in both receptor and viral envelope genes.The various mouse X/P-MLV isolates and the humanized XMRV define six different tropism patterns based on infectivity on rodent cells carrying Xpr1 variants (49). These tropisms distinguish the two wild mouse isolates, CasE#1 and Cz524, and identify two P-MLV host range subgroups and two X-MLV/XMRV subgroups. Specific XPR1 residues responsible for entry of these viruses have been identified by analysis of rodent Xpr1 variants and mutants. These receptor determinants lie in two of the four predicted extracellular loops (ECLs) of Xpr1, ECL3 and ECL4 (31, 44, 48, 49). Two critical amino acids have been defined for X-MLV entry: K500 in ECL3 and T582 in ECL4 (31). These two receptor determinants independently produce X-MLV receptors but are not functionally equivalent, as the Δ582Τ insertion into Xpr1ⁿ generates a receptor for CasE#1, but the E500K substitution does not (48). Sensitivity to the six tropism subgroups is further modulated by specific substitutions at ECL3 residues 500, 507, and 508 (49). The sequence variations that distinguish the rodent XPR1 receptors can result in subtle differences in the efficiency of virus infection or complete resistance to specific X/P-MLVs.The characterization of host genes that effect and/or block entry has obvious importance for a broader understanding of how viruses spread in natural populations and are transmitted to new hosts and how those populations adapt to retrovirus infections. The four house mouse species carry endogenous retroviruses (ERVs) for X-MLVs and P-MLVs (XMVs and PMVs, respectively) (3, 20, 42), and three of these species harbor infectious X-MLVs (4, 19, 48, 49). Restrictive variants of the XPR1 receptor have evolved in these virus-infected mice, along with the virus envelope (env) variants that define the tropism subgroups. We thus sought to examine the evolution of Xpr1 in rodent species, and we extended this functional and sequence analysis to nonrodent species for two reasons. First, identification of XMRV in several human patient cohorts (27, 37, 43), the recent detection of P-MLV-related sequences in patients and blood donors (26), and the multiple instances of transspecies transmission of mouse gammaretroviruses (33) support an effort to describe factors that mediate or modulate virus entry in these species. Second, analysis of nonrodent species with novel patterns of virus restriction may uncover different or additional entry determinants. In the present study, we characterized 49 mice of different species or from different geographic locations and 24 other mammalian species for sequence and functional variants of the Xpr1 receptor. We identified a novel 5th functional Xpr1 variation in Mus, showed that restrictive XPR1 receptors in the three MLV-infected house mouse lineages have different deletions in ECL4, demonstrated that XPR1 is under positive selection, identified novel virus restriction phenotypes in nonrodent species, and demonstrated that XMRV relies on unique entry determinants.     

Murine Sarcoma and Leukemia Viruses: Assay Using Clonal Lines of Contact-Inhibited Mouse Cells

A continuous cell line of highly contact-inhibited cells (NIH/3T3) has been developed from NIH Swiss mouse embryo cultures. Its growth properties are similar to those of 3T3 and BALB/3T3. Although 3T3 is relatively insensitive to focus formation by murine sarcoma viruses, cloned lines of both NIH/3T3 and BALB/3T3 have been isolated that are highly sensitive to sarcoma virus focus formation and leukemia virus growth. The sensitivity and specificity are comparable to those found with primary embryo cells. MSV-transformed lines of NIH/3T3 have been obtained.     

异嗜性小鼠白血病病毒相关病毒研究现状及展望

异嗜性小鼠白血病病毒相关病毒(XMRV)是第一个能够感染人类的γ逆转录病毒,该病毒最早在前列腺癌患者体内被发现。越来越多的研究提示,XMRV可能与前列腺癌和慢性疲劳综合征密切相关。我们就已知的XMRV的生物学特征、流行病学特征及研究展望做简要综述。     

The Urokinase Receptor Takes Control of Cell Migration by Recruiting Integrins and FPR1 on the Cell Surface

The receptor (uPAR) of the urokinase-type plasminogen activator (uPA) is crucial in cell migration since it concentrates uPA proteolytic activity at the cell surface, binds vitronectin and associates to integrins. uPAR cross-talk with receptors for the formylated peptide fMLF (fMLF-Rs) has been reported; however, cell-surface uPAR association to fMLF-Rs on the cell membrane has never been explored in detail.We now show that uPAR co-localizes at the cell-surface and co-immunoprecipitates with the high-affinity fMLF-R, FPR1, in uPAR-transfected HEK-293 (uPAR-293) cells. uPAR/β1 integrin and FPR1/β1 integrin co-localization was also observed. Serum or the WKYMVm peptide (W Pep), a FPR1 ligand, strongly increased all observed co-localizations in uPAR-293 cells, including FPR1/β1 integrin co-localization. By contrast, a low FPR1/β1 integrin co-localization was observed in uPAR-negative vector-transfected HEK-293 (V-293) cells, that was not increased by serum or W Pep stimulations.The role of uPAR interactions in cell migration was then explored. Both uPAR-293 and V-293 control cells efficiently migrated toward serum or purified EGF. However, cell treatments impairing uPAR interactions with fMLF-Rs or integrins, or inhibiting specific cell-signaling mediators abrogated uPAR-293 cell migration, without exerting any effect on V-293 control cells.Accordingly, uPAR depletion by a uPAR-targeting siRNA or uPAR blocking with an anti-uPAR polyclonal antibody in cells constitutively expressing high uPAR levels totally impaired their migration toward serum.Altogether, these results suggest that both uPAR-positive and uPAR-negative cells are able to migrate toward serum; however, uPAR expression renders cell migration totally and irreversibly uPAR-dependent, since it is completely inhibited by uPAR blocking.We propose that uPAR takes control of cell migration by recruiting fMLF-Rs and β1 integrins, thus promoting their co-localization at the cell-surface and driving pro-migratory signaling pathways.     

The Mouse Homolog of the Bovine Leukemia Virus Receptor Is Closely Related to the δ Subunit of Adaptor-Related Protein Complex AP-3, Not Associated with the Cell Surface

A mouse cDNA (mBLVR1) which was highly homologous to the bovine cDNA of the bovine leukemia virus receptor (BLVR) gene was cloned. The mBLVR1 cDNA, of 4,730 bp, covered nearly the full length of the mRNA (about 5 kb) and included an open reading frame (ORF) encoding a protein of 1,199 amino acids. While the bovine BLVR protein was thought to be a type I transmembrane protein, the deduced protein coded by mBLVR1 did not appear to be a typical transmembrane protein. The ORF of mBLVR1 ended at a site 280 amino acids upstream of the termination codon of the bovine BLVR ORF, so the deduced mouse BLVR protein lacked the corresponding transmembrane and cytoplasmic regions of the predicted bovine BLVR protein. No significant hydrophobic region was found in the mouse protein. Recently, a human cDNA which was highly homologous (69.6% homology) to the mouse BLVR gene was reported. The cDNA encodes the δ subunit of the human adaptor-related protein complex AP-3, which aligned almost collinearly with the mouse BLVR protein. AP-3 and all other related adaptor protein complexes have been shown to be associated with intracellular vesicles but not with the cell surface. Thus, the mouse BLVR homolog appeared to be the mouse AP-3 δ subunit itself or closely related to it, but the bovine BLVR gene seemed slightly different from the adaptor subunit gene family.     

The Mouse H-2A Region Influences the Envelope Gene Structure of Tumor-Associated Murine Leukemia Viruses

C57BL/10 (B10) strains congenic at the mouse major histocompatibility locus (H-2) were injected with a modified ecotropic SL3-3 murine leukemia virus (MuLV) to determine the effect of the H-2 genes on the envelope gene structure of recombinant MuLVs. All tested strains rapidly developed T-cell lymphomas, and recombinant proviruses were detected in the tumor DNAs by Southern blot. The B10.D2 (H-2^d), B10.Br (H-2^k), B10.Q (H-2^q), and B10.RIII (H-2^r) strains exhibited a TI phenotype in which almost all tumors contained type I recombinants. These recombinants characteristically acquire envelope gene sequences from the endogenous polytropic viruses but retain the 5′ p15E (TM) gene sequences from the ecotropic virus. The parental B10 (H-2^b) strain, however, had a novel phenotype that was designated NS for nonselective. Only 30% of the B10 tumors had detectable type I recombinants, whereas a proportion of the others appeared to contain type II recombinants that lacked the type I-specific ecotropic p15E gene sequences. Studies of other B10 congenic strains with hybrid H-2 loci and selected F₁ animals revealed that the NS phenotype was regulated by a dominant gene(s) that mapped to the A region of H-2^b. These results demonstrate that a host gene within the major histocompatibility complex can influence the genetic evolution of pathogenic retroviruses in vivo.     

Induction of Syncytia by Neuropathogenic Murine Leukemia Viruses Depends on Receptor Density, Host Cell Determinants, and the Intrinsic Fusion Potential of Envelope Protein

Infection by the neuropathogenic murine leukemia virus (MLV) TR1.3 results in hemorrhagic disease that correlates directly to in vivo syncytium formation of brain capillary endothelial cells (BCEC). This phenotype maps to amino acid 102 in the envelope (Env) protein of TR1.3. Substitution of glycine (G) for tryptophan (W) at this position (W102G Env) in the nonpathogenic MLV FB29 induces both syncytium formation and neurologic disease in vivo. Using an in vitro gene reporter cell fusion assay, we showed that fusion either with murine NIH 3T3 cells or with nonmurine target cells that expressed receptors at or below endogenous murine levels mirrored that seen in BCEC in vivo. In these instances only TR1.3 and W102G Env induced cell fusion. In contrast, when receptor levels on nonmurine cells were raised above endogenous murine levels, FB29 Env was as fusogenic as the neuropathogenic TR1.3 and W102G Env. These results indicate that TR1.3 Env and W102G Env are intrinsically more fusogenic than FB29 Env, that the induction of fusion requires a threshold number of receptors that is greater for FB29 Env than for TR1.3 or W102G Env, and that receptor density on murine NIH 3T3 cells and BCEC is below the threshold for FB29-dependent fusion. Surprisingly, receptor density on NIH 3T3 cells could not be increased by stable expression of exogenous receptors, and FB29-dependent fusion was not observed in NIH 3T3 cells that transiently expressed elevated receptor numbers. These results suggest that an additional undefined host cell factor(s) may limit both receptor expression and fusion potential in murine cells.     

Cytoplasmic Inheritance of a Cell Surface Antigen in the Mouse

Mta is a cell surface antigen of the mouse and serves as a target for specific T killer lymphocytes. Using a killer cell assay, the antigen has been found in 72 strains of laboratory mice and, with one exception, in all tested samples of mice caught in the wild or bred from such, including Mus molossinus, Mus castaneus and Mus spretus. Five strains of rats, non-inbred NMRI mice, most substrains of NZB mice and the closely related strain NZO are negative for Mta. In reciprocal F₁ crosses between several Mta⁺ and two Mta^- strains, the antigen is maternally transmitted; that is, Mta⁺ females bear only positive offspring, whereas Mta^- females bear only negative offspring, regardless of the genotype of the male. Since 34 foster-nursed mice had the Mta type of their genetic mothers, the factor that determines expression of Mta must be transmitted before birth and not via the milk. The cytoplasmic genes of Mta⁺ strains have been combined with the chromosomal genes of Mta^- strains, and vice versa, by repeated backcrossing. All progeny retained the Mta type of their maternal lines. Thus, the Mta type is determined solely by maternal inheritance and is not influenced by chromosomal genes. We found no evidence of incompatibility between the cytoplasmic factors and nuclear genes of Mta^- and Mta ⁺ strains.     

A Putative Cell Surface Receptor for Anemia-Inducing Feline Leukemia Virus Subgroup C Is a Member of a Transporter Superfamily

Domestic cats infected with the horizontally transmitted feline leukemia virus subgroup A (FeLV-A) often produce mutants (termed FeLV-C) that bind to a distinct cell surface receptor and cause severe aplastic anemia in vivo and erythroblast destruction in bone marrow cultures. The major determinant for FeLV-C-induced anemia has been mapped to a small region of the surface envelope glycoprotein that is responsible for its receptor binding specificity. Thus, erythroblast destruction may directly or indirectly result from FeLV-C binding to its receptor. To address these issues, we functionally cloned a putative cell surface receptor for FeLV-C (FLVCR) by using a human T-lymphocyte cDNA library in a retroviral vector. Expression of the 2.0-kbp FLVCR cDNA in naturally resistant Swiss mouse fibroblasts and Chinese hamster ovary cells caused substantial susceptibility to FeLV-C but no change in susceptibilities to FeLV-B and other retroviruses. The predicted FLVCR protein contains 555 amino acids and 12 hydrophobic potential membrane-spanning sequences. Database searches indicated that FLVCR is a member of the major-facilitator superfamily of transporters and implied that it may transport an organic anion. RNA blot analyses showed that FLVCR mRNA is expressed in multiple hematopoietic lineages rather than specifically in erythroblasts. These results suggest that the targeted destruction of erythroblasts by FeLV-C may derive from their greater sensitivity to this virus rather than from a preferential susceptibility to infection.     

Prevention of Contamination by Xenotropic Murine Leukemia Virus-Related Virus: Susceptibility to Alcohol-Based Disinfectants and Environmental Stability

Xenotropic murine leukemia virus-related virus (XMRV) represents a novel γ-retrovirus that is capable of infecting human cells and has been classified as a biosafety level 2 (BSL-2) organism. Hence, XMRV represents a potential risk for personnel in laboratories worldwide. Here, we measured the stability of XMRV and its susceptibility to alcohol-based disinfectants. To this end, we exposed an infectious XMRV reporter virus encoding a secretable luciferase to different temperatures, pH values, and disinfectants and infected XMRV-permissive Raji B cells to measure residual viral infectivity. We found that 1 min treatment of XMRV particles at 60°C is sufficient to reduce infectivity by 99.9%. XMRV infectivity was maximal at a neutral pH but was reduced by 86% at pH 4 and 99.9% at pH 10. The common hand and surface disinfectants ethanol and isopropanol as well as the cell fixation reagent paraformaldehyde abrogated XMRV infectivity entirely, as indicated by a reduction of infectivity exceeding 99.99%. Our findings provide evidence of specific means to inactivate XMRV. Their application will help to prevent unintended XMRV contamination of cell cultures in laboratories and minimize the risk for laboratory personnel and health care workers to become infected with this biosafety level 2 organism.