The primary neutralization epitope of porcine respiratory and reproductive syndrome virus strain VR-2332 is located in the middle of the GP5 ectodomain.

Pigs infected with porcine respiratory and reproductive syndrome virus (PRRSV) strain VR-2332 were found to generate high levels of antibodies (Abs) that bound in an indirect ELISA to synthetic peptides representing segments of the primary envelope glycoprotein (GP5) ectodomain of this virus. Use of overlapping GP5 ectodomain peptides of various length indicated that the epitope recognized by the Abs was located in the middle of the ectodomain (amino acids 36-52), in the same relative segment that contains the single linear neutralization epitope of the closely related mouse arterivirus, lactate dehydrogenase-elevating virus (LDV). The VR-2332 GP5 segment exhibits 77% amino acid homology with the corresponding GP5 ectodomain segments of both the European PRRSV strain Lelystad virus (LV) and LDV. This explains some observed crossreaction between the pig Abs and neutralizing anti-LDV monoclonal Abs with peptides representing the GP5 ectodomains of VR-2332, LV and LDV. The GP5 binding Abs of pigs seem to be the primary PRRSV neutralizing Abs, since the well timed appearance in sera of all VR-2332 infected pigs of GP5 peptide binding Abs correlated 100% with the appearance of neutralizing Abs and earlier studies indicated that GP5 of PRRSV, like that of other arteriviruses, contains the main neutralization epitope of PRRSV. In addition, one neutralizing anti-LDV monoclonal Ab that is specific for the GP5 ectodomain epitope of LDV also strongly neutralized both PRRSV strains, VR-2332 and LV. The PRRSV GP5 epitope is associated with an N-glycan that is conserved in both PRRSV genotypes and all LDV isolates. This N-glycan may impede the humoral immune control of PRRSV in infected pigs and might be responsible for the low immunogenicity of PRRSV when injected into mice.

Replication competition between lactate dehydrogenase-elevating virus quasispecies in mice. Implications for quasispecies selection and evolution.

The common quasispecies of lactate dehydrogenase-elevating virus (LDV), LDV-P and LDV-vx, are highly resistant to the humoral host immune response because the single neutralization epitope on the ectodomain of the primary envelope glycoprotein, VP-3P, carries three large N-glycans. Two laboratory mutants, LDV-C and LDV-v, have lost two of the N-glycans on the VP-3P ectodomain, thereby gaining neuropathogenicity for AKR/C58 mice but at the same time, becoming susceptible to the humoral immune response of the host. In attempts to further assess the origins and evolution of these LDVs we have determined their competitiveness by monitoring their fate in mixed infections of wild type, SCID, nude, and cyclophosphamide-treated mice by reverse transcription/polymerase chain reaction assays that distinguish between them. In mixed infections with LDV-P and LDV-vx, LDV-C and LDV-v became rapidly lost even when present initially in large excess over the former. In mixed infections of mice unable to generate neutralizing antibodies, LDV-C and LDV-v also became replaced by LDV-P and LDV-vx as predominant quasispecies but more slowly than in immunocompetent mice. The results indicate that the humoral immune response plays an important role in the displacement of LDV-C and LDV-v by LDV-P and LDV-vx but that in addition, LDV-C and LDV-v possess an impaired ability to compete with LDV-P and LDV-vx in the productive infection of the subpopulation of macrophages that represents the host for all these LDVs. In addition, LDV-v outcompeted LDV-C in mixed infections and the same was the case for neutralization escape mutants of LDV-v and LDV-C which had regained all three N-glycosylation sites on the VP-3P ectodomain. Thus a hierarchy exists in replication fitness: LDV-P/LDV-vx>LDV-v>LDV-C, which is unrelated to the number of N-glycans on the VP-3P ectodomain. The implications of the results in relation to the evolution and selection of the LDV-quasispecies is discussed. LDV-P and LDV-vx are genetically highly stable and thus seem to have achieved evolutionary stasis with optimum ability to establish viremic persistent infections of mice that are unimpeded by the host immune responses.

Complexity of the single linear neutralization epitope of the mouse arterivirus lactate dehydrogenase-elevating virus.

Results from indirect ELISAs using synthetic peptides of various length that represent segments of the ectodomain of the envelope glycoprotein, VP-3P, of lactate dehydrogenase-elevating virus (LDV) showed that the primary neutralization epitope of LDV is located in a short linear hydrophilic segment in the center of the ectodomain. The epitope becomes slightly altered by amino acid substitutions in the ectodomain and inactivation of virions by various treatments. Neutralizing anti-VP-3P antibodies (Abs) to the epitope interact with the synthetic peptides only if they possess a certain conformation. When the peptides were immobilized on ELISA plates, neutralizing mAbs elicited to inactivated LDV and neutralizing Abs from infected mice bound best to the peptides that consisted of the full-length, 30-amino-acid-long ectodomain. The Abs bound poorly, if at all, to most of the shorter peptides when immobilized, whether truncated at the N- or C-end, but when in solution the same peptides strongly inhibited the binding of the Abs to immobilized full-length peptides. Thus, a conformation of the epitope required for Ab binding and (or) its steric accessibility were lost upon immobilization of the shorter peptides on ELISA plates. Abs raised in mice to peptide-bovine serum albumin conjugates reacted only with immobilized peptides in the indirect ELISA and failed to neutralize LDV. The neutralization epitope of the common LDV quasispecies, LDV-P and LDV-vx, is flanked by N-glycans that block the immunogenicity of the epitope and the neutralization of these LDVs. Abs to a second weakly immunogenic and probably discontinuous epitope appear in LDV infected mice about 1 month postinfection.

Isolation of lactate dehydrogenase-elevating viruses from wild house mice and their biological and molecular characterization.

Lactate dehydrogenase-elevating virus (LDV) was first identified as a contaminant of transplantable mouse tumors that were passaged in laboratory mice. It has been assumed that these LDVs originated from LDVs endemic in wild house mouse populations. In order to test this hypothesis and to explore the relationships between LDVs from wild house mice among each other and to those isolated from laboratory mice, we have isolated LDVs from wild house mice and determined their biological and molecular properties. We have screened for LDV tissues of 243 wild house mice that had been caught in various regions of North, Central and South America between 1985 and 1994. We were able to isolate LDVs from the tissues of four mice, three had been caught in Baltimore, MD and one in Montana. We demonstrate that the phenotypic properties (ability to establish a long-term viremic infection, low immunogenicity of the neutralization epitope, high resistance to antibody neutralization and lack of neuropathogenicity) of the four wild house mouse LDVs are identical to those of the primary LDVs isolated from transplantable tumors (LDV-P and LDV-vx), which are distinct from those of the neuropathogenic LDV-C. Furthermore, ORF 5 and ORF 2 and their protein products (the primary envelope glycoprotein VP-3P, and the minor envelope glycoprotein, respectively) of the wild house mouse LDVs were found to be closely related to those of LDV-P and LDV-vx. The LDVs caught in Baltimore, MD were especially closely related to each other, whereas the LDV isolated in Montana was more distantly related, indicating that it had evolved independently. The ectodomain of VP-3P of all four wild house mouse LDVs, like those of LDV-P and LDV-vx, possess the same three polylactosaminoglycan chains, two of which are lacking in the VP-3P ectodomain of LDV-C. These results further strengthen the conclusion that the three polylactosaminoglycan chains are the primary determinants of the phenotypic properties of LDV-P/vx.

Neuropathogenicity and sensitivity to antibody neutralization of lactate dehydrogenase-elevating virus are determined by polylactosaminoglycan chains on the primary envelope glycoprotein.

Common strains of lactate dehydrogenase-elevating virus (LDV, an arterivirus), such as LDV-P and LDV-vx, are highly resistant to antibody neutralization and invariably establish a viremic, persistent, yet asymptomatic, infection in mice. Other LDV strains, LDV-C and LDV-v, have been identified that, in contrast, are highly susceptible to antibody neutralization and are incapable of a high viremic persistent infection, but at the same time have gained the ability to cause paralytic disease in immunosuppressed C58 and AKR mice. Our present results further indicate that these phenotypic differences represent linked properties that correlate with the number of N-glycosylation sites associated with the single neutralization epitope on the short ectodomain of the primary envelope glycoprotein, VP-3P. The VP-3P ectodomains of LDV-P/vx possess three N-glycosylation sites, whereas those of LDV-C/v lack the two N-terminal sites. We have now isolated four independent neutralization escape variants of neuropathogenic LDV-C and LDV-v on the basis of their ability to establish a high viremic persistent infection in mice. The VP-3P ectodomains of all four variants had specifically regained two N-glycosylation sites concomitant with decreased immunogenicity of the neutralization eptitope and decreased sensitivity to antibody neutralization as well as loss of neuropathogenicity.

Lactate dehydrogenase-elevating virus variants: cosegregation of neuropathogenicity and impaired capability for high viremic persistent infection.

Neuropathogenic isolates of lactate dehydrogenase virus (LDV) differ from non-neuropathogenic isolates in their unique ability to cause a paralytic disease (age-dependent poliomyelitis, ADPM) in immunosuppressed C58 and AKR mice by cytocidally infecting their anterior horn neurons. We have recently reported that an original neuropathogenic LDV isolate, LDV-C-BR, contained a low level of a coexisting non-neuropathogenic LDV which, in a mixed infection of mice, rapidly outcompeted the former resulting in apparent loss of neuropathogenicity of the reisolated LDV. This correlated with an impaired ability of the neuropathogenic LDV to establish a viremic persistent infection. In the present study we identified the presence of three different quasispecies in another original neuropathogenic LDV by sequence analysis of cDNA clones of ORF 5 (encoding the primary envelope glycoprotein VP-3P) obtained from the isolate. Successful development of differential reverse transcription-polymerase chain reaction assays allowed us to biologically clone all three quasispecies through repeated end point dilutions. Only one of the quasispecies (LDV-v) was neuropathogenic. The other two, LDV-vP (probably the same as LDV-P) and LDV-vx (a novel LDV quasispecies that had not been previously identified), were non-neuropathogenic and found to be the common LDV quasispecies associated with almost all LDVs originally isolated from mice carrying various other transplantable tumors. The neuropathogenic LDV-v became selectively amplified in the spinal cords of paralyzed mice, but possessed an impaired ability to establish a persistent viremic infection and was rapidly out-competed by LDV-vP and LDV-vx in mixed infections, just as reported previously for LDV-C-BR. The results further support our hypothesis that neuropathogenicity and impaired capability for viremic persistence of LDV are determined by the same molecular feature. The only consistent and biologically relevant molecular difference we have observed between neuropathogenic and non-neuropathogenic LDVs is the number of polylactosaminoglycan chains associated with the ectodomain of VP-3P.

Neuropathogenicity and susceptibility to immune response are interdependent properties of lactate dehydrogenase-elevating virus (LDV) and correlate with the number of N-linked polylactosaminoglycan chains on the ectodomain of the primary envelope glycoprotein.

We have developed differential RT-PCR methods to distinguish different isolates of LDV and have purified several quasispecies by repeated end point dilution in mice. They fall into two groups, each possessing two or more members. Group A viruses are non-neuropathogenic, highly resistant to in vitro neutralization by antibodies and efficient in establishment of a life-long, persistently viremic infection in mice despite a detectable immune response. Group B viruses, on the other hand, are neuropathogenic, much more sensitive to antibody neutralization and have an impaired ability to establish a high viremia persistent infection in immune competent mice. These properties seem to be interdependent and correlate with the number of N-glycosylation sites on the short (about 30 amino acid long) ectodomain of the primary envelope glycoprotein, VP-3P, which probably is part of the attachment site for the LDV receptor on permissive cells and harbors an epitope(s) reacting with neutralizing antibodies. Group A viruses possess three closely spaced N-linked polylactosaminoglycan chains, whereas group B viruses lack the two N-terminal ones. We postulate that lack of these polylactosaminoglycan chains endows group B viruses with the ability to interact with a receptor on anterior horn neurons resulting in neuropathogenesis. At the same time, it increases an interaction with neutralizing antibodies thus impeding the infection of macrophages newly generated during the persistent phase of infection which is essential for the continued rounds of replication of the virus.

Detection of lactate dehydrogenase-elevating virus in transplantable mouse tumors by biological assay and RT-PCR assays and its removal from the tumor cell.

It is known that lactate dehydrogenase-elevating virus (LDV) of mice is a common contaminant of transplantable tumors of both murine and human origin. It is imperative that tumors that are maintained by transplantation in mice are examined for LDV and freed of the virus, when present, before use in experimental studies, because an LDV infection of mice exerts considerable effects on lymphoid cell populations and cytokine production and other effects. Methods for LDV detection are described using a biological assay and reverse transcription (RT)-polymerase chain reaction (PCR) technology and their application is illustrated. A differential RT-PCR method that distinguishes between three quasispecies of LDV is also described and applied to an examination of LDVs isolated from a number of different tumors. Each of the LDV isolates was found to contain at least two different quasispecies, generally in different concentrations.

ORF 3 of lactate dehydrogenase-elevating virus encodes a soluble, nonstructural, highly glycosylated, and antigenic protein.

Open reading frame (ORF) 3 of the genome of lactate dehydrogenase-elevating virus (LDV), strain P, was cloned into the plasmid pcDNAI/Amp and in vitro transcribed and translated. Translation of ORF 3 yielded a soluble protein of the expected size (about 21 kDa). When synthesized in the presence of endoplasmic reticulum (ER) membranes the resulting glycoprotein of about 36 kDa became associated with the membranes. However, disruption of the ER vesicles by incubation in carbonate buffer, pH 11.5, resulted in the release of the protein from the membranes. Hydrophobic moment analysis of the ORF 3 protein indicated the absence of any potential transmembrane segments, except for a N-terminal signal peptide, but no cleavage of the signal peptide was observed during membrane-associated in vitro synthesis. The ORF 3 protein elicited a strong antibody response in infected mice. The antibodies from infected mice as well as a monoclonal antibody specifically precipitated the in vitro-synthesized ORF 3 protein, but no protein from LDV virions. The overall results suggest that the ORF 3 protein is a nonstructural, highly glycosylated, and antigenic glycoprotein that is probably soluble and secreted or at most only weakly associated with membranes via the signal peptide.

Differential glycosylation of the ectodomain of the primary envelope glycoprotein of two strains of lactate dehydrogenase-elevating virus that differ in neuropathogenicity.

ORF 5 encoding the primary envelope glycoprotein, VP-3P, of a highly neuropathogenic isolate of lactate dehydrogenase-elevating virus (LDV-v) has been sequenced. It exhibits 92% nucleotide identity with the ORF 5 of an LDV isolate that lacks neuropathogenicity, LDV-P, and the amino acid identities of the predicted VP-3Ps of the two strains is 90%. Most striking, however, is the absence in the ectodomain of LDV-v VP-3P of two out of three potential N-glycosylation sites present in the ectodomain of VP-3P of LDV-P. The ectodomain of VP-3P has been implicated to play an important role in host receptor interaction. VP-3P of another neuropathogenic LDV strain, LDV-C, lacks the same two N-glycosylation sites (Godeny et al., 1993). In vitro transcription/translation of the ORFs 5 of LDV-P and LDV-v indicated that all three N-glycosylation sites in the ectodomain of LDV-P VP-3P became glycosylated when synthesized in the presence of microsomal membranes, whereas the glycosylation of the ORF 5 proteins of LDV-v and LDV-C was consistent with glycosylation at a single site. No other biological differences between the neuropathogenic and non-neuropathogenic strains have been detected. They replicate with equal efficiency in mice and in primary macrophage cultures.

Expression of ecotropic murine leukemia virus in the brains of C58/M, DBA2/J, and in utero-infected CE/J mice.

In C58 and AKR mice, endogenous N-tropic, ecotropic murine leukemia virus (MuLV) proviruses become activated in rare cells during embryogenesis. Resultant replication-competent progeny viruses then actively infect a large number of cells throughout the fetus, including cells in the developing central nervous system. By in situ hybridization analyses, we have assessed the presence of ecotropic MuLV RNA in the brains of C58 mice as a function of age. Only a few ecotropic MuLV-positive cells were observed in weanling mice, but the number of positive cells in the brain increased progressively with increasing age of the mice. Throughout the lives of the mice, the ecotropic MuLV RNA-positive cells were primarily located in well-defined white-matter tracts of the brain (commissura anterior, corpus callosum, fimbria hippocampi, optical tract, and striatum) and of the spinal cord. Cells of the subventricular zone also expressed ecotropic MuLV RNA, and in older mice a small number of positive cells were present in the grey matter. Infection of endogenous ecotropic MuLV provirus-less CE/J mice in utero with ecotropic MuLV clone AKR-623 resulted in the extensive infection of brain cells. The regional distribution of ecotropic MuLV RNA-containing cells was the same as observed in the brains of C58 mice, in which cells became infected by endogenously activated virus, but the number of positive cells was higher.

The envelope proteins of lactate dehydrogenase-elevating virus and their membrane topography.

We have studied the membrane topography and N-glycosylation of the envelope proteins of lactate dehydrogenase-elevating virus (LDV, strain P). Transcripts of open reading frames (ORFs) 2, 5, and 6 were in vitro translated in the absence and presence of microsomal membranes, and the products analyzed for molecular weight, sensitivity to endoglycosidase F/N-glycosidase F and proteinases, and reaction with anti-LDV antibodies. The ORF 6 mRNA translation was enhanced in the presence of microsomal membranes. ORF 6 encodes a polytopic class III membrane protein identified as the nonglycosylated virion envelope protein (M/VP-2; approximately 18 kDa). The protein has a very short (about 11 amino acids) ectodomain, a longer (about 79 amino acids) C-terminal endodomain, and crosses the membrane three times between these domains. ORF 5 encodes the primary virion envelope glycoprotein (VP-3P) (25-42 kDa). Our results suggest that it is a polytopic class I glycoprotein. After removal of a signal peptide, the processed protein of about 171 amino acids consists of a short (approximately 30 amino acids) N-terminal ectodomain with three asparagine residues that appear to be N-glycosylated, a segment that crosses the membrane three times, and an about 74 amino acid long C-terminal endodomain. Neutralizing anti-LDV antibodies are probably directed to an epitope(s) in the N-terminal ectodomain. The ORF 2 protein is a standard class I glycoprotein with a single C-terminal membrane anchor segment and its signal peptide is removed during membrane-associated synthesis. The remaining ectodomain (about 165 amino acids) contains three asparagine residues which appear to be N-glycosylated. Our results suggest that the ORF 2 protein may be present in a low concentration in LDV virions (VP-3M).

Cytotoxic T cells are elicited during acute infection of mice with lactate dehydrogenase-elevating virus but disappear during the chronic phase of infection.

Lactate dehydrogenase-elevating virus (LDV) invariably establishes a life-long viremic infection in mice, which is maintained by replication of LDV in a renewable subpopulation of macrophages and escape from all host immune responses. We now demonstrate that cytotoxic T lymphocytes (CTLs) that specifically lyse LDV-infected macrophages and 3T3 cells producing the nucleocapsid protein of LDV were elicited in Swiss, B10.A, and (Swiss x B10.A)F1 mice. To detect target cell lysis, splenocytes needed to be expanded by a 5-day in vitro culture in the presence of recombinant interleukin 2 and syngeneic LDV protein-expressing cells. In vitro culture resulted in the specific expansion of CD8+ cells which mediated the lysis of target cells in a major histocompatibility complex class I-restricted manner. When CTLs were added to macrophage cultures at 1 h after infection with LDV, the lysis of the infected macrophages by the CTLs started about 5 h postinfection (p.i.) and, at an effector cell/target cell ratio of 25:1, resulted in the lysis of all LDV-infected macrophages in a culture by about 7 h p.i. However, lysis of the LDV replication in a culture was not rapid enough to significantly suppress the LDV yield in the culture. LDV replication in mice was also little affected by the presence of CTLs which were induced by immunization with 3T3 cells expressing the LDV nucleocapsid protein. Furthermore, all CTL precursor cells in infected mice had disappeared by 30 days p.i. Loss of CTL precursor cells in infected mice probably reflected high-dose clonal exhaustion, since LDV infection of a mouse results in massive production of LDV in all tissues of the mouse, but especially in lymphoidal tissues, and accumulation of LDV in newly formed germinal centers. Furthermore, slow LDV replication continues in the thymus and other lymphoidal organs.

C58 and AKR mice of all ages develop motor neuron disease after lactate dehydrogenase-elevating virus infection but only if antiviral immune responses are blocked by chemical or genetic means or as a result of old age.

Age-dependent poliomyelitis is a paralytic disease of C58 and AKR mice caused by cytocidal infection of anterior horn neurons with neuropathogenic strains of lactate dehydrogenase-elevating virus (LDV). The motor neurons are rendered LDV-permissive via an unknown mechanism through the expression of ecotropic murine leukemia virus (MuLV) in central nervous system (CNS) glial cells. Only old mice develop paralytic disease after LDV infection, but mice 5-6 months old or older can be rendered susceptible by suppression of anti-LDV immune responses by a single treatment with cyclophosphamide or X-irradiation before LDV infection. Younger mice appeared to be resistant in spite of this immunosuppresive treatment. The present results confirm that mice as young as 1 month of age possess CNS cells expressing ecotropic MuLV and show that these mice are susceptible to paralytic LDV infection provided their anti-LDV immune responses are blocked for an extended period of time by repeated cyclophosphamide treatments or by a genetic defect. Furthermore, old mice become naturally susceptible to paralytic LDV infection because of an impaired ability to mount a motor neuron protective anti-LDV immune response.

Pseudotype virions formed between mouse hepatitis virus and lactate dehydrogenase-elevating virus (LDV) mediate LDV replication in cells resistant to infection by LDV virions.

Infection of cultures of peritoneal macrophages with both lactate dehydrogenase-elevating virus (LDV) and mouse hepatitis virus (MHV) resulted in the formation of pseudotype virions containing LDV RNA which productively infected cells that are resistant to infection by intact LDV virions but not to infection by MHV. These cells were mouse L-2 and 3T3-17Cl-1 cells as well as residual peritoneal macrophages from persistently LDV-infected mice. Productive LDV infection of these cells via pseudotype virions was inhibited by antibodies to the MHV spike protein or to the MHV receptor, indicating that LDV RNA entered the cells via particles containing the MHV envelope. Simultaneous exposure of L-2 cells to both LDV and MHV resulted in infection by MHV but not by LDV. The results indicate that an internal block to LDV replication is not the cause of the LDV nonpermissiveness of many cell types, including the majority of the macrophages in an adult mouse. Instead, LDV permissiveness is restricted to a subpopulation of mouse macrophages because only these cells possess a surface component that acts as an LDV receptor.

Processing and evolution of the N-terminal region of the arterivirus replicase ORF1a protein: identification of two papainlike cysteine proteases.

Two adjacent papainlike cysteine protease (PCP) domains, PCP alpha and PCP beta, were identified in the N-terminal region of the open reading frame 1a replicase proteins of the arteriviruses porcine reproductive and respiratory syndrome virus and lactate dehydrogenase-elevating virus. The replicase of the related virus equine arteritis virus contains only one active PCP in the corresponding region. Sequence comparison revealed that the equine arteritis virus PCP alpha counterpart probably was inactivated by loss of its catalytic Cys residue. For both porcine reproductive and respiratory syndrome virus and lactate dehydrogenase-elevating virus, the generation of two processing products, nsp1 alpha and nsp1 beta, was demonstrated by in vitro translation. Site-directed mutagenesis and sequence comparison were used to identify the putative active-site residues of the PCP alpha and PCP beta protease domains and to show that they mediate the nsp1 alpha/1 beta and nsp1 beta/2 cleavages, respectively.

Lactate dehydrogenase-elevating virus entry into the central nervous system and replication in anterior horn neurons.

The initial replication of lactate dehydrogenase-elevating virus (LDV) in mice, its invasion of the central nervous system (CNS) and infection of anterior horn neurons in C58 and AKXD-16 mice were investigated by Northern and in situ hybridization analyses. Upon intraperitoneal injection, LDV replication in cells in the peritoneum was maximal at 8 h post-infection (p.i.). Next, LDV infection was detected in bone marrow cells and then in macrophage-rich regions of all tissues investigated (12 to 24 h p.i.). By 2 to 3 days p.i., LDV RNA-containing cells had largely disappeared from all non-neuronal tissues due to the cytocidal nature of the LDV infection of macrophages. In the CNS at 24 h p.i. LDV replication was very limited and confined to cells in the leptomeninges. LDV replication in the cells of the leptomeninges should result in the release of progeny LDV into the cerebrospinal fluid and thus its dissemination throughout the CNS. However, in C58 and AKXD-16 mice, which are susceptible to paralytic LDV infection, only little LDV RNA and few LDV-infected cells were detectable in the spinal cord until at least 10 days p.i. Extensive cytocidal infection of anterior horn neurons occurred only shortly before the development of paralytic symptoms between 2 and 3 weeks p.i. The reason for the relatively long delay in LDV infection of anterior horn neurons is not known. No LDV RNA or LDV RNA-containing cells were detected in the brain, except in the leptomeninges at early times after infection.

Infection of central nervous system cells by ecotropic murine leukemia virus in C58 and AKR mice and in in utero-infected CE/J mice predisposes mice to paralytic infection by lactate dehydrogenase-elevating virus.

Certain mouse strains, such as AKR and C58, which possess N-tropic, ecotropic murine leukemia virus (MuLV) proviruses and are homozygous at the Fv-1n locus are specifically susceptible to paralytic infection (age-dependent poliomyelitis [ADPM]) by lactate dehydrogenase-elevating virus (LDV). Our results provide an explanation for this genetic linkage and directly prove that ecotropic MuLV infection of spinal cord cells is responsible for rendering anterior horn neurons susceptible to cytocidal LDV infection, which is the cause of the paralytic disease. Northern (RNA) blot hybridization of total tissue RNA and in situ hybridization of tissue sections demonstrated that only mice harboring central nervous system (CNS) cells that expressed ecotropic MuLV were susceptible to ADPM. Our evidence indicates that the ecotropic MuLV RNA is transcribed in CNS cells from ecotropic MuLV proviruses that have been acquired by infection with exogenous ecotropic MuLV, probably during embryogenesis, the time when germ line proviruses in AKR and C58 mice first become activated. In young mice, MuLV RNA-containing cells were found exclusively in white-matter tracts and therefore were glial cells. An increase in the ADPM susceptibility of the mice with advancing age correlated with the presence of an increased number of ecotropic MuLV RNA-containing cells in the spinal cords which, in turn, correlated with an increase in the number of unmethylated proviruses in the DNA extracted from spinal cords. Studies with AKXD recombinant inbred strains showed that possession of a single replication-competent ecotropic MuLV provirus (emv-11) by Fv-1n/n mice was sufficient to result in ecotropic MuLV infection of CNS cells and ADPM susceptibility. In contrast, no ecotropic MuLV RNA-positive cells were present in the CNSs of mice carrying defective ecotropic MuLV proviruses (emv-3 or emv-13) or in which ecotropic MuLV replication was blocked by the Fv-1n/b or Fv-1b/b phenotype. Such mice were resistant to paralytic LDV infection. In utero infection of CE/J mice, which are devoid of any endogenous ecotropic MuLVs, with the infectious clone of emv-11 (AKR-623) resulted in the infection of CNS cells, and the mice became ADPM susceptible, whereas littermates that had not become infected with ecotropic MuLV remained ADPM resistant.

Disulfide bonds between two envelope proteins of lactate dehydrogenase-elevating virus are essential for viral infectivity.

Disulfide bonds were found to link the nonglycosylated envelope protein VP-2/M (19 kDa), encoded by open reading frame 6, and the major envelope glycoprotein VP-3 (25 to 42 kDa), encoded by open reading frame 5, of lactate dehydrogenase-elevating virus (LDV). The two proteins comigrated in a complex of 45 to 55 kDa when the virion proteins were electrophoresed under nonreducing conditions but dissociated under reducing conditions. Furthermore, VP-2/M was quantitatively precipitated along with VP-3 in this complex by three neutralizing monoclonal antibodies to VP-3. The infectivity of LDV was rapidly and irreversibly lost during incubation with 5 to 10 mM dithiothreitol (> 99% in 6 h at room temperature), which is known to reduce disulfide bonds. LDV inactivation correlated with dissociation of VP-2/M and VP-3. The results suggest that disulfide bonds between VP-2/M and VP-3 are important for LDV infectivity. Hydrophobic moment analyses of the predicted proteins suggest that VP-2/M and VP-3 both possess three adjacent transmembrane segments and only very short ectodomains (10 and 32 amino acids, respectively) with one and two cysteines, respectively. Inactivation of LDV by dithiothreitol and dissociation of the two envelope proteins were not associated with alterations in LDV's density or sedimentation coefficient.