Ectopic expression of murine CD163 enables cell-culture isolation of lactate dehydrogenase-elevating virus 63 years after its discovery.

IMPORTANCE: Mouse models of viral infection play an especially large role in virology. In 1960, a mouse virus, lactate dehydrogenase-elevating virus (LDV), was discovered and found to have the peculiar ability to evade clearance by the immune system, enabling it to persistently infect an individual mouse for its entire lifespan without causing overt disease. However, researchers were unable to grow LDV in culture, ultimately resulting in the demise of this system as a model of failed immunity. We solve this problem by identifying the cell-surface molecule CD163 as the critical missing component in cell-culture systems, enabling the growth of LDV in immortalized cell lines for the first time. This advance creates abundant opportunities for further characterizing LDV in order to study both failed immunity and the family of viruses to which LDV belongs, Arteriviridae (aka, arteriviruses).

The lactate dehydrogenase-elevating virus capsid protein is a nuclear-cytoplasmic protein.

Arteriviruses replicate in the cytoplasm and do not require the nucleus function for virus multiplication in vitro. However, nucleocapsid (N) protein of two arteriviruses, porcine reproductive respiratory syndrome virus and equine arteritis virus, has been observed to localize in the nucleus and nucleolus of virus-infected and N-gene-transfected cells in addition to their normal cytoplasmic distribution. In the present study, the N protein of lactate dehydrogenase-elevating virus (LDV) of mice was examined for nuclear localization. The subcellular localization of LDV-N was determined by tagging N with enhanced green fluorescence protein (EGFP) at the N- and C-terminus. Both N-EGFP and EGFP-N fusion proteins localized to the nucleus and nucleolus of gene-transfected cells. Labeled N also accumulated in the perinuclear region, the site of virus replication. The LDV-N sequence contains a putative 'pat4'-type nuclear localization signal (NLS) consisting of 38-KKKK. To determine its functional significance, a series of deletion constructs of N were generated and individually expressed in cells. The results showed that the 'pat4' NLS was essential for nuclear translocation. In addition, the LDV-N interacted with the importin-alpha and -beta proteins, suggesting that the LDV-N nuclear localization may occur via the importin-mediated nuclear transport pathway. These results provide further evidence for the nuclear localization of N as a common feature within the arteriviruses.

Detection of negative-stranded subgenomic RNAs but not of free leader in LDV-infected macrophages.

The mechanism of synthesis of the seven subgenomic mRNAs of lactate dehydrogenase-elevating virus (LDV) was explored. One proposed mechanism, leader-primed transcription, predicts the formation of free 5'-leader in infected cells which then primes reinitiation of transcription at specific complementary sites on the antigenomic template. No free LDV 5'-leader of 156 nucleotides was detected in LDV-infected macrophages. Another mechanism, independent replication of the subgenomic mRNAs, predicts the presence of negative complements to all subgenomic mRNAs in infected cells which might be generated from subgenomic mRNAs in virions. Full-length antigenomic RNA was detected in LDV-infected macrophages by Northern hybridization at a level of < 1% of that of genomic RNA, but no negative polarity subgenomic RNAs. Negative complements to all subgenomic mRNAs, however, were detected by reverse transcription of total RNA from infected macrophages using as primer an oligonucleotide complementary to the antileader followed by polymerase chain reaction amplification using this sense primer in combination with various oligonucleotide primers complementary to a segment downstream of the junction between the 5' leader and the body of each subgenomic RNA. It is unclear whether these minute amounts of negative subgenomic RNAs function in the replication of the subgenomic mRNAs. They could also be by-products of the RNA replication process. Finally, no subgenomic mRNAs were detected in LDV virions.

Correlation between presence of lactate dehydrogenase-elevating virus RNA and antigens in motor neurons and paralysis in infected C58 mice.

Lactate dehydrogenase-elevating virus (LDV) induces poliomyelitis in immunosuppressed C58 mice resulting in fatal paralysis. We have synthesized and cloned cDNA complementary to the LDV genome, and used the cDNA clones as in situ hybridization probes for the detection of LDV RNA in tissue sections. Direct fluorescent antibody staining using IgG from chronically infected mice was used for the detection of LDV antigens. Using these methods, we have detected LDV RNA and antigens in anterior horn neurons of paralyzed mice. The appearance of LDV RNA and antigen positive motor neurons and their location in the spinal cord correlated with the development of paralytic symptoms. No positive neurons were detected in LDV-infected, susceptible mice without signs of paralysis, but some glial cells of the white and gray matter in the spinal cords of these mice were found to contain LDV RNA. These analyses broaden the host cell range of LDV to include neuronal and other cells in the CNS and support the hypothesis of LDV replication in neurons as the cause of poliomyelitis and paralysis.

Detection of related positive-strand RNA virus genomes by reverse transcription/polymerase chain reaction using degenerate primers for common replicase sequences.

A set of degenerate sense and antisense primers were designed on the basis of short segments with identical amino acids in the predicted ORF 1b replicase proteins of lactate dehydrogenase-elevating virus (LDV), equine arteritis virus (EAV) and porcine reproductive and respiratory syndrome virus, strain Lelystad virus (PRRSV-LV), which are members of a new group of positive-strand RNA viruses. Reverse transcription/polymerase chain reaction amplification using this set of degenerate primers yielded products of the expected size from the genomes of all three viruses. It also yielded a product of appropriate size from the genome of another strain of PRRSV (VR2332), the ORF 1b sequence of which is unknown, but the 3' end of the genome of which differs from that of the PRRSV-LV genome by about 50%. No products were generated from the genome of simian hemorrhagic fever virus (SHFV), another member of this virus group. However, an appropriate product was generated with a second set of degenerate primers which was designed from the same ORF 1b segments of LDV, EAV and PRRSV-LV as the first set but on the basis of human codon preferences. Sequence analysis showed that the amplified SHFV ORF 1b segment exhibited about 50% nucleotide identity with the corresponding segments of ORF 1b of LDV, EAV and PRRSV. The results show that these and other degenerate primer sets might be useful for the search of related viruses in other mammalian species.

Lactate dehydrogenase-elevating virus (LDV): subgenomic mRNAs, mRNA leader and comparison of 3'-terminal sequences of two LDV isolates.

The 3'-terminal 1314 nucleotides of the genome of one isolate of lactate dehydrogenase-elevating virus, LDV-P, has been derived by sequence analyses of cDNAs from several genomic libraries and compared to that of another LDV isolate, LDV-C (Godeny et al. (1990) Virol. 177, 768-771). The 3'-non-coding segment of 80 nucleotides of the two LDV genomes is identical, whereas marked, but varying nucleotide and amino acid divergence is apparent in the three upstream overlapping open reading frames (ORF). The third ORF from the 3'-end exhibits only 82% nucleotide and 90% amino acid identity, whereas the 3'-terminal ORF, which encodes the nucleocapsid protein, exhibits approximately 99% amino acid identity. The second 3'-terminal ORF encodes an 18.8 kDa protein which lacks N-glycosylation sites but possesses 2 or 3 potential transmembrane helices in the N-terminal half of the molecule. A similar membrane organization is observed for the corresponding protein of equine arteritis virus and the M protein of mouse hepatitis virus. The sequence analyses combined with Northern hybridization analyses of RNA from LDV-infected macrophages and spleens of LDV-infected mice indicate that the three ORFs encoded by the 3'-terminal end of the LDV genome are expressed via the three smallest mRNAs (mRNAs 6-8) of the seven subgenomic mRNAs of LDV (mRNAs 2-8), which range in size from about 0.8 to 3.6 kb. All mRNAs have been shown to carry poly(A)-tracts and a common leader sequence. The seven mRNAs were produced in infected macrophage cultures concomitantly with genomic LDV RNA. Maximum LDV RNA synthesis was observed between 6 and 8 h post-infection. The same seven subgenomic mRNAs were detected in macrophages infected with three different isolates of LDV, but different relative amounts of some of the mRNAs were produced. The relative proportions of molecules of mRNAs 1-8 present in 6 h LDV-P-infected macrophages were about 13, 5, 5, 8, 6, 11, 11 and 27% of the total, respectively.

Regulation of transplacental virus infection by developmental and immunological factors: studies with lactate dehydrogenase-elevating virus.

Placental and fetal infections with lactate dehydrogenase-elevating virus (LDV) were determined by virus titration, indirect fluorescence antibody (IFA), and in situ hybridization with cDNA probes. Experiments were designed to determine the effects of gestational age, timing of maternal LDV infection, and immunological (antibody and cytokine) factors on mouse placental and fetal LDV infection. Virus infection of the placenta was detected at high levels (almost all placentas infected) within 24 h post-maternal infection (p.m.i.), whereas fetal LDV infection was detected only at a low level by 24 h p.m.i. The percentage of fetuses becoming LDV infected progressively increased between 24 and 72 h p.m.i. When fetal infection was studied at 72 h p.m.i., earlier gestational ages (9-11 days) were associated with fetal resistance to infection, whereas between 12.5 and 15 days of gestation, virus infection was detected in 50-71% of fetuses. Maternal treatment with interferon-gamma (IFN-gamma) or anti-LDV monoclonal antibodies was associated with reduced rates of fetal, but not placental, LDV infection. These results demonstrate that both developmental and immunological factors are important in the regulation of transplacental LDV infection.

An ORF-2a protein is not present at a significant level in virions of the arterivirus lactate dehydrogenase-elevating virus.

MRNA2 of the arteriviruses lactate dehydrogenase-elevating virus (LDV) and equine arteritis virus (EAV) encodes two proteins that are read in different frames, an about 26 kDa minor envelope glycoprotein and an about 8 kDa protein that lacks N-glycosylation sites and a signal peptide, but possesses a central hydrophobic segment. Recent studies have shown that both proteins of EAV are translated from mRNA 2 in EAV infected BHK cells, that the 8 kDa protein is membrane associated and that small amounts of it are recovered in purified virions (Snijder, E.J., van Tol, H., Pederson, K.W., Raamsman, M.J.B., de Vries, A.A.F., 1999. Identification of a novel structural protein of arteriviruses. J. Virol. 73, 6335-6345). The authors concluded that the 8 kDa protein is another arterivirus envelope protein and designated it E protein. However, we have not detected a significant level of an 8 kDa protein in LDV virions and thus conclude that it is not a structural virion component.

Regulation of immune complexes during infection of mice with lactate dehydrogenase-elevating virus: studies with interferon-gamma gene knockout and tolerant mice.

Mice persistently infected with lactate dehydrogenase-elevating virus (LDV) develop circulating IgG-containing hydrophobic immune complexes, with a molecular mass of 150 to 300 kd, which bind to the surfaces of high-capacity enzyme-linked immunosorbent assay (ELISA) plates. LDV infection also stimulates polyclonal B-cell activation and autoimmunity. For this study, interferon-gamma gene knockout (GKO) mice were utilized to study circulating immune complexes and other parameters of LDV infection. The kinetics of LDV viremia, formation of plasma IgG anti-LDV antibodies, and LDV replication in the spleen and liver were essentially normal in GKO mice. Polyclonal activation of B cells, as reflected by increased total plasma IgG concentration during LDV infection, was found to be intact in GKO mice, although at a lower magnitude than in control mice. The plasma concentration of IgG-containing hydrophobic immune complexes was reduced about 75% in LDV-infected GKO mice relative to normal LDV-infected controls. Allogeneic tissue responses were also found to be reduced in LDV-infected GKO mice relative to those in normal LDV-infected controls. These results dissociate specific anti-LDV immunity from formation of hydrophobic immune complexes, show that the IgG anti-LDV response as well as LDV replication in the spleen and liver are insensitive to physiological levels of interferon (IFN)-gamma, and suggest that IgG-containing immune complexes stimulated by LDV infection are a marker for autoimmunity.

Lelystad virus belongs to a new virus family, comprising lactate dehydrogenase-elevating virus, equine arteritis virus, and simian hemorrhagic fever virus.

Lelystad virus (LV) is an enveloped positive-stranded RNA virus, which causes abortions and respiratory disease in pigs. The complete nucleotide sequence of the genome of LV has been determined. This sequence is 15.1 kb in length and contains a poly(A) tail at the 3' end. Open reading frames that might encode the viral replicases (ORFs 1a and 1b), membrane-associated proteins (ORFs 2 to 6) and the nucleocapsid protein (ORF7) have been identified. Sequence comparisons have indicated that LV is distantly related to the coronaviruses and toroviruses and closely related to lactate dehydrogenase-elevating virus (LDV) and equine arteritis virus (EAV). A 3' nested set of six subgenomic RNAs is produced in LV-infected alveolar lung macrophages. These subgenomic RNAs contain a leader sequence, which is derived from the 5' end of the viral genome. Altogether, these data show that LV is closely related evolutionarily to LDV and EAV, both members of a recently proposed family of positive-stranded RNA viruses, the Arteriviridae.

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.

Production of virus-specific antiserum corresponding to sequences in the lactate dehydrogenase-elevating virus (LDV) ORF6 protein.

The elucidation of the antigenic structure of the envelope proteins of Arteriviridae which includes lactate dehydrogenase-elevating virus (LDV) will provide further understanding of a mechanism of strict host cell specificity. To analyze the linkage between LDV envelope proteins, M/VP-2 and VP-3, which may play an important role in viral infectivity, we generated specific antibody against M/VP-2 that has not been reported in previous studies. A synthetic polypeptide corresponding to the C-terminal region of LDV strain C (LDV-C) ORF6, which encodes M/VP-2, was chemically synthesized and coupled to keyhole limpet hemocyanin (KLH). The peptide was immunogenic in rabbits and induced antibody specific for viral protein. Western blotting and immunofluorescence analysis of virion M/VP-2 in infected macrophages showed that the antibody was able to react specifically with authentic virion protein. The immunoreactive antibody against LDV M/VP-2 described in this study will be useful for further studies of the specific roles of the envelope proteins in arterivirus assembly and infectivity.

Analysis of protein expression by mammalian cell lines stably expressing lactate dehydrogenase-elevating virus ORF 5 and ORF 6 proteins.

Lactate dehydrogenase-elevating virus (LDV) has a strict species-specificity. Because only a subset of mouse primary macrophages have been identified that can support LDV replication in vitro, the precise molecular mechanism of viral entry and replication remains unclear. To analyze the LDV envelope proteins, which probably mediate viral attachment to the host cell, we developed a mammalian system for stable co-expression of LDV open reading frame (ORF) 5- and ORF 6-encoded proteins (ORF 5 and ORF 6 proteins), which correspond to envelope VP-3 and M/VP-2, respectively, and compared these expressed proteins to the native ones. Western blotting analysis combined with N-glycanase digestion revealed that ORF 5 and ORF 6 proteins were similar in size to native VP-3 and M/VP-2, and that ORF 5 protein was N-glycosylated, like the native VP-3. Immunofluorescence microscopy revealed that both ORF 5 and ORF 6 proteins were distributed throughout the cytoplasm and were colocalized in most cells. Moreover, ORF 5 protein was localized both in the perinuclear region and the Golgi complex and transported to the cell surface. This mammalian expression system in which the exogenously expressed proteins closely resemble the native proteins will provide the experimental basis for further studies of the interactions between LDV envelope proteins and host cells.

Characterization of lactate dehydrogenase-elevating virus ORF6 protein expressed by recombinant baculoviruses.

Lactate dehydrogenase-elevating virus (LDV) has a strict species-specificity and can replicate only in a subset of mouse primary macrophages in vitro. Because it is difficult to grow and purify sufficient quantities of LDV virions from the primary macrophages, it has been difficult to further characterize LDV envelope proteins. A few expression systems have been reported for structural analysis of the nonglycosylated envelope protein M/VP-2, however, very few studies of the antigenicity of M/VP-2 have been reported. We cloned and expressed the ORF6 gene, which encodes the M/VP-2, as a fusion protein with a polyhistidine metal-binding tag (6 x His-tag) in Autographa californica nuclear polyhedrosis virus (baculovirus) under the control of the polyhedrin promoter. In Western blotting analysis, the expressed protein was similar in size to the native M/VP-2 plus 6 x His-tag. The usefulness of the baculovirus-expressed LDV ORF6 protein for analysis of the immunogenicity of LDV M/VP-2 was discussed.

Detection of lactate dehydrogenase-elevating virus by use of a fluorogenic nuclease reverse transcriptase-polymerase chain reaction assay.

Lactate dehydrogenase-elevating virus (LDEV) induces persistent infections in laboratory mice, alters in vivo physiology, and is a common contaminant of biological materials such as transplantable tumor cell lines. The fluorogenic nuclease reverse transcriptase polymerase chain reaction (fnRT-PCR) assay combines RT-PCR analysis with an internal fluorogenic hybridization probe, thereby eliminating post-PCR processing and potentially enhancing specificity. An fnRT-PCR assay specific for LDEV was therefore developed by targeting primer and probe sequences to a unique region of the LDEV nucleocapsid (VP1) gene. Using the LDEV fnRT-PCR assay, we detected only LDEV and did not detect other RNA viruses that are capable of naturally infecting rodents. Using this assay, we detected as little as 10 fg of LDEV RNA; the assay was 10-fold less sensitive when directly compared with the mouse bioassay (measurement of serum LD after inoculation), without the problematic false-positive serum LD enzyme elevations associated with the mouse bioassay. Using the fnRT-PCR assay, we also were able to detect viral RNA in numerous tissues and in feces collected from experimentally inoculated C3H/HeN mice, but we did not detect any viral RNA in similar samples collected from age- and strain-matched mock-infected mice. Finally, using the fnRT-PCR assay, we were able to detect LDEV RNA in biological samples that had previously been determined to be contaminated with LDEV by use of the mouse bioassay and an RT-PCR assay at another laboratory. In conclusion, the LDEV fnRT-PCR assay is a potentially high-throughput diagnostic assay for detection of LDEV in mice and contaminated biological materials.

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.

Genomic differences between strains of lactate dehydrogenase-elevating virus.

The RNAs of two independently isolated strains of lactate dehydrogenase-elevating virus (LDV), which differ antigenically and in neurovirulence for C58 mice, were isolated and T1 RNase fingerprinted. Of about 30 unique T1 oligonucleotides, 27 seemed to be common for both strains of LDV, whereas 2 or 3 oligonucleotides were unique for each strain. In other physical and biological properties, such as virion density, molecular weights of their structural proteins, interaction with mouse anti-LDV IgG, and replication in primary cultures of peritoneal macrophages from various mouse strains, the two strains of LDV were indistinguishable. The T1 RNase patterns and the affinity of LDV RNA for oligo(dT) indicated that it contained poly-A.

High-frequency homologous genetic recombination of an arterivirus, lactate dehydrogenase-elevating virus, in mice and evolution of neuropathogenic variants.

On the basis of genome nucleotide differences between a nonneuropathogenic and a neuropathogenic lactate dehydrogenase-elevating virus (LDV) quasispecies (LDV-P and LDV-C, respectively), we have designed sets of primers for polymerase chain reaction (PCR) amplification that can detect recombinants between them in a 1276-nt-long segment ranging from ORF 5 to ORF 7. Mice were infected with large amounts of both LDVs and bled at various times postinfection (p.i.). RNA was extracted from plasma samples and reverse transcribed and the first-strand products were PCR amplified with four sets of sense and antisense primers that discriminate between parental (P/P and C/C) and recombinant (P/C and C/P) genomic segments. Both P/C and C/P recombinants were detected in plasma from six different mice at 1 day p.i. No recombinant products were generated with in vitro mixtures of LDV-P and LDV-C. End-point dilution experiments indicated that the generation of P/C and C/P recombinants varied between mice but that in some mice the frequency of recombination in the 1276-nt-long genome segment was as high as 5%. Sequence analyses of clones of some recombinants indicated that recombination had occurred at 26- to 43-nt-long stretches of homology between the LDV-P and the LDV-C genomes. Sequence analyses of the 3157-nt-long 3' end of the genomes of the neuropathogenic LDV-v and of a newly discovered nonneuropathogenic quasispecies, LDV-vx, showed that LDV-v is a natural recombinant of LDV-vx that has specifically acquired by a double recombination about 400 nt of the 5' end of ORF 5 of the neuropathogenic LDV-C and thereby the unique properties of LDV-C, neuropathogenicity and high sensitivity to antibody neutralization. In dual infections of mice with LDV-P and LDV-C all genetic recombinants, like the LDV-C parent itself, had been lost by 7 days p.i., and only LDV-P persisted. The results further support the view that LDV-P and LDV-vx have evolved to a highly stable relationship with their host, the mouse.