Demyelination Determinants Map to the Spike Glycoprotein Gene of Coronavirus Mouse Hepatitis Virus

doi:10.1128/JVI.74.19.9206-9213.2000

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Journal of Virology, October 2000, p. 9206-9213, Vol. 74, No. 19
0022-538X/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.

Demyelination Determinants Map to the Spike Glycoprotein Gene of Coronavirus Mouse Hepatitis Virus

Jayasri Das Sarma,¹ Li Fu,¹ Jean C. Tsai,² Susan R. Weiss,² and Ehud Lavi¹^,^*

Division of Neuropathology, Department of Pathology and Laboratory Medicine,¹ and Department of Microbiology,² School of Medicine, University of Pennsylvania, Philadelphia, Pennsylvania 19104

Received 19 April 2000/Accepted 20 June 2000

	ABSTRACT

Top Abstract Introduction Materials and Methods Results Discussion References

Demyelination is the pathologic hallmark of the human immune-mediated neurologic disease multiple sclerosis, which may betriggered or exacerbated by viral infections. Several experimentalanimal models have been developed to study the mechanism of virus-induceddemyelination, including coronavirus mouse hepatitis virus (MHV)infection in mice. The envelope spike (S) glycoprotein of MHVcontains determinants of properties essential for virus-host interactions.However, the molecular determinants of MHV-induced demyelinationare still unknown. To investigate the mechanism of MHV-induceddemyelination, we examined whether the S gene of MHV containsdeterminants of demyelination and whether demyelination is linkedto viral persistence. Using targeted RNA recombination, we replacedthe S gene of a demyelinating virus (MHV-A59) with the S geneof a closely related, nondemyelinating virus (MHV-2). Recombinantviruses containing an S gene derived from MHV-2 in an MHV-A59background (Penn98-1 and Penn98-2) exhibited a persistence-positive,demyelination-negative phenotype. Thus, determinants of demyelinationmap to the S gene of MHV. Furthermore, viral persistence is insufficientto induce demyelination, although it may be a prerequisite forthe development ofdemyelination.

	INTRODUCTION

Top Abstract Introduction Materials and Methods Results Discussion References

Primary demyelination is a pathologic process in which myelin is destroyed, while neuronal axons remain relatively preserved.The demyelinating process can occur by either a direct attackon oligodendrocytes, the cells that produce and maintain myelin,or an autoimmune attack against myelin components, resulting insecondary destruction of oligodendrocytes. The most prevalentprimary demyelinating disease in humans is multiple sclerosis(MS), which affects over a quarter of a million individuals inthe United States (2). The etiology and pathogenesis of MShave long been investigated; however, causation has not been proven.There is a consensus that the process involves a T-cell-mediatedautoimmune phenomenon that may be triggered by one or more viralinfections (1). Several experimental animal models have beendeveloped in order to better understand the mechanism of demyelination.Experimental autoimmune encephalomyelitis and several virus-inducedexperimental models, including coronavirus infection in mice (5),have been instrumental in providing insight into the pathogenesisofdemyelination.

Coronaviruses, members of the order Nidovirales, form a group of enveloped single-stranded RNA viruses (22, 33, 36,46). Many members of the nidoviruses, including coronavirusesand arteriviruses, infect the central nervous system and provideexperimental animal model systems for neurologic diseases (30).The A59 and JHM strains of the murine member of the coronaviruses(mouse hepatitis virus [MHV]) produce demyelination in mice thatmimics many of the pathologic features of MS (12, 15, 26,39, 42, 46, 47). Chronic MHV-induced demyelination isimmune mediated (11, 45), may be partially T-cell dependent(8), and is associated with viral persistence (25, 39)and concomitant enhancement of major histocompatibility complexclass I antigens and RNA (9, 31, 32, 43, 44). However,many aspects of the mechanism of MHV-induced demyelination arestillunknown.

Various biologic properties of MHV are associated with the viral envelope spike (S) glycoprotein (3, 4, 6, 10,16, 35, 40). However, demyelination determinants in MHVhave never been directly localized to any specific viral proteinor gene. Direct molecular analysis and mapping of biologic propertiesto viral genes have been difficult because the large (31-kb) MHVgenome (23, 37) is still not available in the form of a completeinfectious clone amenable to genetic manipulation. The recentdevelopment of the technique of targeted RNA recombination isa useful tool for 3'-end genomic manipulations (38). This methodis based on the high rate of recombination of a recipient virus(e.g., a temperature-sensitive [ts] mutant of A59) coinfectedwith a transfected plasmid containing the 3' end of A59 and inwhich portions can be replaced with parallel portions of othercoronaviruses. The technique of targeted recombination recentlyalso became an important tool for studies of MHV pathogenesis(27, 28, 34, 40). Thus, to investigate whether the S genehas a significant role in controlling demyelination, we replacedthe S gene of a demyelinating strain of MHV (MHV-A59) with theS gene of a nondemyelinating, closely related strain of MHV usingtargeted RNArecombination.

(This work was presented in part at the annual meeting of the American Society for Virology, July 1999, Amherst, Mass.)

	MATERIALS AND METHODS

Top Abstract Introduction Materials and Methods Results Discussion References

Viruses and cells. The following viruses were used in this study: wild-type MHV-A59 (26, 37); wild-type MHV-2 (14); and Alb4 (17), ats mutant of MHV-A59 containing an 87-nucleotide deletion in thespacer B region of the nucleocapsid (N) gene. In a control virus(wtR13), described elsewhere (40), an MHV-A59 S gene was reintroducedinto the genome of MHV-A59. Penn97-1 is a product of tissue culturerecombination due to a dual infection with MHV-A59 and MHV-2 (J.Das Sarma et al., submitted for publication). Plaque-purifiedstocks of all the viruses used in this study had titers of 10⁷ to 10⁸ PFU/ml. Viruses were propagated and assayed in L2 and 17Cl-1murine fibroblast cells at 37°C in Dulbecco's modified Eagle medium(GIBCO BRL, Gaithersburg, Md.) containing 10% heat-inactivatedfetal bovine serum (FBS) and 1% penicillin-streptomycin in thepresence of 5% CO₂. Spinner cultures of L2 cells were maintainedin Joklik's modified Eagle medium with 10% FBS at densities ofbetween 2 × 10⁵ and 2 × 10⁶ cells perml.

Plasmids. The pGEM-T^(a) vector was purchased from Promega, Madison, Wis. The transcription vector pMH54 (obtained from Paul Masters) consistsof the extension of plasmid pFV1 (7, 19) to include the 3'1.1 kb of the hemagglutinin-esterase (HE) gene. It contains theentire 3' end of the MHV-A59 genome downstream to the HE gene.The S gene open reading frame (ORF) sequences of pMH54 are identicalto those of our wild-type strain MHV-A59. In addition, silentnucleotide substitutions were made at codons 12 and 13 of theS gene, generating an AvrII site. An SbfI site was created 11bp downstream of the termination codon of the S gene ORF (19).The AvrII and SbfI sites were useful for introducing differentS genes into the background of pMH54 (40).

To generate a plasmid containing the MHV-2 S gene, we first cloned the MHV-2 S gene into the pGEM-T^(a) vector. MHV-2 genomic RNA was extracted from cytoplasmic RNAfrom infected L2 fibroblasts, and the 4,083-bp S gene was amplifiedusing two synthetic primers, SG1F and SG1R (Table 1). The SG1Fprimer was used to introduce an AvrII restriction site immediatelyafter the signal sequence of the S gene. The SG1R primer was usedto introduce an SbfI restriction site 11 bp downstream of thestop codon in the S gene. The 4,083-bp PCR fragment was gel purified,ligated into the pGEM-T^(a) vector between the T7 and SP6 RNA polymerase promoters, and thencloned. Restriction digestion analysis of the insert was usedto select positive clones, and cDNA sequencing was used to verifythe S gene insert. We then removed the MHV-2 S gene from the pGEM-T^(a) vector by digestion with AvrII and SbfI and gel purified andsubcloned it into the corresponding site in pMH54 following AvrIIand SbfI restriction site enzyme digestion, dephosphorylation,and gel purification of pMH54. The new plasmid was named pMHV2.We sequenced the S gene portion of it, in order to verify thatit contained the exact sequence of the MHV-2 S gene.

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TABLE 1. Primers used for introducing restriction sites into the MHV-2 S gene and for recombinant virus genome sequencing

Targeted RNA recombination. Targeted RNA recombination of the S gene was carried out between the Alb4 virus and synthetic capped RNAs transcribed frompMHV2 as previously described (34, 38). MHV-2 S gene recombinantviruses were selected by antibody neutralization treatment for2 h at room temperature. The released viruses were treated withA2.1 and A2.3, anti-S monoclonal antibodies (obtained from JohnFleming) that are specific for the S protein of MHV-A59. The antibodytreatment neutralized the parent virus Alb4 and MHV-A59 but notMHV-2 or recombinant viruses containing the S gene derived fromMHV-2. Viruses were then identified by plaque assays based onthe selection of viruses with small plaques. MHV-2 produces syncytium-negative,small plaques in L2 cell cultures at 37°C. Putative recombinantviruses were identified by the presence of AvrII and SbfI restrictionsites following digestion analysis. Selected recombinants wereplaque purified two more times, and viral stocks were preparedin 17Cl-1 cells. The identity of the S gene of selected recombinantviruses and the absence of mutations in the S gene were confirmedby sequenceanalysis.

Genome sequencing. For sequencing of the MHV-2 S gene in the various constructs, oligonucleotide primers were designed based on a recent sequenceanalysis of the MHV-2 genome (Das Sarma et al., submitted). Reversetranscriptase (RT) PCR amplification was carried out using cytoplasmicRNAs extracted from virus-infected L2 cell monolayers as templates.The oligonucleotides listed in Table 1 were used for amplificationas specified in each experiment. Plasmid cDNAs and double-strandedPCR products were gel purified and analyzed by automated sequencingusing the Taq dye terminator procedure from a DyeDeoxy Terminatorcycle sequencing kit (Applied Biosystems). The primers used foramplification were also used for sequencing, and each fragmentwas sequenced in bothdirections.

Infection of mice. All animal experiments used 4-week-old, virus-free C57BL/6 mice (Jackson Laboratories, Bar Harbor, Maine). Viruses were dilutedinto phosphate-buffered saline (PBS) containing 0.75% bovine serumalbumin. Mice were anesthetized with methoxyflurane (Methofane;Pittman-Moore, Mundelein, Ill.). For intracerebral (i.c.) injection,25 µl of diluted virus was injected into the left cerebral hemisphere.Mock-infected controls were injected similarly with an uninfectedL2 cell lysate at a similardilution.

Virulence and virus titers in mice. Virulence was assessed by calculating the lethal dose that killed 50% of the mice (LD₅₀). Mice were injected i.c. with serial10-fold dilutions of viruses (five mice per dilution). Signs ofdisease or death were monitored on a daily basis up to 21 dayspostinfection. LD₅₀ values were calculated by the Reed-Muenchmethod (41).

For measurement of virus titers in the liver and brain, mice were sacrificed at selected times postinfection (1, 3, 5, 7,9, and 11 days postinfection) and perfused with 5 ml of sterilePBS. Brains and livers were removed aseptically and separatelyplaced directly into 1 ml of isotonic saline with 0.167% gelatin(gel saline). All organs were stored at $-$ 80°C until virus titerswere determined. Organs were homogenized, and virus titers weredetermined by plaque assays on L2 cell monolayers as previouslydescribed (26).

Histologic analysis. For analysis of organ pathology, mice were infected i.c., sacrificed at various times, and perfused with 5 ml of saline. Brainsand livers were removed. One half of the brain and a portion ofthe liver were fixed in 10% phosphate-buffered formalin, and therest of the brain and a portion of the liver were used for theevaluation of virus titers. Formalin-fixed tissues were embeddedin paraffin, sectioned, and stained with hematoxylin and eosin(H&E). H&E-stained sections were used for pathological evaluationby light microscopy (24, 26). Slides were coded and read ina blindedfashion.

For assessment of demyelination, mice were infected i.c. with 5 PFU per mouse, with 10 mice per virus. At 30 days postinfection,infected mice underwent perfusion with PBS, followed by perfusionwith 10% phosphate-buffered formalin. Brains and spinal cordswere removed, and tissues were embedded in paraffin and sectionedfor staining with Luxol fast blue to detect plaques of demyelination.Demyelination was quantified by examining one spinal cord section(four quadrants) from each of five or six levels of spinal cordfor each mouse; thus, approximately 200 quadrants were examinedfor each dose of virus. Slides were coded and read in a blindedfashion (26, 35).

Immunohistochemical analysis. Formalin-fixed, paraffin-embedded tissue samples were deparaffinized, rehydrated through graded alcohols, and permeabilizedin 0.2% Triton X-100-PBS for 15 min. Tissue was then incubatedwith the primary antibody (polyclonal rabbit anti-MHV; 1:100 dilution)at 37°C for 1 h, and isotype-matched negative controls were usedat similar concentrations. Tissue sections with each control antibodywere used in each experiment. An UltraProbe universal immunostainingkit (Biomeda Corp., Foster City, Calif.), which uses an avidin-biotincomplex with alkaline phosphatase as the marker enzyme, was usedin all experiments. The kit contains fast red-naphthol phosphateas the substrate-chromogen reagent. The kit was used with a MicroProbesystem (Fisher Scientific, Pittsburgh, Pa.) and with capillarygap technology as previously described (13). Ten percent FBSwas added to the secondary antibody as a blocking reagent againstnonspecific binding. The slides were covered with Crystal/Mount(Biomeda).

Analysis of viral persistence. Four-week-old C57BL/6 mice were infected i.c. with the following viruses: 1,000 PFU of MHV-A59, 1,000 PFU of MHV-2, 2,500PFU of wtR13, 300 PFU of Penn97-1, 5 PFU of Penn98-1, and 5 PFUof Penn98-2. The doses of 1,000 PFU of MHV-A59 (0.25 LD₅₀) and2,500 PFU of wtR13 (0.36 LD₅₀) were known to produce sufficientdemyelination. The other viruses were given at doses of 1 LD₅₀or higher to ascertain that substantial pathology would be producedin the mice in the event that persistence was not detected. Controlmice were injected with uninfected cell lysate. Five mice pervirus per time point were analyzed independently, with similarresults (see Fig. 6 for a representativeexperiment).

Mice were sacrificed by an overdose of methoxyflurane and perfused intracardially with diethyl pyrocarbonate-treated PBS at5 days postinfection (peak of acute infection) and at 30 dayspostinfection (peak of chronic demyelination). Organs (liver,brain, and spinal cord) were removed, snap-frozen in liquid nitrogen,ground, and homogenized to a fine powder under liquid nitrogen.RNA was isolated with an RNeasy Mini kit (Qiagen, Chatsworth,Calif.) and quantified by optical density measurement at 260 nm.Equal amounts of total tissue RNA from the samples were reversetranscribed with the SuperScript preamplification system of thefirst-strand cDNA synthesis kit (GIBCO BRL), and amplificationwas carried out by PCR. A pair of oligonucleotide primers, IZJ5(5'-GCTCCAACAGTTGGTGCC-3') and IZJ6 (5'-ACGTAGGACCTTGCTAACTTC-3')was designed for PCR amplification from the most conserved regionof the N gene and the 3' untranslated region. The reaction consistedof 3 min of denaturation at 94°C, 1 min of denaturation at 94°C,45 s of annealing at 55°C, and 2 min of extension at 65°C. After30 cycles, the final products were extended for 5 min at 72°C.The resulting amplified fragment of 601 bp was analyzed by 1.2%agarose gel electrophoresis. A second RT-PCR was performed oneach sample with a second pair of N gene primers: M3 (5'-CACATTAGAGTCATCTTCTA-3')and M4 (5'-GAAGTAGATAATGTAAGCGT-3') (18).

	RESULTS

Top Abstract Introduction Materials and Methods Results Discussion References

Selection of viruses with recombinant S genes. Targeted recombination was carried out between synthetic capped RNAs transcribed from pMHV2 and the recipient virus Alb4,according to the scheme depicted in Fig. 1. Recombinant viruses,containing the MHV-2-derived S gene, were selected based on thepresence of small plaques and following neutralization by theMHV-A59 S protein-specific monoclonal antibodies A2.1 and A2.3.The viruses were further plaque purified twice and analyzed forthe successful repair of the Alb4 deletion. RT-PCR was carriedout with primers IZJ5 and IZJ6 (Table 1), which amplified a 602-nucleotideregion surrounding the 87-nucleotide N gene deletion of Alb4.The PCR-amplified product derived from Alb4 was shorter than thatderived from wild-type MHV-A59; thus, recombinant viruses in whichthe deletion was repaired had a fragment of the same length asthat amplified from wild-type virus MHV-A59 (Fig. 2A). Small-plaqueviruses with larger PCR fragments were putative MHV-2 S gene recombinantviruses.

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FIG. 1. Schematic diagram of targeted recombination performed in this study. Recombination occurred between Alb4 and a synthetic RNA transcribed from vector pMHV2, in which the S gene of MHV-A59 was replaced with the S gene of MHV-2. Infection of Alb4 simultaneous with transfection with pMHV2 RNA resulted in the generation of two recombinant viruses, Penn98-1 and Penn98-2, which contained the MHV-2 S gene flanked by MHV-A59 sequences (as confirmed by DNA sequencing) and the inserted AvrII and SbfI restriction sites. Since both restriction sites derived from pMHV2 were present in the recombinant viruses, recombination must have occurred 5' to the S gene. Black bars represent sequences derived from MHV-A59; white bars represent sequences derived from MHV-2; and gray bars represent plasmid sequences. ntd, nucleotide; M, membrane protein gene.

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FIG. 2. RT-PCR analysis of putative recombinant viruses (RC2 to RC16). Following characterization and sequencing of the S gene region, the putative recombinant viruses RC2 and RC4 were later designated Penn98-1 and Penn98-2, respectively. (A) A 602-nucleotide region surrounding the Alb4 deletion was amplified with primers IZJ5 and IZJ6 from the genomic RNAs of putative recombinants as well as Alb4 and wild-type MHV-A59. The faster electrophoretic mobility of Alb4 corresponds to the deletion in the N gene, which does not exist in MHV-A59 and which has been repaired in all of the putative recombinant viruses tested. Lane M, size markers. (B) An 868-nucleotide fragment surrounding the AvrII restriction site was amplified from the genomes of putative recombinants, wild-type MHV-A59, and Alb4 using primers FIJ79 and MHV-2S1R and was digested with AvrII prior to electrophoresis. Undigested Alb4 and MHV-A59 are in contrast to the digested recombinant viruses, which contain the AvrII restriction site. (C) A 1,313-nucleotide fragment surrounding the SbfI restriction site was amplified from the genomes of putative recombinant viruses, wild-type MHV-A59, and Alb4 using Penn11F and RIJ84 and was digested with SbfI prior to electrophoresis. The digestion of the recombinant viruses with SbfI indicates the existence of this restriction site in all of the putative recombinant viruses, in contrast to Alb4 and MHV-A59, which do not contain this restriction site.

The putative recombinants were then screened for the presence of the AvrII and SbfI restriction sites. An 868-nucleotide fragmentsurrounding the AvrII site was amplified from the genomes of allthe recombinant viruses, wild-type MHV-A59, and Alb4 using primersFIJ79 and MHV-2S1R. The amplified products were digested withAvrII, which produced two bands of 366 and 502 bp in S recombinantsbut not in wild-type MHV-A59 or Alb4 (Fig. 2B). Similarly, a 1,313-nucleotidefragment surrounding the SbfI site was amplified using primersPenn11F and RIJ84. Digestion with SbfI generated two fragments(498 and 815 nucleotides) in S recombinants (Fig. 2C).

The S gene of recombinant viruses was sequenced using three PCR-amplified overlapping DNA fragments. One fragment was producedusing primers FIJ79 and MHV-2S1R, a second one was produced usingprimers SG1F and SG1R, and the third was generated using primersPenn11F and RIJ84 (Table 1). The presence of the entire MHV-2S gene with flanking regions identical to those in MHV-A59 wasverified in two of the putative recombinant viruses, RC2 and RC4,which were then designated Penn98-1 and Penn98-2.

Replication and pathogenesis of chimeric viruses. The virulence of the recombinant viruses compared to that of the parental viruses was determined by LD₅₀ experiments. LD₅₀experiments revealed that the virulence of both Penn98-1 and Penn98-2(LD₅₀ of each, 5 PFU) was higher than that of both parental viruses(LD₅₀s of MHV-A59 and wtR13 [40], 4,000 and 6,800 PFU, respectively)but was closer to that of MHV-2 (LD₅₀, 200 PFU). The Alb4 ts mutantvirus was nonpathogenic in mice. To analyze the pathogenesis ofthe new recombinant viruses in mice, we injected mice i.c. withPenn98-1 (5 PFU = 1 LD₅₀), Penn98-2 (5 PFU = 1 LD₅₀), and wtR13(2,500 PFU = 0.36 LD₅₀). Penn98-1 and Penn98-2 replicated efficientlyin both brain and liver (Fig. 3). Liver titers of these viruseswere higher than brain titers. The kinetics of replication weresimilar to those of MHV-2 (Das Sarma et al., submitted), suggestingthat the S gene contains determinants of virulence and hepatotropism.

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FIG. 3. Viral replication in the brains and livers of mice following i.c. injection with 5 PFU each of Penn98-1 and Penn98-2. Each time point represents the mean titer for two or three mice. Titers are expressed as log₁₀ PFU per gram of tissue.

Brain and liver sections from animals infected i.c. with wild-type MHV-A59, wild-type MHV-2, wtR13, Penn98-1, and Penn98-2were stained with H&E and analyzed by light microscopy. Histopathologicstudies revealed that Penn98-1 and Penn98-2 produced acute meningoencephalitissimilar to that caused by MHV-A59. Brain pathology consisted offocal acute encephalitis, characterized by inflammatory infiltratesof mononuclear cells (predominantly lymphocytes), microglial proliferation,microglial nodules, and neuronophagia. Areas of involvement includedthe regions of the brain typically susceptible to MHV-A59 infection(24). Liver pathology consisting of moderate to severe hepatitisfollowing Penn98-1 and Penn98-2 infection was characterized bymultiple foci of necrosis throughout the liver. Each area of necrosisconsisted of degenerating hepatocytes, polymorphonuclear and lymphocyticinflammatory infiltrates, and cellular debris. The extent anddistribution of the hepatitis caused by 5 PFU each of Penn98-1and Penn98-2 were similar to the hepatic changes produced by 1,000PFU of MHV-2 and more severe than the changes produced by 5,000PFU of MHV-A59.

Immunohistochemical analysis of viral antigen was done on tissue sections obtained from mice during acute infection with therecombinant viruses (Penn98-1 and Penn98-2), and the results werecompared to those for sections obtained from mice infected withMHV-A59 and MHV-2. In MHV-A59-infected mice, viral antigen wasdistributed in focal areas of the brain parenchyma, concomitantwith the distribution of inflammatory infiltrates, as previouslydescribed (24, 29). In MHV-2-infected mice, viral antigenwas detected in the meninges, choroid plexus, and ependymal cells.No viral antigen was detected in neurons, and the involvementof glial cells was minimal and restricted to the subependymallocation. In Penn98-1- and Penn98-2-infected mice, the distributionof viral antigen was similar to that seen with MHV-A59 infection(Fig. 4).

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FIG. 4. Immunohistochemical detection of viral antigen in brain sections 5 days postinfection using rabbit anti-MHV polyclonal antibodies. (Top) Section from a Penn98-1-infected brain showing antigen detection in numerous neurons and glial cells in an area of acute encephalitis similar to that caused by MHV-A59. (Bottom) Section from a Penn98-2-infected brain showing similar antigen detection. Alkaline phosphatase was the marker enzyme; fast red-naphthol phosphate was the substrate-chromogen reagent; magnification, ×148.

Demyelination in mice infected with S gene recombinant viruses. Previous studies revealed that i.c. infection of 4-week-old mice with MHV-A59 produced chronic demyelination, which couldbe best demonstrated in spinal cord sections at 30 days postinfection(26). Infection with MHV-2 did not produce demyelination (DasSarma et al., submitted). To test the effect of the S gene ondemyelination, we examined the ability of recombinant virusesPenn98-1 and Penn98-2 to induce demyelination compared to thatof wild-type recombinant wtR13 and wild-type MHV-A59 and MHV-2.Penn98-1 and Penn98-2 did not produce demyelination in any ofthe seven mice injected with each virus. Like wild-type MHV-A59,wild-type recombinant wtR13, containing an S gene derived fromMHV-A59, produced demyelination in 100% of the mice (five of five)(Fig. 5). All three recombinant viruses (wtR13, Penn98-1, andPenn98-2) were given at the same dose (5 PFU). The recombinantwtR13 produced larger demyelinating lesions when given at 2,500PFU than when given at 5 PFU, but with both doses of virus, 100%of the mice were affected.

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FIG. 5. Analysis of demyelination induced by recombinant viruses. Spinal cord sections were obtained from mice infected with different recombinant viruses and sacrificed 30 days after infection; the sections were stained with Luxol fast blue for myelin. Infection with wtR13 at 2,500 PFU resulted in extensive demyelination. Similar but smaller demyelinating lesions were seen in all mice infected with 5 PFU of wtR13. In contrast, all five mice infected with 5 PFU of Penn98-1 and all five mice infected with 5 PFU of Penn98-2 showed normal spinal cords at multiple levels tested.

Viral persistence. In order to investigate whether differences in the abilities of viruses to cause demyelination were associated with differencesin viral persistence, we amplified viral RNA from livers, brains,and spinal cords of mice infected with demyelinating and nondemyelinatingviruses. As shown in Fig. 6, during the acute phase of infection,PCR products of the correct band size (601 bp), consistent withMHV RNA, were detected at 5 days postinfection in all mice infectedwith each of the viruses. Viral RNA was detected in all threeanatomic locations examined (liver, brain, and spinal cord). However,at 30 days postinfection, PCR products corresponding to viralRNA were detected only in the MHV-A59-infected spinal cords andnot in the livers or brains of the same mice. No PCR productswere detected in the livers, brains, or spinal cords of mice infectedwith MHV-2 or another nondemyelinating virus, Penn97-1, or inorgans of control uninfected mice. With a second pair of primers,RT-PCR amplified a fragment of the predicted size of 147 bp onlyin the sample of MHV-A59-infected spinal cord and not in the liveror brain of the same mouse. The spinal cord had the most abundantviral transcripts during the chronic phase. This result is consistentwith previous reports suggesting that the spinal cord is the majorsite of viral persistence during chronic infection with JHM andMHV-A59 (26, 39). Mice infected with the nondemyelinatingviruses MHV-2 and Penn97-1 and uninfected controls had negativeresults.

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FIG. 6. Analysis of viral persistence by RT-PCR amplification with MHV-specific primers, which amplify N gene sequences conserved in all sampled viruses. Mice were sacrificed during acute disease at 5 days postinfection (top panels) or during chronic demyelinating disease at 30 days postinfection (bottom panels). Infection and mock infection of L2 fibroblast cells were used as positive and negative controls, respectively (bottom left panel). Viruses were detected in livers, brains, and spinal cords of mice during acute infection. A spinal cord signal was detected in MHV-A59-, Penn98-1-, and Penn98-2-infected mice during chronic infection but not in MHV-2- and Penn98-1-infected mice. Lanes M, size markers.

To study the effect of the S gene on viral persistence, we studied infection of mice with the newly constructed recombinantviruses Penn98-1 and Penn98-2. As a control, we used wtR13, inwhich the S gene of MHV-A59 was reintroduced into an MHV-A59 background.Following infection with Penn98-1 and Penn98-2, viral RNA wasdetected in the livers and brains of the mice during the acutephase and in the spinal cords of the mice at 30 days postinfection.Similar RNA patterns were found in mice infected with wtR13 andMHV-A59. Thus, Penn-98-1 and Penn98-2 produced chronic persistentinfection of the spinal cord but did not producedemyelination.

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

Because of the lack of an infectious clone that could be genetically manipulated, the examination of genomic control of biologicproperties of coronaviruses relied, until recently, on indirectstudies characterizing mutants, variants, and recombinant viruses.Recently, the technique of targeted recombination created newopportunities for the investigation of genomic determinants ofbiologic properties. Mutations in the 3' end and even the exchangeof complete genes became feasible. One of the most significantbiologic properties of coronaviruses is the ability of some strainsto persist and produce chronic inflammatory demyelination, similarto that found in MS. Information about the mechanism of this phenomenonmay be useful for understanding MS, since there is strong epidemiologicalevidence that the immune-mediated pathology in MS may be triggeredor initiated by viral infections. Thus, we began to explore themolecular determinants of demyelination in MHV-induceddemyelination.

We produced two independently constructed recombinant viruses containing an S gene derived from the nondemyelinating, nonpersistentvirus MHV-2. The two viruses had identical phenotypes and wereable to produce encephalitis (like that caused by MHV-A59) andhepatitis (like that caused by both parental viruses) but wereunable to produce demyelination similar to that caused by MHV-2.In order to rule out any possible effect of the procedure itselfor mutation in the recipient virus (Alb4) used for the recombinationprocedure on the phenotype of the viruses, a control recombinantvirus was used in parallel. The control virus (wtR13), in whichan MHV-A59 S gene was reintroduced into the genome of MHV-A59,was selected using the same procedure as that used for the tworecombinant viruses with the MHV-2 S genes. Control virus wtR13,as expected, had the same phenotype as wild-type MHV-A59. Theinability of the viruses with an MHV-2 S gene to demyelinate suggeststhat the S gene may contain determinants of demyelination whichare independent of the molecular determinants of acute encephalitisand viral persistence. Examining the phenotype of a recombinantvirus with an S gene derived from MHV-A59 in an MHV-2 backgroundwould obviously further strengthen this statement. However, suchrecombination is not possible at the presenttime.

Penn98-1 and Penn98-2 both produce acute encephalitis, unlike MHV-2, which does not cause encephalitis or demyelination. Encephalitiscaused by these two viruses is associated with a viral antigendistribution similar to that of MHV-A59, as shown here by immunohistochemicalstudies. This result suggests that although the pathologic processof encephalitis may be a prerequisite for demyelination, it isnot by itself sufficient to induce demyelination, and additionaldeterminants or factors are necessary for the induction of demyelination.This observation also suggests that important determinants ofencephalitis exist outside of the Sgene.

The biologic property of viral persistence is essentially the failure of the immune system to clear virus from infected organs,mainly the central nervous system. Viral persistence has beendemonstrated in infections with all of the neurotropic demyelinatingstrains of MHV, including MHV-A59 and JHM (15, 25, 39).In most cases, only viral RNA is detectable in the chronic persistentstate, but this finding may reflect only the higher sensitivityof the methods used for the detection of viral RNA than for thedetection of infectious viral titers and viral antigens. Viralpersistence appears to be an important factor and may even bea prerequisite for MHV-induced demyelination during chronic immune-mediateddemyelination. However, MHV-induced demyelination during an acuteinfection may involve a different mechanism, perhaps even a directcytolytic effect of the virus on oligodendrocytes. In the presentstudy, we found that MHV strains that do not persist, such asMHV-2 and Penn97-1, also do not demyelinate. However, the persistence-positive,demyelination-negative, phenotype of Penn98-1 and Penn98-2 indicatesfor the first time that viral persistence per se is insufficientto induce demyelination. However, viral persistence may be necessaryfor the development of demyelination, perhaps by providing a continuoustrigger for immune-mediated myelin destruction. An alternativeexplanation for the phenotype of Penn98-1 and Penn98-2 is thatviral persistence in mice infected with these viruses may occurin neuronal cells of the gray matter, while persistence in MHV-A59-infectedmice occurs in the white matter. Additional factors independentof persistence may be necessary for the development of demyelinationin mice containing persistent virus. Further studies in our laboratoryare under way to determine the nature of these additional factorsand the precise relationship between viral persistence anddemyelination.

The exchange of the S gene between MHV-2 and MHV-A59 also produced a more virulent virus. A dose of 5 PFU was sufficient toproduce hepatitis and encephalitis to an extent similar to orgreater than that seen with 1,000 to 5,000 PFU of wild-type parentalviruses MHV-2 and MHV-A59. This finding also provides furthersupport for the observation that molecular determinants of MHVvirulence are present within the S gene (40). However, determinantsoutside the S gene may also influence virulence. Certain interactionsbetween different parts of the viral genome (for instance, theS gene and parts of gene 1) may account for the enhancement ofviral virulence. This observation also supports the idea thathomologous RNA recombination may be important for the evolutionof more virulent coronaviruses or RNA viruses in general, as previouslypostulated (20, 21).

In conclusion, the present report provides direct evidence by targeted RNA recombination that the S gene of MHV controls certainmolecular determinants of demyelination. Demyelination may dependon the integrity of other, non-S gene determinants within theviral genome. The findings presented here pave the way for furtherstudies to investigate in more detail the potential role of theviral envelope S glycoproteins in autoimmunity and demyelination.These studies are potentially relevant to other forms of demyelination,includingMS.

	ACKNOWLEDGMENTS

This work was supported in part by National Multiple Sclerosis Society grant RG-2615 and PHS grantNS30606.

We thank Vahe Bedian and the staff of the DNA Sequencing Facility at the University of Pennsylvania for assistance with viralsequencing, Paul Masters for the gifts of pMH54 and Alb4 virus,John Fleming for the gift of anti-S protein monoclonal antibodies,and Elsa Aglow for histologyexpertise.

	FOOTNOTES

^* Corresponding author. Mailing address: University of Pennsylvania, School of Medicine, Division of Neuropathology, Departmentof Pathology and Laboratory Medicine, 613 Stellar-Chance Building,Philadelphia, PA 19104-6100. Phone: (215) 898-8198. Fax: (215)898-9969. E-mail: lavi{at}mail.med.upenn.edu.

REFERENCES

Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References

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1.	Allen, I., and B. Brankin. 1993. Pathogenesis of multiple sclerosis $---$ the immune diathesis and the role of viruses. J. Neuropathol. Exp. Neurol. 52:95-105[Medline].
2.	Anderson, D. W., J. H. Ellenberg, C. M. Leventhal, S. C. Reingold, M. Rodriguez, and D. H. Silberberg. 1992. Revised estimate of the prevalence of multiple sclerosis in the United States. Ann. Neurol. 31:333-336[CrossRef][Medline].
3.	Buchmeier, M. J., H. A. Lewicki, P. J. Talbot, and R. L. Knobler. 1984. Murine hepatitis virus-4 (strain JHM)-induced neurologic disease is modulated in vivo by monoclonal antibody. Virology 132:261-270[CrossRef][Medline].
4.	Collins, A. R., R. L. Knobler, H. Powell, and M. J. Buchmeier. 1982. Monoclonal antibody to murine hepatitis virus-4 (strain JHM) defines the viral glycoprotein responsible for attachment and cell-cell fusion. Virology 119:358-371[CrossRef][Medline].
5.	Dal Canto, M. C., and S. G. Rabinowitz. 1982. Experimental models of virus-induced demyelination of the central nervous system. Ann. Neurol. 11:109-127[CrossRef][Medline].
6.	Dalziel, R. G., P. W. Lampert, P. J. Talbot, and M. J. Buchmeier. 1986. Site-specific alteration of murine hepatitis virus type 4 peplomer glycoprotein S results in reduced neurovirulence. J. Virol. 59:463-471[Abstract/Free Full Text].
7.	Fischer, F., C. F. Stegen, C. R. Koetzner, and P. S. Masters. 1997. Analysis of a recombinant mouse hepatitis virus expressing a foreign gene reveals a novel aspect of coronavirus transcription. J. Virol. 71:5148-5160[Abstract].
8.	Fleming, J. O., F. I. Wang, M. D. Trousdale, D. R. Hinton, and S. A. Stohlman. 1993. Interaction of immune and central nervous systems: contribution of anti-viral Thy-1+ cells to demyelination induced by coronavirus JHM. Regional Immunol. 5:37-43[Medline].
9.	Gombold, J. L., and S. R. Weiss. 1992. Mouse hepatitis virus A59 increases steady-state levels of MHC mRNAs in primary glial cell cultures and in the murine central nervous system. Microb. Pathog. 13:493-505[CrossRef][Medline].
10.	Hingley, S. T., J. L. Gombold, E. Lavi, and S. R. Weiss. 1994. MHV-A59 fusion mutants are attenuated and display altered hepatotropism. Virology 200:1-10[CrossRef][Medline].
11.	Houtman, J. J., and J. O. Fleming. 1996. Dissociation of demyelination and viral clearance in congenitally immunodeficient mice infected with murine coronavirus JHM. J. Neurovirol. 2:101-110[Medline].
12.	Houtman, J. J., and J. O. Fleming. 1996. Pathogenesis of mouse hepatitis virus-induced demyelination. J. Neurovirol. 2:361-376[Medline].
13.	Jamieson, D. J., D. Usher, D. J. Rader, and E. Lavi. 1995. Apolipoprotein(a) deposition in atherosclerotic plaques of cerebral vessels: a potential role for endothelial cells in lesion formation. Am. J. Pathol. 147:1567-1574[Abstract].
14.	Keck, J. G., L. H. Soe, S. Makino, S. A. Stohlman, and M. M. C. Lai. 1988. RNA recombination of murine coronavirus: recombination between fusion-positive mouse hepatitis virus A59 and fusion-negative mouse hepatitis virus 2. J. Virol. 62:1989-1998[Abstract/Free Full Text].
15.	Knobler, R. L., P. W. Lampert, and M. B. A. Oldstone. 1982. Virus persistence and recurring demyelination produced by a temperature sensitive mutant of MHV-4. Nature 298:279-280[CrossRef][Medline].
16.	Knobler, R. L., L. A. Tunison, P. W. Lampert, and M. B. A. Oldstone. 1982. Selected mutants of mouse hepatitis virus type 4 (JHM strain) induce different CNS diseases. Pathobiology of disease induced by wild type and mutants ts8 and ts15 in BALB/c and SJL/J mice. Am. J. Pathol. 109:157-168[Abstract].
17.	Koetzner, C. A., M. M. Parker, C. S. Ricard, L. S. Sturman, and P. S. Masters. 1992. Repair and mutagenesis of the genome of a deletion mutant of the coronavirus mouse hepatitis virus by targeted RNA recombination. J. Virol. 66:1841-1848[Abstract/Free Full Text].
18.	Kunita, S., E. Terada, K. Goto, and N. Kagiyama. 1992. Sequence analysis and molecular detection of mouse hepatitis virus using the polymerase chain reaction. Lab. Anim. Sci. 42:593-598[Medline].
19.	Kuo, L., G.-J. Godeke, M. J. B. Raamsman, P. S. Masters, and P. J. M. Rottier. 2000. Retargeting of coronavirus by substitution of the spike glycoprotein ectodomain: crossing the host cell species barrier. J. Virol. 74:1393-1406[Abstract/Free Full Text].
20.	Lai, M. M. C. 1992. RNA recombination in animal and plant viruses. Microbiol. Rev. 56:61-79[Abstract/Free Full Text].
21.	Lai, M. M. C., R. S. Baric, S. Makino, J. G. Keck, J. Egbert, J. L. Leibowitz, and S. A. Stohlman. 1985. Recombination between nonsegmented RNA genomes of murine coronaviruses. J. Virol. 56:449-456[Abstract/Free Full Text].
22.	Lai, M. M. C., and D. Cavanagh. 1997. The molecular biology of coronaviruses. Adv. Virus Res. 48:1-100.
23.	Lai, M. M. C., and S. A. Stohlman. 1981. Comparative analysis of RNA genomes of mouse hepatitis viruses. J. Virol. 38:661-670[Abstract/Free Full Text].
24.	Lavi, E., S. P. Fishman, M. K. Highkin, and S. R. Weiss. 1988. Limbic encephalitis following inhalation of murine coronavirus MHV-A59. Lab. Investig. 58:31-36[Medline].
25.	Lavi, E., D. H. Gilden, M. K. Highkin, and S. R. Weiss. 1984. Persistence of MHV-A59 RNA in a slow virus demyelinating infection in mice as detected by in situ hybridization. J. Virol. 51:563-566[Abstract/Free Full Text].
26.	Lavi, E., D. H. Gilden, Z. Wroblewska, L. B. Rorke, and S. R. Weiss. 1984. Experimental demyelination produced by the A59 strain of mouse hepatitis virus. Neurology 34:597-603[Abstract/Free Full Text].
27.	Lavi, E., J. A. Haluskey, and P. S. Masters. 1998. Targeted recombination between MHV-2 and MHV-A59 to study neurotropic determinants of MHV. Adv. Exp. Med. Biol. 440:537-541[Medline].
28.	Lavi, E., L. Kuo, J. A. Haluskey, and P. S. Masters. 1998. The pathogenesis of MHV nucleocapsid gene chimeric viruses. Adv. Exp. Med. Biol. 440:543-547[Medline].
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