Infection with Cytotoxic T-Lymphocyte Escape Mutants Results in Increased Mortality and Growth Retardation in Mice Infected with a Neurotropic Coronavirus

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J Virol, July 1998, p. 5912-5918, Vol. 72, No. 7
0022-538X/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.

Infection with Cytotoxic T-Lymphocyte Escape Mutants Results in Increased Mortality and Growth Retardation in Mice Infected with a Neurotropic Coronavirus

Lecia Pewe,¹ Shurong Xue,² and Stanley Perlman¹^,²^,³^,^*

Departments of Pediatrics¹ and Microbiology² and Interdisciplinary Program in Immunology,³ University of Iowa, Iowa City, Iowa 52242

Received 2 February 1998/Accepted 2 April 1998

	ABSTRACT

Top Abstract Introduction Materials & Methods Results Discussion References

C57BL/6 mice infected with mouse hepatitis virus strain JHM (MHV-JHM) develop a chronic demyelinating encephalomyelitis severalweeks after inoculation. Previously, we showed that mutationsin the immunodominant CD8 T-cell epitope (S-510-518) could bedetected in nearly all samples of RNA and virus isolated fromthese mice. These mutations abrogated recognition by T cells harvestedfrom the central nervous systems of infected mice in direct exvivo cytotoxicity assays. These results suggested that cytotoxicT-lymphocyte (CTL) escape mutants contributed to virus amplificationand the development of clinical disease in mice infected withwild-type virus. In the present study, the importance of thesemutations was further evaluated by infecting naive mice with MHV-JHMvariants isolated from infected mice and in which epitope S-510-518was mutated. Compared to mice infected with wild-type virus, variantvirus-infected animals showed higher mortality and morbidity manifestedby decreased weight gain and neurological signs. Although a delayin the kinetics of virus clearance has been demonstrated in previousstudies of CTL escape mutants, this is the first illustrationof significant changes in clinical disease resulting from infectionwith viruses able to evade the CD8 T-cell immune response.

	INTRODUCTION

Top Abstract Introduction Materials & Methods Results Discussion References

Cytotoxic T-lymphocyte (CTL) escape mutants have been identified in several viral infections and appear to be most importantwhen the CTL response is strong and functionally monospecific(10, 19, 25). Such mutants have been detected in human patientsinfected with human immunodeficiency virus type 1 (HIV-1), hepatitisB virus, hepatitis C virus, and Epstein-Barr virus (3, 4,10, 12, 18, 19, 25, 36, 38, 45, 47). CTL escapemutants have also been identified in animal models of viral infections.CTL escape mutants were first identified in mice transgenic fora T-cell receptor for lymphocytic choriomeningitis virus thatwere infected with this virus (37). In later studies, wild-typemice were infected with virus mutated in one or more of the immunodominantCTL epitopes (23, 29). Infection with mutated virus did notresult in increased morbidity or mortality, although the kineticsof virus clearance was delayed. These studies in humans and experimentalanimals suggest but do not prove that CTL escape mutants resultin disease progression or significantly change the outcome ofthe infection in question.

In previous reports, we showed that viral CTL escape mutants were selected in C57BL/6 (B6) mice infected with wild-type mousehepatitis virus strain JHM (MHV-JHM) (34, 35). In the modelused in those experiments, suckling B6 mice were infected intranasallywith MHV-JHM at 10 days of age. To prevent the fatal acute encephalitis,pups were nursed by dams previously immunized against the virus.Mice infected with wild-type MHV-JHM remained asymptomatic duringthe early stages of the disease process, but 40 to 90% developeda chronic demyelinating disease with clinical signs of hind limbparalysis several weeks after inoculation (33). Virus was readilyisolated from symptomatic mice but not from those that remainedasymptomatic (33). Previously, we and others showed that twoCD8 T-cell epitopes within the surface (S) glycoprotein of thevirus were recognized by CTLs in B6 mice (2, 7). The moreimmunodominant of the two, encompassing amino acids 510 to 518of the S glycoprotein (S-510-518 [CSLWNG PHL]), was mutated innearly all samples of virus isolated from symptomatic mice (34).Epitope S-510-518 is encoded by a region of the S gene prone todeletion and single-base mutation (1, 7, 31, 40), andthis may enhance the likelihood of development of CTL escape mutants.Mutations in residues 2 to 7 of the epitope have been detected,although only a single nucleotide change was usually present inthe RNA isolated from an individual animal (34, 35). Thesemutations abrogated recognition by CTLs isolated from the centralnervous systems (CNS) of MHV-infected mice and assayed in directex vivo cytotoxicity assays (34). Mutations were not detectedin the RNA encoding the less dominant CTL epitope encompassingresidues 598 to 605 of the S glycoprotein (S-598-605 [RCQI F ANI])or in the RNA flanking either of these epitopes. Mutations aroseat early times after infection and were only rarely detected inmice that did not develop clinical disease (34, 35). Fromthese results, we concluded that the development of CTL escapemutants was necessary but not sufficient for the expression ofclinical disease in B6 mice.

Although antiviral CD8 T cells are critical for clearance of MHV (11, 15, 46) and variant virus was most likely selectedby escape from the immune response, it was not possible to determinedefinitively from those experiments whether CTL escape variantscontributed to virus persistence or arose as a consequence ofpersistence. If CTL escape mutants are a major factor in viruspersistence, infection of naive mice with MHV-JHM mutated in epitopeS-510-518 (variant virus) under the same experimental conditionsas described above could change the balance between the pathogenand host and thereby provides an excellent model for determiningwhether infection with CTL escape mutants can cause more rapiddisease progression and a worse outcome.

	MATERIALS AND METHODS

Top Abstract Introduction Materials & Methods Results Discussion References

Animals. MHV-seronegative 5- or 6-week-old B6 and BALB/c mice were purchased from Jackson Laboratories (Bar Harbor, Maine) and HarlanSprague Dawley (Indianapolis, Ind.). Mice were inoculated intranasallywith 4 × 10⁴ PFU of wild-type or variant virus. Animals were monitored dailyfor clinical disease, and weights were determined every 4 to 6days until sacrifice.

Cells. BALB/c 17Cl-1 cells were grown in Dulbecco modified Eagle medium supplemented with 5% fetal calf serum, 5% tryptose phosphate,and antibiotics. EL-4 (H-2^b) and MC57 (H-2^b) cells were grown in RPMI medium supplemented with 10% fetalcalf serum and antibiotics.

Viruses. MHV-JHM, used in all studies, was grown and titers were determined as previously described (33). MHV-JHM with mutationsin epitope S-510-518 was harvested from chronically infected brainsand spinal cords. Virus was plaque purified twice, and largeramounts were prepared by growth in 17Cl-1 cells. The presenceof the desired mutations in S-510-518 was confirmed by sequencingas previously described (34). No mutations were detected inepitope S-598-605 or in the 200 nucleotides surrounding eitherepitope (34). Virus titers from infected brains and spinal cordswere determined as previously described (33).

Recombinant vaccinia virus (VV) expressing the nucleocapsid (N) (VV-N), transmembrane (M) (VV-M), and S (VV-S) glycoproteinswere constructed as described previously (28). A recombinantVV expressing the small membrane protein (E) (VV-E) was providedby J. Leibowitz, Texas A&M University. The N, M, and S genes werecloned behind the T7 promoter and required coinfection with vTF7.3(kindly provided by B. Moss, National Institutes of Health) toprovide T7 RNA polymerase. The E gene was under the control ofan early-late VV promoter.

Isolation of mononuclear cells from the CNS. Cells were isolated from the CNS of B6 mice as previously described (6). In brief, mice were perfused with phosphate-bufferedsaline, and brains were removed. Tissue was ground between frostedglass slides and triturated by vigorous pipetting in 5 ml of RPMImedium with 10% fetal calf serum. Following thorough dispersionof the tissue, Percoll (Pharmacia, Uppsala, Sweden) was addedto a final concentration of 30%. The lysate was spun at 1,300× g for 30 min at 4°C. The Percoll and lipid layers were aspirated,the cell pellet was washed twice, and the cells were counted.

Direct ex vivo cytoxicity assays with CNS-derived lymphocytes. Mononuclear cells were harvested from the brains of B6 mice acutely infected with variant virus and analyzed in direct exvivo cytotoxicity assays with EL-4 cells coated with the indicatedpeptides at a final concentration of 1 µM as previously described(7). The effector-to-target cell ratio was 50:1. Spontaneousrelease was <14%.

Histology and immunohistochemistry. Mice were perfused with phosphate-buffered saline, and the brains and spinal cords were fixed in formalin prior to being embeddedin paraffin. For histological examination, sections were cut,processed, and stained with luxol fast blue in order to detectareas of demyelination. For detection of viral antigen, sectionswere prepared, processed, and reacted with mouse monoclonal anti-MHV-JHMantibody (anti-N antibody 5B188.2, kindly provided by M. Buchmeier,Scripps Research Institute) as previously described (42). Afterincubation with primary antibodies, samples were incubated withbiotinylated goat antimouse antibody (Jackson Immunoresearch Labs,West Grove, Pa.). Sections were then treated with avidin-conjugatedhorseradish peroxidase (Jackson Immunoresearch Labs), with 3,3'-diaminobenizidineas the final substrate. No staining was observed if CNS tissuefrom uninfected animals was processed with antibody to MHV-JHMor if irrelevant antibody was used as the primary antibody inthe analysis of MHV-infected tissue.

Analysis of RNA by blot hybridization. RNA was isolated from infected brains and spinal cords by the guanidinium isothiocyanate-cesium chloride method and analyzedby slot blot hybridization as previously described (32). Serialdilutions of each sample were analyzed, and radioactivity wascounted by using a radioanalytic imaging detector (AMBIS [SanDiego, Calif.] 4000). An average counts per minute per microgramwas calculated for each RNA sample.

IFN- $gamma$ ELISPOT assays. Gamma interferon (IFN- $gamma$ ) enzyme-linked immunospot (ELISPOT) assays were performed as described previously (48). Briefly,Immulon MaxiSorp plates (Nunc, Kamstrup, Denmark) were coatedwith 2 µg of anti-IFN- $gamma$ antibody (rat monoclonal R4-6A2; Pharmingen,San Diego, Calif.) per ml in 0.05 M carbonate buffer, pH 8.2.For antigen presentation, MC57 cells were either infected withVV-E or vTF7.3 or dually infected with vTF7.3 and VV-S, VV-N,or VV-M. MC57 cells express major histocompatibility complex (MHC)class I but not class II antigen and are useful stimulators fordetermining antigen-specific IFN- $gamma$ secretion by CD8 T cells. Previously,we showed by complement lysis prior to CTL assay that CD8 andnot CD4 T cells responded to antigen presented by these cells(6). In each case, virus was used at a multiplicity of infectionof 3. Mononuclear cells harvested from wild-type MHV-JHM- or variantMHV-JHM-infected mouse brains (2,500 to 50,000 cells/well) weremixed with irradiated, VV-infected MC57 cells and incubated for36 h. ELISPOTs were developed by addition of polyclonal rabbitanti-mouse IFN- $gamma$ (kindly provided by J. Cowdery, University ofIowa). Following a 16-h incubation, samples were developed bysequential addition of alkaline phosphatase-conjugated donkeyanti-rabbit immunoglobulin G (Jackson Immunoresearch Labs) andsubstrate (5-bromo-4-chloro-3-indoyl phosphate [Sigma, St. Louis,Mo.]) dissolved in 3% agarose in a phosphate-accepting 2-amino-2-methyl-1-propanolbuffer prepared as previously described (41). ELISPOT-formingcells were directly counted under ×10 magnification with a dissectingmicroscope. Samples were analyzed by linear regression, and resultswere expressed as numbers of ELISPOTs per 100,000 cells.

Statistical analysis. Statistical significance was determined as described in the figure legends. Analysis was performed with the help of the BiostatisticsCore Facility at the University of Iowa.

	RESULTS

Top Abstract Introduction Materials & Methods Results Discussion References

Infection with variant virus results in increased mortality and decreased growth. Virus mutated in epitope S-510-518 was isolated from four individual mice and prepared as described in Materials and Methods.The four isolates chosen for further study were mutated eitherin residues previously identified as the major or auxiliary anchorsfor binding to the MHC H-2D^b molecule (CSLWSGPHL and CSRWNGPHL) or in a residue predictedto affect binding to the T-cell receptor (CSL W N R PHL) (17)or contained a three-nucleotide deletion (ECF W N G PHL). Thesemutations did not affect the ability of the virus to cause acuteencephalitis in naive 6-week-old B6 mice (reference 32 and datanot shown). Variant epitope S-510-518 was recognized only at highconcentrations in CTL assays with lymphocytes derived from theCNS of mice with encephalitis caused by wild-type MHV-JHM (34).Acute infection with variant virus did not induce a CD8 T-cellresponse against either wild-type or variant epitope S-510-518in direct ex vivo cytotoxicity assays with CNS-derived lymphocytes.As expected, epitope S-598-605, which is not mutated in variantvirus, was still recognized in these assays (Fig. 1).

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FIG. 1. Recognition of epitope S-598-605 (RCQIFANI) but not wild-type (CSLWNGPHL) or variant (CSLWSGPHL, CSLWNRPHL, and ECFWNGPHL) S-510-518 epitopes in mice infected with variant virus. Lymphocytes harvested from the brains of mice with acute encephalitis were used in direct ex vivo cytotoxicity assays. Only peptide S-598-605 sensitized EL-4 cells for lysis above the background level (uncoated EL-4 cells [NONE]). Each peptide was analyzed in 3 to 14 independent experiments. The mean percent specific lysis for all experiments is shown. Bars show standard errors.

Next, the effect of these mutations on the ability of virus to persist was determined by infecting suckling mice nursed bydams immunized against MHV-JHM. Half of each litter was inoculatedwith wild-type virus and the other half was inoculated with variantvirus to control for variability in the amount of protective antibodytransmitted to the suckling mice. In preliminary experiments,we observed that mice infected with variant virus were often deador moribund by 20 to 25 days postinoculation (p.i.). At this time,mice infected with wild-type virus are usually asymptomatic, althougha few start to develop signs of hind limb paralysis. Therefore,to simplify the experimental design, all surviving mice, whethersymptomatic or not, were sacrificed at 21 days p.i., and brainsand spinal cords were analyzed for the presence of infectiousvirus or viral RNA and protein. In other models of MHV-induceddisease, infectious virus is cleared by this time after inoculation(15, 16, 20, 21, 34).

By 21 days p.i., significantly more mice infected with variant virus (38%) than mice infected with wild-type virus (9%) haddied (Fig. 2A; Table 1). In addition, more of the variant virus-infectedmice that survived to 21 days were symptomatic, with clinicalsigns of jitteriness, hind limb paresis, abnormal gait, and poorweight gain (Table 1). Pooled data for all of the mice infectedwith variant virus as well as data for mice infected with eachvariant virus are shown in Table 1. The weight gain for naivemice infected with wild-type or variant virus at 10 days of lifeis shown in Fig. 2B. Differences in growth became most apparentat 16 to 18 days p.i. By day 20, surviving mice infected withvariant virus weighted 15% less than mice infected with wild-typevirus (11.1 versus 13.0 g). As described above, this is the approximatetime frame for virus clearance in other models of MHV-inducedneurological disease, and differences would be evident at thistime point if virus was cleared less efficiently in variant virus-infectedmice.

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FIG. 2. Infection with variant virus results in increased mortality and morbidity. Suckling B6 mice were infected with wild-type MHV-JHM (45 mice) or variant virus (55 mice [17, 23, and 15 mice with virus encoding epitopes CSLWSGPHL, CSLWNRPHL, and ECFWNGPHL, respectively]). Also, suckling BALB/c mice were infected with wild-type virus (8 mice) or variant virus (11 mice [3 and 8 mice with virus encoding epitopes CSLWNRPHL and ECFWNGPHL, respectively]). Mice were nursed by dams previously immunized against MHV-JHM as described previously (33). All surviving mice were harvested at 21 days p.i. (A) Mice were monitored daily for mortality. The difference in survival between the two groups of B6 mice as analyzed by an accelerated-failure-time regression model with Weibull residual was statistically significant (P = 0.0069). (B) The same groups of mice were weighed every 4 to 6 days. Mean weights ± standard errors are shown. The pattern of weight gain diverged significantly (P $<=$ 0.0001) between the two groups of B6 mice as determined by a mixed-model analysis of variance.

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TABLE 1. Summary of mortality and morbidity after infection with wild-type and variant MHV-JHM^a

These differences in outcome occurred only in mice containing the MHC H-2D^b allele. When the same experimental approach was used with BALB/cmice (H-2^d), no difference in mortality or growth between mice infectedwith wild-type and variant viruses was observed (Fig. 2). Lowlevels of infectious virus could be isolated from the spinal cordsof the same fraction of mice infected with either type of virus(4 of 8 mice infected with wild-type virus [geometric mean titer± standard error = 2.73 ± 0.21] and 5 of 11 mice infected withvariant virus [geometric mean titer ± standard error = 3.22 ±0.17]).

Mice infected with variant virus develop a demyelinating encephalomyelitis. The hallmark of MHV-JHM-induced neurological disease is demyelination with concomitant inflammatory infiltration. To determineif similar pathological findings could be demonstrated in theCNS of mice infected with variant virus, brains and spinal cordswere harvested and examined after staining for myelin with luxolfast blue. Large areas of demyelination were detected in the spinalcords of these animals, with extensive inflammatory infiltratespresent in the vicinity of these lesions (Fig. 3A). Viral antigenwas present in the white matter in areas with early signs of demyelination(Fig. 3B) and adjacent to regions of demyelination. Viral antigenwas detected predominantly in the white matter, but a few MHV-positivecells were also identified in the gray matter of the spinal cord.These findings are indistinguishable from what is observed inmice with demyelination induced by wild-type virus and show thatpersistence of variant virus results in the same disease as occursin mice infected with wild-type virus but in a higher percentageof animals and at earlier times p.i.

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FIG. 3. Infection with variant MHV-JHM results in a demyelinating encephalomyelitis. The brain and spinal cord from a mouse infected with virus encoding variant epitope CSLWSGPHL were harvested at 21 days p.i. The sample was fixed in formalin and embedded in paraffin. (A) Five-micrometer sections were cut, processed, and stained with luxol fast blue in order to detect areas of demyelination. (B) Sections (5 to 10 µm) were prepared and analyzed for viral antigen by using antibody to the N protein as described in Materials and Methods. Sections were lightly stained with hematoxylin after processing. Viral antigen (asterisks) is detected in the white matter adjacent to an area of demyelination. Bar, 100 µm (A) and 50 µm (B).

Virus is cleared more slowly in mice infected with variant virus. The most likely explanation for these results is that variant MHV-JHM, which no longer encodes the immunodominant CTL epitope,is not cleared as efficiently as is wild-type virus. To determineif the increased mortality and morbidity described above correlatedwith a decrease in MHV clearance, virus titers in brains and spinalcords were measured at 21 days p.i. As shown in Table 2, viruswas detected in the brains and the spinal cords of 48 and 74%,respectively, of mice infected with variant virus but in only19 and 30%, respectively, of brains and spinal cords harvestedfrom wild-type-infected mice. When only mice in which infectiousvirus could be detected were further analyzed, there were no significantdifferences in the titers of virus in the brain or spinal cordbetween mice infected with wild-type and variant viruses (Table2).

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TABLE 2. Virus titers in mice surviving to 21 days p.i.^a

MHV-JHM shows a specific tropism for the CNS, but other closely related strains of MHV, such as MHV-A59, also infect the liver.To determine if the loss of epitope S-510-518 changed viral tropism,livers, lungs, kidneys, and hearts were assayed for infectiousvirus. No virus could be detected in any of these organs fromthree moribund variant virus-infected mice harvested at 21 daysp.i.

Although the presence of infectious virus is the best measure of virus persistence, high-level expression of viral RNA andprotein in the absence of infectious virus could also result inclinical and pathological disease. This occurs in human patientswith subacute sclerosing panencephalitis caused by a persistentmeasles virus infection (13). To determine if high levels ofviral RNA could be detected in MHV-infected mice in the absenceof infectious virus, viral RNA in the spinal cord was quantitatedby slot blot analysis and compared to the virus titer in 29 animals.As shown in Fig. 4, mice with higher titers of infectious virusin general had higher levels of viral RNA, indicating that thepresence of virus correlated with the viral burden in these animals.Some mice with detectable infectious virus had low levels of viralRNA, but in no animals were high levels of viral RNA detectedin the absence of infectious virus. This correlation was truefor mice infected with either wild-type or variant virus. Theseresults show that the detection of infectious virus was a validmeasure of virus persistence in these MHV-infected mice.

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FIG. 4. Levels of infectious virus and viral RNA in the spinal cords of infected mice are correlated. Levels of infectious virus and viral RNA were measured as described in Materials and Methods. Fifteen mice infected with wild-type MHV-JHM, six mice infected with the epitope CSLWSGPHL variant, and eight mice infected with the epitope ECFWNGPHL variant were used in these analyses. The limit of detection, 160 PFU/g of tissue, is indicated by the horizontal line. Infectious virus could not be detected in 14 mice (shown as a single square below the line of detection). Each sample of RNA was analyzed in two independent experiments, and the average of the two is shown. RNA levels were quantitated by using a radioanalytic imaging system. The RNA level in the sample marked with an asterisk was 4.49 × 10⁴ cpm/µg.

No additional CTL epitopes are recognized in mice infected with variant virus. In humans infected with HIV-1, additional CTL epitopes are recognized after selection of mutations at a dominant CTL epitopeoccurs (25). Similarly, CTLs from mice infected with lymphocyticchoriomenigitis virus in which all three CTL epitopes are mutatedrecognize a novel CTL epitope (23). To determine if additionalCTL epitopes were recognized in mice infected with variant MHV-JHM,CNS-derived lymphocytes from mice with acute encephalitis wereanalyzed in direct ex vivo assays with target cells infected withrecombinant VV expressing the four MHV structural proteins (S,N, M, or E). Samples were analyzed both for cytotoxicity and forIFN- $gamma$ secretory activity by using an ELISPOT assay. With bothassays, only the S glycoprotein was recognized in mice infectedwith variant virus. The data for the IFN- $gamma$ ELISPOT assay are shownin Fig. 5. To determine further if additional epitopes were recognizedby cells harvested from these mice, a panel of S-specific peptidesmatching the consensus motif for binding to the H-2D^b and H-2K^b molecules (7) was analyzed in IFN- $gamma$ ELISPOT assays. In theseassays, only S-598-605 stimulated cells to secrete IFN- $gamma$ (datanot shown). These data suggest that no novel CTL epitopes arerecognized in mice infected with variant virus.

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FIG. 5. IFN- $gamma$ secretion in response to VV-expressed MHV proteins by lymphocytes isolated from brains of mice with MHV-induced acute encephalitis. Four mice infected with wild-type MHV-JHM (A) and six mice infected with variant virus (four with the epitope CSRWNGPHL variant and two with the epitope CSLWSGPHL variant) (B) were used in these studies. The number of IFN- $gamma$ -secreting cells was determined by an ELISPOT assay as described in Materials and Methods. VV-infected MC57 cells expressing T7 RNA polymerase alone (T7) were used as a negative control for VV-infected MC57 cells expressing viral S, M, N, or E proteins. The data shown are the mean number of IFN- $gamma$ -secreting spots per 100,000 cells and standard error for each sample.

Mutations in epitope S-598-605 are not selected in mice persistently infected with variant virus. Mutations in epitope S-510-518 but not epitope S-598-605 are selected in mice persistently infected with wild-type MHV-JHM.Since only S-598-605 is recognized by CTLs in mice acutely infectedwith variant virus and this epitope is also located in the hypervariableregion of the S protein (7, 13, 31), it was possible thatmutations in this epitope could be selected in persistently infectedmice. To determine if such mutations were selected, infectiousvirus was isolated from six mice infected with variant virus (twoeach with CSLWSGPHL, CSLWNRPHL, and ECFWNGPHL), and the regionencompassing this epitope was sequenced as described previously(34). Only wild-type sequence was detected, showing that furtherescape from CTL surveillance did not occur in these mice. As expected,sequence analysis of the RNA encompassing epitope S-510-518 revealedthe presence of neither additional mutations nor reversion towild-type sequence.

Above, we showed that low levels of infectious virus could be isolated at 21 days p.i. from BALB/c mice infected with wild-typeor variant virus. In these mice, mutated epitope S-510-518 shouldconfer no selective advantage, and reversion to the wild-typesequence would be predicted to occur. However, sequence analysisof virus isolated from five BALB/c mice infected with variantvirus revealed the presence of only mutated epitope S-510-518,suggesting that, in fact, virus containing wild-type epitope S-510-518did not have a significant selective advantage.

	DISCUSSION

Top Abstract Introduction Materials & Methods Results Discussion References

The unique finding in the present study is a clear demonstration of increased mortality and morbidity attributable to theloss of CTL recognition. MHV-JHM is a virulent strain of virusthat causes a fatal acute encephalitis in the absence of experimentalintervention (e.g., infection with attenuated virus or passiveinfusion of antiviral antibodies or T cells [16, 21]). Thedemyelinating disease observed in survivors is, in large part,immune mediated (15, 44). Thus, the outcome of a given infectionis determined by the balance between the viral infection and thehost immune response. Infection with MHV-JHM mutated in epitopeS-510-518, which is able to avoid the dominant CTL response inB6 mice, decreases the kinetics of virus clearance and therebychanges the balance between the virus and the host and, consequently,the outcome of the infection. These results are consistent withour previous studies showing that the outgrowth of CTL escapemutants correlated with virus amplification and the developmentof clinical disease after infection with wild-type virus (34).

Of note is that the mechanism of MHV-induced demyelination has not been completely determined. Both CD4 and CD8 T cells arebelieved to be effector cells in this process (15, 16), andif MHV-induced demyelination is similar to that caused by Theiler'sencephalomyelitis virus, CD4 T cells are most important (26,43). Also, CD8 T cells recognizing epitope S-598-605 were detectedin variant virus-infected mice (Fig. 1). Thus, it is not surprisingthat demyelination occurs to the same extent in mice infectedwith wild-type virus and with virus lacking the immunodominantCD8 T-cell epitope.

Although the presence of CTL escape mutants has been clearly demonstrated in previous studies, it has been difficult to demonstratetheir biological significance. First, CTL escape mutants havebeen demonstrated most commonly in viral infections of humans(19, 25). In most viral infections of humans, the CTL responseis polyclonal and not focused on a single epitope. A monospecificCTL response is relatively uncommon in a genetically diverse population,and by extension, the frequency of CTL mutants developing in alarge population is relatively low. However, such mutations havebeen reported. In New Guinea, a large fraction of the populationexpress the HLA-A11 allele, and Epstein-Barr virus isolated fromthis population is mutated in an amino acid critical for recognitionby virus-specific CTLs (9). Second, there is often a shiftto subdominant CTL epitopes after the CTL response to a dominantepitope is evaded (epitope spreading) (22, 27). This was recentlydemonstrated by Borrow et al. in a study of a patient acutelyinfected with HIV-1 in which CTL escape mutants arose very earlyafter infection (5). The virus load did not increase acutely,presumably because the response to new CTL epitopes was able tocontain the infection. The shift to subdominant epitopes may result,however, in less effective control of the infection (30), andin the patient reported by Borrow et al. (5), the responseto subdominant CTL epitopes was subsequently unable to preventdisease progression. Similarly, the response to epitope S-598-605is unable to control the infection in mice persistently infectedwith MHV-JHM (34). Of note is that we have been unable thusfar to detect a CTL response to any additional epitopes in miceinfected with variant virus (Fig. 5).

While mortality and morbidity are increased after infection with MHV mutated in epitope S-510-518, virus is still clearedin a minority of animals, and these mice remain asymptomatic.In marked contrast, when mice in which MHC class I function isdisrupted genetically [ $beta$ 2-microglobulin ( $-$ / $-$ ) mice] are infectedwith MHV in the model described above, no suckling mice survivethe acute encephalitis. This is true even when large amounts ofneutralizing antibody are delivered passively to each sucklingmouse (unpublished observations). In addition, $beta$ 2-microglobulin( $-$ / $-$ ) mice are very susceptible to infection with attenuated strainsof MHV-JHM and with the closely related strain MHV-A59 (11,15). Thus, the antiviral CD8 T-cell response is critical forvirus clearance.

In variant virus-infected mice that clear the infection, clearance may be mediated by CD8 T cells recognizing the less immunodominantCTL epitope, epitope S-598-605 (Fig. 1). Epitope S-598-605 isalso likely to be the target for antiviral CTLs in mice infectedwith MHV-A59, since epitope S-510-518 is deleted in this virus(7, 24, 31). Although the precursor frequency for CD8 Tcells recognizing S-598-605 in mice immunized with wild-type virusis similar to that for CD8 T cells recognizing epitope S-510-518(8), peptide S-598-605 is 50- to 200-fold less potent at sensitizingtargets for lysis (7). This relative lack of potency may explainwhy MHV mutated in epitope S-510-518 is able to persist in mostmice in the presence of a CTL response to epitope S-598-605. Thislack of potency may also explain why virus mutated in epitopeS-598-605 does not develop. CTL escape mutants develop peferentiallywhen the T-cell response is strong (10, 39), and the responseto the epitope may be too weak to select for viral mutants. Insupport of this, ex vivo proliferation of CTLs responsive to epitopeS-598-605 can be detected only when stimulators are coated withpeptide S-598-605 and not when antigen is presented endogenously(8), suggesting that the ligand density for these CTLs on mostcells is too low for recognition.

Alternatively, clearance of variant virus may be mediated by components of the immune system other than CD8 T cells. For example,anti-MHV cytotoxic CD4 T cells have been demonstrated in B6 miceinfected with MHV-A59 (14). Although antiviral cytotoxic CD4T cells have not been demonstrated in mice infected with MHV-JHM,these cells could well contribute to clearance in animals infectedwith variant virus.

	ACKNOWLEDGMENTS

We thank G. Wu, M. Dailey, J. Harty, and M. Stoltzfus for critical review of the manuscript.

This research was supported in part by grants from the National Institutes of Health (NS 36592) and from the National MultipleSclerosis Society (RG2864-A-2).

	FOOTNOTES

^* Corresponding author. Mailing address: Department of Pediatrics, University of Iowa, Medical Laboratories 2042, Iowa City,IA 52242. Phone: (319) 335-8549. Fax: (319) 335-8991. E-mail:Stanley-Perlman{at}uiowa.edu.

REFERENCES

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

1. Banner, L., J. G. Keck, and M. M. C. Lai. 1990. A clustering of RNA recombination sites adjacent to a hypervariable region of the peplomer gene of murine coronavirus. Virology 175:548-555[Medline].

2. Bergmann, C. C., Q. Yao, M. Lin, and S. A. Stohlman. 1996. The JHM strain of mouse hepatitis virus induces a spike protein-specific D^b-restricted CTL response. J. Gen. Virol. 77:315-325[Abstract/Free Full Text].

3. Bertoletti, A., A. Costanzo, F. V. Chisari, M. Levero, M. Artini, A. Sette, A. Penna, T. Giuberti, F. Fiaccadori, and C. Ferrari. 1994. Cytotoxic T lymphocyte response to a wild type hepatitis B virus epitope in patients chronically infected by variant viruses carrying substitutions within the epitope. J. Exp. Med. 180:933-943[Abstract/Free Full Text].

4. Bertoletti, A., A. Sette, F. V. Chisari, A. Penna, M. Levrero, M. De Carli, F. Fiaccadori, and C. Ferrari. 1994. Natural variants of cytotoxic epitopes are T-cell receptor antagonists for antiviral cytotoxic T cells. Nature 369:407-410[Medline].

5. Borrow, P., H. Lewicki, X. Wei, M. Horwitz, N. Peffer, H. Meyers, J. A. Nelson, J. Gairin, B. Hahn, M. B. A. Oldstone, and G. Shaw. 1997. Antiviral pressure exerted by HIV-1-specific cytotoxic T lymphocytes (CTLs) during primary infection demonstrated by rapid selection of CTL escape mutants. Nat. Med. 3:205-211[Medline].

6. Castro, R. F., G. D. Evans, A. Jaszewski, and S. Perlman. 1994. Coronavirus-induced demyelination occurs in the presence of virus-specific cytotoxic T cells. Virology 200:733-743[Medline].

7. Castro, R. F., and S. Perlman. 1995. CD8⁺ T-cell epitopes within the surface glycoprotein of a neurotropic coronavirus and correlation with pathogenicity. J. Virol. 69:8127-8131[Abstract].

8. Castro, R. F., and S. Perlman. 1996. Differential antigen recognition by T cells from the spleen and central nervous system of coronavirus-infected mice. Virology 222:247-251[Medline].

9. De Campos-Lima, P. O., V. Levitsky, J. Brooks, S. P. Lee, L. Hu, A. B. Rickinson, and M. G. Masucci. 1994. T cell responses and virus evolution: loss of HLA A11-restricted CTL epitopes in Epstein-Barr virus isolates from highly A11-positive populations by selective mutation of anchor residues. J. Exp. Med. 179:1297-1305[Abstract/Free Full Text].

10. Franco, A., C. Ferrari, A. Sette, and F. V. Chisari. 1995. Viral mutations, TCR antagonism and escape from the immune response. Curr. Opin. Immunol. 7:524-531[Medline].

11. Gombold, J., R. Sutherland, E. Lavi, Y. Paterson, and S. R. Weiss. 1995. Mouse hepatitis virus A59-induced demyelination can occur in the absence of CD8+ T cells. Microb. Pathog. 18:211-221[Medline].

12. Goulder, P., R. Phillips, R. Colbert, S. McAdam, G. Ogg, M. Nowak, P. Giangrande, G. Luzzi, B. Morgan, A. Edwards, A. J. McMichael, and S. Rowland-Jones. 1997. Late escape from an immunodominant cytotoxic T-lymphocyte response associated with progression to AIDS. Nat. Med. 3:212-217[Medline].

13. Hall, W., and P. W. Choppin. 1981. Measles-virus proteins in the brain tissue of patients with subacute sclerosing panencephalitis. N. Engl. J. Med. 304:1152-1155[Medline].

14. Heemskerk, M., H. Schoemaker, W. Spaan, and C. Boog. 1995. Predominance of MHC class II-restricted CD4⁺ cytotoxic T cells against mouse hepatitis virus A59. Immunology 84:521-527[Medline].

15. 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]

16. Houtman, J. J., and J. O. Fleming. 1996. Pathogenesis of mouse hepatitis virus-induced demyelination. J. Neurovirol. 2:361-376. [Medline]

17. Hudrisier, D., H. Mazarguil, M. B. A. Oldstone, and J. E. Gairin. 1995. Relative implication of peptide residues in binding to major histocompatibility complex class I H-2D^b: application to the design of high-affinity, allele-specific peptides. Mol. Immunol. 32:895-907[Medline].

18. Klenerman, P., S. Rowland-Jones, S. McAdam, J. Edwards, S. Daenke, D. Lalloo, B. Koppe, W. Rosenberg, D. Boyd, A. Edwards, P. Glangrande, R. E. Phillips, and A. J. McMichael. 1994. Cytotoxic T-cell activity antagonized by naturally occurring HIV-1 gag variants. Nature 369:403-407[Medline].

19. Koup, R. 1994. Virus escape from CTL recognition. J. Exp. Med. 180:779-782[Free Full Text].

20. Kyuwa, S., and S. A. Stohlman. 1990. Pathogenesis of a neurotropic murine coronavirus, strain JHM in the central nervous system of mice. Semin. Virol. 1:273-280.

21. Lane, T. E., and M. J. Buchmeier. 1997. Murine coronavirus infection: a paradigm for virus-induced demyelinating disease. Trends Microbiol. 5:9-14[Medline].

22. Lehmann, P., T. Forsthuber, A. Miller, and E. E. Sercarz. 1992. Spreading of T-cell autoimmunity to cryptic determinants of an autoantigen. Nature 358:155-157[Medline].

23. Lewicki, H., M. Von Herrath, C. Evans, J. L. Whitton, and M. Oldstone. 1995. CTL escape viral variants. II. Biologic activity in vivo. Virology 211:443-450[Medline].

24. Luytjes, W., L. S. Sturman, P. J. Bredenbeek, J. Charite, B. A. M. van der Zeijst, M. C. Horzinek, and W. J. M. Spaan. 1987. Primary structure of the glycoprotein E2 of coronavirus MHV-A59 and identification of the trypsin cleavage site. Virology 161:479-487[Medline].

25. McMichael, A. J., and R. E. Phillips. 1997. Escape of human immunodeficiency virus from immune control. Annu. Rev. Immunol. 15:271-296[Medline].

26. Miller, S. D., and W. J. Karpus. 1994. The immunopathogenesis and regulation of T-cell-mediated demyelinating diseases. Immunol. Today 15:356-361[Medline].

27. Miller, S. D., C. Vanderlugt, W. Begolka, W. Pao, R. Yauch, K. Neville, Y. Katz-Levy, A. Carrizosa, and B. Kim. 1997. Persistent infection with Theiler's virus leads to CNS autoimmunity via epitope spreading. Nat. Med. 3:1133-1136[Medline].

28. Mobley, J., G. Evans, M. O. Dailey, and S. Perlman. 1992. Immune response to a murine coronavirus: identification of a homing receptor-negative CD4⁺ T cell subset that responds to viral glycoproteins. Virology 187:443-452[Medline].

29. Moskophidis, D., and R. M. Zinkernagel. 1995. Immunobiology of cytotoxic T-cell escape mutants of lymphocytic choriomeningitis virus. J. Virol. 69:2187-2193[Abstract].

30. Nowak, M. A., R. M. May, R. E. Phillips, S. Rowland-Jones, D. G. Lalloo, S. McAdam, P. Klenerman, B. Koppe, K. Sigmund, C. R. M. Bangham, and A. J. McMichael. 1995. Antigenic oscillations and shifting immunodominance in HIV-1 infections. Nature 375:606-611[Medline].

31. Parker, S. E., T. M. Gallagher, and M. J. Buchmeier. 1989. Sequence analysis reveals extensive polymorphism and evidence of deletions within the E2 glycoprotein gene of several strains of murine hepatitis virus. Virology 173:664-673[Medline].

32. Perlman, S., G. Jacobsen, A. L. Olson, and A. Afifi. 1990. Identification of the spinal cord as a major site of persistence during chronic infection with a murine coronavirus. Virology 175:418-426[Medline].

33. Perlman, S., R. Schelper, E. Bolger, and D. Ries. 1987. Late onset, symptomatic, demyelinating encephalomyelitis in mice infected with MHV-JHM in the presence of maternal antibody. Microb. Pathog. 2:185-194[Medline].

34. Pewe, L., G. Wu, E. M. Barnett, R. Castro, and S. Perlman. 1996. Cytotoxic T cell-resistant variants are selected in a virus-induced demyelinating disease. Immunity 5:253-262[Medline].

35. Pewe, L., S. Xue, and S. Perlman. 1997. Cytotoxic T-cell-resistant variants arise at early times after infection in C57BL/6 but not in SCID mice infected with a neurotropic coronavirus. J. Virol. 71:7640-7647[Abstract].

36. Phillips, R. E., S. Rowland-Jones, D. F. Nixon, F. M. Gotch, J. P. Edwards, A. O. Ogunlesi, J. G. Elvin, J. A. Rothbard, C. R. M. Bangham, C. R. Rizza, and A. J. McMichael. 1991. Human immunodeficiency virus genetic variation that can escape cytotoxic T cell recognition. Nature 354:453-459[Medline].

37. Pircher, H., D. Moskophidis, U. Rohrer, K. Burki, H. Hengartner, and R. Zinkernagel. 1990. Viral escape by selection of cytotoxic T cell-resistant virus variants in vivo. Nature 346:629-633[Medline].

38. Price, D., P. Goulder, P. Klenerman, A. Sewell, P. Easterbrook, M. Troop, C. R. Bangham, and R. E. Phillips. 1997. Positive selection of HIV-1 cytotoxic T lymphocyte escape variants during primary infection. Proc. Natl. Acad. Sci. USA 94:1890-1895[Abstract/Free Full Text].

39. Rehermann, B., C. Pasquinelli, S. Mosier, and F. Chisari. 1995. Hepatitis B virus (HBV) sequence variation in cytotoxic T lymphocyte epitopes is not common in patients with chronic HBV infection. J. Clin. Invest. 96:1527-1534.

40. Rowe, C. L., S. C. Baker, M. J. Nathan, and J. O. Fleming. 1997. Evolution of mouse hepatitis virus: detection and characterization of S1 deletion variants during persistent infection. J. Virol. 71:2959-2967[Abstract].

41. Sedgwick, J. D., and P. G. Holt. 1983. A solid-phase immunoenzymatic technique for the enumeration of specific antibody-secreting cells. J. Immunol. Methods 57:301-309[Medline].

42. Sun, N., D. Grzybicki, R. Castro, S. Murphy, and S. Perlman. 1995. Activation of astrocytes in the spinal cord of mice chronically infected with a neurotropic coronavirus. Virology 213:482-493[Medline].

43. Tsunoda, I., and R. S. Fujinami. 1996. Two models of multiple sclerosis: experimental allergic encephalomyelitis and Theiler's murine encephalomyelitis virus. J. Neuropathol. Exp. Neurol. 55:672-686.

44. Wang, F., S. A. Stohlman, and J. O. Fleming. 1990. Demyelination induced by murine hepatitis virus JHM strain (MHV-4) is immunologically mediated. J. Neuroimmunol. 30:31-41[Medline].

45. Weiner, A., A. Erickson, J. Kanospon, K. Crawford, E. Muchmore, A. Hughes, M. Houghton, and C. M. Walker. 1995. Persistent hepatitis C virus infection in a chimpanzee is associated with emergence of a cytotoxic T lymphocyte escape variant. Proc. Natl. Acad. Sci. USA 92:2755-2759[Abstract/Free Full Text].

46. Williamson, J. S., and S. A. Stohlman. 1990. Effective clearance of mouse hepatitis virus from the central nervous system requires both CD4⁺ and CD8⁺ T cells. J. Virol. 64:4589-4592[Abstract/Free Full Text].

47. Wolinsky, S. M., B. Korber, A. U. Neumann, M. Daniels, K. Kunstman, A. Whetsell, M. Furtado, Y. Cao, D. Ho, J. Safrit, and R. Koup. 1996. Adaptive evolution of human immunodeficiency virus-type 1 during the natural course of infection. Science 272:537-542[Abstract].

48. Xue, S., and S. Perlman. 1997. Antigen specificity of CD4 T cell response in the central nervous system of mice infected with mouse hepatitis virus. Virology 238:68-78[Medline].

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1.	Banner, L., J. G. Keck, and M. M. C. Lai. 1990. A clustering of RNA recombination sites adjacent to a hypervariable region of the peplomer gene of murine coronavirus. Virology 175:548-555[Medline].
2.	Bergmann, C. C., Q. Yao, M. Lin, and S. A. Stohlman. 1996. The JHM strain of mouse hepatitis virus induces a spike protein-specific D^b-restricted CTL response. J. Gen. Virol. 77:315-325[Abstract/Free Full Text].
3.	Bertoletti, A., A. Costanzo, F. V. Chisari, M. Levero, M. Artini, A. Sette, A. Penna, T. Giuberti, F. Fiaccadori, and C. Ferrari. 1994. Cytotoxic T lymphocyte response to a wild type hepatitis B virus epitope in patients chronically infected by variant viruses carrying substitutions within the epitope. J. Exp. Med. 180:933-943[Abstract/Free Full Text].
4.	Bertoletti, A., A. Sette, F. V. Chisari, A. Penna, M. Levrero, M. De Carli, F. Fiaccadori, and C. Ferrari. 1994. Natural variants of cytotoxic epitopes are T-cell receptor antagonists for antiviral cytotoxic T cells. Nature 369:407-410[Medline].
5.	Borrow, P., H. Lewicki, X. Wei, M. Horwitz, N. Peffer, H. Meyers, J. A. Nelson, J. Gairin, B. Hahn, M. B. A. Oldstone, and G. Shaw. 1997. Antiviral pressure exerted by HIV-1-specific cytotoxic T lymphocytes (CTLs) during primary infection demonstrated by rapid selection of CTL escape mutants. Nat. Med. 3:205-211[Medline].
6.	Castro, R. F., G. D. Evans, A. Jaszewski, and S. Perlman. 1994. Coronavirus-induced demyelination occurs in the presence of virus-specific cytotoxic T cells. Virology 200:733-743[Medline].
7.	Castro, R. F., and S. Perlman. 1995. CD8⁺ T-cell epitopes within the surface glycoprotein of a neurotropic coronavirus and correlation with pathogenicity. J. Virol. 69:8127-8131[Abstract].
8.	Castro, R. F., and S. Perlman. 1996. Differential antigen recognition by T cells from the spleen and central nervous system of coronavirus-infected mice. Virology 222:247-251[Medline].
9.	De Campos-Lima, P. O., V. Levitsky, J. Brooks, S. P. Lee, L. Hu, A. B. Rickinson, and M. G. Masucci. 1994. T cell responses and virus evolution: loss of HLA A11-restricted CTL epitopes in Epstein-Barr virus isolates from highly A11-positive populations by selective mutation of anchor residues. J. Exp. Med. 179:1297-1305[Abstract/Free Full Text].
10.	Franco, A., C. Ferrari, A. Sette, and F. V. Chisari. 1995. Viral mutations, TCR antagonism and escape from the immune response. Curr. Opin. Immunol. 7:524-531[Medline].
11.	Gombold, J., R. Sutherland, E. Lavi, Y. Paterson, and S. R. Weiss. 1995. Mouse hepatitis virus A59-induced demyelination can occur in the absence of CD8+ T cells. Microb. Pathog. 18:211-221[Medline].
12.	Goulder, P., R. Phillips, R. Colbert, S. McAdam, G. Ogg, M. Nowak, P. Giangrande, G. Luzzi, B. Morgan, A. Edwards, A. J. McMichael, and S. Rowland-Jones. 1997. Late escape from an immunodominant cytotoxic T-lymphocyte response associated with progression to AIDS. Nat. Med. 3:212-217[Medline].
13.	Hall, W., and P. W. Choppin. 1981. Measles-virus proteins in the brain tissue of patients with subacute sclerosing panencephalitis. N. Engl. J. Med. 304:1152-1155[Medline].
14.	Heemskerk, M., H. Schoemaker, W. Spaan, and C. Boog. 1995. Predominance of MHC class II-restricted CD4⁺ cytotoxic T cells against mouse hepatitis virus A59. Immunology 84:521-527[Medline].
15.	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]
16.	Houtman, J. J., and J. O. Fleming. 1996. Pathogenesis of mouse hepatitis virus-induced demyelination. J. Neurovirol. 2:361-376. [Medline]
17.	Hudrisier, D., H. Mazarguil, M. B. A. Oldstone, and J. E. Gairin. 1995. Relative implication of peptide residues in binding to major histocompatibility complex class I H-2D^b: application to the design of high-affinity, allele-specific peptides. Mol. Immunol. 32:895-907[Medline].
18.	Klenerman, P., S. Rowland-Jones, S. McAdam, J. Edwards, S. Daenke, D. Lalloo, B. Koppe, W. Rosenberg, D. Boyd, A. Edwards, P. Glangrande, R. E. Phillips, and A. J. McMichael. 1994. Cytotoxic T-cell activity antagonized by naturally occurring HIV-1 gag variants. Nature 369:403-407[Medline].
19.	Koup, R. 1994. Virus escape from CTL recognition. J. Exp. Med. 180:779-782[Free Full Text].
20.	Kyuwa, S., and S. A. Stohlman. 1990. Pathogenesis of a neurotropic murine coronavirus, strain JHM in the central nervous system of mice. Semin. Virol. 1:273-280.
21.	Lane, T. E., and M. J. Buchmeier. 1997. Murine coronavirus infection: a paradigm for virus-induced demyelinating disease. Trends Microbiol. 5:9-14[Medline].
22.	Lehmann, P., T. Forsthuber, A. Miller, and E. E. Sercarz. 1992. Spreading of T-cell autoimmunity to cryptic determinants of an autoantigen. Nature 358:155-157[Medline].
23.	Lewicki, H., M. Von Herrath, C. Evans, J. L. Whitton, and M. Oldstone. 1995. CTL escape viral variants. II. Biologic activity in vivo. Virology 211:443-450[Medline].
24.	Luytjes, W., L. S. Sturman, P. J. Bredenbeek, J. Charite, B. A. M. van der Zeijst, M. C. Horzinek, and W. J. M. Spaan. 1987. Primary structure of the glycoprotein E2 of coronavirus MHV-A59 and identification of the trypsin cleavage site. Virology 161:479-487[Medline].
25.	McMichael, A. J., and R. E. Phillips. 1997. Escape of human immunodeficiency virus from immune control. Annu. Rev. Immunol. 15:271-296[Medline].
26.	Miller, S. D., and W. J. Karpus. 1994. The immunopathogenesis and regulation of T-cell-mediated demyelinating diseases. Immunol. Today 15:356-361[Medline].
27.	Miller, S. D., C. Vanderlugt, W. Begolka, W. Pao, R. Yauch, K. Neville, Y. Katz-Levy, A. Carrizosa, and B. Kim. 1997. Persistent infection with Theiler's virus leads to CNS autoimmunity via epitope spreading. Nat. Med. 3:1133-1136[Medline].
28.	Mobley, J., G. Evans, M. O. Dailey, and S. Perlman. 1992. Immune response to a murine coronavirus: identification of a homing receptor-negative CD4⁺ T cell subset that responds to viral glycoproteins. Virology 187:443-452[Medline].
29.	Moskophidis, D., and R. M. Zinkernagel. 1995. Immunobiology of cytotoxic T-cell escape mutants of lymphocytic choriomeningitis virus. J. Virol. 69:2187-2193[Abstract].
30.	Nowak, M. A., R. M. May, R. E. Phillips, S. Rowland-Jones, D. G. Lalloo, S. McAdam, P. Klenerman, B. Koppe, K. Sigmund, C. R. M. Bangham, and A. J. McMichael. 1995. Antigenic oscillations and shifting immunodominance in HIV-1 infections. Nature 375:606-611[Medline].
31.	Parker, S. E., T. M. Gallagher, and M. J. Buchmeier. 1989. Sequence analysis reveals extensive polymorphism and evidence of deletions within the E2 glycoprotein gene of several strains of murine hepatitis virus. Virology 173:664-673[Medline].
32.	Perlman, S., G. Jacobsen, A. L. Olson, and A. Afifi. 1990. Identification of the spinal cord as a major site of persistence during chronic infection with a murine coronavirus. Virology 175:418-426[Medline].
33.	Perlman, S., R. Schelper, E. Bolger, and D. Ries. 1987. Late onset, symptomatic, demyelinating encephalomyelitis in mice infected with MHV-JHM in the presence of maternal antibody. Microb. Pathog. 2:185-194[Medline].
34.	Pewe, L., G. Wu, E. M. Barnett, R. Castro, and S. Perlman. 1996. Cytotoxic T cell-resistant variants are selected in a virus-induced demyelinating disease. Immunity 5:253-262[Medline].
35.	Pewe, L., S. Xue, and S. Perlman. 1997. Cytotoxic T-cell-resistant variants arise at early times after infection in C57BL/6 but not in SCID mice infected with a neurotropic coronavirus. J. Virol. 71:7640-7647[Abstract].
36.	Phillips, R. E., S. Rowland-Jones, D. F. Nixon, F. M. Gotch, J. P. Edwards, A. O. Ogunlesi, J. G. Elvin, J. A. Rothbard, C. R. M. Bangham, C. R. Rizza, and A. J. McMichael. 1991. Human immunodeficiency virus genetic variation that can escape cytotoxic T cell recognition. Nature 354:453-459[Medline].
37.	Pircher, H., D. Moskophidis, U. Rohrer, K. Burki, H. Hengartner, and R. Zinkernagel. 1990. Viral escape by selection of cytotoxic T cell-resistant virus variants in vivo. Nature 346:629-633[Medline].
38.	Price, D., P. Goulder, P. Klenerman, A. Sewell, P. Easterbrook, M. Troop, C. R. Bangham, and R. E. Phillips. 1997. Positive selection of HIV-1 cytotoxic T lymphocyte escape variants during primary infection. Proc. Natl. Acad. Sci. USA 94:1890-1895[Abstract/Free Full Text].
39.	Rehermann, B., C. Pasquinelli, S. Mosier, and F. Chisari. 1995. Hepatitis B virus (HBV) sequence variation in cytotoxic T lymphocyte epitopes is not common in patients with chronic HBV infection. J. Clin. Invest. 96:1527-1534.
40.	Rowe, C. L., S. C. Baker, M. J. Nathan, and J. O. Fleming. 1997. Evolution of mouse hepatitis virus: detection and characterization of S1 deletion variants during persistent infection. J. Virol. 71:2959-2967[Abstract].
41.	Sedgwick, J. D., and P. G. Holt. 1983. A solid-phase immunoenzymatic technique for the enumeration of specific antibody-secreting cells. J. Immunol. Methods 57:301-309[Medline].
42.	Sun, N., D. Grzybicki, R. Castro, S. Murphy, and S. Perlman. 1995. Activation of astrocytes in the spinal cord of mice chronically infected with a neurotropic coronavirus. Virology 213:482-493[Medline].
43.	Tsunoda, I., and R. S. Fujinami. 1996. Two models of multiple sclerosis: experimental allergic encephalomyelitis and Theiler's murine encephalomyelitis virus. J. Neuropathol. Exp. Neurol. 55:672-686.
44.	Wang, F., S. A. Stohlman, and J. O. Fleming. 1990. Demyelination induced by murine hepatitis virus JHM strain (MHV-4) is immunologically mediated. J. Neuroimmunol. 30:31-41[Medline].
45.	Weiner, A., A. Erickson, J. Kanospon, K. Crawford, E. Muchmore, A. Hughes, M. Houghton, and C. M. Walker. 1995. Persistent hepatitis C virus infection in a chimpanzee is associated with emergence of a cytotoxic T lymphocyte escape variant. Proc. Natl. Acad. Sci. USA 92:2755-2759[Abstract/Free Full Text].
46.	Williamson, J. S., and S. A. Stohlman. 1990. Effective clearance of mouse hepatitis virus from the central nervous system requires both CD4⁺ and CD8⁺ T cells. J. Virol. 64:4589-4592[Abstract/Free Full Text].
47.	Wolinsky, S. M., B. Korber, A. U. Neumann, M. Daniels, K. Kunstman, A. Whetsell, M. Furtado, Y. Cao, D. Ho, J. Safrit, and R. Koup. 1996. Adaptive evolution of human immunodeficiency virus-type 1 during the natural course of infection. Science 272:537-542[Abstract].
48.	Xue, S., and S. Perlman. 1997. Antigen specificity of CD4 T cell response in the central nervous system of mice infected with mouse hepatitis virus. Virology 238:68-78[Medline].