Differences in affinity of binding of lymphocytic choriomeningitis virus strains to the cellular receptor alpha-dystroglycan correlate with viral tropism and disease kinetics.

alpha-Dystroglycan (alpha-DG) was recently identified as a receptor for lymphocytic choriomeningitis virus (LCMV) and several other arenaviruses, including Lassa fever virus (W. Cao, M. D. Henry, P. Borrow, H. Yamada, J. H. Elder, E. V. Ravkov, S. T. Nichol, R. W. Compans, K. P. Campbell, and M. B. A. Oldstone, Science 282:2079-2081, 1998). Data presented in this paper indicate that the affinity of binding of LCMV to alpha-DG determines viral tropism and the outcome of infection in mice. To characterize this relationship, we evaluated the interaction between alpha-DG and several LCMV strains, variants, and reassortants. These viruses could be divided into two groups with respect to affinity of binding to alpha-DG, dependence on this protein for cell entry, viral tropism, and disease course. Viruses that exhibited high-affinity binding to alpha-DG displayed a marked dependence on alpha-DG for cell entry and were blocked from infecting mouse 3T6 fibroblasts by 1 to 4 nM soluble alpha-DG. In addition, high-affinity binding to alpha-DG correlated with an ability to infiltrate the white pulp (T-dependent) area of the spleen, cause ablation of the cytotoxic T-lymphocyte (CTL) response by day 7 postinfection, and establish a persistent infection. In contrast, viruses with a lower affinity of binding to alpha-DG were only partially inhibited from infecting alpha-DG(-/-) embryonic stem cells and required a concentration of soluble alpha-DG higher than 100 nM to prevent infection of mouse 3T6 fibroblasts. These viruses that bound at low affinity were mainly restricted to the splenic red pulp, and the host generated an effective CTL response that rapidly cleared the infection. Reassortants of viruses that bound to alpha-DG at high and low affinities were used to map genes responsible for the differences described to the S RNA, containing the virus attachment protein glycoprotein 1.

Transgenic mice expressing human HLA and CD8 molecules generate HLA-restricted measles virus cytotoxic T lymphocytes of the same specificity as humans with natural measles virus infection.

Control of primary measles virus (MV) infection in humans and continued maintenance of immune memory that protects against reinfection are mediated primarily through the anti-MV T cell response, as judged by observations of children with defects in antibody formation but competency in making T cells. Further, the failure of T cell responses in those infected with MV most often leads to overwhelming infection. To better define and manipulate the elements involved in human T cell responses to MV, we analyzed the generation of HLA-restricted cytotoxic T lymphocytes (CTL) in a small animal model. Transgenic mice expressing the human class I MHC antigen HLA-B27 in conjunction with human CD8 molecules produced vigorous HLA-restricted CTL responses to MV antigens, paralleling those in MV infection of humans. In addition, such humanized mice generated human CD8 coreceptor-dependent HLA-B27-restricted CTL with the same specificity for recognition of MV fusion (F) peptide RRYPDAVYL as reported for humans during natural MV infection. Neither murine beta(2)-microglobulin nor murine CD8 substituted adequately as coreceptors for the HLA-B27 heavy chain. By contrast, HLA-A2.1-restricted responses to measles could be generated in the absence of expression of human beta(2)-microglobulin or CD8(+) molecules in HLA-A2.1/K(b) transgenic mice. Thus a small animal model is now available for studying strategies for optimizing human CD8(+) T cell responses and for testing vaccines. This model offers the potential, when combined with the newly reported CD46 transgenic mouse model in which MV replicates in cells of the immune system, for uncoding the molecular mechanism of MV-induced immunosuppression.

Measles virus infection in a transgenic model: virus-induced immunosuppression and central nervous system disease.

Measles virus (MV) infects 40 million persons and kills one million per year primarily by suppressing the immune system and afflicting the central nervous system (CNS). The lack of a suitable small animal model has impeded progress of understanding how MV causes disease and the development of novel therapies and improved vaccines. We tested a transgenic mouse line in which expression of the MV receptor CD46 closely mimicked the location and amount of CD46 found in humans. Virus replicated in and was recovered from these animals' immune systems and was associated with suppression of humoral and cellular immune responses. Infectious virus was recovered from the CNS, replicated primarily in neurons, and spread to distal sites presumably by fast axonal transport. Thus, a small animal model is available for analysis of MV pathogenesis.

Evidence for an underlying CD4 helper and CD8 T-cell defect in B-cell-deficient mice: failure to clear persistent virus infection after adoptive immunotherapy with virus-specific memory cells from muMT/muMT mice.

Adoptive transfer of virus-specific memory lymphocytes can be used to identify factors and mechanisms involved in the clearance of persistent virus infections. To analyze the role of B cells in clearing persistent infection with lymphocytic choriomeningitis virus (LCMV), we used B-cell-deficient muMT/muMT (B-/-) mice. B-/- mice controlled an acute LCMV infection with the same kinetics and efficiency as B-cell-competent (B+/+) mice via virus-specific, major histocompatibility complex (MHC) class I-restricted CD8(+) cytotoxic T lymphocytes (CTL). CTL from B-/- and B+/+ mice were equivalent in affinity to known LCMV CTL epitopes and had similar CTL precursor frequencies (pCTL). Adoptive transfer of memory cells from B+/+ mice led to virus clearance from persistently infected B+/+ recipients even after in vitro depletion of B cells, indicating that B cells or immunoglobulins are not required in the transfer population. In contrast, transfer of memory splenocytes from B-/- mice failed to clear virus. Control of virus was restored neither by transferring higher numbers of pCTL nor by supplementing B-/- memory splenocytes with LCMV-immune B cells or immune sera. Instead, B-/- mice were found to have a profound CD4 helper defect. Furthermore, compared to cultured splenocytes from B+/+ mice, those from B-/- mice secreted less gamma interferon (IFN-gamma) and interleukin 2, with differences most pronounced for CD8 T cells. While emphasizing the importance of CD4 T-cell help and IFN-gamma in the control of persistent infections, the CD4 T-helper and CD8 T-cell defects in B-/- mice suggest that B cells contribute to the induction of competent T effector cells.

CD40 ligand-mediated interactions are involved in the generation of memory CD8(+) cytotoxic T lymphocytes (CTL) but are not required for the maintenance of CTL memory following virus infection.

CD8(+) cytotoxic T lymphocytes (CTL) play a key role in the control of many virus infections, and the need for vaccines to elicit strong CD8(+) T-cell responses in order to provide optimal protection in such infections is increasingly apparent. However, the mechanisms involved in the induction and maintenance of CD8(+) CTL memory are currently poorly understood. In this study, we investigated the involvement of CD40 ligand (CD40L)-mediated interactions in these processes by analyzing the memory CTL response of CD40L-deficient mice following infection with lymphocytic choriomeningitis virus (LCMV). The maintenance of memory CD8(+) CTL precursors (CTLp) at stable frequencies over time was not impaired in CD40L-deficient mice. By contrast, the initial generation of memory CTLp was affected. CD40L-deficient mice produced lower levels of CD8(+) CTLp during the primary immune response to LCMV than did wild-type controls, despite the fact that the LCMV-specific effector CTL response of CD40L-deficient mice was indistinguishable from that of control animals. The differentiation of naïve CD8(+) T cells into effector and memory CTL thus involves pathways that can be discriminated from each other by their requirement for CD40L-mediated interactions. Expression of CD40L by CTLp themselves was not an essential step during their expansion and differentiation from naïve CD8(+) cells into memory CTLp; instead, the reduction in memory CTLp generation in CD40L-deficient mice was likely a consequence of defects in the CD4(+) T-cell response mounted by these animals. These results thus suggest a previously unappreciated role for CD40L in the generation of CD8(+) memory CTLp, the probable nature of which is discussed.

A model of measles virus-induced immunosuppression: enhanced susceptibility of neonatal human PBLs.

Measles virus (MV) still incites one of the most contagious infections of humankind. Despite the development and use of an excellent live attenuated virus vaccine, over one million infants and children continue to die each year from measles. The main cause of morbidity and mortality is virus-induced immunosuppression of lymphocyte function, which allows secondary infections. Here we report an in vivo model for the study of MV-induced immunosuppression. Human peripheral blood leukocytes (PBLs) grafted onto mice with severe combined immunodeficiency disease (SCID mice) to create hu-PBLS-SCID mice produce human IgG that is suppressed by MV infection. Immunosuppression is dependent on the involvement of live virus and is dramatically more severe for PBLs obtained from newborns than PBLs from adults. Suppression of IgG synthesis by PBLs from newborns occurs as early as ten days after administration of MV to hu-PBLS-SCID mice compared with 44 days required for PBLs from adults. Further, MV infection of SCID mice reconstituted with PBLs from newborns.

CD40L-deficient mice show deficits in antiviral immunity and have an impaired memory CD8+ CTL response.

The ligand for CD40 (CD40L) is expressed on the surface of activated CD4+ T cells and its role in T-B cell collaborations and thymus-dependent humoral immunity is well established. Recently, by generating CD40L-knockout mice, we have confirmed its previously described role in humoral immunity and defined another important function of this molecule in the in vivo clonal expansion of antigen-specific CD4+ T cells. Here, we investigated the potential in vivo role of CD40L in antiviral immunity by examining the immune response mounted by CD40L-deficient mice following infection with lymphocytic choriomeningitis virus (LCMV), Pichinde virus, or vesicular stomatitis virus. Humoral immune responses of CD40L-deficient mice to these viruses were severely compromised, although moderate titres of antiviral IgM and some IgG2a were produced by virus-infected CD40L-deficient mice by a CD4+ T cell-independent mechanism. By contrast, CD40L-deficient mice made strong primary CTL responses to all three viruses. Interestingly however, although memory CTL activity was detectable in CD40L-deficient mice two months after infection with LCMV, the memory CTL response was much less efficient than in wild-type mice. Together, the results show that CD40-CD40L interactions are required for strong antiviral humoral immune responses, and reveal a novel role for CD40L in the establishment and/or maintenance of CD8+ CTL memory.

Competitive selection in vivo by a cell for one variant over another: implications for RNA virus quasispecies in vivo.

Infidelity of genome applications of RNA viruses leads to the generation of viral quasispecies both in vitro and in vivo. However, the biological significance of such generated variants in vivo is largely unknown and controversial. To study this issue, we continued our evaluation of the tropism of a lymphocytic choriomeningitis virus (LCMV) variant termed clone 13 with its parental virus clonal pool ARM 53b (wild-type parent) for neuronal cells in vivo. Earlier in vivo and in vitro studies noted that the wild-type virus contained a Phe at glycoprotein (GP) residue 260 which correlated with neuron tropism compared with LCMV variants containing a Leu at residue 260 which showed selected tropism for cells of the immune system (C.F. Evans, P. Borrow, J. C. de la Torre, and M. B. A. Oldstone J. Virol. 68:7367-7373, 1994; L. Villarete, T. Somasundaram, and R. Ahmed, J. Virol 68:7490-7496, 1994). Here we (i) evaluated the ability of the viral variants with either a Phe or Leu at GP residue 260 to replicate in vivo in the spleen, liver, or brain, (ii) analyzed the ability of these viruses to compete against each other for cell (neuron)-specific selection following a single viral inoculation of different ratios of both viruses, and (iii) utilized genetic reassortants of both viruses to test their ability to replicate in neurons in vivo. We found that viral variants containing either a Phe or Leu at GP residue 260 were equally capable of replicating in neurons, but when inoculated together, neurons selected for the viral population containing Phe at GP residue 260 over viruses containing a Leu at this position. This was in contrast to selection in the liver and spleen that favored viruses with Leu and not Phe at GP residue 260. Analysis of inoculations with viral reassortants indicated that genes encoded on the short RNA (the GP and nucleoprotein, not the L [polymerase] and Z proteins that are encoded by the large RNA) were associated with neurotropism. Since the nucleoprotein sequences of wild-type Armstrong and clone 13 are identical, it is likely that specific cytoplasmic factors of the neurons play a fundamental role in the selection of virus with Phe at GP residue 260.

An essential role for type 1 interferon-gamma in terminating persistent viral infection.

The mechanism(s) by which infectious material is cleared by the host is an area of intensive study. This is especially so with the realization that persistent viral infection is a cause of chronic disease in humans and presents a major health problem. We have used the murine model of infection with lymphocytic choriomeningitis virus to evaluate immune clearance. Mice with a targeted disruption of the IFN-gamma gene mount effective cytotoxic T lymphocyte (CTL) responses after an acute viral challenge and clear virus. CD4+ T cells are not required but CD8+ T cells are mandatory. In contrast, CTL from mice with targeted disruption of the IFN-gamma gene are unable to clear virus from persistently infected mice. In addition to the requirement for IFN-gamma, CD4+ T cells are essential for maintaining a CD8(+)-mediated cure of persistent viral infection.

CTL escape viral variants. I. Generation and molecular characterization.

Cytotoxic T lymphocytes (CTL) play a pivotal role in preventing persistent viral infections and aborting acute infections. H-2Db-restricted CTL optimally recognize a specific peptide of 9 to 11 amino acids (aa) derived from a viral protein and held in place (restricted) by a MHC class I glycoprotein on the surfaces of infected cells. Only three peptide sequences with the appropriate Db motif from lymphocytic choriomeningitis virus Armstrong strain (LCMV) are known to be presented to CTL by H-2Db molecules; they are from the glycoproteins (GP), residues 33-41 KAVYNFATC (GP1) and 276-286 SGVENPGGYCL (GP2), and the nucleoprotein (NP), 396-404 FQPQNGQFI. Incubation of virally infected H-2b cells with CTL clones that recognize only GP1, GP2, or NP leads to the selection of viral variants which upon infecting cells bearing H-2b molecules, escape recognition by CTL of the appropriate specificity. Nucleic acid sequencing showed a single mutation in GP1 (aa 38 F-->L), GP2 (aa 282 G-->D), or NP (aa 403 F-->L) in the variant viruses. When wild-type (wt) LCMV peptides and the three variant peptides (GP1, GP2, NP) were synthesized and subjected to a competitive inhibition binding assay, no differences in binding affinity for H-2Db were found between the wt and variant peptides. Uninfected cells coated with the wt peptide were recognized and lysed by the appropriate CTL clone or by in vivo-primed bulk CTL, but similar targets coated with the GP1, GP2, or NP variant peptides were not. This result, coupled with computer graphic analysis of these variant peptides with the recently solved three-dimensional structure for the Db MHC class I molecule, placed the side chain of the mutated residues on the outer surface of the MHC-peptide complex and accessible to the T cell receptor. Ala substitution at GP residue 38 or 282 or at NP 403 also abrogated CTL recognition and lysis. Inoculation of any one of the mutated viral variants into mice produced an effective CTL response to the other two nonmutated GP or NP peptides, suggesting that production of biologically relevant CTL escape virus variants in vivo requires selection of mutations in more than one and likely all the CTL epitopes, a low probability event.

Behavioral effects of persistent lymphocytic choriomeningitis virus infection in mice.

Lymphocytic choriomeningitis virus (LCMV) is a nonlytic murine virus that provides a valuable model system for studying the behavioral correlates of CNS viral infection. Newborn or immunosuppressed mice infected with LCMV develop a persistent tolerant infection characterized by continuous viral production. Virus can be found in various body organs including lung, liver, kidney, and brain. In brain, neurons are the predominant CNS cells infected and the greatest number of persistently infected neurons are found in the cerebral cortex, hippocampus, other limbic structures and parts of the hypothalamus. Despite continuous infection throughout the animal's life, neurons show no structural injury or dropout. Mice from the DBA/2J strain were infected with LCMV (1000 plaque-forming units) within 18 h of birth and tested for behavioral function as adults. Plaque assays indicated persistent infection in virus-injected mice. Mice were tested for their ability to learn a Y-maze spatial discrimination to avoid the onset of a mild footshock (0.43 mA). The number of correct avoidance responses made during training was taken as a measure of acquisition performance. The virus-infected mice showed a deficit in acquisition of the Y-maze discrimination compared to that seen in vehicle-injected and noninjected controls. Following additional training to reach control levels of performance, the infected mice and the controls were injected with the cholinergic antagonist scopolamine. Scopolamine (2.0 mg/kg) disrupted the performance of the infected mice significantly more than control performance, suggesting that a cholinergic dysfunction accounted for some of the learning deficit. A separate group of virus-infected mice exhibited hypoactivity during the first exposure to a locomotor testing apparatus.(ABSTRACT TRUNCATED AT 250 WORDS)

Antigen presentation and cytotoxic T lymphocyte killing studied in individual, living cells.

Interactions between individual, living fibroblasts and cytotoxic T lymphocyte (CTL) clones were analyzed by using video-enhanced differential interference contrast and fluorescence microscopy in a multimode configuration. Fibroblasts expressing known major histocompatibility complex I alleles (MC57: H-2b; Balb: H-2d) were sensitized for killing by incubating or microinjecting them with peptide fragments of lymphocytic choriomeningitis virus. Previous determination of the CTL clones' specificity for these peptides and MHC-I alleles enabled us to study CTL killing of fibroblasts, and nonlethal CTL interaction with targets due to "mismatches" of the CTL, target, and/or peptide. During viral peptide-specific MHC-restricted CTL killing, distinct morphological alterations were observed (CTL shape changes, movements of granules in CTL cytoplasm, and target cell contraction and blebbing). When no killing occurred, CTL engaged in prolonged, nonrandom movement on the target cells. Alloreactive and virus-specific CTL displayed the same morphology during killing. To study antigen presentation further within individual, living cells, a LCMV glycoprotein peptide (aa 272-286, LSDSSGVENPGGYCL) was covalently labeled with tetramethylrhodamine. In 51Cr release assays, the labeled peptide specifically induced potent CTL killing, but neither labeled nor unlabeled peptide proved toxic for unsensitized targets. Microinjection of the labeled peptide into the cytoplasm of fibroblast cells led to CTL killing of those cells, yet nearby uninjected cells contacted by CTL were not killed, indicating that killing was due to presentation of microinjected peptide rather than binding of extracellular peptide to cell surface MHC. Peptide-injected target cells were killed only when combined with CTL specific for the peptide and for the MHC allele of the injected cell.

Cytotoxic T lymphocytes cleanse viral gene products from individually infected neurons and lymphocytes in mice persistently infected with lymphocytic choriomeningitis virus.

Lymphocytes and/or monocytes/macrophages carry viral genetic information in most, if not all, persistent and latent viral infections, and serve as potential reservoirs for maintaining or reintroducing the infection. Similarly, neurons can be persistently infected by several DNA and RNA viruses whose continued presence can alter the physiologic function of these cells, leading to disorders in neurotransmitters and disease. Here, we document that adoptive transfer of virus-specific cytotoxic T lymphocytes clears virus and viral nucleic acid sequences, in vivo, from individually infected lymphocytes, macrophages, and neurons. By plaquing, infectious center, Northern blot, and in situ hybridization at the single cell level, virus was efficiently removed from these cells.

Virus-induced immunosuppression. 1. Age at infection relates to a selective or generalized defect.

Viruses that persist must develop strategies to escape immunologic surveillance in order to survive. Investigation of lymphocytic choriomeningitis virus (LCMV)-induced persistence has indicated that this virus avoids immune clearance mainly by aborting the viral specific cytotoxic T lymphocyte (CTL) response, a response that is necessary for terminating viral infection. This study demonstrates that persistence established in immunologically immature newborns selectively depletes the LCMV-specific CTL response but does not hinder CTL responses to the RNA and DNA viruses influenza, vaccinia, or herpes simplex. In contrast, persistence established in immunologically mature adults leads not to selective but rather to generalized immunosuppression during which CTL responses to LCMV, influenza, vaccinia, and herpes simplex viruses are all ablated or down-regulated. These results indicate that the state of maturity of the immune system at the time of virus-induced immunosuppression can result in two distinct phenotypes. These observations may account for the differing patterns of infection caused by hepatitis B virus or human immunodeficiency virus initiated in the neonatal period compared to that initiated in adulthood.

Vaccination to prevent persistent viral infection.

Persistent virus infections are increasingly being recognized as a significant cause of human morbidity and mortality. To establish persistence, a virus must establish infection and evade eradication by the host immune response, in particular by cytotoxic T lymphocytes (CTL). We have studied a virus that establishes persistence in part by suppressing the CTL response of the infected host. The virus persists in many cell types, including lymphocytes and macrophages. We show that prior immunization with a vaccine designed to induce CTL (in the absence of antiviral antibody) confers complete protection against subsequent establishment of persistence in all tissues analyzed. The vaccine can be designed to express as few as 10 amino acids of a viral protein that comprise the CTL epitope. Further, two CTL epitopes for two discrete MHC haplotypes can be successfully used in a single vaccine that protects both strains of mice. Hence, a "string of CTL epitopes" (beads) concept for vaccination is feasible. Finally, the CTL vaccine provided protection against the establishment of persistence by an immunosuppressive virus.

Novel LCMV-specific H-2k restricted CTL clones recognize internal viral gene products and cause CNS disease.

H-2k (C3H/Hej) cytotoxic T lymphocytes (CTL) specific for lymphocytic choriomeningitis virus (LCMV) were cloned. Three clones recognizing internal viral antigens were studied. One such CTL clone recognized neither the glycoprotein nor nucleoprotein encoded by the viral short RNA segment, but reacted with a protein encoded by the long RNA segment, either the viral polymerase, or the Z protein. This one clone, in addition to primary CTL harvested from immunized C3H mice, failed to lyse target cells expressing the Z protein, suggesting recognition was to the viral polymerase. Two other clones recognized the viral nucleoprotein, amino acids 93-100, as determined by protein deletion and peptide mapping studies. When introduced directly into the central nervous systems of LCMV-infected histocompatible mice, all clones were active in vivo and capable of causing immunopathologically mediated death.

A common antiviral cytotoxic T-lymphocyte epitope for diverse major histocompatibility complex haplotypes: implications for vaccination.

Of nine established murine haplotypes, mice of three types (H-2d, H-2u, and H-2q) possess major histocompatibility complex class I glycoproteins able to present an identical viral peptide for recognition and lysis by virus-specific cytotoxic T lymphocytes. Incorporation of this viral epitope into a recombinant vaccinia vaccine and administration of a single dose protects mice with these three haplotypes from an ordinarily lethal challenge of virus. Hence, a common epitope can exist. The sharing of the ability to bind such epitopes among different MHC haplotypes underscores the feasibility of developing an effective cytotoxic T-lymphocyte vaccine for outbred populations like humans.

Diversity of T-cell receptors in virus-specific cytotoxic T lymphocytes recognizing three distinct viral epitopes restricted by a single major histocompatibility complex molecule.

Cytotoxic T lymphocytes (CTL) recognize virus peptide fragments complexed with class I major histocompatibility complex (MHC) molecules on the surface of virus-infected cells. Recognition is mediated by a membrane-bound T-cell receptor (TCR) composed of alpha and beta chains. Studies of the CTL response to lymphocytic choriomeningitis virus (LCMV) in H-2b mice have revealed that three distinct viral epitopes are recognized by CTL of the H-2b haplotype and that all of the three epitopes are restricted by the Db MHC molecule. The immunodominant Db-restricted CTL epitope, located at LCMV glycoprotein amino acids 278 to 286, was earlier noted to be recognized by TCRs that consistently contained V alpha 4 segments but had heterogeneous V beta segments. Here we show that CTL clones recognizing the other two H-2Db-restricted epitopes, LCMV glycoprotein amino acids 34 to 40 and nucleoprotein amino acids 397 to 407 (defined in this study), utilize TCR alpha chains which do not belong to the V alpha 4 subfamily. Hence, usage of V alpha and V beta in the TCRs recognizing peptide fragments from one virus restricted by a single MHC molecule is not sufficiently homogeneous to allow manipulation of the anti-viral CTL response at the level of TCRs. The diversity of anti-viral CTL likely provides the host with a wider option for attacking virus-infected cells and prevents the emergence of virus escape mutants that might arise if TCRs specific for the virus were homogeneous.

Role of viral strains and host genes in determining levels of immune complexes in a model system: implications for HIV infection.

Virus-antibody immune complexes form during infection with most RNA and DNA viruses, including those with human immunodeficiency virus (HIV). Yet a subset of individuals so infected apparently does not mount such responses. To understand the principles involved, we studied the formation and deposition of virus-antibody immune complexes in the circulation in a model system utilizing mice persistently infected with lymphocytic choriomeningitis virus (LCMV). Although mice of several genetic haplotypes could be persistently infected with LCMV, mount anti-LCMV antibody responses, and form immune complexes levels varied among murine strains. Earlier, genetic analysis of high and low immune complex formers, their F1 crosses, and appropriately selected recombinant inbred strains located the ability to mount heightened immune responses in genes within the MHC. Further, variations among LCMV strains in the capacity to incite high levels of immune complex formation were found. Persistent infection with LCMV Armstrong (ARM) strain was associated with high levels of complexes in the circulation and marked deposits in the glomeruli of high-responder SWR/J mice. In contrast, persistent infection of SWR/J mice with LCMV Traub strain led to very low levels of circulating complexes and minimal immune complex deposition in tissues. The amount of virus carried during both infections was roughly equivalent indicating that the genetics of both the host and the virus play essential roles in whether or not immune complexes develop. Antibody responses in SWR/J mice persistently infected with LCMV ARM were 5- to 10-fold higher than responses of age- and sex-matched mice infected with LCMV Traub.(ABSTRACT TRUNCATED AT 250 WORDS)

Infection of lymphocytes by a virus that aborts cytotoxic T lymphocyte activity and establishes persistent infection.

For viruses to establish persistent infections in their hosts, they must possess some mechanism for evading clearance by the immune system. When inoculated into adult immunocompetent mice, wild-type lymphocytic choriomeningitis virus (LCMV ARM) induces a CD8(+)-mediated cytotoxic T lymphocyte (CTL) response that clears the infection within 7-14 d (CTL+ [P-]). By contrast, variant viruses isolated from lymphoid tissues of persistently infected mice fail to induce a CTL response and are thus able to establish a persistent infection in adult mice (CTL- [P+]). This report compares the interaction of CTL+ (P-) and CTL- (P+) viruses with cells of the immune system. Both types of virus initially bind to 2-4% of CD4+ and CD8+ T lymphocytes and replicate within cells of both subsets. The replication of CTL- (P+) and CTL+ (P-) viruses in lymphocytes in vivo is similar for the first 5 d after initiating infection. Thereafter, in mice infected with CTL- (P+) variants, lymphocytes retain viral genetic information, and infectious virus can be recovered throughout the animals' lives. In contrast, when adult mice are infected with wild-type CTL+ (P-) LCMV ARM, virus is not recovered from lymphocytes for greater than 7 d after infection. A CD8(+)-mediated anti-LCMV CTL response is induced in such mice. Clearance of infected lymphocytes is produced by these LCMV-specific CTLs, as shown by their ability to lyse lymphocytes expressing LCMV determinants in vitro and the fact that depletion of CD8+ lymphocytes before infection with CTL+ (P-) viruses results in levels of infected lymphocytes similar to those found in undepleted CTL- (P+)-infected mice. Hence, CTL-mediated lysis of T lymphocytes carrying infectious virus is a critical factor determining whether virus persists or the infection is terminated.