Immunologic mechanisms in the pathogenesis of virus-induced leukemia. IV. Mechanism of target cell recognition by autoreactive thymocytes

Neonatal infection of mice with Moloney murine leukemia virus (MuLV-M) results in the establishment of a chronic virus-carrier state. Such MuLV-carrier mice exhibit several immunologic abnormalities including generalized immunosuppression and autoimmunity. Previously, we found thymocytes from MuLV-M-carrier mice to be cytotoxic for normal syngeneic and allogeneic fibroblasts but not for xenogeneic (hamster) target cells. However, when the same syngeneic or allogeneic target cells were infected with MuLV-M, they were "spared" from the autoreactivity, leading us to speculate that the MuLV receptor on the target cell membrane was involved in the autoreactivity. To address this question, we tested MuLV-carrier thymocytes for their ability to lyse hamster/mouse-hybrid target cells; some of which possessed chromosome 5 (which codes for the ecotropic MuLV receptor). Of the nine hybrid cell lines initially tested, only the five clones that carried chromosome 5 were killed by the autoreactive thymocytes. In additional experiments, we noted that the cytotoxic reaction was inhibited in the presence of a monoclonal antibody that reacts with an MuLV-M gp70 epitope. The results suggest that the autoreactive cytotoxicity is mediated, at least in part, through the formation of a "bridge" between MuLV budding from the membrane of the thymocytes and the ecotropic MuLV receptor on the target cells.     

Biology of cloned cytotoxic T lymphocytes specific for lymphocytic choriomeningitis virus. VI. Migration and activity in vivo in acute and persistent infection

Cloned cytotoxic T lymphocytes (CTL) specific for lymphocytic choriomeningitis virus (LCMV) were adoptively transferred to syngeneic mice acutely or persistently (carrier mice) infected with LCMV. Although infectious virus was cleared from the spleens during acute LCMV infection begun 24 hr earlier and the spleens remained clear of virus for the 4 days of testing, there was no concomitant reduction of viral titers in lymph nodes. In contrast, adoptive transfer of cloned CTL into animals with persistent rather than acute LCMV infection resulted in deaths of syngeneic but not allogeneic recipients. LCMV-immune spleen cells taken 30 to 50 days after a primary immunization and activated by in vitro stimulation before transfer also caused death of syngeneic carrier mice. However, LCMV-immune spleen cell per se provoked no clinical manifestations when transferred but cleared infectious virus and viral nucleic acid sequences from syngeneic carrier mice. The migration of 51Cr-labeled, LCMV-specific, H-2-restricted cloned CTL was assessed in vivo. The circulation of these CTL clearly differed from that of spleen cells freshly isolated from uninfected mice and from non-LCMV-specific CTL clone. Further, the circulatory pattern of LCMV-specific, H-2-restricted, cloned CTL in carrier mice was markedly different than in uninfected animals; only 7% of the injected cells remained in the lungs of uninfected mice 8 hr after injection, whereas 30% had accumulated in the liver. However, 55% of the cells injected into carrier mice still remained in their lungs 8 to 16 hr later. Hence, LCMV-specific, H-2-restricted, cloned CTL have unique trafficking patterns in the presence of LCMV antigens and immune activities in vivo.     

H-21-linked control of immunological resistance to viral leukemogenesis as a response to preleukemic cells

The mechanism of resistance to leukemogenesis by two radiation leukemia virus variants, A-RadLV and D-RadLV, was investigated. Resistance to these viruses is linked to H-21 in both B10.S and C57BL/10 mice. The resistance of virus-infected mice to transplantation of syngeneic. A- or D-RadLV-induced lymphoma cells was similar to their resistance to leukemogenesis by the same viruses. This resistance could be transferred by lymphoid cells from immune donors to normal recipients, and it was specific for RadLV lymphomas. Virus-primed (responder x sensitive)F1 hybrids rejected only resistant-type parental lymphoma cells. Hence, it appears that H-21-linked resistance to RadLV leukemogenesis is regulated by Ir genes. Resistant mice immunized by A- or D-RadLV rejected syngeneic lymphoma cells, irrespective of whether they were sensitive or resistant to the RadLV variant used for the induction of the lymphoma cells. It follows that resistant and sensitive type lymphomas are antigenically similar for the effector mechanism, and that the Ir genes may be expressed in the sensitization phase of the reaction. In virus-infected mice which are resistant to A- or D-RadLV we were able to demonstrate the presence of preleukemic lymphocytes. Normal mice could be immunized by these preleukemic cells against lymphoma challenge. These data are interpreted to suggest that mice having H-21-linked resistance to RadLV infection may be sensitized by their preleukemic cells, and that these preleukemic cells are then arrested in their development as a result of the immune response.     

H-2I-linked control of immunological resistance to viral leukemogenesis as a response to preleukemic cells

The mechanism of resistance to leukemogenesis by two radiation leukemia virus variants, A-RadLV and D-RadLV, was investigated. Resistance to these viruses is linked toH-2I in both B10.S and C57BL/10 mice. The resistance of virus-infected mice to transplantation of syngeneic, A- or D-RadLV-induced lymphoma cells was similar to their resistance to leukemogenesis by the same viruses. This resistance could be transferred by lymphoid cells from immune donors to normal recipients, and it was specific for RadLV lymphomas. Virus-primed (responder x sensitive)F₁ hybrids rejected only resistant-type parental lymphoma cells. Hence, it appears thatH-2I-linked resistance to RadLV leukemogenesis is regulated byIr genes. Resistant mice immunized by A- or D-RadLV rejected syngeneic lymphoma cells, irrespective of whether they were sensitive or resistant to the RadLV variant used for the induction of the lymphoma cells. It follows that resistant and sensitive type lymphomas are antigenically similar for the effector mechanism, and that theIr genes may be expressed in the sensitization phase of the reaction. In virus-infected mice which are resistant to A- or D-RadLV we were able to demonstrate the presence of preleukemic lymphocytes. Normal mice could be immunized by these preleukemic cells against lymphoma challenge. These data are interpreted to suggest that mice havingH-2I-linked resistance to RadLV infection may be sensitized by their preleukemic cells, and that these preleukemic cells are then arrested in their development as a result of the immune response.     

Persistent infection of some standard cell lines by lymphocytic choriomeningitis virus: transmission of infection by an intracellular agent.

Cell-free cytoplasmic extracts of the Syrian hamster cell lines C13/SV28 and BHK-21F were immunogenic in Syrian hamsters. The resulting antisera cross-reacted completely with antisera against lymphocytic choriomeningitis virus (LCMV) in an immunoradiometric assay employing BHK-21F antigen. Several other Syrian hamster cell lines not previously known to be infected with LCMV were also strongly positive when assayed for viral antigens. Also, several mouse sera and antisera raised in Syrian hamsters against cells transformed by papovaviruses had high titers of anti-LCMV activity. No cytopathic effect was evident in any of the persistently infected cell lines. Culture media from these cells were not infectious and showed no evidence of defective interfering particles. However, cell-free extracts of all the persistently infected cells contained material capable of transmitting the persistent infection to uninfected cells of Syrian hamsters, rats, mice, green monkeys, and humans. The onset of infection is much slower than when LCMV virions are used. When 2 X 10(6) uninfected BHK cells were treated with an extract from 100 persistently infected cells, the new infection was apparent within about 12 days. When an extract from 10(6) cells was used, the new infection was apparent within about 5 days, but not sooner. The intracellular infectious material was sensitive to treatment with deoxycholate, Nonidet P-40, or ether but resistant to treatment with RNase or trypsin. It was also large (5,000S) and heterodisperse on sucrose gradients. The infectious material was probably contained in large lipid vesicles and their integrity was probably essential for infection. When a few persistently infected cells were cocultivated with many uninfected cells, a few discrete colonies positive for LCMV antigens were observed after about 5 days. Since the culture media were not infectious, the infection probably spread by cell-cell contact. Several different experiments indicated that interferon did not play a major role in mediating persistence in this case. Persistent infections by LCMV can be maintained without expression of extracellular virus particles and without appearance of large amounts of viral antigens on the cell surface. Cell-cell contact could still allow transmission of intracellular infectious material. In an animal, these properties could circumvent immune surveillance.     

A replication-defective variant of Moloney murine leukemia virus. I. Biological characterization.

We have studied the virus produced by a clone, termed 8A, that was isolated from a culture of murine sarcoma virus-transformed mouse cells after superinfection with Moloney murine leukemia virus (MuLV-M). Clone 8A produced high levels of type C virus particles, but only a low titer of infectious murine sarcoma virus and almost no infectious MuLV. When fresh cultures of mouse cells were infected with undiluted clone 8A culture fluids, they released no detectable pogeny virus for several weeks after infection. Fully infectious MuLV was then produced in these cultures. This virus was indistinguishable from MuLV-M by nucleic acid hybridization tests and in its insensitivity to Fv-1 restriction. It also induced thymic lymphomas in BALB/c mice. To explain these results, we propose that cone 8A is infected with a replication-defective variant of MuLV-M. Particles produced by clone 8A, containing this defective genome, can establish an infection in fresh cells but cannot produce progency virus at detectable levels. Several weeks after infection, the defect in the viral genome is corrected by back-mutation or by recombination with endogenous viral genomes, resulting in the formation of fully infectious progeny MuLV. The progeny MuLV'S that arose in two different experiments were found to be genetically different from each other. This is consistent with the hypothesis that, in each experiment, the progeny virus is formed clone 8A cells and assayed for infectivity by the calcium phosphate transfection technique. No detectable MuLV was produced by cells treated with this DNA. This finding, along with positive results obtained in control experiments, indicates that clone 8A cells do not contain a normal MuLV provirus.     

Alterations of acetylcholine enzymes in neuroblastoma cells persistently infected with lymphocytic choriomeningitis virus.

Persistent infection of murine neuroblastoma cells with a relatively non-cytopathic virus, lymphocytic choriomeningitis virus (LCMV), significantly lowered the cells' concentrations of choline acetyl transferase (CAT) and acetylcholine esterase (ACHE), enzymes which make or degrade acetylcholine. Quantities of acetylcholine enzymes remained depressed during the observation period of more than two years. This cellular luxury function was turned off without observable alterations in the cells' vital functions – growth rates, protein and RNA synthesis. Cloning experiments showed that CAT and ACHE levels were altered in the majority of LCMV infected neuroblastoma cells in culture and not limited to a specific subpopulation. Cells persistently infected with virus also contained receptors for neurotoxin A and α bungarotoxin. Six months after becoming infected, neuroblastoma cells having significant alterations in luxury functions stopped making infectious virus. Instead these cells now produced a defective interfering virus component. Similar events to those seen in vitro with neuroblastoma cells also occurred in vivo. Mice inoculated with LCMV at birth carried high titers of LCMV in brain tissues and viral antigens in neuronal cells as adults. Some of these mice also showed significant alterations in their ability to make and degrade acetylcholine when compared to age and sex matched controls.     

Virus-lymphocyte interaction: T cells of the helper subset are infected with lymphocytic choriomeningitis virus during persistent infection in vivo.

The lifelong persistence of lymphocytic choriomeningitis virus (LCMV) in neonatally or congenitally infected mice is accompanied by a suppression of virus-specific T-cell responses. In this study, we identified the subset of T cells infected with LCMV during persistent infection in vivo. Using specific monoclonal antibodies to separate the different lymphocyte cell populations and employing both an infectious center assay and immunofluorescence to detect the virus, we found that infection is confined primarily to T cells of the helper subset (L3T4+ Lyt2-), with minimal involvement of cytotoxic T cells (Lyt2+ L3T4-) and mature B cells. About 0.54 to 1.1% of L3T4+ T cells were producing the virus, as determined by the infectious center assay. In contrast, 9.1 to 12.2% of these L3T4+ T cells contained viral antigen, as shown by immunofluorescence studies. This finding suggested that, at any given time, a substantial number of infected T cells were not producing infectious virus. This infection of T helper cells may be involved in the suppression of LCMV-specific T-cell responses observed in persistently infected mice.     

Viral proteins and RNAs in BHK cells persistently infected by lymphocytic choriomeningitis virus

Some Syrian hamster cell lines persistently infected with lymphocytic choriomeningitis virus (LCMV) do not produce extracellular virus particles but do contain intracytoplasmic infectious material. The proteins of these cells were labeled with [35S]methionine or with [3H]glucosamine and [3H]mannose, and immunoprecipitates were prepared with anti-LCMV sera. A substantial amount of the LCMV nucleocapsid protein (molecular weight about 58,000) was detected, along with GP-C, the precursor of the virion glycoproteins GP-1 and GP-2. GP-1 and GP-2 themselves were not detected. A new method of transferring proteins electrophoretically from sodium dodecyl sulfate-polyacrylamide gels to diazotized paper in high yield revealed several additional LCMV proteins present specifically in the persistently infected cells, at apparent molecular weights (X10(3] of 112, 107, 103, 89, 71 (probably GP-C), 58 (nucleocapsid protein), 42 to 47 (probably GP-1), and 40 (possibly GP-2). By iodinating intact cells with I3, GP-1 but not GP-2 or GP-C was revealed on the surfaces of the persistently infected cells, whereas both GP-1 and GP-C were found on the surfaces of acutely infected cells. The absence of GP-C from the plasma membrane of the persistently infected cells might be related to defective maturation of the virus in these cells. Cytoplasmic viral nucleoprotein complexes were labeled with [3H]uridine in the presence or absence of actinomycin D, purified partially by sedimentation in D2O-sucrose gradients, and adsorbed to fixed Staphylococus aureus cells in the presence of anti-LCMV immunoglobulin G. Several discrete species of viral RNA were released from the immune complexes with sodium dodecyl sulfate. Some were appreciably smaller than the 31S and 23S species of standard LCMV virions, indicating that defective interfering viral RNAs are probably present in the persistently infected cells. Ribosomal 28S and 18S RNAs, labeled only in the absence of actinomycin D, were coprecipitated with anti-LCMV serum but not with control serum, indicating their association with LCMV nucleoproteins in the cells.     

AKR leukemogenesis: identification and biological significance of thymic lymphoma receptors for AKR retroviruses.

We have previously demonstrated that in vitro cell lines of mouse thymic lymphomas express surface receptors specific for the retrovirus that induced them. This study extends these observations to an analysis of receptor-bearing cells in the preleukemic and leukemic phases of spontaneous AKR thymic lymphomagenesis. AKR mice regularly begin expressing N-tropic retroviruses (as assayed on NIH fibroblasts by the XC plaque assay) in several tissues early in life; thymic lymphocytes also express these viruses, but are not autonomously transformed. Later thymic lymphomas emerge which are capable of metastasizing in the host of origin or transplanting leukemias into syngeneic hosts. Just prior to the appearance of thymic lymphomas, these mice also begin producing xenotropic retroviruses [as assayed in xenogeneic (For example, mink) fibroblasts], and concomitant with the appearance of the leukemias is the appearance of "recombinant" retroviruses which cause mink fibroblast foci (MCF); these viruses express elements of both N- and X-tropic virus envelopes and N-tropic viral gene products in their cores. Spontaneous AKR leukemias also produce other retroviruses which do not cause XC plaques or mink fibroblast foci; these are called SL viruses. The subject of this study was to test whether in vivo thymocytes in the preleukemic and leukemic periods also bear receptors specific for N-tropic, recombinant MCF and SL AKR retroviruses. We demonstrated that each spontaneous thymic lymphoma does bear receptors that bind viruses produced by the lymphomas and MCF-247 to a high degree and that bind N-ecotropic AKR retroviruses less well. Thymic lymphocytes predominating in the preleukemic period do not express detectable levels of receptors for either of the viruses. In some mice, receptor-positive cells co-exist with receptor-negative cells; only the receptor-positive cells are capable of transplanting leukemia to syngeneic hosts. We conclude that the presence of specific cell surface receptors for lymphoma cell-produced and recombinant AKR retroviruses is a marker for leukemia in these hosts.     

Antibody prevents the establishment of persistent arenavirus infection in synergy with endogenous T cells.

A cardinal feature of the biology of lymphocytic choriomeningitis virus (LCMV) is its ability to establish persistent infections in mice. Persistence is usually established by infection of the mouse during the in utero or neonatal period. Susceptibility can be extended to the adult by treatment with immunosuppressive agents or by infection with immunosuppressive strains of LCMV. In this study we investigated the capacity of passively acquired anti-LCMV antibodies to prevent the establishment of persistence in both neonatal and adult mice. Suckling BALB/c mouse pups nursed by mothers immunized against LCMV before pregnancy had higher survival rates following infection than controls and withstood challenge doses of up to 400 PFU without becoming persistently infected. To establish that maternal antibody alone and not maternally derived T cells provided this protection, nonimmune mothers were infused with monoclonal anti-LCMV neutralizing antibodies within 24 h after delivering their pups. Pups nursing on these passively immunized mothers were resistant to persistent LCMV infection. The establishment of persistence in adult BALB/c mice by the immunosuppressive, macrophage-tropic LCMV variant, clone 13 was also prevented by prophylactic treatment with anti-LCMV monoclonal antibodies. However, the protection afforded by passively acquired antibody was found to be incomplete if the recipients lacked functional CD8+ T cells. While 65% of neonatal athymic (nu/nu) mice nursed by immune nu/+ dams resisted low-dose viral challenge (25 PFU), the majority of nude pups challenged with high doses of virus (100 PFU) became persistently infected. Also, protection was incomplete in beta2-microglobulin knockout mice, which lack functional CD8+ T cells, suggesting that a cooperative effect was exerted by the combination of neutralizing antibody and endogenous T cells. These results indicate that antibodies provide an effective barrier to the establishment of persistent infections in immunocompetent mice and reaffirm that vaccines which induce strong humoral responses may provide efficient protection against arenavirus infections.     

CD4+ T cells are required to sustain CD8+ cytotoxic T-cell responses during chronic viral infection.

In this study, we have examined the relative contributions of CD4+ and CD8+ T cells in controlling an acute or chronic lymphocytic choriomeningitis virus (LCMV) infection. To study acute infection, we used the LCMV Armstrong strain, which is cleared by adult mice in 8 to 10 days, and to analyze chronic infection, we used a panel of lymphocyte-tropic and macrophage-tropic variants of LCMV that persist in adult mice for several months. We show that CD4+ T cells are not necessary for resolving an acute LCMV infection. CD4+ T-cell-depleted mice were capable of generating an LCMV-specific CD8+ cytotoxic T-lymphocyte (CTL) response and eliminated virus with kinetics similar to those for control mice. The CD8+ CTL response was critical for resolving this infection, since beta 2-microglobulin knockout (CD8-deficient) mice were unable to control the LCMV Armstrong infection and became persistently infected. In striking contrast to the acute infection, even a transient depletion of CD4+ T cells profoundly affected the outcome of infection with the macrophage- and lymphocyte-tropic LCMV variants. Adult mice given a single injection of anti-CD4 monoclonal antibody (GK1.5) at the time of virus challenge became lifelong carriers with high levels of virus in most tissues. Unmanipulated adult mice infected with the different LCMV variants contained virus for prolonged periods (> 3 months) but eventually eliminated infection from most tissues, and all of these mice had LCMV-specific CD8+ CTL responses. Although the level of CTL activity was quite low, it was consistently present in all of the chronically infected mice that eventually resolved the infection. These results clearly show that even in the presence of an overwhelming viral infection of the immune system, CD8+ CTL can remain active for long periods and eventually resolve and/or keep the virus infection in check. In contrast, LCMV-specific CTL responses were completely lost in chronically infected CD4-depleted mice. Taken together, these results show that CD4+ T cells are dispensable for short-term acute infection in which CD8+ CTL activity does not need to be sustained for more than 2 weeks. However, under conditions of chronic infection, in which CD8+ CTLs take several months or longer to clear the infection, CD4+ T-cell function is critical. Thus, CD4+ T cells play an important role in sustaining virus-specific CD8+ CTL during chronic LCMV infection. These findings have implications for chronic viral infections in general and may provide a possible explanation for the loss of human immunodeficiency virus-specific CD8+ CTL activity that is seen during the late stages of AIDS, when CD4+ T cells become limiting.     

Virus-induced immune complex disease: specific anti-viral antibody and C1q binding material in the circulation during persistent lymphocytic choriomeningitis virus infection

Mice of several strains persistently infected with lymphocytic choriomeningitis virus (LCMV) mount continuous anti-LCMV immune responses leading to the formation and tissue deposition of immune complexes. Such mice carry infectious virus-immunoglobulin (presumably anti-LCMV antibody) complexes in the circulation. We have now determined that anti-LCMV antibody both complexed and free is found in the circulation of mice persistently infected with LCMV. This antibody reacts specifically against the three main LCMV structural polypeptides: nucleoprotein, 63,000 m.w. and two glycopeptides, GP-1 and GP-2 with m.w. of 45,000 and 35,000, respectively. A C1q binding assay was developed and found to be effective in measuring C1Q binding substances (presumably virus-anti-viral Ig complexes) in the circulations of several strains of mice persistently infected with LCMV. With different strains of mice, the levels, time of formation, and fate of C1q binding materials varied markedly. Formation of antibodies to LCMV was correlated with the detection of C1q binding materials. Mice (SWR/J) persistently infected with lactic dehydrogenase virus also form infectious virus-Ig in their sera but deposit minimal amounts of complexes in their tissues. In such mice, C1q binding substances did not form in the circulation.     

Elevated natural killer cell-mediated cytotoxicity, plasma interferon, and tumor cell rejection in mice persistently infected with lymphocytic choriomeningitis virus

To assess the effects of chronic virus infection on NK cells, the related phenomena of interferon (IFN) production, NK cell activation, and resistance to tumor implants were studied in mice persistently infected with lymphocytic choriomeningitis virus (LCMV). NK cells from these LCMV-carrier mice displayed augmented killing of the NK-sensitive YAC-1 target cell. They did not lyse the more resistant targets L-929 and P815, whereas NK cells from acutely infected mice efficiently lysed all three cell types. The plasma from LCMV-carrier mice contained an antiviral substance identified as IFN type I, based on species specificity, virus nonspecificity, resistance to pH 2, and sensitivity to antibody to type I IFN. IFN titers in plasma from LCMV-carrier mice were 32 to 64 U/ml, about 20-fold less than those in acutely infected mice. Both the IFN and NK cell levels continuously remained elevated in the LCMV carrier mice up to at least 6 months of age. IFN is known to activate NK cells and to induce their blastogenesis in vivo. As determined by centrifugal elutriation, large NK blast-size cells were isolated from the spleens of acutely infected mice, but not from either normal or LCMV-carrier mice, suggesting augmented NK cell-mediated lysis in the absence of enhanced proliferation. Poly inosinic-cytidylic acid induced high levels of NK cell-mediated cytotoxicity and blastogenesis in both control and LCMV-carrier mice, but IFN was induced to lower levels in carriers as compared with controls. Coincidental with augmented NK cell activity, the LCMV-carrier mice rejected intravenously injected 125IUdR-labeled tumor cells more efficiently than did normal mice. Thus, LCMV carrier mice have low levels of type I IFN, moderately augmented NK cell activity lasting for at least 6 months, and increased resistance to tumor cell implants. This indicates that augmented NK cell-mediated cytotoxicity can be maintained in vivo over prolonged periods of time in the presence of chronic low-level IFN stimulation.     

Production of random classes of immunoglobulins in brain tissue during persistent viral infection paralleled by secretion of interleukin-6 (IL-6) but not IL-4, IL-5, and gamma interferon

The activities of cytokines were determined in cerebrospinal fluid (CSF) and serum of mice persistently or intracerebrally acutely infected with lymphocytic choriomeningitis (LCM) virus (LCMV). In contrast to CBA/J (LCMV carrier) mice that responded with low levels of LCMV-specific antibody, high-responder NMRI (carrier) mice showed antibody production by B cells outside of lymphoid organs. The B cells that had infiltrated the brains of LCMV carrier mice exhibited no preferential immunoglobulin isotype or subtype virus-specific antibody production. Phenotypic analysis of the brain infiltrates in virus carrier mice revealed dominance of CD4+ T cells in contrast to virtual absence of CD4+ and dominance of CD8+ in mice with acute LCM. In NMRI but not in CBA/J carrier mice, significant concentrations of interleukin-6 (IL-6) were detected in CSF and serum; IL-2, IL-4, IL-5, granulocyte-macrophage CSF (GM-CSF), and gamma interferon (IFN-gamma) were not elevated. In contrast, during acute, lethal LCM, IL-6 and IFN-gamma were found at high concentrations, and IL-4, IL-5, and GM-CSF were detectable in CSF and serum, but virus-specific antibody-producing cells were not (yet) detectable in the brain. Thus, distinct cytokine patterns are found in acute versus chronic LCMV infection of the brain: in LCM carrier mice, local random-class immunoglobulin production correlated with the absence of IL-2, IL-4, IL-5, and IFN-gamma but active secretion of IL-6.     

Blockade but Not Overexpression of the Junctional Adhesion Molecule C Influences Virus-Induced Type 1 Diabetes in Mice

Type 1 diabetes (T1D) results from the autoimmune destruction of insulin-producing beta-cells in the pancreas. Recruitment of inflammatory cells is prerequisite to beta-cell-injury. The junctional adhesion molecule (JAM) family proteins JAM-B and JAM–C are involved in polarized leukocyte transendothelial migration and are expressed by vascular endothelial cells of peripheral tissue and high endothelial venules in lympoid organs. Blocking of JAM-C efficiently attenuated cerulean-induced pancreatitis, rheumatoid arthritis or inflammation induced by ischemia and reperfusion in mice. In order to investigate the influence of JAM-C on trafficking and transmigration of antigen-specific, autoaggressive T-cells, we used transgenic mice that express a protein of the lymphocytic choriomeningitis virus (LCMV) as a target autoantigen in the β-cells of the islets of Langerhans under the rat insulin promoter (RIP). Such RIP-LCMV mice turn diabetic after infection with LCMV. We found that upon LCMV-infection JAM-C protein was upregulated around the islets in RIP-LCMV mice. JAM-C expression correlated with islet infiltration and functional beta-cell impairment. Blockade with a neutralizing anti-JAM-C antibody reduced the T1D incidence. However, JAM-C overexpression on endothelial cells did not accelerate diabetes in the RIP-LCMV model. In summary, our data suggest that JAM-C might be involved in the final steps of trafficking and transmigration of antigen-specific autoaggressive T-cells to the islets of Langerhans.     

In vivo selection of neutralization-resistant virus variants but no evidence of B cell tolerance in lymphocytic choriomeningitis virus carrier mice expressing a transgenic virus-neutralizing antibody

B cell tolerance is maintained by active deletion and functional anergy of self-reactive B cells depending on the time, amount, and site of the self-antigen expression. To study B cell tolerance toward a transplacentally transmitted viral Ag, we crossed transgenic mice expressing the mu heavy and the kappa light chain of the lymphocytic choriomeningitis virus (LCMV)-neutralizing mAb KL25 (HL25-transgenic mice) with persistently infected LCMV carrier mice. Although HL25-transgenic LCMV carrier mice exhibited the same high virus titers as nontransgenic LCMV carrier mice, no evidence for B cell tolerance was found. In contrast, enhanced LCMV-neutralizing Ab titers were measured that, however, did not clear the virus. Instead, LCMV isolates from different tissues turned out to be neutralization resistant Ab escape variants expressing different substitutions of amino acid Asn119 of the LCMV-glycoprotein 1 that displays the neutralizing B cell epitope. Virus variants with the same mutations were also selected in vitro in the presence of the transgenic mAb KL25 confirming that substitutions of Asn119 have been selected by LCMV-neutralizing Abs. Thus, despite abundant expression of viral neo-self-antigen in HL25-transgenic LCMV carrier mice, transgenic B cells expressing LCMV-neutralizing Abs were rather stimulated than tolerized and neutralization resistant Ab escape variants were selected in vivo.     

Tumorigenicity of persistently infected tumors in nude mice is a function of both virus and host cell type.

Although BHK-21 cells persistently infected with wild-type vesicular stomatitis virus (VSV) are sensitive to natural killer (NK) cells and do not form tumors in athymic nude mice, BHK-21 cells persistently infected with a previously isolated mutant virus (VSV-P) are resistant to NK cells and form tumors in nude mice. We used this VSV-P mutant to persistently infect HeLa cells and mouse tumor cell lines. A mouse mastocytoma line (P815) persistently infected with VSV-P was similar to BHK-21 cells in that it was resistant to NK cell lysis and formed tumors in nude mice. However, neither HeLa cells nor mouse myeloma lines persistently infected with VSV-P were resistant to NK cell lysis in vitro, and neither formed tumors in nude mice. Rejection by nude mice of HeLa cells and mouse myeloma cell lines persistently infected with VSV-P could be ablated by rabbit antiserum to asialo-GM1, implicating NK cells in the in vivo rejection of these persistently infected tumors. These results suggest that NK cell recognition and killing of virus-infected cells in vivo and in vitro depend upon genetic contributions from both the virus and the host cell.     

Combined infection by Moloney murine leukemia virus and a mink cell focus-forming virus recombinant induces cytopathic effects in fibroblasts or in long-term bone marrow cultures from preleukemic mice.

We described previously a preleukemic state in mice inoculated with Moloney murine leukemia virus (M-MuLV) characterized by generalized hematopoietic hyperplasia in the spleen. To investigate this further, long-term bone marrow cultures (LTBMC) from preleukemic mice were established. Surprisingly, LTBMC from M-MuLV-inoculated preleukemic mice showed less hematopoiesis than LTBMC from control mice. This resulted from a quantitative defect in establishment of bone marrow stromal cells in the LTBMC. This phenomenon could also be observed in LTBMC from normal mice infected in vitro with a stock of M-MuLV containing a mink cell focus-forming virus (MCF) derivative (M-MCF), but not in LTBMC infected with M-MuLV alone. This implicated MCF derivatives in the reduction in bone marrow stromal cells. The phenomenon could also be detected in infected NIH 3T3 cells. Combined infection of M-MuLV plus M-MCF resulted in fewer cells, in comparison to uninfected cells or cells infected with either virus alone. Further studies indicated that this was predominantly due to an inhibition in cell growth rather than to cell lysis. The cytopathic effect did not appear to result from overreplication of viral DNA, as measured by Southern blots. Thus, combined infection with M-MuLV and an MCF derivative had cytostatic effects on cell growth. This phenomenon might also contribute to the leukemogenic process in vivo.     

Induction of alloreactive cytotoxic T cells by acute virus infection of mice

Alloreactive cytotoxic T lymphocytes (CTL) distinct from virus-specific CTL and activated natural killer (NK) cells were generated during acute lymphocytic choriomeningitis virus (LCMV) infection of C57BL/6J mice. The alloreactive CTL shared similar antigenic markers (Thy-1.2+, Lyt-2.2+, and asialo GM1-) with the virus-specific CTL that appeared at the same time 7 days postinfection, but had different target specificities. These alloreactive CTL lysed allogeneic but not syngeneic or xenogeneic targets. These were distinct from activated NK cells, which lysed all target cell types, peaked 3 days postinfection, and had a phenotype of asialo GM1+, Thy-1 +/-, Lyt-2.2-. Cold target competition studies indicated that there were several subsets of alloreactive T cells with distinct specificities, and that these alloreactive T cells were not subsets of the virus-specific T cells. Similar types of alloreactive CTL were induced at much lower levels in C3H/St mice. This may indicate that the generation of this "aberrant" T cell activity is under genetic control. Hence, the LCMV infection of C57BL/6J mice induces several cytotoxic effector populations including alloreactive CTL, activated NK cells, and virus-specific CTL. Virus infections therefore have the ability not only to polyclonally stimulate B cells, as previously described, but also to stimulate CTL.