Experimental autoallergic sialadenitis in the LEW rat. III. Role of CD4+ T cells in EAS induction

Experimental autoallergic sialadenitis (EAS) in the LEW rat is an induced autoimmune disease of the salivary tissues. EAS is characterized by a lymphocytic infiltration that consists of both CD4+ (helper/inducer T-cell subset) and CD8+ (cytotoxic/suppressor T-cell subset) T cells and results in the immune-mediated destruction of the exocrine salivary glands. To investigate the role that each of the T-cell subsets may have in the pathogenesis of EAS, LEW rats sensitized with WF SMG homogenate were injected with monoclonal antibodies to deplete or inactivate, in vivo, the CD4, CD5 (OX19; pan T lymphocyte), CD8, or RT6 (70% of peripheral T cells) T-cell populations. Treatment with the OX8 (CD8), OX19 (CD5), or W3/25 (CD4) only partially reduced in vivo the respective splenic or lymph node T-cell subsets when analyzed on Day 14, while treatment with DS4.23 (anti-RT6) resulted in greater than 95% depletion of RT6+ spleen and lymph node T cells. EAS incidence and severity was significantly reduced in the W3/25 (CD4) treatment group (11% incidence rate; histologic score 1.0) as compared to medium-injected controls (88% incidence rate; histologic score 2.9). Although the incidence and severity of EAS in the OX19 (71%; histologic score 1.7), OX8 (55%; histologic score 1.7), and RT6 (67%; histologic score 1.6) treatment groups appeared decreased, the reduction was not statistically significant. These results provide evidence that CD4+ T cells have an important role in EAS induction and demonstrate that in vivo treatment with anti-CD4 can ameliorate and/or prevent EAS in the LEW rat.     

Lack of plasma protein hemopexin dampens mercury-induced autoimmune response in mice

Several factors affect the autoimmune response, including iron-dependent modulation of T cells. Hemopexin is the plasma protein with the highest binding affinity to heme. It mediates heme-iron recovery in the liver, thus controlling heme-iron availability in peripheral cells. The aim of the present study was to investigate the role of hemopexin in the progress of an autoimmune response. To this end, we chose a mouse model of mercury-induced autoimmunity and evaluated the susceptibility of hemopexin-null mice to mercury treatment compared with wild-type controls. In this study we show that lack of hemopexin dampens mercury-induced autoimmune responses in mice. Hemopexin-null mice produced fewer antinuclear autoantibodies and had reduced deposits of immune complexes in the kidney after mercuric chloride treatment compared with wild-type mice. These features were associated with a reduction in activated T cells and lower absolute B cell number in spleen and impaired IgG1 and IgG2a production. In contrast, in hemopexin-null mice the response to OVA/CFA immunization was maintained. In addition, hemopexin-null mice had reduced transferrin receptor 1 expression in T cells, possibly due to the increase in heme-derived iron. Interestingly, CD4(+)T cells isolated from mercury-treated hemopexin-null mice show reduced IFN-gamma-dependent STAT1 phosphorylation compared with that of wild-type mice. Our data suggest that hemopexin, by controlling heme-iron availability in lymphocytes, modulates responsiveness to IFN-gamma and, hence, autoimmune responses.     

Suppression of experimental allergic encephalomyelitis in rats by mercuric chloride

Brown-Norway (BN) rats are uniquely susceptible to development of autoimmune phenomena and enlargement of lymph nodes and spleen after repeated injections of mercuric chloride. Despite its ability to produce autoimmunity, HgCl2 inhibited the development in BN rats of experimental allergic encephalomyelitis (EAE), another autoimmune process. The inhibition by mercury was probably due to lack of the normal absorption and granulomatous reaction to the EAE inoculum in the enlarged lymph nodes draining the inoculation site. Lewis rats did not develop enlarged nodes from HgCl2 treatment. Lewis lymph nodes absorbed the EAE inoculum abundantly and developed an extensive granulomatous reaction despite the mercury treatment, and there was only a slight inhibition of EAE. Therefore, the ability of HgCl2 to produce lymphadenopathy in BN rats may be responsible for the inability of these rats to absorb the inoculated antigen. The mercury-induced failure of absorption was manifested as an inhibition of EAE in BN rats.     

不同品系大鼠RTI基因抗原表达数量的研究

目的研究不同品系大鼠RT1A、RT1B和RT1D基因表达的抗原总数量,以及在CD4＋T细胞和CD8＋T细胞上表达的数量,为免疫学研究提供数据支持。方法采集四种品系BN、Lewis、F344、SHR大鼠的静脉血,制备淋巴细胞,与有荧光标记的单克隆抗体反应,应用流式细胞术检测抗原数量。结果发现RT1A、RT1B和RT1D基因表达的抗原在不同品系大鼠体内表达的数量不同,其中F344大鼠表达的RT1A抗原最多,BN大鼠表达的RT1B抗原和RT1D抗原均为最多。RT1A、RT1B和RT1D基因表达的抗原在CD4＋T细胞和CD8＋T细胞上表达的数量也不同,Lewis大鼠在CD4＋T细胞上表达的RT1A抗原最多,BN大鼠在CD4＋T细胞上表达的RT1B和RT1D抗原最多。F344大鼠在CD8＋T细胞上表达的RT1A抗原最多;F344大鼠在CD8＋T细胞上表达的RT1B和RT1D抗原最多。同一品系大鼠之间雌雄动物RT1A、RT1B和RT1D基因表达的抗原也不同。结论不同品系大鼠RT1A、RT1B和RT1D基因的抗原总表达数量之间差异有显著性,在CD4＋T细胞上和CD8＋T细胞上表达的数量差异也有显著性。     

Autoreactive T cells in mercury-induced autoimmunity. Ability to induce the autoimmune disease

It has been previously shown that autoreactive T cells appear during mercury-induced autoimmunity in Brown-Norway (BN) rats. In the present work, it is shown that: 1) T cells and T helper cells from HgCl2-injected BN rats are able to actively transfer autoimmunity in normal BN rats; the disease transferred is exacerbated when recipients are treated with the antisuppressor/cytotoxic T cell monoclonal antibody (OX8); 2) normal T cells preincubated with HgCl2 are also able to transfer the disease in OX8-treated but not in T cell-depleted rats; and 3) T cells from HgCl2-injected BN rats also transferred the disease in both normal and T cell depleted rats. It is concluded that: 1) autoreactive T cells, and presumably anti-Ia T cells are involved in the pathogenesis of mercury-induced autoimmunity; 2) these autoreactive T cells induce suppressor/cytotoxic T cells to proliferate in normal syngeneic recipients; the fact that this T cell subset did not proliferate in HgCl2-injected BN rats suggests that HgCl2 also affects T suppressor cells; and 3) mercury-induced autoimmunity could result from the additive effect of the emergence of autoreactive T cells and of a defect at the T suppressor level.     

The balance between CD45RChigh and CD45RClow CD4 T cells in rats is intrinsic to bone marrow-derived cells and is genetically controlled

The level of CD45RC expression differentiates rat CD4 T cells in two subpopulations, CD45RC(high) and CD45RC(low), that have different cytokine profiles and functions. Interestingly, Lewis (LEW) and Brown Norway (BN) rats, two strains that differ in their ability to mount type 1 and type 2 immune responses and in their susceptibility to autoimmune diseases, exhibit distinct CD45RC(high)/CD45RC(low) CD4 T cell ratios. The CD45RC(high) subpopulation predominates in LEW rats, and the CD45RC(low) subpopulation in BN rats. In this study, we found that the antiinflammatory cytokines, IL-4, IL-10, and IL-13, are exclusively produced by the CD45RC(low) CD4 T cells. Using bone marrow chimeras, we showed that the difference in the CD45RC(high)/CD45RC(low) CD4 T cell ratio between naive LEW and BN rats is intrinsic to hemopoietic cells. Furthermore, a genome-wide search for loci controlling the balance between T cell subpopulations was conducted in a (LEW x BN) F(2) intercross. Genome scanning identified one quantitative trait locus on chromosome 9 (approximately 17 centiMorgan (cM); log of the odds ratio (LOD) score 3.9). In addition, two regions on chromosomes 10 (approximately 28 cM; LOD score 3.1) and 20 (approximately 40 cM; LOD ratio score 3) that contain, respectively, a cytokine gene cluster and the MHC region were suggestive for linkage. Interestingly, overlapping regions on these chromosomes have been implicated in the susceptibility to various immune-mediated disorders. The identification and functional characterization of genes in these regions controlling the CD45RC(high)/CD45RC(low) Th cell subpopulations may shed light on key regulatory mechanisms of pathogenic immune responses.     

In vivo induced allo-reactive natural killer cells.

We have previously shown that rat allo-selective cells of the CD2+CD5- phenotype were generated in Brown Norway (BN) rats after immunization with allogeneic Wistar/Furth (WF) cells, whereas immunization with semi-allogeneic F1 (WF/BN) cells generated CD2+CD5+ effector T cells. We now report that the allo-selective CD2+CD5- lymphocytes lacked expression of intact CD3 complexes and expressed NKR-P1 molecules although lower as compared to classical NK cells, implicating that these lymphocytes constitute a subset of NK cells. The CD5+ T cells were not cytolytically active in BN rats immunized with WF cells indicating an intersubset regulation with mutually exclusive activation of either allo-selective T cells or allo-selective NK cells. Cold target inhibition showed that lysis of both allogeneic target cells and NK-sensitive target cells was mediated by the same NKR-P1 intermediate effector cells. These NK cells lysed WF but not allogeneic Fischer 344 or autologous BN target cells, indicating selective recognition of an allogeneic determinant. Semiallogeneic F1 (WF/BN) target cells were not lysed. Furthermore, target cells from F1 (WF/BN) x WF back-cross hybrids lacking expression of RT1n (self-MHC class I) were susceptible to lysis, whereas back-cross hybrids expressing RT1n were protected from lysis, indicating that self-MHC molecules conferred protection from lysis. These findings implicate the existence of NKR-P1intermediate and NKR-P1high NK cell subsets with different regulation and function in vivo.     

Characterization of RT6 bearing rat lymphocytes. I. Ontogeny of the RT6+ subset

The RT6 alloantigen is present on approximately 70% of peripheral T cells in the rat, but is absent from thymocytes and bone marrow lymphocytes. The results of further phenotypic analysis in the present study demonstrated that the RT6 alloantigen is expressed on approximately 45% of the helper/inducer (CD4; W3/25+) and 80% of the cytotoxic/suppressor (CD8; OX8+) peripheral T-cell subsets. Ontogenetic and thymus ablation studies indicated that the RT6+ T-cell subset is thymus-dependent and normally develops after the appearance of RT6-T cells in neonatal rats, and that the expression of RT6 is a post-thymic maturational event. Furthermore, intrathymic adoptive transfer of bone marrow cells demonstrated that RT6+ T cells are thymus-derived cells. These results show that most if not all RT6+ T cells are the progeny of RT6- T cells. However, they do not exclude the possibility that a separate lineage of RT6- T cells exists, which also has OX8+ and W3/25+ subsets. The possible developmental and functional relationships of RT6- and RT6+ T cells in the rat are discussed.     

The CD8 T cell compartment plays a dominant role in the deficiency of Brown-Norway rats to mount a proper type 1 immune response.

Differential cytokine production by T cells plays an important role in regulating the nature of an immune response. In the rat, Brown-Norway (BN) and Lewis (LEW) strains differ markedly in their susceptibility to develop either type 1 or type 2-mediated autoimmune manifestations. BN rats are susceptible to type 2-dependent systemic autoimmunity, while LEW rats are resistant. Conversely, type 1-mediated, organ-specific autoimmune disease can be easily induced in LEW, but not in BN, rats. The mechanisms involved in the differential development of type 1 and type 2 immune responses by these two strains are still unknown. In the present study we analyzed the contributions of APC, CD4 and CD8 T cells, and MHC molecules in the difference between LEW and BN rats to develop a type 1 immune response. First, we show that the defect of BN T cells to produce type 1 cytokines in vitro does not require the presence of APC and, by using an APC-independent stimulation assay, we have localized the defect within the T cell compartment. Both CD4 and CD8 T cells are involved in the defect of BN rats to develop a type 1 immune response with a major contribution of the CD8 T cell compartment. This defect is associated with an increase in the type 2 cytokine IL-4 in both BN T cell populations, but neutralization of this cytokine does not restore this defect. Finally, by using MHC congenic rats, we show that the MHC haplotype is not involved in the defect of BN T cells to mount a proper type 1 cytokine response.     

Recapitulation of normal and abnormal BioBreeding rat T cell development in adult thymus organ culture

Congenitally lymphopenic diabetes-prone (DP) BioBreeding (BB) rats develop spontaneous T cell-dependent autoimmunity. Coisogenic diabetes-resistant (DR) BB rats are not lymphopenic and are free of spontaneous autoimmune disease, but become diabetic in response to depletion of RT6+ T cells. The basis for the predisposition to autoimmunity in BB rats is unknown. Abnormal T cell development in DP-BB rats can be detected intrathymically, and thymocytes from DR-BB rats adoptively transfer diabetes. The mechanisms underlying these T cell developmental abnormalities are not known. To study these processes, we established adult thymus organ cultures (ATOC). We report that cultured DR- and DP-BB rat thymi generate mature CD4 and CD8 single-positive cells with up-regulated TCRs. DR-BB rat cultures also generate T cells that express RT6. In contrast, DP-BB rat cultures generate fewer CD4+, CD8+, and RT6+ T cells. Analysis of the cells obtained from ATOC suggested that the failure of cultured DP-BB rat thymi to generate T cells with a mature phenotype is due in part to an increased rate of apoptosis. Consistent with this inference, we observed that addition of the general caspase inhibitor Z-VAD-FMK substantially increases the number of both mature and immature T cells produced by DP-BB rat ATOC. We conclude that cultured DR-BB and DP-BB rat thymi, respectively, recapitulate the normal and abnormal T cell developmental kinetics and phenotypes observed in these animals in vivo. Such cultures should facilitate identification of the underlying pathological processes that lead to immune dysfunction and autoimmunity in BB rats.     

Single expression of CD45RC and RT6 in correlation with T-helper 1 and T-helper 2 cytokine patterns in the rat

Previous studies involving the function and development of peripheral T cells have proposed that, in the rat, CD4(+)CD45RC(+)RT6(-) and CD4(+)CD45RC(-)RT6(+) T-cell subsets may represent Th1 and Th2 cells, respectively. Here we tested this hypothesis directly by analyzing frequencies of IFN-gamma- and IL-4-producing cells in these two subpopulations using ELISPOT assays. We found that the CD4(+)CD45RC(-)RT6(+) subset showed higher numbers of IL-4-producing cells than the CD4(+)CD45RC(+)RT6(-) subset and, though less pronounced, that the latter demonstrated higher numbers of IFN-gamma producers. Therefore, we conclude that our results provide evidence for the existence of phenotypically defined Th1 and Th2 cells in the rat. This is supported by the finding that the ratios of IFN-gamma/IL-4 and CD45RC/RT6 correlated positively among various rat strains. Finally, rat strains susceptible to induction of a Th1-mediated autoimmune disease showed the highest CD45RC/RT6 ratio, whereas the reverse was true for strains susceptible to a Th2-mediated autoimmune disease.     

Anti-CD4 monoclonal antibody therapy suppresses autoimmune disease in MRL/Mp-lpr/lpr mice.

MRL/Mp-lpr/lpr (MRL/lpr) mice spontaneously develop systemic autoimmune disease, characterized by vasculitis, lymphadenopathy, glomerulonephritis, and autoantibody formation. The target organ inflammatory lesions are composed largely of CD4+ "helper" T cells, while the massively enlarged lymph nodes are composed primarily of CD3+ CD4- CD8- TCR alpha/beta + "double-negative" T cells. In this study we investigated the effect of treatment of MRL/lpr mice with anti-CD4 monoclonal antibody (mAb); control groups consisted of animals treated with normal saline or rat immunoglobulin (Ig). Anti-CD4 mAb treatment, which was started at 4 weeks and continued through 20 weeks of age, resulted in a dramatic reduction of both the frequency and severity of the autoimmune disease, as demonstrated histologically and serologically. Anti-CD4 mAb therapy markedly reduced the frequency of glomerulonephritis and eliminated vasculitis of the major renal arterial branches. Glomerulonephritis was detected in 9 of 9 saline-treated, 9 of 9 rat Ig-treated, but in only 1 of 9 anti-CD4 mAb-treated mice; vasculitis was detected in 6 of 9 saline-treated, 7 of 9 rat Ig-treated, but in none of 9 anti-CD4 mAb-treated mice. The frequency of antinuclear antibodies, titer of anti-dsDNA antibodies, and total Ig levels were all significantly reduced by anti-CD4 mAb therapy. These data support the hypothesis that CD4+ T cells play a central role in the disease process in this autoimmune strain.     

HgCl2-induced perturbation of the T cell network in experimental allergic encephalomyelitis. II. In vivo demonstration of the role of T suppressor and contrasuppressor cells.

In the companion paper (J. Rossert et al., Cell. Immunol. 137, 1991), we showed by using limiting dilution analysis that Lewis (LEW) rats injected with HgCl2 and immunized with myelin (LEWHg/MYE) exhibit anti-basic protein CD4+ T helper cells (Th), at least 10-fold more frequent CD8+ T suppressor cells (Ts), and T contrasuppressor cells (Tcs). These Tcs cells were shown to be CD4+ T cells adhering to Vicia villosa (VV) lectin and allowed Th cells to proliferate despite the presence of Ts cells. The CD8+ Ts cells might be responsible for the protection from experimental allergic encephalomyelitis (EAE) observed in about 70% of LEW rats injected with HgCl2. The concomitant presence of CD4+ Tcs cells might explain that 30% of the rats escaped this protection. The aim of this work is to demonstrate in vivo the roles of CD8+ Ts cells and Tcs cells in mercury-induced protection from EAE. It will be shown that LEWHg/MYE rats depleted of CD8+ cells as well as LEWHg/MYE rats transferred with VV lectin-adherent Tcs cells develop EAE. These data demonstrate that CD8+ Ts cells are responsible for HgCl2-induced protection and that Tcs cells are involved in the control of Ts cells in vivo.     

Dihydropyridine receptors are selective markers of Th2 cells and can be targeted to prevent Th2-dependent immunopathological disorders

Th1 cells that produce IFN-gamma are essential in the elimination of intracellular pathogens, and Th2 cells that synthetize IL-4 control the eradication of helminths. However, highly polarized Th1 or Th2 responses may be harmful and even lethal. Thus, the development of strategies to selectively down-modulate Th1 or Th2 responses is of therapeutic importance. Herein, we demonstrate that dihydropyridine receptors (DHPR) are expressed on Th2 and not on Th1 murine cells. By using selective agonists and antagonists of DHPR, we show that DHPR are involved in TCR-dependent calcium response in Th2 cells as well as in IL-4, IL-5, and IL-10 synthesis. Nicardipine, an inhibitor of DHPR, is beneficial in experimental models of Th2-dependent pathologies in rats. It strongly inhibits the Th2-mediated autoimmune glomerulonephritis induced by injecting Brown Norway (BN) rats with heavy metals. This drug also prevents the chronic graft vs host reaction induced by injecting CD4(+) T cells from BN rats into (LEW x BN)F(1) hybrids. By contrast, treatment with nicardipine has no effect on the Th1-dependent experimental autoimmune encephalomyelitis triggered in LEW rats immunized with myelin. These data indicate that 1) DHPR are a selective marker of Th2 cells, 2) these calcium channels contribute to calcium signaling in Th2 cells, and 3) blockers of these channels are beneficial in the treatment of Th2-mediated pathologies.     

D-penicillamine-induced autoimmunity in Brown-Norway rats. Similarities with HgCl2-induced autoimmunity

D-penicillamine (DP) has been previously shown to induce an autoimmune disease in Brown-Norway (BN) rats, characterized by a dermatitis, by the production of antinuclear antibodies, by the formation fo circulating immune complexes, and by linear IgG deposits along the glomerular basement membrane. These manifestations are quite similar to those observed in mercuric chloride (HgCl2)-induced autoimmunity. The mechanism of the latter disease has been recently partly elucidated. The aim of this study was to compare DP and HgCl2-induced autoimmunity in BN rats and to compare the mechanisms involved in both situations. A transient increase in the number of spleen cells, affecting B cells and CD4+ T cells, and an increase in serum IgE concentration, previously reported in HgCl2-induced autoimmunity, were observed during DP treatment. Autoreactive anti-class II T cells able to proliferate not only in the presence of autologous B cells but also in the presence of syngeneic normal B cells were found in DP-treated BN rats. Spontaneous regulation occurred, associated with the disappearance of autoreactive T cells. Suppressor CD8+ T cells were not involved in this phenomenon. Mechanisms involved in both the induction and the regulation of DP-induced autoimmunity seem to be quite similar to those reported in HgCl2-induced autoimmunity.     

Cellular and molecular mechanism for Kilham rat virus-induced autoimmune diabetes in DR-BB rats

Kilham rat virus (KRV) causes autoimmune diabetes in diabetes-resistant BioBreeding (DR-BB) rats; however, the mechanism by which KRV induces autoimmune diabetes without the direct infection of beta cells is not well understood. We first asked whether molecular mimicry, such as a common epitope between a KRV-specific peptide and a beta cell autoantigen, is involved in the initiation of KRV-induced autoimmune diabetes in DR-BB rats. We found that KRV peptide-specific T cells generated in DR-BB rats infected with recombinant vaccinia virus expressing KRV-specific structural and nonstructural proteins could not induce diabetes, indicating that molecular mimicry is not the mechanism by which KRV induces autoimmune diabetes. Alternatively, we asked whether KRV infection of DR-BB rats could disrupt the finely tuned immune balance and activate autoreactive T cells that are cytotoxic to beta cells, resulting in T cell-mediated autoimmune diabetes. We found that both Th1-like CD45RC+CD4+ and cytotoxic CD8+ T cells were up-regulated, whereas Th2-like CD45RC-CD4+ T cells were down-regulated, and that isolated and activated CD45RC+CD4+ and CD8+ T cells from KRV-infected DR-BB rats induced autoimmune diabetes in young diabetes-prone BioBreeding (DP-BB) rats. We conclude that KRV-induced autoimmune diabetes in DR-BB rats is not due to molecular mimicry, but is due to a breakdown of the finely tuned immune balance of Th1-like CD45RC+CD4+ and Th2-like CD45RC-CD4+ T cells, resulting in the selective activation of beta cell-cytotoxic effector T cells.     

A regulatory CD4+ T cell subset in the BB rat model of autoimmune diabetes expresses neither CD25 nor Foxp3

Biobreeding (BB) rats model type 1 autoimmune diabetes (T1D). BB diabetes-prone (BBDP) rats develop T1D spontaneously. BB diabetes-resistant (BBDR) rats develop T1D after immunological perturbations that include regulatory T cell (Treg) depletion plus administration of low doses of a TLR ligand, polyinosinic-polycytidylic acid. Using both models, we analyzed CD4+CD25+ and CD4+CD45RC- candidate rat Treg populations. In BBDR and control Wistar Furth rats, CD25+ T cells comprised 5-8% of CD4+ T cells. In vitro, rat CD4+CD25+ T cells were hyporesponsive and suppressed T cell proliferation in the absence of TGF-beta and IL-10, suggesting that they are natural Tregs. In contrast, CD4+CD45RC(-) T cells proliferated in vitro in response to mitogen and were not suppressive. Adoptive transfer of purified CD4+CD25+ BBDR T cells to prediabetic BBDP rats prevented diabetes in 80% of recipients. Surprisingly, CD4+CD45RC-CD25- T cells were equally protective. Quantitative studies in an adoptive cotransfer model confirmed the protective capability of both cell populations, but the latter was less potent on a per cell basis. The disease-suppressing CD4+CD45RC-CD25- population expressed PD-1 but not Foxp3, which was confined to CD4+CD25+ cells. We conclude that CD4+CD25+ cells in the BBDR rat act in vitro and in vivo as natural Tregs. In addition, another population that is CD4+CD45RC-CD25- also participates in the regulation of autoimmune diabetes.     

Functional and genetic analysis of two CD8 T cell subsets defined by the level of CD45RC expression in the rat

Differential cytokine production by T cells plays an important role in the outcome of the immune response. We show that the level of CD45RC expression differentiates rat CD8 T cells in two subpopulations, CD45RC(high) and CD45RC(low), that have different cytokine profiles and functions. Upon in vitro stimulation, in an Ag-presenting cell-independent system, CD45RC(high) CD8 T cells produce IL-2 and IFN-gamma while CD45RC(low) CD8 T cells produce IL-4, IL-10, and IL-13. In vitro, these subsets also exhibit different cytotoxic and suppressive functions. The CD45RC(high)/CD45RC(low) CD8 T cell ratio was determined in Lewis (LEW) and Brown-Norway (BN) rats. These two rat strains differ with respect to the Th1/Th2 polarization of their immune responses and to their susceptibility to develop distinct immune diseases. The CD45RC(high)/CD45RC(low) CD8 T cell ratio is higher in LEW than in BN rats, and this difference is dependent on hemopoietic cells. Linkage analysis in a F(2)(LEW x BN) intercross identified two quantitative trait loci on chromosomes 9 and 20 controlling the CD45RC(high)/CD45RC(low) CD8 T cell ratio. This genetic control was confirmed in congenic rats. The region on chromosome 9 was narrowed down to a 1.2-cM interval that was found to also control the IgE response in a model of Th2-mediated disorder. Identification of genes that control the CD45RC(high)/CD45RC(low) CD8 T cell subsets in these regions could be of great interest for the understanding of the pathophysiology of immune-mediated diseases.     

Experimental autoimmune encephalomyelitis in "low" and "high" interleukin 2 producer rats. I. Cellular basis of induction

Albino Oxford (AO) rats in comparison to the Dark August (DA) strain exhibit lower susceptibility to the induction of experimental autoimmune encephalomyelitis (EAE), and interleukin 2 (IL-2) production by their spleen and lymph node cells is significantly lower. The cellular analysis of these differences in the outcome of the EAE induction, possibly related to the differences in the IL-2 production, revealed different changes in the T cell subsets in the draining lymph node (DLN) and different cellular composition of the mononuclear infiltrates in the central nervous system (CNS). After the encephalitogenic challenge, the frequency of CD8+ T cells was much higher and the expansion of CD4+ T cells was much lower in the DLN of "low" IL-2 producer rats. AO rats have not shown any clinical sign of EAE, although histological lesions in the early phases of EAE (Day 7-9) were similar to those seen in diseased DA rats. CD4/CD8 T cell ratios and the number of cells bearing receptor for IL-2 (IL-2-R+ cells) and cells bearing class II MHC antigens (Ia+) were significantly lower in the mononuclear cell infiltrates of AO rats. These data are compatible with the notion that CD4+ IL-2-R+ encephalitogenic T cells induce clinical signs of EAE in susceptible animals and show that CD8+ T cells are present in a higher percentage in the lesions of the symptom-free AO rats.     

Activation of MHC-restricted rat T cells by cloned syngeneic thyrocytes

We have previously demonstrated that rat thyrocytes express MHC class II Ag (RT1.B&D) in response to IFN-gamma. To determine whether MHC class II-positive thyrocytes can be recognized by MHC-restricted T cells, we used our clone of rat thyroid cells (1B-6) derived from the Fisher rat thyroid cell line (FRTL-5) and known to express MHC class II Ag in response to recombinant rat IFN-gamma. CD4+ and CD8+ normal syngeneic Fisher rat spleen T cells were selected by flow cytometry and averaged greater than 96% purity. We demonstrated that irradiated MHC class II-positive but not class II-negative 1B-6 thyrocytes stimulated CD4+ T cells in a primary sensitization reaction over 4 days. In contrast, CD8+ T cells had no response in similar experiments. This stimulation of CD4+ T cells was dose dependent for 1B-6 thyrocytes and was abrogated by anti-rat MHC class II mAb (MRC OX-6). Autoreactive (Fisher) and alloreactive (Buffalo) T cell lines and isolated CD4+ T cells derived from these lines, which were developed against Fisher rat spleen cells, similarly recognized MHC class II Ag expressed on 1B-6 cells but had no detectable response to 1B-6 MHC class II-negative thyrocytes or MHC class II-positive human thyroid cells. The CD4+ T cell recognition of 1B-6 cells via MHC class II Ag supports our previous data with autologous human thyroid T cell co-cultures and is indicative of an autospecific role for thyrocytes in the development of autoimmune thyroiditis.