B220+ double-negative T cells suppress polyclonal T cell activation by a Fas-independent mechanism that involves inhibition of IL-2 production

Fas-mediated apoptosis is a key mechanism for elimination of autoreactive T cells, yet loss of function mutations in the Fas signaling pathway does not result in overt T cell-mediated autoimmunity. Furthermore, mice and humans with homozygous Fas(lpr) or Fas ligand(gld) mutations develop significant numbers of B220+ CD4- CD8- double-negative (DN) alphabeta T cells (hereafter referred to as B220+ DN T cells) of poorly understood function. In this study, we show that B220+ DN T cells, whether generated in vitro or isolated from mutant mice, can suppress the ability of activated T cells to proliferate or produce IL-2, IL-10, and IFN-gamma. B220+ DN T cells that were isolated from either lpr or gld mice were able to suppress proliferation of autologous and syngeneic CD4 T cells, showing that suppression is Fas independent. Furthermore, restoration of Fas/Fas ligand interaction did not enhance suppression. The mechanism of suppression involves inhibition of IL-2 production and its high affinity IL-2R alpha-chain (CD25). Suppression also requires cell/cell contact and TCR activation of B220+ DN T cells, but not soluble cytokines. These findings suggest that B220+ DN T cells may be involved in controlling autoreactive T cells in the absence of Fas-mediated peripheral tolerance.     

Evidence for early onset, polyclonal activation of T cell subsets in mice homozygous for lpr.

Mice homozygous for lpr and gld develop profound lymphadenopathy characterized by the accumulation of two functionally anergic T cell subsets, a predominant B220+CD4-CD8- double negative (DN) population and a minor, closely related CD4 dull+ B220+ population. Lymph nodes from diseased lpr and gld mice also contain abnormally high numbers of conventional T cells, and we reported recently that a high proportion of lpr and gld CD4+B220- T cells have the hallmarks of primed or memory T cells. In the present study, we further investigated the extent, ontogeny, and possible causes of T cell activation in lpr and gld mice. The criteria used to identify primed or memory T cells included activation-dependent increases in the expression of CD44, LFA-1, and the early activation Ag, CD69, and decreases in the expression of Mel-14 and CD45RB, as well as quantitative differences in the in vitro production of IFN-gamma and the TNF-alpha by stimulated cells. A comparison of TCR V beta gene utilization by lpr T cell subsets also was undertaken. The results showed that T cell activation was widespread and complex. CD8+ T cells exhibited a similar pattern of activation to CD4+B220- T cells. The activation of these two subsets occurred in parallel, was in evidence by 4 to 6 wk of age, and was both chronic and progressive. The proportions of CD44hiLFA-1hi, CD4+B220-, and CD8+ T cells increased steadily between 4 and 20 wk of age, but changes in T cell growth, Mel-14, and CD45RB expression and cytokine secretion were not observed until mice were older than 11 wk. A very different pattern of activation was observed for B220+ T cells. At all ages, B220+ DN and CD4+B220+ T cells were CD44hiMel-14hi and 60 to 75% were CD69+. The expression of CD69 appeared to be stimulus dependent rather than constitutive, suggesting that these cells, too, may be chronically stimulated in vivo. In keeping with their anergic state, DN T cells responded poorly to cross-linking of CD69. The stimuli inducing chronic activation of CD4+B220- and CD8+ T cells are unlikely to include inappropriate reactions to autoantigens because there was no evidence for selective accumulation of CD4+ or CD8+ T cells bearing particular V beta genes or potentially self-reactive cells that normally are deleted in the thymus. By comparison, C3H-lpr DN cells displayed some potentially significant differences in V beta 6 and V beta 9 expression from CD4+B220- and CD8+ T cells.(ABSTRACT TRUNCATED AT 400 WORDS)     

Phenotypic and functional analysis of murine CD3+,CD4-,CD8- TCR-gamma delta-expressing peripheral T cells

Murine CD3+,CD4-,CD8- peripheral T cells, which express various forms of the TCR-gamma delta on their cell surface, have been characterized in terms of their cell-surface phenotype, proliferative and lytic potential, and lymphokine-producing capabilities. Three-color flow cytofluorometric analysis demonstrated that freshly isolated CD3+,CD4-, CD8- TCR-gamma delta lymph node cells were predominantly Thy-1+,CD5dull,IL-2R-,HSA-,B220-, and approximately 70% Ly-6C+ and 70% Pgp-1+. After CD3+,CD4-,CD8-splenocytes were expanded for 7 days in vitro with anti-CD3-epsilon mAb (145-2C11) and IL-2, the majority of the TCR-gamma delta cells expressed B220 and IL-2R, and 10 to 20% were CD8+. In comparison to CD8+ TCR-alpha beta T cells, the population of CD8+ TCR-gamma delta-bearing T cells exhibited reduced levels of CD8, and about 70% of the CD8+ TCR-gamma delta cells did not express Lyt-3 on the cell surface. Functional studies demonstrated that splenic TCR-gamma delta cells proliferated when stimulated with mAb directed against CD3-epsilon, Thy-1, and Ly-6C, but not when incubated with an anti-TCR V beta 8 mAb, consistent with the lack of TCR-alpha beta expression. In addition, activated CD3+,CD4-,CD8- peripheral murine TCR-gamma delta cells were capable of lysing syngeneic FcR-bearing targets in the presence of anti-CD3-epsilon mAb and the NK-sensitive cell line, YAC-1, in the absence of anti-CD3-epsilon mAb. Finally, activated CD3+, CD4-,CD8-,TCR-gamma delta+ splenocytes were also capable of producing IL-2, IL-3, IFN-gamma, and TNF when stimulated in vitro with anti-CD3-epsilon mAb.     

Cytokine production by mature and immature CD4-CD8- T cells. Alpha beta-T cell receptor+ CD4-CD8- T cells produce IL-4.

This study follows our previous investigation describing the production of four cytokines (IL-2, IL-4, IFN-gamma, and TNF-alpha) by subsets of thymocytes defined by the expression of CD3, 4, 8, and 25. Here we investigate in greater detail subpopulations of CD4-CD8- double negative (DN) thymocytes. First we divided immature CD25-CD4-CD8-CD3- (CD25- triple negative) (TN) thymocytes into CD44+ and CD44- subsets. The CD44+ population includes very immature precursor T cells and produced high titers of IL-2, TNF-alpha, and IFN-gamma upon activation with calcium ionophore and phorbol ester. In contrast, the CD44- subset of CD25- TN thymocytes did not produce any of the cytokines studied under similar activation conditions. This observation indicates that the latter subset, which differentiates spontaneously in vitro into CD4+CD8+, already resembles CD4+CD8+ thymocytes (which do not produce any of the tested cytokines). We also subdivided the more mature CD3+ DN thymocytes into TCR-alpha beta- and TCR-gamma delta-bearing subsets. These cells produced cytokines upon activation with solid phase anti-CD3 mAb. gamma delta TCR+ DN thymocytes produced IL-2, IFN-gamma and TNF-alpha, whereas alpha beta TCR+ DN thymocytes produced IL-4, IFN-gamma, and TNF-alpha but not IL-2. We then studied alpha beta TCR+ DN T cells isolated from the spleen and found a similar cytokine production profile. Furthermore, splenic alpha beta TCR+ DN cells showed a TCR V beta gene expression profile reminiscent of alpha beta TCR+ DN thymocytes (predominant use of V beta 8.2). These observations suggest that at least some alpha beta TCR+ DN splenocytes are derived from alpha beta TCR+ DN thymocytes and also raises the possibility that these cells may play a role in the development of Th2 responses through their production of IL-4.     

Ontogeny and function of B220+ L3T4+ T-cell subset of MRL/Mp-lpr/lpr mice

T-cell-enriched populations obtained from lymph nodes (LNs) of 4-month-old MRL/Mp-lpr/lpr (MRL-lpr), C3H/HeJ-lpr/lpr (C3H-lpr), and C3H/HeJ-gld/gld (C3H-gld) mice were studied for the expression of B220, L3T4, and Lyt 2 antigens. A new B220+ L3T4+ phenotype was demonstrated in T-cell populations of these mice by two-color flow cytometry with phycoerythrin-conjugated monoclonal antibodies (MoAb) to L3T4 and FITC-anti-B220 MoAb. The generation of the T subset was apparently under the influence of the lpr or gld gene, since it could not be demonstrated in T-cell-enriched populations of MRL/Mp- +/+ and normal C3H mice. The expression level of L3T4 antigen on the T subset was lower than that on B220- L3T4+ cells, while the level of B220 antigen was similar to that of B220+ L3T4- or B220+ Lyt 2- cells. The B220+ L3T4+ phenotype appeared in LNs and spleens, but not in thymuses, of MRL-lpr mice as early as 2 months of age. Its proportion to whole LN T cells at this age was equivalent to that observed in 4-month-old mice. Functional studies on FACS-sorted cell populations revealed that the T subset similar to B220+ L3T4- cells possessed deficiencies in the IL-2-IL-2 receptor system. The appearance of the T subset with an intermediate phenotype and its functional defects suggests that lpr and gld genes in these autoimmune mice exert their influences on the ontogeny and function of L3T4+ T cells and contribute to the induction of early lupus.     

Unique cell surface phenotypes of proliferating lymphocytes in mice homozygous for lpr and gld mutations, defined by monoclonal antibodies to MRL/Mp-lpr/lpr T cells

In mice bearing the autosomal recessive gene of either lpr or gld, generalized T-cell proliferation and autoimmunity occurs. The surface antigen profiles of these proliferating cells were analyzed using two-color flow cytometry analysis with two newly established rat monoclonal antibodies (ALP-1, ALP-2) directed to lpr cells. The Lp-1 antigen, defined by ALP-1, is expressed exclusively on approximately one-half of proliferating lpr and gld lymph node cells. The Lp-2 antigen, like B 220, is expressed on 80-90% of lpr and gld lymph node cells, the cells in B-cell lineage and a small population of Ly-2+ T cells from normal mice. Thus, the lpr and gld lymph node cells were classified into three subsets, Lp-1+/Lp-2+, Lp-1-/Lp-2+ and Lp-1-/Lp-2-. After stimulation with Con A or a combination of IL-2 and phorbol ester, a small population of T cells from normal mice became Lp-1+. The same treatment increased Lp-2+/Ly-2+ and induced Lp-2+/L3T4+ T-cell populations. Therefore, it seems likely that these phenotypically unique T cells are generated at some stage during the proliferation and differentiation of certain normal T-cell subpopulations. The aberrant T cells in mice with lpr and gld mutations may even be normal regulatory T cells, if they are not proliferating abnormally.     

Stimulation of murine T cells via the Ly-6C antigen: lack of proliferative response in aberrant T cells from lpr/lpr and gld/gld mice despite high Ly-6C antigen expression

Cross-linking of cell surface Ly-6C molecules with the 6C3 rat monoclonal antibody (MAb) followed by anti-rat immunoglobulin antibody acts in concert with phorbol myristate acetate (PMA) as a potent mitogenic stimulus for normal T cells. Specificity of this stimulation was demonstrated by its absence in T cells from NZB, NOD, or STb/J mice which lack the 6C3 determinant. In 6C3+ normal strains, the extent of 6C3-mediated stimulation varied, depending on the level of 6C3 antigen expression. Analysis of this stimulation in purified T cell subsets revealed that in Ly-6.1 strains (e.g., BALB/c, CBA/J), Lyt-2+ cells responded, but not L3T4+ cells, whereas in Ly-6.2 strains (e.g., C57BL/6, MRL-+/+), both subsets produced IL 2 and proliferated, although with different kinetics. Moreover, in adult MRL-+/+ mice, the minor Lyt-2-/L3T4- subset from the lymph nodes gave low responses to 6C3 cross-linking, whereas that from the thymus reacted strongly. Stimulation via Ly-6C therefore provides a pathway for differential activation of normal T cells. In contrast, the expanding population of Lyt-2-/L3T4- T cells from lpr/lpr or gld/gld mice did not proliferate in response to 6C3 antigen cross-linking plus PMA despite high levels of 6C3 antigen expression. Responsiveness of lpr/lpr T cells could not be restored with IL 1, IL 2, or both. These T cells also failed to be triggered by conjunction of PMA with either Thy-1 antigen cross-linking or concanavalin A. Moreover, they were not stimulated, in the presence of PMA, by doses of ionomycin that were optimal for normal T cells, but did respond to higher ionomycin concentrations (2 micrograms/ml), and this response was not altered by Ly-6C cross-linking. It is concluded that the Ly-6C pathway of T cell activation is not functional in the aberrant lpr/lpr (and gld/gld) T cells, and that this defect may reflect abnormalities of intracellular signaling.     

Evidence for the existence of distinct heterogeneity among the peripheral CD4-CD8- T cells from MRL-lpr/lpr mice based on the expression of the J11d marker, activation requirements, and functional properties

Autoimmune-susceptible, MRL-lpr/lpr (lpr) mice develop a profound lymphadenopathy resulting from the accumulation of CD4-CD8- (double-negative, DN) cells in peripheral lymphoid organs. The source and the mechanism of this abnormal accumulation of cells is still unknown. Recently, we reported that a significant number (approximately 35%) of the CD4-CD8- cells expressed J11d, a marker expressed by immature thymocytes but not by mature functional peripheral T cells. In the present study, we investigated the phenotype, growth requirements, and functional properties of purified J11d+ and J11d- subpopulations. Using the mAb, F23.1, which recognizes a TCR determinant encoded by the V beta 8 gene family, it was observed that approximately 30% of the J11d+ and J11d- DN cells expressed this determinant. Further studies on the thymus revealed that J11d+ DN cells from lpr thymus also contained F23.1+ cells (approximately 25%), whereas, similar cells from normal MRL(-)+/+mice were all F23.1-, consistent with earlier reports in other normal strains. Further phenotypic studies revealed that the peripheral J11d+ and J11d- cells from lpr mice were similar in expressing CD3, Ly-5 (B220), and Ly-24 (Pgp-1) determinants. When stimulated with phorbol myristic acetate (PMA) and recombinant IL-2 (rIL-2), only J11d- cells but not J11d+ cells responded by proliferation. However, in the presence of calcium ionophore (A23187) and PMA, both J11d+ and J11d- subpopulations proliferated by producing and responding to endogenous IL-2 but not IL-4. The lymph node T cells from 1-month-old MRL-lpr/lpr mice responded strongly when stimulated with PMA + rIL-4 or PMA + rIL-6. In contrast both J11d+ and J11d- subpopulations failed to respond when similarly stimulated. The J11d+ but not J11d- cells demonstrated spontaneous cytotoxic activity against the NK-sensitive YAC-1 tumor targets. The J11d- cells did not exhibit cytotoxic potential in spite of culture with PMA + rIL-2. Even after repeated culture in vitro with PMA + A23187 or PMA + rIL-2, both J11d+ and J11d- subpopulations failed to express the mature phenotype bearing CD4 and/or CD8 antigens. The present study demonstrates the expansion of unique J11d+, alpha beta-TCR+, DN T cells with cytotoxic potential in lpr mice and further suggests the existence of phenotypic and functional heterogeneity among the abnormal lpr DN cells.     

Effect of xid on autoimmune C3H-gld/gld mice

The xid gene was introduced into C3H-gld/gld mice to determine its effects on the development of autoimmune disease. C3H-gld/gld.xid mice were compared with C3H-gld/gld mice for the development of lymphadenopathy, surface phenotype of lymph node (LN) cells, c-myb oncogene RNA production, serum immunoglobulin (Ig) levels, and autoantibody production. In addition, C3H-gld/gld and C3H-lpr/lpr mice were examined for serum Ig and autoantibody levels. The results showed that the xid gene had no effect on either the development of the severe lymphadenopathy characteristic of C3H-gld/gld mice or the phenotype of the Ly-2-, L3T4-, Ly-5(B220)+ T-cell subset that is expanded in the LN and spleens of these mice. Similarly, xid did not affect the high levels of c-myb oncogene RNA expression by C3H-gld/gld LN and spleen cells. By contrast, the xid gene caused a significant reduction in serum IgM but not IgA levels and almost completely ablated the generation of both IgM and IgG anti-ssDNA antibodies and anti-dsDNA antibodies. These data suggest that the xid gene can dramatically decrease the B-cell manifestations of autoimmunity in gld homozygotes without affecting their abnormal T-cell expansion. Comparisons of age-matched C3H-gld/gld and C3H-lpr/lpr mice showed that they had similarly elevated serum IgM and IgA levels and anti-ssDNA and anti-dsDNA antibody levels providing further evidence that gld and lpr produce parallel defects in C3H mice.     

IL-7-dependent homeostatic proliferation in the presence of a large number of T cells in gld mice

In gld mice, CD4 and 8-double-negative (DN) T cells as well as naive and memory-phenotype T cells accumulate in the peripheral lymphoid organs. Although Fas ligand (L) defect accounts for the progressive accumulation of abnormal DN T cells, the existence of other mechanisms which may be involved in the defective homeostasis in gld mice has been unclear. In this study, we analyze T-cell homeostasis in gld mice using adoptive transfer systems. It was shown that a gld, but not C57BL/6 (B6), environment led to augmented proliferation of B6 T cells transferred without up-regulation of CD69. Thus, the augmented T-cell proliferation seemed to result from mal-homeostatic proliferation even in the presence of a large number of recipient T cells. T cells from lpr mice showed no significant proliferation in the B6 environment, suggesting that the absence of Fas-Fas L interaction was not responsible for the mal-homeostatic proliferation. Although similar levels of IL-7 mRNA were detected in gld and B6 spleens, the intensity of CD127 and the proportion of CD127+ cells in the T cells were significantly lower in gld mice than in B6 mice, suggesting that IL-7 excess in a gld environment is responsible for the abnormal proliferation of transferred T cells. The administration of anti-CD127 antibody inhibited the proliferation of transferred lymphocytes. Thus, IL-7-dependent proliferation seems to be involved in the abnormal proliferation of lymphocytes in gld recipients.     

Rapid T cell receptor modulation accompanies lack of in vitro mitogenic responsiveness of double negative T cells to anti-CD3 monoclonal antibody in MRL/Mp-lpr mice

The role of the CD8-, CD4- (double negative) (DN) T cells accumulating in MRL/Mp-lpr/lpr (lpr) mice is unclear. Although they bear the TCR/CD3, the lpr DN cells do not respond to Ag, and the specificity of TCR/CD3 on these cells is unknown. With the aid of monoclonal anti-murine CD3 epsilon (145-2C11), we have investigated the function of the CD3 molecule on the DN cells. 145-2C11 was not mitogenic for lpr DN lymph node cells (LNC), even in the presence of the phorbol ester 12-O-tetradecanoylphorbol 13-acetate, whereas MRL/Mp-+/+ (+/+) LNC responded strongly. Surprisingly, CD3 modulation induced by 145-2C11 was much more rapid for lpr DN than for +/+ LNC. For example, the modulation observed after 10 min in lpr DN LNC required at least 2 h in +/+ cells. This was not due solely to a property of the 145-2C11 antibody, because both TPA and the F23.1 anti-TCR mAb also provoked a faster modulation of the TCR in lpr DN LNC. Double-staining experiments showed that co-culturing +/+ and lpr DN LNC did not alter their respective rates of modulation, which suggests an intrinsic defect in the lpr DN cells. Moreover, in LNC from 6-wk-old lpr mice (before the appearance of DN cells), as well as in normal phenotype-bearing T cells (CD8+ or CD4+) from 6-mo-old lpr mice, the CD3 modulation was similar to that of +/+ LNC. After modulation, the CD3 molecule was reexpressed at the surface of both +/+ and lpr DN cells during subsequent incubation of the cells without 145-2C11. In addition, spontaneous recycling of CD3 was similar in +/+ and lpr DN LNC. The rapid modulation of the lpr DN TCR/CD3 is presumably related to the anergy of this cell population.     

Accelerated programmed cell death of MRL-lpr/lpr T lymphocytes.

MRL-lpr/lpr (lpr) mice develop a polyclonal accumulation of abnormal peripheral T lymphocytes, which bear surface alpha beta TCR, CD3, and the B220 isoform of CD45, but lack CD4, CD8, and CD2. These T cells have a constitutively phosphorylated CD3 zeta chain and manifest a defect in signal transduction that results in a lack of IL-2 production and proliferation. We investigated whether this signaling abnormality might contribute to their accumulation via a defect in T cell elimination in the periphery. T cell deletion occurs through a process of programmed cell death with DNA degradation, or apoptosis. Viable lymphocytes from lpr mice were found to undergo rapid programmed cell death in culture within 4 h without additional activation, which was not observed in lymphocytes from normal MRL-+/+ or C57BL/6-+/+ mice. Both nonmature B220+ and mature B220- T lymphocytes from lpr mice display this accelerated programmed cell death, indicating that this is a defect affecting all peripheral T lymphocytes in lpr mice. In vitro apoptosis of lpr T cells could be inhibited with PMA, a stimulator of protein kinase C. Thus, the massive accumulation of T lymphocytes in the lymphoid tissue of lpr mice is not due to a defect in their ability to undergo programmed cell death in vitro. The activation state of lpr T cells may contribute to their rapid degradation of DNA in vitro.     

Abnormal thymocyte development and production of autoreactive T cells in T cell receptor transgenic autoimmune mice.

Development of a C57BL/6-+/+ TCR transgenic mouse containing the rearranged TCR alpha- and beta-chain specific for the Db + HY male Ag results in production of a nearly monoclonal population of early thymocytes expressing the Db + HY reactive TCR. These thymocytes are autoreactive in H-2Db male mice and undergo clonal deletion and down-regulation of CD8. To study the effect of the lpr gene on development of autoreactive T cells, these transgenic mice were backcrossed with C57BL/6-lpr/lpr mice. T cell populations in the thymus and spleen were analyzed by three-color flow cytometry for expression of CD4, CD8, and TCR. The thymus of TCR transgenic H-2b/b lpr/lpr male mice had an increase in percent and absolute number of CD8dull thymocytes compared to TCR transgenic H-2b/b +/+ male mice. However, there was not a complete defect in clonal deletion, because clonal deletion and down-regulation of CD8 was apparent in both +/+ and lpr/lpr H-2Db HY+ male mice compared to H-2Db HY- female mice. The phenotype of splenic T cells was almost identical in TCR transgenic +/+ and lpr/lpr males with about 50% CD4-CD8- T cells and 50% CD8+ T cells. However, there was a dramatic increase in the SMLR proliferative response of splenic T cells from TCR transgenic lpr/lpr males compared to TCR transgenic +/+ males. To determine the specificity of this response, spleen cells from TCR transgenic lpr/lpr and +/+ mice were cultured with irradiated H-2b/b and H-2k/k male and female spleen cells. T cells from TCR transgenic C57BL/6-lpr/lpr male mice had an increased proliferative response to H-2b/b male spleen cells compared to T cells from TCR transgenic C57BL/6(-)+/+ male mice, but both lpr/lpr and +/+ mice had a minimal response to irradiated H-2b/b female or H-2k/k male or female stimulator cells. The splenic T cells from TCR transgenic lpr/lpr mice also had an increased specific cytotoxic activity against H-2b/b male target cells compared to TCR transgenic +/+ mice. These results demonstrate that there is a defect in negative selection of self-reactive T cells in the thymus of lpr/lpr mice and a defect in induction or maintenance of clonal anergy of self-reactive T cells in the periphery of lpr/lpr mice.     

Gammadelta T cells promote a Th1 response during coxsackievirus B3 infection in vivo: role of Fas and Fas ligand

Fas/Fas ligand (FasL) interactions regulate disease outcome in coxsackievirus B3 (CVB3)-induced myocarditis. MRL(+/+) mice infected with CVB3 develop severe myocarditis, a dominant CD4(+) Th1 (gamma interferon [IFN-gamma(+)]) response to the virus, and a predominance of gammadelta T cells in the myocardial infiltrates. MRL lpr/lpr and MRL gld/gld mice, which lack normal expression of Fas and express a mutated FasL, respectively, have minimal myocarditis and show a dominant CD4(+) Th2 (interleukin-4 [IL-4(+)]) phenotype to CVB3. Spleen cells from virus-infected wild-type, lpr, and gld animals proliferate equally to virus in vitro. Adoptive transfer of gammadelta T cells from hearts of CVB3-infected MRL(+/+) mice (FasL(+)) into infected MRL gld/gld recipients (FasL(-)/Fas(+)) restores both disease susceptibility and Th1 cell phenotype. However, transfer of these cells into MRL lpr/lpr recipients (FasL(+)/Fas(-)) did not promote myocarditis and the viral response remained Th2 biased. This paralleled the expression of very high surface levels of FasL by myocardial gammadelta T cells, as well as their propensity to selectively lyse Th2 virus-specific CD4(+) T cells. These results demonstrate that Fas/FasL interactions conferred by gammadelta T cells on lymphocyte subpopulations may regulate the cytokine response to CVB3 infection and pathogenicity.     

Phenotypic, functional, and molecular genetic comparisons of the abnormal lymphoid cells of C3H-lpr/lpr and C3H-gld/gld mice

Lymph node cells from C3H mice homozygous for lpr and gld were compared for expression of cell surface antigens, lectin-binding sites, functional characteristics, expression of ecotropic MuLV, and organization of Ig and T cell receptor (TcR) beta-chain genes. The abnormal cells (Ly-2-/L3T4-) populating nodes of both mutant strains were specifically purified by using plate separation techniques. The purified abnormal cells were shown to express the beta-chain of the TcR, to exhibit rearrangements of the beta-chain genes, and to express TcR beta and alpha gene mRNA, demonstrating the T cell origin of these populations. FMF analyses of the separated abnormal cells showed them to be Thy-1+, Ly-1+, Ly-2-, L3T4-, Ly-5(B220)+, Ly-6+, Ly-22+, Ly-24+, sIg-, ThB-, Ia-, HSA-/+, and PC.1+ and to bind at high levels lectins that normally bind preferentially to B cells. These cells did not proliferate or generate CTL in response to stimulation with alloantigens, and supernatants of cells stimulated with Con A were devoid of IL 2. These characteristics do not correspond to those of any known immature or mature population of normal T cells. The findings that the abnormal T cells of lpr and gld homozygotes are indistinguishable for each parameter examined support the suggestion that these mutations may affect different enzymes in a common metabolic pathway of major importance to T cell differentiation and function.     

IL-12 drives IFN-gamma-dependent autoimmune kidney disease in MRL-Fas(lpr) mice

IL-12 is secreted by kidney tubular epithelial cells in autoimmune MRL-Fas(lpr) mice before renal injury and increases with advancing disease. Because IL-12 is a potent inducer of IFN-gamma, the purpose of this study was to determine whether local provision of IL-12 elicits IFN-gamma-secreting T cells within the kidney, which, in turn, incites injury in MRL-Fas(lpr) mice. We used an ex vivo retroviral gene transfer strategy to construct IL-12-secreting MRL-Fas(lpr) tubular epithelial cells (IL-12 "carrier cells"), which were implanted under the kidney capsule of MRL-Fas(lpr) mice before renal disease for a sustained period (28 days). IL-12 "carrier cells" generated intrarenal and systemic IL-12. IL-12 fostered a marked, well-demarcated accumulation of CD4, CD8, and double negative (CD4-CD8- B220+) T cells adjacent to the implant site. We detected more IFN-gamma-producing T cells (CD4 > CD8 > CD4-CD8- B220+) at 28 days (73 +/- 14%) as compared with 7 days (20 +/- 8%) after implanting the IL-12 "carrier cells;" the majority of these cells were proliferating (60-70%). By comparison, an increase in systemic IL-12 resulted in a diffuse acceleration of pathology in the contralateral (unimplanted) kidney. IFN-gamma was required for IL-12-incited renal injury, because IL-12 "carrier cells" failed to elicit injury in MRL-Fas(lpr) kidneys genetically deficient in IFN-gamma receptors. Furthermore, IFN-gamma "carrier cells" elicited kidney injury in wild-type MRL-Fas(lpr) mice. Taken together, IL-12 elicits autoimmune injury by fostering the accumulation of IFN-gamma-secreting CD4, CD8, and CD4-CD8- B220+ T cells within the kidney, which, in turn, promote a cascade of events culminating in autoimmune kidney disease in MRL-Fas(lpr) mice.     

Expression of a bone marrow-associated Ly-6 determinant on the T cell population expanding in the lymph nodes of the autoimmune mouse strain MRL/Mp-lpr/lpr

In this report we describe the reactivity patterns of two monoclonal anti-Ly-6.2 antibodies toward lymph node (LN) cells of the autoimmune MRL/Mp-lpr/lpr (lpr) and the normal congenic MRL/Mp-+/+ (+/+) mouse strains. The monoclonal antibody 34-11-3, which has previously been found to detect a LN-associated Ly-6.2 antigen, reacted with both lpr and +/+ LN cells. Another monoclonal antibody, 34-10-7, which has been demonstrated to detect a bone marrow- (BM) associated determinant, was found to react with a small proportion of +/+ LN cells and unexpectedly with a high percentage of lpr LN cells. The expression of this BM determinant found in the LN of lpr mice was age dependent, and its presence on Thy-1.2+ cells increased with the expansion of a subset of Lyt-1+2- cells. In contrast, dual labeling experiments showed that in +/+ and young lpr mice a small subset of Lyt-1+2+ cells express this BM-associated Ly6.2 determinant. Therefore these findings demonstrate that the lpr gene-dependent T cell expansion in the LN results in both aberrant expression and association of lymphocyte cell surface markers.     

Characterization and differentiation of CD4-, CD8- thymocytes sorted with the Ly-24 marker

Heterogeneity within the CD4-, CD8- thymocyte population was explored by flow microfluorometry on thymocytes from 6-wk-old female C57BL/6 mice. Double negative cells were obtained by twice killing thymocytes with anti-CD4 and anti-CD8 antibodies. The resultant population lacked CD4, CD8, and Ig on cell surfaces; it contained cells bearing Ly-24 (27%), Ly-6C (6%), and Ly-5 (B220) detected by 6B2 (6%). These markers are the same as those characteristic of lpr/lpr T cells; they also are found on bone marrow cells. In order to investigate the maturational pathway of CD4-, CD8- thymocytes, such cells were cultured in vitro for 6 days with phorbol myristate acetate + calcium ionophore. There was a marked increase in cells bearing Ly-24 with time; by 6 days essentially all bore Ly-24. A lesser increase (to 15%) in 6B2 + Thy-1 positive cells was observed. Small numbers of cells bearing CD4 and/or CD8 also were found after 6 days in vitro. In additional studies, CD4-, CD8- cells were first sorted with respect to Ly-24 and then cultured with phorbol myristate acetate + calcium ionophore. Ly-24+ cells proliferated vigorously and formed clusters whereas Ly-24- cells did not. The former gave rise to large numbers of CD4+, CD8+ cells; the latter exhibited little differentiation. These studies demonstrate substantial heterogeneity within the CD4-, CD8- thymocyte population. Use of the markers Ly-24, Ly6C, and 6B2 allows a subdivision of such progenitor thymocytes. Different stages of maturation as well as possible lineages of cells may be investigated by combining such hemopoietic cell surface markers with in vitro culture.