Defective B cell tolerance induction in New Zealand black mice. I. Macrophage independence and comparison with other autoimmune strains

B cell unresponsiveness was examined in vitro by using spleen cells from autoimmune NZB, BXSB/Mp male, MRL/Mp-Ipr/Ipr (MRL/l), and control mice, and the tolerogen trinitrophenyl human gamma-globulin (TNP-HGG). The B cell subset responsive to TNP-Brucella abortus in each autoimmune and control strain that was tested was highly susceptible to tolerance induction with the use of high epitope density conjugates (TNP30HGG and TNP32HGG). When a tolerogen with a lower epitope density was used (TNP7HGG), several control strains were all rendered tolerant in a thymic-independent and hapten-specific manner. NZB B cells were resistant to all concentrations of TNP7HGG tested, whereas B cells from BXSB/Mp male and MRL/1 mice were resistant to low concentrations of this tolerogen. NZB mice were resistant in addition to tolerance induction with TNP9HGG, TNP10HGG, and TNP12.7HGG. Experiments were performed to determine whether splenic macrophages played a role in resistance to tolerance in NZB mice. The mixing of NZB and control DBA/2J T cell-depleted splenocytes revealed no modulatory effects by the accessory cells in culture. Moreover, B cells rigorously depleted of macrophages by double Sephadex G-10 column passage exhibited characteristic patterns of resistance or susceptibility in NZB and control strains, respectively. These findings support the conclusion that resistance to tolerance in NZB mice is determined at the B cell level and are consistent with the hypothesis that diverse immunoregulatory disturbances contribute in varying degrees to the development of systemic lupus erythematosus in different inbred strains of mice.     

Responses of B cells from autoimmune mice to IL-5

Three strains of mice (NZB/W F1 X NZW (NZB/W), BXSB, and MRL/Mp-lpr/lpr (MRL/lpr] develop an autoimmune disease that is clinically and immunologically similar to human SLE. A characteristic of these mice is polyclonal B cell hyperactivity. To explore whether this may be related to hyper-responsiveness to B cell stimulatory factors, we investigated the proliferative and secretory responses of B cells from these mice to semi-purified natural and rIL-5, a major regulator of B cell development in the mouse. As this lymphokine stimulates growth and differentiation of activated B cells, attention was focused on in vivo-activated B cell populations, obtained from the interface of 50/65% Percoll density gradients, from normal or autoimmune mice. This cell population from NZB/W mice secreted IgM and incorporated [3H]TdR at significantly higher levels in response to IL-5, and was more sensitive to IL-5, than a comparable population from several normal murine strains. NZB/W female and male mice displayed heightened responses to IL-5, indicating that this is characteristic of the strain in general and is not associated with the accelerated severe disease of the females. Small resting B cells from NZB/W and normal mice were insensitive to IL-5 stimulation. In contrast to NZB/W mice, no difference was observed in the magnitude of either proliferative or Ig secretory responses between in vivo-activated B cell populations from autoimmune BXSB and MRL/lpr or normal mice. Thus, B cell hyper-responsiveness to IL-5 is a characteristic of NZB/W mice but not of two other lupus-prone murine strains. As one unique feature of NZB/W mouse B cells compared to normal and other autoimmune B cells is an elevated proportion of Ly-1+ B cells, the possibility of IL-5 hyper-responsiveness being associated with this B cell subpopulation was investigated. Fluorescence-activated cell sorter sorted Ly-1+ and Ly-1- B cells both responded to IL-5, however Ly-1+ B cells consistently showed a higher stimulation index in both proliferative and Ig secretory responses to this lymphokine.     

Characteristics of in vitro production of antibodies to DNA in normal and autoimmune mice.

The in vitro production of antibodies to dsDNA was studied with spleen cells from normal and autoimmune mice. After culture for 4 days, the binding of dsDNA in the culture supernatant was measured by a radioimmunoprecipitation assay. The production of antibodies to dsDNA by spleen cells appeared at 15 hr after culture and reached a plateau at 24 hr. No antibodies were produced by thymus cells or splenic T cells. The specificity for dsDNA was shown by competitive inhibition with nonradioactive nucleic acids. Autoimmune strains of mice (NZB/NZW, BXSB, MRL/1) produced more antibodies to dsDNA than did several control strains. Young B/W mice and control strain mice produced mainly IgM antibodies, whereas older B/W mice produced predominantly IgG antibodies to dsDNA. The in vitro production of antibodies to dsDNA by aged B/W spleen cells was macrophage and T cell dependent.     

Increased spontaneous polyclonal activation of B lymphocytes in mice with spontaneous autoimmune disease.

Early in life, mice of four kinds [NZB, (NZB X NZW)F1, MRL/1, and male BXSB] with autoimmune disease spontaneously produced far more (greater than 3 S.D.) anti-hapten antibody-forming cells in spleens and greater concentrations of anti-hapten antibodies in sera than immunologically normal strains of mice (AKR, BALB/c, C57BL/6, DBA/1-J, DBA/2J, LG/J, 129, NZW, and female BXSB). This increased nonspecific antibody production by the abnormal animals' B cells correlated well with the spontaneous development of anti-single-stranded DNA antibodies, but not with serum levels of the viral envelope glycoprotein, gp70. These results suggest that the spontaneous formation of autoantibodies in mice whose immunologic disorder is manifested by a lupus-like disease may result from polyclonal activation of B cells by endogenous or exogenous B cell activators.     

Abnormal polyclonal B cell activation in NZB/NZW F1 mice

Spleen cells from autoimmune (10-mont-old) NZB/NZW (B/W) mice failed to generate appreciable numbers of antibody-forming cells (AFC) in vitro to TNP-substituted sheep erythrocytes in response to the polyclonal B cell activators (PBA), LPS and PPD, despite normal DNA synthetic responses to these agents and normal AFC responses to TNP-Ficoll. The failure to respond to PBA in old B/W mice was not due to suppressor T cells since anti-brain-associated-theta-treated spleen cells still failed to generate AFC in response to PBA. The defect was age-related since cells from young B/W mice generated vigorous AFC responses to PBA. It is suggested that the failure of the spleen cells of old B/W mice to generate AFC is a result of in vitro polyclonal B cell activation in the course of autoantibody formation.     

The effect of thymectomy on lupus-prone mice

The effect of neonatal thymectomy on the induction and/or modification of murine SLE disease was examined in several representative groups of mice with early-life SLE (MRL/Mp-lpr/lpr females, BXSB males, (NZB X W)F1 females, (NZW X BXSB)F1 males and females), late-life SLE (MRL/Mp-+/+ and BXSB females), and normal strains (BALB/c and C57BL/6 females). Our results indicated that thymectomy prevented disease only in the MRL/Mp-lpr/lpr SLE mice, and that this effect diminished as thymectomy was delayed beyond 3 wk post-natally. In the other SLE mice studied, neonatal thymectomy did not modify disease symptoms to any significant degree. Moreover, depletion of mature T cells from donor BXSB male bone marrow did not affect the expression of early-life SLE in thymectomized BXSB female recipients. Neonatal thymectomy did not induce SLE in normal mice. Of note, neonatal thymectomy did not completely deplete the Thy-1.2+ cell population, i.e., 10 to 15% remained in the spleens of the thymectomized mice. This incomplete T cell depletion, together with the previously demonstrated dependence on and hyperresponsiveness of BXSB and (NZB X W)F1 B cells to T helper cell-derived accessory signals, cast doubts on earlier conclusions that B cells from some SLE mice can autonomously proliferate and differentiate to autoantibody-secreting cells. It seems more appropriate to conclude that B cells from the various SLE mice vary in their degree of response to, and production of, T cell-derived helper signals, and thus in their expression of B cell hyperactivity and disease.     

Treatment of murine lupus with monoclonal anti-T cell antibody

Three strains of autoimmune mice (MRL/lpr, NZB/NZW, and BXSB) were treated with repeated injections of rat monoclonal anti-T cell antibody (anti-Thy-1.2) in order to determine 1) the extent and duration of target cell depletion, 2) the effect of T cell depletion on the course of autoimmunity, and 3) the magnitude and consequences of the host immune response to the monoclonal antibody. Mice were treated with 6 mg of anti-Thy-1.2 every 2 wk beginning early in their disease. Treatment produced a substantial reduction in circulating T cells in all three strains. Therapy was beneficial in MRL/lpr mice. It reduced lymphadenopathy, lowered autoantibody concentrations, retarded renal disease, and prolonged life. In contrast, treatment did not improve autoimmunity in NZB/NZW mice, and it caused fatal anaphylaxis in BXSB mice. These findings demonstrate that monoclonal antilymphocyte antibodies can serve as specific probes to examine the cells that contribute to autoimmunity. Moreover, they illustrate the potential therapeutic value of monoclonal antilymphocyte antibodies when a pathogeneic cell subset can be identified. However, the same antibody may have a broad range of effects, from efficacy to severe toxicity, even in diseases that share clinical features.     

Abrogation of murine lupus by the xid gene is associated with reduced responsiveness of B cells to T-cell-helper signals

Introduction of the xid genetic mutation into strains of mice (NZB, MRL/1, BXSB), which are normally susceptible to a lupus-like disorder, significantly delays the onset of disease and reduces the polyclonal B-cell activation characteristic of the lupus-prone strains. Evidence is presented here which shows that B cells from NZB and MRL/1 mice which carry the xid mutation have drastically reduced responses to T-cell-derived B-cell-growth- and differentiation-inducing activities. These results are in accord with a theory that acceleration of lupus onset may be due to overproduction of and/or increased responsiveness to B-cell activation signals.     

Changes in the compositions of the null cell compartment with murine autoimmunity

The subpopulations that comprise the null cell compartment were examined sequentially in various strains of autoimmune-prone mice. Different patterns emerged that were consistent within strains but differed from strain to strain. Abnormalities appear earlier in life in short-lived mice, such as male BXSB and MRL/1 mice, than in relatively long-lived strains, such as female BXSB and NZB mice. The accumulation of T cells in MRL/1 mice was accompanied by null cell changes that contrasted with those that developed in AKR/J mice after their spleens were infiltrated with leukemic T cells. It would seem that lymphocyte perturbations with murine autoimmunity also involve their precursor cells and that these precursor cell changes vary in different strains, perhaps in relation to different genetic factors.     

Resistance to tolerance induction in B cells of autoimmune mice—Abnormal expansion of low affinity IgG-producing B-cell population

Several strains of mice are known to develop spontaneous autoimmune diseases like lupus erythematosus and they show various immunological abnormalities as well. Despite different genetic backgrounds, they manifest various immunological abnormalities in common, e.g., polyclonal B-cell activation (PBA) and resistance to tolerance induction. To elucidate mechanisms of the development of autoimmunity, tolerance inducibility was examined in autoimmune and normal mice using trinitrophenylated carboxymethyl cellulose (TNP-CMC) as tolerogen which is known to induce TNP-specific B-cell tolerance without the participation of T cells. NZB and MRL/Mp-lpr/lpr mice were used as autoimmune mice and C57BL/6, BALB/c, and MRL/Mp-+/+ mice as nonautoimmune mice. When TNP-CMC-injected mice were challenged with T-independent antigens, all of the mice tested were shown to be tolerant. In contrast, when TNP-CMC-injected mice were challenged with T-dependent antigen and secondary IgG responses were assessed, autoimmune mice showed rather hyperreactivity, while nonautoimmune mice showed hyporesponsiveness. Cyclophosphamide improved this defective tolerance inducibility. By the solid-phase radioimmunoassay it was revealed that average affinity of serum anti-TNP antibodies produced in TNP-CMC-injected mice was low. Such low affinity antibodies were produced in large amount in autoimmune mice. Hence, it was suggested that B-cell clones destined to produce low affinity IgG antibodies were responsible for the resistance to tolerance induction and such clones were expanding in autoimmune mice.     

Studies of congenic MRL-Ipr/Ipr.xid mice

Highly inbred MRL-Ipr/Ipr.xid congenic mice were bred and compared with their + littermates. The xid-bearing congenics developed lymphadenopathy consisting of dull Ly-1+ T cells and impairment of cellular proliferation and IL 2 production in response to the T cell mitogen Con A. Thus, the lpr gene was fully expressed. The xid gene, however, was also expressed as indicated by the failure to respond to immunization with TNP-Ficoll and flow cytometric analysis of splenic B cells. The xid gene was associated with a marked reduction in IgM anti-ssDNA and anti-nDNA of both classes, and serum Ig-bound gp 70. Kidney disease was markedly retarded as was death from the autoimmune process. These studies suggest that the T cell lymphoproliferation and dysfunction characteristic of MRL-Ipr/Ipr mice is not sufficient to induce accelerated autoimmunity; xid is able to markedly slow the process. The xid gene interferes with the development of a B cell subset necessary for maximum autoantibody production, anti-gp 70 production, and the resultant immune complex renal and cardiac disease. The present finding of protection against accelerated autoimmunity in MRL-Ipr/Ipr mice by xid, coupled with previous demonstrations of protection against autoimmunity in other autoimmune mouse strains, suggests that a common approach to the therapy of systemic lupus may be possible.     

Biased expression of variable region gene families of the immunoglobulin heavy chain in autoimmune-prone mice

We have examined usage of variable region gene families of the immunoglobulin heavy chain (VH gene family) in spleens of MRL/MpJ-1pr/lpr (MRL/lpr), (NZB x NZW)F1, and BXSB mice by Northern analysis using various VH probes, including the VHPAR gene which we cloned and identified as a gene encoding the heavy-chain variable region of antipoly(ADP-ribose) antibody. The amount of VHS107 family mRNA was almost constant for the same amount of splenic crude RNA in autoimmune-prone and normal mice, while concentrations of other family mRNAs were elevated in autoimmune-prone mice. For example, per splenic RNA the VHPAR family was expressed in MRL/lpr mice 10 times more than in their normal counterpart, MRL/MpJ-+/+ (MRL/+) mice. These results indicate the bias of VH gene usage in autoimmune-prone mice. Expression of the VHS107 family was depressed from an early life stage of MRL/lpr and male BXSB mice. Furthermore, the expression of IL-4 and IL-5 were quantitatively compared, as B cell differentiation factor was thought to be produced by abnormally proliferative T cells in lymph nodes of MRL/lpr mice. We could not, however, observe overproduction of IL-4 and IL-5 mRNA in the lymph nodes.     

IgG anti-DNA autoantibodies within an individual autoimmune mouse are the products of clonal selection

Although mice from almost all inbred strains produce IgM anti-DNA antibody in response to B cell mitogens, only (NZB x NZW)F1 mice and mice from other strains that are genetically predisposed to autoimmunity spontaneously produce anti-DNA antibody of the IgG isotype. Because (NZB x NZW)F1 mice display marked B cell hyperactivity, anti-DNA antibody production in these mice has been thought to result from spontaneous, polyclonal B cell activation. Although this may be true for IgM anti-DNA antibodies, our results demonstrate that IgG anti-DNA antibodies are not polyclonal. Rather, IgG anti-DNA autoantibodies within an individual autoimmune mouse are oligoclonal and somatically mutated. These results demonstrate that IgG anti-DNA autoantibodies are the products of clonally selective B cell stimulation and exhibit the same characteristics as secondary immune antibodies to conventional immunogens: they are IgG, they are clonally restricted, and they are somatically mutated.     

Undernutrition without malnutrition restricts the numbers and proportions of Ly-1 B lymphocytes in autoimmune (MRL/I and BXSB) mice

MRL/Mp-lpr/lpr (MRL/l) and BXSB mice represent inbred mouse strains in which lymphoproliferative disease and autoimmune disease that includes lethal renal disease routinely occurs by 6 months of age. Chronic energy intake restriction increases longevity and health span of MRL/l and BXSB mice as it does in mice of other short-lived as well as long-lived strains. Chronic energy intake restriction forestalls development of the lymphoproliferative process, prevents development of renal lesions, decreases levels of circulating immune complexes, and permits maintenance of vigorous immunologic function with age. We have reported that in autoimmune-prone mice, a population of Ly-1 B lymphocytes that is associated with autoimmune disease and is greatly expanded among cells of the spleen, peritoneal exudate, and peripheral blood can be reduced in proportion as a consequence of undernutrition without malnutrition. Herein, we demonstrate that in MRL/l and BXSB mice, chronic energy intake restriction imposed at weaning inhibited accumulation of Ly-1 B lymphocytes throughout the lymphoid system, i.e., among cells of the spleen, thymus, mesenteric lymph nodes, bone marrow, peritoneal exudate, and peripheral blood when these tissues or fluids were studied at age 3 or 5 months. These results extend our previous finding that autoimmune-prone mice possess unusually large numbers of Ly-1 B cells in their lymphoid tissues which can be reduced in frequency as a function of diet toward the levels present in long-lived autoimmune-resistant mice.     

Effects of calorie restriction on immunologic functions and development of autoimmune disease in NZB mice.

Chronic energy (calorie) intake restriction (CEIR) prolonged life, inhibited autoimmune disease, and influenced immunologic and hematologic parameters in NZB mice. Abnormalities in numbers and proportions of T and B cells populations were corrected. Deficient responses to phytomitogens, mixed lymphocyte reactions, formation of plaque-forming cells to sheep red blood cells in vitro, production of cytotoxic T lymphocytes after in vitro stimulation, and interleukin 2 production were also corrected. CEIR prevented the extreme splenomegaly that normally occurs with age in NZB mice. This influence was associated with reduction of a greatly expanded non-T, non-B lymphoid cell population. Calorie restriction also prevented in NZB mice the rapid decrease in total numbers of colony-forming B cells in bone marrow that is also characteristic of mice of this strain. The influences of CEIR on immune parameters and hematopoiesis were generally less marked in non-autoimmune-prone DBA/2 mice than in autoimmune-prone NZB mice. CEIR has been shown to produce profound influences on several strains of autoimmune-prone mice (NZB x NZW)F1, MRL/lpr, BXSB, and NZB herein). In each of these strains, the pathogenesis and manifestations of autoimmune disease are dissimilar. Therefore, it seems likely that calorie restriction acts on an as yet elusive mechanism that operates to foster development of the diseases associated with aging common to each of these autoimmune strains as well as autoimmune-resistant mice and rats. Further investigation of the molecular and cellular bases of the benefits of CEIR seems urgent.     

CBA/N X-linked defect delays expression of the Y-linked accelerated autoimmune disease in BXSB mice

BXSB male mice spontaneously develop progressive autoimmune disease characterized by high serum immunoglobulins, including anti-nuclear antibodies (ANA), enlarged spleen and lymph nodes, and diffuse proliferative glomerulonephritis. Females develop symptoms at a much slower rate. The mechanisms underlying the autoimmune disease and the nature of the Y-linked accelerating factor have not yet been elucidated. We found that the male progeny of the cross between the non-autoimmune strain CBA/Ca and BXSB (CBA/Ca X BXSB)F1 showed progressing signs of autoimmunity starting at 6 to 7 mo. In contrast, the male progeny that resulted from BXSB males crossed with immune-defective CBA/N females (Xid) were devoid of splenic B colonies, were nonresponsive to TNP-Ficoll, and were free of autoimmune disease for at least 10 mo. At 18 mo, some of the (CBA/N X BXSB)F1 mice developed weak antinuclear antibodies, but no spleen or lymph node enlargement was seen. The same mice had low anti-TNP Ficoll responses but did not produce B colonies in vitro. The role of the X chromosome in regulating expression of autoimmunity in young and old BXSB mice is discussed.     

Administration of monoclonal anti-T cell antibodies retards murine lupus in BXSB mice

Murine lupus in BXSB mice is associated with B cell hyperactivity, monocyte proliferation, and impaired T cell function. However, the significance of these abnormalities, and the relationship among them, has not been clearly established. To examine the role of T cells in the pathogenesis of autoimmune disease in BXSB mice, we depleted specific T cell subsets from BXSB males by using rat IgG2b monoclonal antibodies (MAb) to either Thy-1.2 (on all T cells) or L3T4 (on "helper/inducer" T cells). A single injection of anti-Thy-1.2 (6 mg i.v.) at age 3 mo produced a sustained 40 to 50% reduction in circulating T cells for 6 mo. Treatment prevented monocytosis, reduced anti-DNA antibody concentration, and retarded renal disease, but it did not prolong life. Repeated injections of rat MAb to Thy-1.2 were precluded by the development of a host immune response to rat immunoglobulin (Ig) that can cause anaphylaxis in BXSB mice. In contrast, rat MAb to L3T4 stimulated little or no immune response to rat Ig. We therefore were able to treat BXSB mice weekly with anti-L3T4 (2 mg i.p.) from age 3 to 12 mo. Treatment reduced circulating L3T4+ cells beneath the level of detection by fluorescence analysis. It also significantly reduced monocytosis, anti-DNA antibody production, renal disease, and mortality. These findings establish that monocytosis and autoimmunity in BXSB mice are promoted by T cells. They extend our previous observation that MAb to L3T4 retard autoimmunity in NZB/NZW F1 mice. Our finding that treatment with MAb to L3T4 is effective in two strains of lupus-prone mice suggests that treatment with MAb to Leu-3/T4, the human homologue for L3T4, may be effective in people with systemic lupus erythematosus.     

Studies of immune responses in mice prone to autoimmune disorders. II. Decreased down-regulation by auto-anti-idiotype antibody in autoimmune-prone mice

Three lines of evidence are presented which suggest that autoimmune-prone mice are deficient in the production of auto-anti-idiotype antibody during their immune response to trinitrophenylated Ficoll (TNP-F). NZB, MRL lpr/lpr and older BXSB male mice have no hapten-augmentable plaque-forming cells (PFC). Hapten-augmentable PFC have been previously shown to be cells whose secretion of antibody has been inhibited by the binding of auto-anti-idiotype antibody to cell surface idiotype. Sera from TNP-F immunized NZB mice lack PFC inhibiting activity (anti-idiotype antibody). Spleen cells from TNP-F immune NZB mice fail to transfer anti-idiotype antibody-mediated suppression to naive mice as do spleen cells from immune non-autoimmune-prone mice. Taken together these data suggest that autoimmune-prone mice are deficient in auto-anti-idiotype antibody-mediated downward regulation of their immune responses. It was further shown that the immune response of NZB mice to TNP-F shows a slower decline in splenic PFC and a greater heterogeneity of PFC affinity than do the responses of non-autoimmune-prone strains. Since athymic (nude) mice, which were previously shown to be defective in the production of auto-anti-idiotype antibody, also show a slower decline in splenic PFC and an increased heterogeneity of PFC affinity, it is suggested that these peculiarities of the immune responses of autoimmune-prone and athymic mice are also the consequences of the lack of auto-anti-idiotype antibody-mediated down-regulation.     

Elicitation of experimental allergic encephalomyelitis (EAE) in mice with the aid of pertussigen

Seeking common abnormalities in mice genetically predisposed to lupus-like autoimmune disease, we investigated (1) the ontogeny of Ia antigens (I-A/I-E) on the surfaces of resident peritoneal macrophages (rpM phi) of lupus and normal mice, (2) spontaneous and lectin-induced in vitro production of M phi-stimulating factors (interferon, IFN; M phi-activating factor, MAF; M phi-Ia-inducing/recruiting factor, MIRF), and (3) responses of rpM phi from such animals to Ia-inducing signals. Indirect immunofluorescence techniques showed that Ia+ rpM phi increased numerically during the life spans of MRL/Mp lpr/lpr, while no such increase was observed in age-matched non-lpr MRL/Mp +/+ or (MRL/Mp lpr/lpr X MRL/Mp +/+)F1 hybrid mice. However, neonatal thymectomy, which prevents lymphoproliferation and autoimmune disease in MRL/Mp lpr/lpr mice, had no effect on this enhanced M phi I-A/I-E expression. NZB mice developed a similar increase with age, whereas BXSB and (NZB X NZW)F1 lupus mice, like immunologically normal controls, had low numbers of I-A/I-E+ rpM phi. Cultured splenocytes of lupus mice, including those with high percentages of I-A/I-E+ rpM phi, did not spontaneously (in the absence of mitogens) elaborate MIRF, MAF, or IFN activity. Furthermore, concanavalin A-stimulated splenocytes from lupus mice, particularly strains with early autoimmune disease manifestations [MRL/Mp lpr/lpr, male BXSB, and female (NZB X NZW)F1] produced levels of these lymphokines that were lower than normal controls. MRL/Mp lpr/lpr and NZB rpM phi, when stimulated in vitro with the supernatant of a MIRF-producing T cell hybridoma, did not hyperrespond. Our study shows that increased I-A/I-E+ rpM phi occur in some, but not all, lupus mice and this increase does not correlate with increased spontaneous or mitogen-induced production of M phi-stimulating lymphokines nor with hyperresponsiveness to Ia-inducing signals.     

Defective isotype-specific regulation of IgA anti-erythrocyte autoantibody-forming cells in NZB mice

B cell hyperactivity characterizes many autoimmune diseases. In NZB mice this is manifested by a variety of immunologic aberrations, including increased B cell proliferation and hyper IgM and IgA secretion in vitro. Recent studies have shown that IgA secretion can be suppressed or enhanced in an isotype-specific manner by a soluble factor(s), called IgA-binding factor (IgABF), produced by IgA FcR-bearing T cells. We now show that T cells from young NZB mice, cultured with high concentrations of IgA, produce an IgABF that has aberrant biologic activity when compared to IgABF produced from IgA FcR+ T cells of BALB/c mice. Although BALB/c IgABF normally suppresses proliferation and secretion by IgA-producing B cells, neither proliferation nor IgA secretion from normal murine IgA-B cells is suppressed by NZB IgABF. In fact, IgA secretion is significantly enhanced by NZB IgABF. We also present the first evidence of IgA anti-mouse erythrocyte (anti-MRBC) autoantibody-forming cells present in the spleens of NZB mice. Whereas BALB/c IgABF suppresses the in vitro generation of IgA anti-MRBC autoantibody-forming cells by NZB spleen cells, NZB IgABF enhances this response. Of particular interest is the development of IgA anti-MRBC autoantibody-forming cells in cultures of spleen cells from nonautoimmune BALB/c mice in the presence of NZB IgABF. These studies suggest that isotype-specific T cells factors might play an important role in the development of autoantibody-forming cells.