Culture and characterization of thymic epithelium from autoimmune NZB and NZB/W mice

Autoimmune NZB and NZB/W mice display early abnormalities in thymus histology, T cell development, and mature T cell function. Abnormalities in the subcapsular/medullary thymic epithelium (TE) can also be inferred from the early disappearance of thymulin from NZB. It has also been reported that NZB thymic epithelial cells do not grow in culture conditions that support the growth of these cells from other strains of mice. In order to study the contribution of TE to the abnormal T cell development and function in NZB and NZB/W mice, we have devised a culture system which supports the growth of TE cells from these mice. The method involves the use of culture vessels coated with extracellular matrix produced by a rat thymic epithelial cell line. TEA3A1, and selective low-calcium, low-serum medium. In addition TEA3A1 cells have been used as an antigen to generate monoclonal antibodies specific for subcapsular/medullary TE. These antibodies, as well as others already available, have been used to show that the culture conditions described here select for cells displaying subcapsular/medullary TE markers, whereas markers for cortical TE and macrophages are absent.     

Similar in vivo expansion of B cells from normal DBA/2 and autoimmune NZB mice in xid recipients

B cells from normal DBA/2 and autoimmune NZB mice were transferred into H-2-compatible xid recipients where they engrafted without irradiation or other manipulation of the host. The properties of these cells and their interaction with the host environment were analyzed at the single cell level with a splenic focus assay. When similar numbers of NZB and DBA/2 anti-DNA-producing B cell precursors were transferred, they expanded at similar rates in xid recipients. The rate of expansion varied with the strain of the recipient: it was fastest in autoimmune-prone NZB . xid and slowest in DBA/2 . xid hosts. Cells producing antibodies reactive with the autoantigen DNA proliferated substantially faster than those reactive with the non-autoantigen trinitrophenylated keyhole limpet hemocyanin. These results suggest that 1) B cells from NZB mice do not behave differently from DBA/2 B cells, 2) the internal milieu of the recipient into which the cells are transferred has an important effect on B cell proliferation, and 3) B cells capable of autoantibody production may have a selective growth and/or differentiation advantage relative to other B cells.     

Elimination of immune complex deposits from the kidneys of autoimmune NZB/N mice administered a xeno-spleen perfusate

54 autoimmune NZB/N mice, 6 and 10 months of age, were intravenously injected 0.2 ml solution prepared during perfusion of the isolated sheep spleen with a buffer solution. Perfusion solution was injected 8 times with 2-3-day intervals. The control group of 43 mice received intravenously 0.2 ml of a buffer solution in the similar manner. After the treatment the levels of anti-DNA antibodies and circulating immune complexes were significantly decreased in the sera of mice which received the perfusion solution, as compared with the levels of control groups. Immunofluorescent studies showed a marked decrease in the number of glomerular immune complexes deposits in mice treated with perfusion solution. Six- and ten-month old mice exhibited a similar effect. The perfusion solution may be capable of eliminating the immune complexes from the blood and kidneys of autoimmune 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.     

B-B cell interactions in the spontaneous activation of B cells in autoimmune NZB mice.

We analyzed the mechanism of spontaneous B cell activation in lupus mice by using anticlass-II antibody in vitro. The in vitro culture of B cells from old NZB mice markedly produced Ig without any stimulation, while B cells from NZW mice did not. The addition of anticlass-II antibody (anti-Iad antibody) to the culture inhibited Ig production of NZB B cells in a concentration-dependent manner. On the other hand, the addition of anticlass-I antibody (anti-H-2Dd antibody) and anticlass-II antibody with different specificity (anti-Iak) gave no effect on the Ig production of NZB B cells. When mitomycin C-treated B cells were added to in vitro culture of responder B cells as a stimulator, Ig production of responder B cells was enhanced in a concentration-dependent manner. However, the enhancing effect of the stimulator B cells was abrogated by the pretreatment with anticlass-II antibody. The stimulator B-cell activity to NZB B cells was marked in NZB B cells, moderate in NZB/W F1 B cells, and weak in NZW B cells. Furthermore, the stimulator B-cell activity with regard to NZB B cells was marked in old female NZB B cells, moderate in old male NZB B cells, and weak in young NZB B cells. The expression of class II antigens on the surface of old female NZB B cells was significantly higher than that of old male NZB and young NZB B cells. These results suggest that in lupus mice the spontaneous B-cell activation is induced by an abnormal B-B cell interaction mediated by class II antigens.     

Bacterial lipopolysaccharides activate immune suppressor cells in newborn mice

Neonatal injection of C57B1/6 mice with bacterial LPS results in an impairment of the ability of splenic lymphocytes to respond to erythrocyte antigens in vitro 4 weeks later. This impairment is due either to a de novo activation of suppressor cells or to an enhancement of the longevity of “naturally occurring” suppressor cells found in the newborn spleen since cells from LPS-injected mice also inhibited normal control responses. The suppressor cells from LPS-injected mice are not macrophages and, by conventional criteria, appear to be T lymphocytes. Results of this study raise questions concerning the effects of suppressor cells on LPS-potentiated antibody formation and the multiplicity of pathways for activation of antibody-forming precursor cells.     

The differential ability of splenic adherent cells from B6.lpr mice to induce suppressor T cells

Hapten-coupled splenic adherent cells or resident peritoneal cells from autoimmune B6.lpr mice that are over 5 mo of age fail to induce first-order inducer suppressor T cells (Ts1). However, the same population of hapten-coupled cells can induce both delayed-type hypersensitivity responses and third-order effector suppressor T cells (Ts3). Thus, splenic and peritoneal antigen-presenting cells from B6.lpr mice display a defined defect in the ability to induce certain suppressor T cell responses. The cellular defect in Ts1 induction is controlled by the lpr gene, since age-matched congenic B6 mice do not display this defect. The splenic adherent cell defect is temporarily correlated with the autoimmunity that develops in B6.lpr animals. The antigen-presenting defect in the B6.lpr splenic adherent population for Ts1 induction is reversible by culturing the cells in interferon-gamma. The results are discussed as an illustration of the relationship between experimental models of autoimmunity and defects in a suppressor T cell cascade.     

Immune complexes present in the sera of autoimmune mice activate rheumatoid factor B cells

The fate of an autoreactive B cell is determined in part by the nature of the interaction of the B cell receptor with its autoantigen. In the lpr model of systemic autoimmunity, as well as in certain human diseases, autoreactive B cells expressing rheumatoid factor (RF) binding activity are prominent. A murine B cell transgenic model in which the B cell receptor is a RF that recognizes IgG2a of the j allotype (IgG2aj), but not the b allotype, was used in this study to investigate how the form of the autoantigen influences its ability to activate B cells. We found that sera from autoimmune mice, but not from nonautoimmune mice, were able to induce the proliferation of these RF+ B cells but did not stimulate B cells from RF- littermate controls. The stimulatory factor in serum was found to be IgG2aj, but the IgG2aj was stimulatory only when in the form of immune complexes. Monomeric IgG2aj failed to stimulate. Immune complexes containing lupus-associated nuclear and cytoplasmic autoantigens were particularly potent B cell activators in this system. Appropriate manipulation of such autoantibody/autoantigen complexes may eventually provide a means for therapeutic intervention in patients with certain systemic autoimmune disorders.     

B cells and dendritic cells from V kappa 8 light chain transgenic mice activate MRL-lpr/gld CD4+ T cells

Autoreactive CD4+ T cells are required for full expression of disease in human systemic lupus erythematosus and in spontaneous murine lupus. However, the Ag specificity of these CD4+ T cells remains largely unknown. Rheumatoid factor (RF) B cells function as highly efficient APCs by taking up immune complexes (IC) and presenting IC constituents to T cells. We hypothesized that Ag-specific CD4+ T cells in lupus-prone mice could be identified by stimulating the CD4+ T cells with RF B cells from AM14 RF BCR transgenic mice pulsed with IC containing lupus-associated autoantibodies and autoantigens. This approach identified several independent T cell lines that proliferated robustly in response to IC-pulsed spleen cells from the AM14 RF BCR transgenic mice. However, these T cells did not recognize an IC constituent. Instead, these T cells recognized a determinant dependent on the inheritance of the transgene-encoded Vkappa8 L chain, most likely a neoantigen created by the insertion of the transgene into the genome. Additionally, although the precise nature of the neoantigen is not known, the T cells described in this report may provide a useful tool for examining the role of T cells in the RF autoantibody response.     

Establishment of a nucleoside-specific suppressor T cell line from SLE prone (NZB/NZW)F1 mice

A long-term cultured suppressor T cell line (GTS-124) was established from an autoimmune mouse strain, (NZB X NZW)F1, by a two-part procedure: a) B/W F1 mice were made tolerant to guanosine (G) by administration of a tolerogen, the G-modified copolymer of D-glutamic acid and D-lysine (G-D-GL); and b) the spleen cells obtained from tolerant mice were repeatedly stimulated with mitomycin C-treated G-modified syngeneic spleen cells. The GTS-124 cells suppressed the secondary in vitro response to G-keyhole limpet hemocyanin (G-KLH) but did not suppress the response to unrelated antigens, sheep erythrocytes (SRBC), or trinitrophenyl-KLH (TNP-KLH). The expression of Thy-1 antigen on the cell surface of GTS-124 was demonstrated by flow cytometry. Growth of GTS-124 cells was dependent on IL 2. To determine whether GTS-124 cells could suppress the response to nucleosides other than G, KLH coupled with four nucleosides (adenosine [A], G, cytidine [C], and thymine riboside [T]) collectively (AGCT-KLH) was first used as the antigen in the assay system. The PFC response to the individual nucleosides (anti-A, -G, -C, and -T PFC) were effectively inhibited by GTS-124 cells, suggesting that the GTS-124 cells mediated cross-suppression toward all four nucleosides. A more stringent cross-suppression test was conducted by using only the T moiety bound to KLH (T-KLH) as antigen. The results showed that GTS-124 cells were capable of suppressing the T-specific response. The cross-suppression could be seen after repeated selection on a G-BSA-coated dish. These results provide direct evidence that the suppressor T cells induced by in vitro stimulation with G-modified self can indeed suppress the response to nucleosides other than G.     

Demonstration of active suppressor cells in spleens of young NZB mice

NZB mice, a strain prone to the development of autoimmune disease, have during the first 2 weeks of life suppressor cells in their spleens which can in coculture with adult spleen cells suppress the antibody response to sheep red blood cells (SRBC) generated in culture by the adult cells. The suppressive activity of spleen cells from NZB mice in the first week after birth is similar to that of spleen cells from 4-day-old C57BL/6 mice, a strain which does not spontaneously develop autoimmune disease. As in “normal” strains of mice, suppressor cell activity in NZB mice is diminished at 2 weeks and undetectable at 3 weeks of age. The data indicate that there is no defect inherent in the suppressor cells detected in the spleens of newborn and young NZB mice and suggest that the development of autoimmune responses does not result from a lack of suppressor cells in the young animals.     

Modulation of autoimmunity in NZB mice by cyclophosphamide-induced, nonspecific suppressor cells

A group of NZB mice received six biweekly injections of cyclophosphamide-induced nonspecific suppressor cells, with treatment commencing at 2 mo of age. Mice were evaluated for Coombs and natural thymocytotoxic antibody at 6-wk intervals thereafter, and for anti-DNA autoantibodies, total IgM and IgG levels, and renal histology at selected time points. The administration of suppressor cells resulted in marked and prolonged suppression of both Coombs and natural thymocytotoxic antibody reactivity in the majority of animals while not measurably affecting the levels of anti-DNA autoantibodies, the total IgM and IgG levels, or the life span of the mice.     

Regulation of the immune response in autoimmune NZB/NZW F1 mice. I. The spontaneous generation of splenic suppressor cells.

The lymphoproliferative responses of rat peripheral blood lymphocytes to phytohemagglutinin (PHA) were studied following treatment with single or multiple doses of cyclophosphamide. A dose-dependent lymphocytopenia was observed with both regimes. The remaining lymphocytes had decreased responses to PHA. Serum collected 24 hr after a single injection of cyclophosphamide and used at a concentration of 5% enhanced the response of cells from normal or cyclophosphamide-treated rats. Serum collected after a course of treatment did not have this effect, but it lacked the marked suppressive activity, at a concentration of 20%, which was shown by normal rat serum. The enhancing activity was not dialysable. Doses of cyclophosphamide adequate to abolish primary antibody production to sheep erythrocytes did not totally abrogate responsiveness to PHA. Thus, the pattern of immunological defects in cyclophosphamide-treated rats consisted of decreased primary antibody production, lymphocytopenia with a decreased response of the remaining lymphocytes to PHA, and diminution of serum suppressive activity.     

Myelin-specific regulatory T cells accumulate in the CNS but fail to control autoimmune inflammation

Treatment with ex vivo-generated regulatory T cells (T-reg) has been regarded as a potentially attractive therapeutic approach for autoimmune diseases. However, the dynamics and function of T-reg in autoimmunity are not well understood. Thus, we developed Foxp3gfp knock-in (Foxp3gfp.KI) mice and myelin oligodendrocyte glycoprotein (MOG)(35-55)/IA(b) (MHC class II) tetramers to track autoantigen-specific effector T cells (T-eff) and T-reg in vivo during experimental autoimmune encephalomyelitis (EAE), an animal model for multiple sclerosis. MOG tetramer-reactive, Foxp3(+) T-reg expanded in the peripheral lymphoid compartment and readily accumulated in the central nervous system (CNS), but did not prevent the onset of disease. Foxp3(+) T cells isolated from the CNS were effective in suppressing naive MOG-specific T cells, but failed to control CNS-derived encephalitogenic T-eff that secreted interleukin (IL)-6 and tumor necrosis factor (TNF). Our data suggest that in order for CD4(+)Foxp3(+) T-reg to effectively control autoimmune reactions in the target organ, it may also be necessary to control tissue inflammation.     

Role of T cells in regulating expression of the B cell repertoire. Anti-ssDNA precursor frequency of DBA/2 B cells is increased in the presence of T cells from NZB mice

Splenic B cells from DBA/2 and NZB mice were compared with regard to precursor frequency of anti-ssDNA-producing cells. Using a modification of the splenic fragment assay, we show that NZB T cells are capable of increasing the frequency of expression of anti-ssDNA precursors in DBA/2 splenic B cells. When limiting numbers of splenic B cells of DBA/2 origin were adoptively transferred into an irradiated (1200 rad) recipient, the co-transfer of NZB T cells markedly increased the frequency of anti-ssDNA precursors in cultured splenic fragments. The anti-ssDNA produced under these conditions was exclusively IgM and exhibited a high degree of cross-reactivity with TNP and fluorescein. Thus, the increase in anti-ssDNA precursor frequency reflected an expansion of the B cell repertoire to include precursors of polyspecific antibody-producing cells that under normal circumstances are not expressed. The ability of NZB T cells to increase the anti-ssDNA precursor frequency was further defined by the CBA/N immunodeficiency gene xid, in that B cells from DBA/2.xid donors did not exhibit increased anti-ssDNA precursor frequency in the presence of NZB T cells. When NZB splenic B cells were co-transferred with DBA/2 T cells, the anti-DNA precursor frequency of the NZB B cells was not reduced. This study demonstrates that T cells can influence the emergency of B cell clones in an Ag-nonspecific manner. The well documented in vivo spontaneous polyclonal activation of NZB B cells may be secondary to T cell-mediated expansion of the B cell repertoire.     

Properties of fractionated spleen cells from NZB/W mice.

The unit gravity sedimentation technique was used to separate spleen cells from sevveral strains of mice. Settling patterns (plot of cell number against settling rate) were similar for BALB/c, DBA/2, C3H/He, and NZB/W mice of different ages. In particular, no subpopulation was found by this technique to be missing from the spleens of old NZB/W mice.A number of functional studies performed with the separated cells proved more informative than the settling patterns themselves. Fractions of cells which sedimented at a rate of between about 6 mm/hr and 10 mm/hr were enriched in responsiveness to PHA, Con A, and allogeneic cells. These fractions obtained from old NZB/W mice lacked such activities. However, the active fractions from young NZB/W spleens, which were enriched in θ-bearing cells, could restore the responsiveness of old NZB/W mice to primary immunization with sheep erythrocytes. These studies indicate that functional separation of spleen cells from NZB/W mice is possible and that activities lacking in whole spleens from old NZB/W mice are also lacking in the separate fractions. The ability to restore helper T cell function in old NZB/W mice with active fractions from young NZB/W mice has implications for further study and treatment of their autoimmune disease.     

Cloning of B cells from autoimmune MRL-lpr/lpr and MRL.xid mice

The relationship between colony formation (cloning) of B cells and their activation in murine autoimmunity was investigated in MRL-lpr/lpr and MRL.xid mice. Cells from MRL-lpr/lpr mice showed similar requirements for in vitro growth as normal CBA/J and BALB/c cells, with maximal colony formation in the presence of the supporting factors lipopolysaccharide and sheep red blood cells. The frequency of colony-forming cells from MRL-lpr/lpr spleens or hapten-specific B-cell preparations was slightly greater than the two normal control strains, with this difference significant only for a comparison of BALB/c and MRL-lpr/lpr spleens. In contrast, MRL-lpr/lpr mice bearing the xid gene for B-cell immunodeficiency (MRL.xid) had markedly reduced B-cell colony formation. These mice nevertheless expressed anti-DNA antibodies, although at levels reduced from that of MRL-lpr/lpr controls. These results indicate that enhanced in vitro colony formation need not accompany B-cell hyperactivity in murine autoimmune disease and that autoantibody production can occur in mice with impairment in this growth property.     

Hormonal modulation of responses to thymus-independent and thymus-dependent antigens in autoimmune NZB/W mice

Previous work suggested that gonadal steroids influence immunity through the thymus, but the mechanisms were unclear. To investigate the effects of these hormones on immune responses to T1 and TD antigens in autoimmune mice, we studied hybrid NZB/W mice and the nonautoimmune DBA/2 strain. Mice castrated at 14 days of age were implanted with Silastic capsules releasing, in adults, physiologic levels of E2 in males or Te in females. Sham-operated controls received empty capsules. Splenic PFC were quantified 4 to 5 days after challenge with the TI2 antigen TNP-Ficoll, the TI1 antigen TNP-LPS, or the TD antigen SRBC. Young castrated NZB/W males implanted with E2 had striking enhancement of IgM responses to TNP-Ficoll when compared to castrated Te-treated females and comparable sham-operated controls of both sexes. E2 also stimulated responses to TNP-LPS. In response to challenge with SRBC, young E2-treated NZB/W males had a consistent trend to increased IgM PFC, and the stimulatory effect of E2 on IgG plaques was variable. Physiologic doses of Te had no consistent effect on responses in young mice. In old female NZB/W mice, Te caused PFC response after immunization with TNP-Ficoll to resemble age-matched NZB/W males. As sham-operated NZB/W females grew older, PFC responses to SRBC fell. This age-related phenomenon was delayed, however, in female castrates implanted with Te. In contrast, Te clearly suppressed responses to TNP-LPS. Implantation of E2 did not alter responses to TNP-Ficoll, TNP-LPS, or SRBC in nonautoimmune DBA/2 males. This finding suggested that exogenous E2 given in physiologic doses did not influence immunologic responsiveness in a normal strain to the degree seen in hormone-sensitive NZB/W mice. It was concluded that E2 enhanced responses to a variety of exogenous antigens in autoimmune NZB/W mice. The most consistent E2-induced increase in PFC response was observed with TI antigens, suggesting that E2 exerted its effects on B cells or Ts.