Two defects in old New Zealand Black mice are involved in the loss of low-dose paralysis to type III pneumococcal polysaccharide

Treatment of normal mice with a subimmunogenic dose of type III pneumococcal polysaccharide (SSS-III) results in the development of an antigen-specific state of unresponsiveness termed low-dose paralysis. This unresponsiveness is mediated by T suppressor cells and can be transferred by Lyt-2+ T cells, but not by L3T4+ T cells, obtained 18 hr after priming. As autoimmune New Zealand Black (NZB) mice age, there is a progressive decrease in low-dose paralysis to SSS-III. The defect in older NZB mice resulting in decreased suppressive activity was investigated by transferring primed Lyt-2+ T cells from young into old mice, and vice versa. Enlarged Lyt-2+ T cells from old NZB mice could not suppress the SSS-III response of young recipients. However, Lyt-2+ T cells of normal cell size were efficient in inhibiting the antibody response upon transfer. Primed Lyt-2+ T cells from young NZB mice did not affect the response of old recipients, but effectively suppressed the response of young mice. These results suggest that there are two defects involved in the decline of low-dose paralysis to SSS-III in aging NZB mice: Enlarged Lyt-2+ T cells may lose their ability to function as mediators of suppression; and B cells may become resistant to T cell-mediated suppression.     

Evidence that autoimmunity in NZB mice is caused by a defect in immune specificity rather than a generalized defect in tolerance of self-antigens

NZB mice which were already producing anti-erythrocyte autoantibodies were not able to respond to their own liver F antigen, thus providing evidence that their autoimmunity is not caused by a generalized breakdown in self-tolerance mechanisms. The specificity of autoantibodies produced in the spontaneous hemolytic anemia was different from that of antierythrocyte antibodies induced in normal mice and in young NZB mice by injections of rat erythrocytes. This indicates that the B-cell clones which can be triggered by heterologous antigen are different from those responsible for the NZB disease; the latter clones may not exist in normal mice.     

Specific antigen-binding and antibody-secreting lymphocytes associated with the erythrocyte autoantibody responses of NZB and genetically unrelated mice.

The receptor characteristics as well as incidence of antigen-binding lymphocytes (ABL) or B and T cell classes with membrane receptors specific for the exposed (X) and cryptic (HB) murine erythrocyte autoantigens were examined in NZB and nine control strains of mice. Whereas only NZB and NZB hybrid mice synthesize anti-X autoantibody pathogenetically implicated in the genetically determined autoimmune hemolytic anemia, the NZB as well as control strains synthesize the ubiquitous anti-HB anti-erythrocyte autoantibody. By utilizing immunocytoadherence assays, maximum numbers of specific ABL of both B and T lymphocyte classes were optimally demonstrated at erythrocyte:lymphocyte ratios of 20:1 and after lymphocyte fixation at 56 degrees C for 20 min. Surface membrane receptor specificity was established by inhibition with semi-purified soluble X or HB autoantigen. Inhibition of immunocyto-adherence with class specific antisera to mouse immuno-globulins demonstrated that the receptors on both B and T cells were of IgM class. Specific receptors regenerated in vitro after trypsinization which excluded the role of cytophilic antibody in the immunocytoadherence reactions. B lymphocyte ABL reactive with the X autoantigen were demonstrable in NZB, NZB hybrid, and control mice. Only in NZB and NZB hybrid mice, strains that uniformly synthesize anti-X autoantibody, were X ABL of T lymphocyte class demonstrated. The presence and incidence of T lymphocyte X ABL is compatible with the expression of a single dominant gene carried by the NAB strain. The incidence of B lymphocyte X ABL increased with age, suggesting proliferation of this cell population. HB ABL of both B and T lymphocyte classes were observed in all strains, concordant with the ubiquitous presence of humoral anti-HB autoantibodies. Differentiation of precursor B cells are evaluated by PFC assay of cells secreting specific autoantibodies. Anti-X PFC were observed only in NZB and NZB hybrid mice; and the observed frequency suggested that less than 3.5% of the specific ABL were differentiated for the secretion of anti-X autoantibody. Anti-HB PFC were observed in all strains and represented as high as 11.8% of specific ABL. Genetic determination of the anti-X anti-erythrocyte autoantibody response does not prescribe the presence of precursors of the antibody-forming cell, but rather appears to influence regulation of the differentiation of these cells. These data suggest that circumvention of immunologic tolerance to this specific erythrocyte autoantigen may occur at the level of the T lymphocyte; or alternatively, that T lymphocytes as well as B lymphocytes, are induced to proliferate and differentiate in the NZB strain.     

The Lbw2 locus promotes autoimmune hemolytic anemia

The lupus-prone New Zealand Black (NZB) strain uniquely develops a genetically imposed severe spontaneous autoimmune hemolytic anemia (AIHA) that is very similar to the corresponding human disease. Previous studies have mapped anti-erythrocyte Ab (AEA)-promoting NZB loci to several chromosomal locations, including chromosome 4; however, none of these have been analyzed with interval congenics. In this study, we used NZB.NZW-Lbw2 congenic (designated Lbw2 congenic) mice containing an introgressed fragment of New Zealand White (NZW) on chromosome 4 encompassing Lbw2, a locus previously linked to survival, glomerulonephritis, and splenomegaly, to investigate its role in AIHA. Lbw2 congenic mice exhibited marked reductions in AEAs and splenomegaly but not in anti-nuclear Abs. Furthermore, Lbw2 congenics had greater numbers of marginal zone B cells and reduced expansion of peritoneal cells, particularly the B-1a cell subset at early ages, but no reduction in B cell response to LPS. Analysis of a panel of subinterval congenic mice showed that the full effect of Lbw2 on AEA production was dependent on three subloci, with splenomegaly mapping to two of the subloci and expansions of peritoneal cell populations, including B-1a cells to one. These results directly demonstrated the presence of AEA-specific promoting genes on NZB chromosome 4, documented a marked influence of background genes on autoimmune phenotypes related to Lbw2, and further refined the locations of the underlying genetic variants. Delineation of the Lbw2 genes should yield new insights into both the pathogenesis of AIHA and the nature of epistatic interactions of lupus-modifying genetic variants.     

Studies on the influence of the internal environment on autoantibody production by B cells

Purified splenic B cells from autoimmune NZB and nonautoimmune DBA/2 mice were transferred to unmanipulated H-2 compatible xid recipients. The number of autoantibody-secreting clones present in recipient mice was quantitated at varying times after transfer using a splenic fragment assay. We found that NZB and DBA/2 B cells expanded equally well in equivalent xid environments. Cells from either donor expanded significantly better in autoimmune-prone NZB.xid as compared with DBA/2.xid recipients. Moreover, clones producing antibodies reactive with T cell surface antigens, bromelain-treated mouse red cells, or DNA expanded more rapidly than did cells producing antibodies to the nonautoantigen TNP-KLH. Serum autoantibody levels rose in concert with the increased numbers of autoantibody-producing lymphocytes. We conclude that factors present in the internal milieu of autoimmune-prone NZB.xid mice, rather than an intrinsic B cell defect, facilitate the expansion of (auto)antibody-secreting B cells.     

Delineation of spontaneous erythrocyte autoantibody responses of NZB and other strains of mice.

Four anti-erythrocyte autoantibody responses (anti-X, anti-HB, anti-HOL, and anti-I) that occur spontaneously in mice have been characterized with regard to antigenic specificities, predominant immunoglobulin class, and pathogenetic importance. Each autoantibody response exhibits specificity for an independent erythrocyte membrane autoantigen (X, HB, HOL, or I) or a soluble analogue (SEA-X or SEA-HB) present in the plasma. The anti-X response, unique to NZB mice, is directed to a normally exposed murine erythrocyte autoantigen, whereas the anti-HB response is directed to a cryptic erythrocyte autoantigen exposed by limited enzymatic cleavage of the membrane. The anti-I response also is directed to a cryptic but distinct autoantigen, and anti-HOL autoantibodies react with an erythrocyte autoantigen located at the cytoplasmic surface of the membrane. Analysis of the predominant immunoglobulin class of each of the autoantibodies has demonstrated that anti-HB and anti-I antibodies are predominantly of IgM class, whereas anti-X and anti-HOL antibodies are IgG immunoblobulins. Only anti-X and anti-HB autoantibodies are recovered from Coombs' positive erythrocytes from NZB mice and erythrocytes with surface C3 are detected only in NZB mice greater than 9 months of age. These data suggest that only the anti-X and anti-HB responses are pathogenetically implicated in the autoimmune hemolytic anemia of NZB mice.     

Expression of Lyt-1 by a subset of B lymphocytes

Using two-color flow cytometry and multiparameter data analysis, we have shown that the IgM bright, large subset of mouse splenic B lymphocytes express Lyt-1. This is not due to B cell uptake of immune complexes of Lyt-1 and antibody from T cells. The IgM bright cells of autoimmune NZB mice express more Lyt-1 than normal controls. This is because IgM containing plasmablasts, which are greatly increased in NZB spleens, are Lyt-1+. NZB spleen also contains more cells that are Lyt-1+ (but perhaps Lyt-1.2-), Thy-1.2 dull, and smaller in size than cells in normal mice. Thus, Lyt-1 is common to the T and B cell precursor or is induced independently during the ontogeny of T and at least one subset of B cells. We suggest that it be called Lyt-1.     

Evidence for a B lymphocyte defect underlying the anti-X anti-erythrocyte autoantibody response of NZB mice.

The autoimmune hemolytic anemia of NZB mice is pathogenetically mediated by a genetically prescribed anti-erythrocyte autoantibody response directed to the X erythrocyte autoantigen. The cellular locus of the immunoregulatory defect underlying the anti-X response was explored by adoptively transferring bone marrow cells (BMC) from NZB mice to lethally irradiated histocompatible recipients. Before adoptive transfer, BMC from donor mice were assayed for antigen-binding lymphocytes with receptors for the X autoantigen (X-ABL) by immunocytoadherence assays and for anti-X autoantibody-secreting cells (X-PFC) by plaque-forming cell assays. Twelve weeks after adoptive transfer, splenic lymphocytes from recipient mice were assayed for X-PFC and humoral anti-X autoantibody by Coombs' tests. Transfer of 15 to 30 x 10(6) BMC containing 6 to 12 x 10(3) X-ABL but no X-PFC from 6- to 8-week-old NZB mice to lethally irradiated BALB/c, B10.D2, C57BL/Ks, and DBA/2 mice produced X-PFC in 70% of the recipients. Development of X-PFC was not simply dependent upon available X-ABL since transfer of 15-30 x 10(6) BMC, containing comparable numbers of X-ABL, from BALB/c, B10.D2, C57BL/Ks, or DBA/2 mice to NZB or syngeneic recipients did not produce X-PFC. Transfer of BMC from NZB mice to BALB/c, B10.D2, and DBA/2 mice with weekly administrations of AKR anti-theta antiserum had no effect on the development of X-PFC; Tlymphocyte ablation was evidenced by the absence of theta+ spleen cells. These results suggest that the pathogenetic anti-X response is not genetically prescribed at the level of macrophages, humoral factors, or T cells, but rather appears to be a phenotypic expression of a primary B lymphocyte defect permitting or promoting differentiation of NZB X-ABL.     

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.     

Tolerance defects in New Zealand Black and New Zealand Black X New Zealand White F1 mice

The susceptibility of autoimmune NZB and (NZB X NZW)F1 mice to the induction of tolerance by monomeric BSA was compared with several normal mouse strains. Unresponsiveness in T and B lymphocyte compartments was probed by challenging with DNP8BSA and measuring anti-DNP and anti-BSA antibodies separately. Tolerance induced by monomeric BSA was carrier specific, and there was no evidence of epitope-specific suppression. Normal NZW, NFS, and B10.D2 mice were easily rendered tolerant with monomeric BSA and did not produce anti-DNP or anti-BSA antibodies after challenge with DNP8BSA. By contrast, the lack of anti-DNP antibody response in similarly treated NZB mice was dependent on the dose of monomeric BSA, indicating that the helper T cells were partially resistant to tolerance induction. NZB mice treated with a high dose of monomeric BSA produced anti-BSA, but not anti-DNP, antibodies after immunization. Thus, the anti-carrier B cells in NZB mice may have been primed by monomeric BSA. The presence of the xid gene on the NZB background rendered the mice susceptible to induction of tolerance, suggesting that the tolerance defect in NZB mice involves the B cell compartment. This abnormal antibody response was a dominant trait: (NZB X NFS)F1 and (NZB X B10.D2)F1 mice had the same characteristics as NZB mice. These F1 hybrids do not develop autoimmune disease, indicating that resistance to experimental tolerance induction expressed at a B cell level may not be sufficient for disease development. In contrast to NZB and other NZB F1 hybrids, (NZB X NZW)F1 hybrids treated with monomeric BSA and challenged with DNP8BSA responded to both DNP and BSA. The contribution of a B cell defect to the tolerance abnormality of (NZB X NZW)F1 mice was examined by analyzing the effect of the xid gene on the progeny of (NZB.xid X NZW)F1 mice. Unlike the effect of the xid gene on NZB mice, both phenotypically normal heterozygous female and phenotypically xid hemizygous male mice produced anti-DNP and anti-BSA antibodies after tolerance induction and immunization, demonstrating that a major helper T cell abnormality was present in (NZB X NZW)F1 mice. The (NZW X B10.D2)F1 hybrid was rendered tolerant by this procedure, indicating that the helper T cell defect (NZB X NZW)F1 mice may have resulted from gene complementation with the NZB mice contributing partial resistance of T helper cells to tolerance induction.(ABSTRACT TRUNCATED AT 400 WORDS)     

Lyt-2+ cells. Requirements for concanavalin A-induced proliferation and interleukin 2 production

The requirements for inducing Lyt-2+ T cell proliferation in response to concanavalin A (Con A) were examined. Purified Lyt-2+ or L3T4+ spleen cells of C57BL/6 origin were stimulated with Con A and syngeneic macrophages (MO) in the presence of monoclonal antibodies to T cell markers or to polymorphic determinants on major histocompatibility complex molecules, and assessed for the ability to proliferate and to produce interleukin (IL) 2. alpha I-Ab failed to inhibit the Con A response of Lyt-2+ cells at dilutions that significantly inhibited the response of L3T4+ cells. In contrast, alphaKb/Db or alpha Lyt-2.2 specifically inhibited the response of Lyt-2+ cells, but not L3T4+ cells. The ability of alpha Kb/Db and of alpha Lyt-2.2 to inhibit the response of Lyt-2+ cells was dependent upon the concentration of Con A. These data demonstrate that optimal triggering of T cell subsets to proliferate and to produce IL-2 in response to Con A requires interactions with the appropriate restricting major histocompatibility complex molecule. The role of accessory cells in Lyt-2+ Con A-induced proliferation and IL-2 production was also investigated. Purified Lyt-2+ cells and purified L3T4+ cells failed to respond to Con A in the absence of MO. IL-1 reconstituted the response when MO were limiting, but failed to restore the response of either Lyt-2+ or L3T4+ cells when T cells were rigorously purified to remove all MO. These results demonstrate that triggering Lyt-2+ T cells, like L3T4+ T cells, requires accessory cells, and that this does not merely reflect a requirement for IL-1 production. Thus, Con A-induced proliferation and IL-2 production by Lyt-2+ T cells requires intimate contact with accessory cells and interactions dependent upon the class I-restricting element.     

The role of tumor-specific Lyt-1+2- T cells in eradicating tumor cells in vivo. I. Lyt-1+2- T cells do not necessarily require recruitment of host's cytotoxic T cell precursors for implementation of in vivo immunity

The present study determines the Ly phenotype of T cells mediating tumor cell rejection in vivo and investigates some of cellular mechanisms involved in the in vivo protective immunity. C3H/HeN mice were immunized to syngeneic X5563 plasmacytoma by intradermal (i.d.) inoculation of viable X5563 tumor cells, followed by the surgical resection of the tumor. Spleen cells from these immune mice were fractionated by treatment with anti-Lyt antibodies plus complement, and each Lyt subpopulation was tested for the reconstituting potential of in vivo protective immunity in syngeneic T cell-depleted mice (B cell mice). When C3H/HeN B cell mice were adoptively transferred with Lyt-1-2+ T cells from the above tumor-immunized mice, these B cell mice exhibited an appreciable cytotoxic T lymphocyte (CTL) response to the X5563 tumor, whereas they failed to resist the i.d. challenge of X5563 tumor cells. In contrast, the adoptive transfer of Lyt-1+2- anti-X5563 immune T cells into B cell mice produced complete protection against the subsequent tumor cell challenge. Although no CTL or antibody response against X5563 tumors was detected in the above tumor-resistant B cell mice, these mice were able to retain Lyt-1+2- T cell-mediated delayed-type hypersensitivity (DTH) responses to the X5563 tumor. These results indicate that Lyt-1+2- T cells depleted of the Lyt-2+ T cell subpopulation containing CTL or CTL precursors are effective in in vivo protective immunity, and that these Lyt-1+2- T cells implement their in vivo anti-tumor activity without inducing CTL or antibody responses. The mechanism(s) by which Lyt-1+2- T cells function in vivo for the implementation of tumor-specific immunity is discussed in the context of DTH responses to the tumor-associated antigens and its related Lyt-1+2- T cell-mediated lymphokine production.     

Immunoregulation in the Peyer's patch microenvironment. Cellular basis for the enhanced responses by the B cells of X-linked immunodeficient CBA/N mice

The Peyer's patches (PP) of X-linked immunodeficient (xid) CBA/N and hemizygous (CBA/N X DBA/2)F1 (CDF1) male mice contain a B cell subpopulation that expresses the Lyb-5 maturational marker and is responsive to type 2 and T cell-dependent antigens in vitro, a B cell phenotype which is absent from the spleens of xid mice. Experiments reported here show that xid spleen B cells co-cultured with B cell-depleted PP cells from xid mice differentiated into specific plaque-forming cells in response to trinitrophenyl-Ficoll (type 2) and sheep erythrocytes (T cell-dependent). Two cell types were involved in this normalization of xid B cell responses. An accessory cell activity present in the PP, but not the spleens, of both CDF1 male (xid) and CDF1 female (normal) mice was required for the response to either the type 2 or T cell-dependent antigens. In the presence of this PP accessory cell, T cells from the PP of either xid or normal mice supported responses to both classes of antigens. In contrast, T cells from the spleens of xid mice did not support the response to trinitrophenyl-Ficoll, although the splenic T cells from normal mice did synergize with PP accessory cells in allowing plaque-forming cell development by xid B cells to this type 2 antigen. The xid PP T cell activity required for the type 2 response by xid B cells was present in the Ly-1+, Lyt-2- subpopulation, and the xid PP accessory cell activity was provided by an enriched population of dendritic accessory cells. These results demonstrate the the lymphoreticular cells comprising the PP microenvironment provide effective support for the differentiation of xid B cells in response to type 2 and T cell-dependent antigens.     

Proliferation of anti-DNA-producing NZB B cells in a non-autoimmune environment

This study demonstrates that purified NZB B cells, but not other NZB spleen cell populations, are capable of transferring anti-DNA antibody production into unirradiated H-2-compatible xid recipients. The number of autoantibody-producing B cells and the concentration of anti-DNA antibody found in the recipients correlated directly with the number of NZB B cells transferred. In addition, the number of anti-DNA-secreting lymphocytes found in the xid hosts increased exponentially with time post cell transfer. Several lines of evidence suggest that this phenomenon reflected the rapid proliferation of donor NZB B cells in the xid environment. Significantly, such proliferation was characteristic of donor cells that produced autoantibodies, but not of splenic B cells as a whole. These results suggest that stimulated NZB B cells can both induce and perpetuate autoantibody production in a normally non-autoimmune environment and in the absence of autoimmune helper cells.     

Genetic control of lymphocyte suppression. I. Lack of suppression in aged NZB mice is due to a B cell defect.

Con A-activated cells from old NZB mice were found capable of inhibiting the polyclonal response of cells from young NZB and BALB/c animals. Furthermore, Con A-preactivated spleen cells from young NZB and BALB/c mice did not significantly affect the response of spleen cells from old NZB mice. These results suggest that the defective suppressive activity in old NZB mice may be traced to a defect at the B cell level.     

Induction of autoimmune phenomena in normal mice treated with natural thymocytotoxic autoantibody

Natural thymocytotoxic autoantibody (NTA) developed spontaneously in New Zealand Black (NZB) mice consists of two autoantibodies in terms of target cell specificity. One of the autoantibodies, NTA-2, is strongly cytotoxic only against desialized lymphocytes, whereas the other one, NTA-1, is cytotoxic against both intact thymocytes and asialolymphocytes. To study the pathogenic role of NTA in murine autoimmunity, DBA/2 mice were injected every other day with affinity-purified NTA (NTA-1, NTA-2). Control mice received normal mice sera (NMS) or saline. After 20 days of treatment, spleen cells from DBA/2 mice treated with NTA-1 or NTA-2 showed a significant increase in the number of anti-ssDNA plaque-forming cells and IgM-producing cells. Sera from NTA-treated mice showed greater DNA binding than sera from control mice did. The levels of proteinuria were moderately increased in NTA-2-treated mice. Con A responsiveness of thymocytes was markedly reduced in NTA-2-treated mice. On the other hand, Con A-activated spleen cells from both control and NTA-treated mice equally suppressed anti-SRBC antibody production in vitro, suggesting that NTA treatment didn't affect the direct precursors of suppressor T cells. Finally, prior absorption of NTA-1 by thymocytes prevented its ability to induce anti-DNA antibodies; however, prior absorption of NTA-2 by thymocytes didn't affect its activity.     

Functional dissection of lupus susceptibility loci on the New Zealand black mouse chromosome 1: evidence for independent genetic loci affecting T and B cell activation

In previous work, we demonstrated linkage between a broad region on New Zealand Black (NZB) chromosome 1 and increased costimulatory molecule expression on B cells and autoantibody production. In this study, we produced C57BL/6 congenic mice with homozygous NZB chromosome 1 intervals of differing lengths. We show that both B6.NZBc1(35-106) (numbers denote chromosomal interval length) and B6.NZBc1(85-106) mice produce IgG anti-nuclear autoantibodies, but B6.NZBc1(35-106) mice develop significantly higher titers of autoantibodies and more severe renal disease than B6.NZBc1(85-106) mice. Cellular analysis of B6.NZBc1(85-106) mice revealed splenomegaly and increased numbers of memory T cells. In addition to these features, B6.NZBc1(35-106) mice had altered B and T cell activation with increased expression of CD69, and for B cells, costimulatory molecules and MHC. Introduction of an anti-hen egg white lysozyme Ig transgene, as a representative nonself-reactive Ig receptor, onto the B6.NZBc1(35-106) background corrected the B cell activation phenotype and led to dramatic normalization of splenomegaly and T cell activation, but had little impact on the increased proportion of memory T cells. These findings indicate that there are multiple lupus susceptibility genes on NZB chromosome 1, and that although B cell defects play an important role in lupus pathogenesis in these mice, they act in concert with T cell activation defects.     

Regulation of primary cytotoxic T lymphocyte responses generated during mixed leukocyte culture with H-2d identical Qa-1-disparate cells

Cytotoxic lymphocyte (CTL) responses are not usually generated during primary mixed leukocyte culture (MLC) with H-2 identical cells. Thus NZB mice are unusual in that their spleen cells do mount CTL responses during primary MLC with H-2d identical stimulator cells; the predominant target antigen for these NZB responses is Qa-1b. Considering the numerous immunoregulatory defects in NZB mice, we postulated that these NZB anti-Qa-1 primary CTL responses were due to an abnormality in T suppressor cell activity. Cellular interactions capable of suppressing NZB anti-Qa-1 primary CTL responses were investigated by using one-way and two-way MLC with spleen cells from NZB mice and other H-2d strains. Although H-2d identical one-way MLC with the use of NZB responders resulted in substantial CTL responses, only minimal CTL responses were detected from two-way MLC with the use of NZB spleen cells plus nonirradiated spleen cells from other H-2d mice. Thus the presence of non-NZB spleen cells in the two-way H-2d identical MLC prevented the generation of NZB CTL. Noncytotoxic mechanisms were implicated in the suppression of the NZB CTL responses during two-way MLC, because only minimal CTL activity was generated when NZB spleen cells were cultured with semiallogeneic, H-2d identical (e.g., NZB X BALB) F1 spleen cells. The observed suppression could be abrogated with as little as 100 rad gamma-irradiation to the non-NZB spleen cells. The phenotype of these highly radiosensitive spleen cells was Thy-1+, Lyt-1+, Lyt-2-, L3T4+. The functional presence of these cells in the spleens of semiallogeneic, H-2d identical F1 mice indicated that their deficiency in NZB mice was a recessive trait. These data suggest that NZB mice lack an L3T4+ cell present in the spleens of normal mice that is capable of suppressing primary anti-Qa-1 CTL responses. This model system should facilitate additional investigations of the cellular interactions and immunoregulatory mechanisms responsible for controlling primary CTL responses against non-H-2K/D class I alloantigens. The model may also provide insight into the immunoregulatory defects of autoimmune NZB mice.     

Rescue of the tumor-specific immune response of aged mice in vitro

In contrast to young mice, old mice fail to reject a transplanted challenge of the highly immunogenic, ultraviolet light-induced tumor 1591-RE. Old mice also fail to mount a cytolytic tumor-specific immune response in vivo, and spleen cells of old mice are defective in their ability to generate tumor-specific T cells in vitro. In the present study we report the results of cell culture mixing experiments that show that this deficiency is due to a decreased responsiveness of the Lyt-2+ tumor-specific cytolytic T cell precursors of the old animals. We also demonstrate with limiting dilution analysis that the defective responsiveness is not due to a clonal exhaustion of the precursors. In fact, the responsiveness could be restored in vitro by culturing the spleen cells of old animals at high density or by the addition of excess Lyt-1-/Lyt-2-/2000-rad-resistant spleen cells from young or old mice. Our results suggest that the rescue of tumor immunity in old individuals may be possible, perhaps by educating effector cells in vitro for adoptive immunotherapy.     

T cells subsets responsible for clearance of Sendai virus from infected mouse lungs

T cell subsets responsible for clearance of Sendai virus from mouse lungs determined by adoptive transfer of immune spleen cell fractions to infected nude mice. T cells with antiviral activity developed in spleens by 7 days after intranasal infection. Spleen cell fractions depleted of Lyt-2+, Lyt-1+, or L3T4+ cells showed antiviral activity in vivo, although the degree of the activity was lower than that of control whole spleen cells. The antiviral activity of the Lyt-2+ cell-depleted fraction was consistently higher than that of L3T4+ (Lyt-1+)-depleted cells. In vitro cytotoxic activity against Sendai virus-associated, syngeneic lipopolysaccharide-blast cells was detected in stimulated cells from intraperitoneally immunized mice but was lost after depletion of Lyt-2+ cells. Multiple injection of anti-Sendai virus antibody into infected nude mice had no effect on lung virus titer. These results indicate that L3T4+ (Lyt-1+) and Lyt-2+ subsets are cooperatively responsible for efficient clearance of Sendai virus from the mouse lung.