Central tolerance induction in natural immunoglobulin-allotype-specific T cells

While self toleance is induced to IgG(b)(2a) in Igh(b / b) mice, an anti-IgG(b)(2a) T cell activity emerges in their Igh(a / a) congenic counterparts. This activity is revealed by postnatal transfer of Igh(a / a) T splenocytes into Igh(a / b) F(1), in which total suppression of IgG(2a)(b) expression is established. Here, we sought to determine whether the natural T cell unresponsiveness to IgG(2a)(b) in Igh(b / b) mice involved a central tolerance. Based on the kinetics of postnatal thymic C(gamma2a)(b) gene expression in Igh(b / b) mice, we transplanted thymi from Igh(b / b) donors of diverse ages into tolerogen-free Igh(a / a) nu / nu recipients. The state of T cell tolerance or responsiveness to IgG(2a)(b) in these reconstituted nu / nu hosts was determined by monitoring the capacity of their splenocytes to induce suppression in Igh(a / b) F(1). These experiments demonstrated that: (i) in the Igh(a / a) nu / nu recipients of adult Igh(b / b) thymi, 33 to 65 % T splenocytes were from nu / nu recipient origin, but these peripheral Igh(a / a) T cells were rendered tolerant to IgG(2a)(b) during their differentiation through the adult Igh(b / b) thymi, (ii) circulating IgG(2a)(b) was not a prerequisite for this tolerance induction, (iii) Igh(b / b) thymic epithelium was unable to induce tolerance to IgG(2a)(b) and (iv) IgG(2a)(b)-producing / presenting cells, colonizing the Igh(b / b) thymi, were certainly responsible of full tolerance induction to IgG(2a)(b).     

Normal T splenocytes are able to induce immunoglobulin allotypic suppression in F1 hybrid mice

A chronic suppression of Igh-1b and Igh-3b (IgG2a and IgG2b of b haplotype) allotype expression has been induced by injecting T splenocytes from normal BALB/c or BC8 mice into newborn F1 hybrids of appropriate Igh congenic strains: BALB/c into (BALB/c Igha X CB20 Ighb)F1 and BC8 into (BC8 Igha X C57BL/6 Ighb)F1 or (C57BL/6 X BC8)F1. This suppression does not affect IgM (IgH-6b) or IgA (Igh-2b) expression. When the Ighb haplotype is paternally transmitted, the proportion of T splenocyte recipients showing allotypic suppression increases with time reaching 70% 40 weeks after birth. We also succeeded in inducing this pattern of suppression in 2 out of 13 cases when the Ighb was inherited from the mother. These normal T splenocytes are therefore clearly allotype specific. As Igh-6b production is not affected by the suppression, these T splenocytes are believed to influence B cells more or less committed to Igh-1b or Igh-3b production rather than more precocious Igh-6b (IgM of b haplotype) carrying precursors in the classical IgM-IgG filiation pathway.     

Non-tolerant B cells cause autoimmunity in anti-CD8 IgG2a-transgenic mice

Using a pair of γ2a/x immunoglobulin genes, transgenic mice were generated to study tolerance induction in B cells that express IgG2a autoantibodies. The transgenic IgG2a specifically binds CD8 α chains of the CD8.2 allotype expressed on the surface of CD8⁺ T cells, but not CD8 molecules expressed by the CD8.1 allele. Thus, IgG2a transgenic mice expressing the CD8.1 allele were used as controls to monitor B cell development and mice expressing CD8.2 were used to study B cell tolerance. Both types of mice showed transgenic γ2a expression on the surface of B cells. Expression of endogenous heavy chain alleles was strongly inhibited in immature B cell subsets, whereas mature B cells co-expressed transgenic γ2a and endogenous IgM/D. The transgenic x chain expression leads only to partial allelic exclusion of endogenous light chains. B cells that express high levels of transgenic CD8.2-specific IgG2a were identified using soluble CD8-Ig. In CD8.1⁺ and in CD8.2⁺ mice, we found no differences in expression and maturation of transgenic anti-CD8.2 IgG2a⁺ B cells. High levels of serum anti-CD8.2 IgG2a antibodies led to the elimination of CD8⁺ T cells, causing a severe defect in cytotoxic immune responses. These results show that tolerance induction is incomplete in the CD8.2⁺ mice, either because IgG2a⁺ B cells are resistant to censoring mechanisms or because the secreted CD8-specific IgG2a antibodies render the CD8 autoantigen inaccessible to the B cells. This contrasts strongly with the efficient induction of B cell tolerance in mice expressing anti-CD8.2 IgM autoantibodies.     

Apparent trans-chromosomal antibody class switch in mice bearing an Igh(a) mu-chain transgene on an Igh(b) genetic background

Native high molecular weight dextran induces a thymus-independent response in BALB/c mice. When the dextran epitope is linked to a protein carrier the response becomes thymus-dependent. IgG antibodies produced after secondary immunization had epitope specificity and idiotope of myeloma M104E. The antibody of M104E (mu, lambda1) is representative for antibodies produced by mice with immunoglobulin haplotype Igh(a) in response to immunization with dextran B1355S. Myeloma product and physiological antibodies share specificity for the alpha(1-3) glucosidic linkage and have idiotopes in common. Mice with haplotypes other than Igh(a) (e.g. Igh(b)) are unable to yield this type of response. A complete rearranged immunoglobulin mu-chain gene with a VDJ-region from BALB/c (Igh(a)) myeloma protein M104E had been introduced into the genome of BALB/c congenic mice having the haplotype Igh(b). As was shown previously in our laboratory the M104E mu-chain transgene confers Igh(a)-type reactivity to Igh(b) mice. In experiments described in this report we used the thymus-dependent form of the antigen to immunize mice bearing the M104E mu-chain, either alone or together with the lambda1-chain, as a transgene on an Igh(b) genetic background. Serological analysis revealed a class switch to IgG very similar to that seen in BALB/c mice with respect to magnitude, kinetics, epitope and idiotope specificity. The pattern of IgG subclass expression was indistinguishable in mu-chain transgenic Igh(b) and normal BALB/c mice. The class switch occurred even though, as is shown here, the transgene had become incorporated in a site not linked to the Igh locus on chromosome 12. We propose a model for this apparent trans-chromosomal class switch recombination which is based on mechanisms known for conventional switch recombination.     

Marginal zone B cell enrichment and strong follicular B cell reduction correlate with a delayed IgG response in a light chain diversity restricted mouse model

Recently developed B6.kappa(-)lambda(SEG) mice (by crossing kappa(-) and C57BL/6 mice congenic for the wild Mus spretus SEG strain lambda locus lacking genes coding for lambda1 and lambda3) have a very reduced light chain diversity. B6.kappa(-)lambda(SEG) mice produce only lambda2 and lambdax light chains. Regardless of their Igh haplotype, B6.kappa(-)lambda(SEG) mice show a restricted B cell distribution by light chain subtype with lambdax dominance in all peripheral compartments except peritoneal cavity where lambda2 is dominant. This distribution suggests that selection mechanisms act differently in different B cell compartments on lambda2 and lambdax bearing B cells. Sequence analysis before or following immunization did not reveal unusual mechanisms of diversification. B6.kappa(-)lambda(SEG) mice still respond to various challenging antigens using new Ab patterns. In particular, regardless of Igh(a) or Igh(b) haplotypes, the anti-2,4-dinitrophenyl response is characterized by a restricted diversity for both heavy and light chains and a delayed IgG response when compared to B6 and B6.kappa(-) mice. We suggest that the delayed IgG response is due to the expansion of marginal zone B cells whereas follicular B cells are strongly reduced.     

Igh-1b-specific CD4+CD8- T cell clones of the Th1 subset selectively suppress the Igh-1b allotype in vivo.

The demonstration of major histocompatibility complex (MHC)-restricted T helper (Th) cells specific for peptides from the variable (V) regions of syngeneic immunoglobulin (Ig) (idiopeptides) opens the possibility that Th cells regulate B cell functions via idiopeptide-based cognate T-B interactions. As a model for such interactions we investigated the influence of Ig allotype-specific T cells on the differentiation of H-2-syngeneic B cells expressing that particular Ig allotype. We established a BALB/c (H-2d, Iga) CD4+CD8- T cell line and clones of the Th1 subset (interleukin 2+, interleukin 4-, interferon-gamma+, tumor necrosis factor-alpha+) that recognized Igh-1 (IgG2a) of the b allotype (Igh-1b) together with I-Ad. These T cells specifically suppressed surface Igh-1b+ B cells in vitro and in vivo. In 12 out of 15 6-week-old (BALB/c X B10.D2)F1 mice neonatally injected with Igh-1b-specific T cells, the serum Igh-1b concentrations were less than 5% of the levels in the controls. Thus, allotype suppression can be accomplished solely by adoptive transfer of Igh-1b-specific CD4+ T cells. The in vivo suppression was specific for Igh-1b+ B cells as the recipients' levels of Igh-1a and Igh-4b (IgG1b) were unaffected. The V beta 14-specific anti-T cell receptor (TcR) monoclonal antibody 14-2 inhibited activation of hybridomas derived from two of the clones. Collectively the data indicate that suppression resulted from cognate interactions between allopeptide-specific TcR alpha/beta+ T cells and normal unmanipulated B lymphocytes presenting their endogenous Igh-1b in association with MHC class II molecules. The data support the possibility that normal B cells can be suppressed by idiopeptide-specific T cells in vivo.     

Idiopathic paraproteinaemia V. Expression of Igh1 and Igh5 allotypes within the homogeneous immunoglobulins of ageing (C57BL/LiARij X CBA/BrARij)F1 mouse

The role of genetic factors linked to the immunoglobulin loci and the development of idiopathic paraproteinaemia (IP)--a benign B-cell proliferative disorder--was investigated in F1 hybrid mice of low (CBA/BrARij) and high (C57BL/LiARij) IP frequency strains. Igh1 and Igh5 allotypes were used as markers for the (parental type) origin of homogeneous immunoglobulins (H-Ig) which appeared in the sera of the F1 mice with ageing. The frequencies of H-Ig in the F1 mice were intermediate with those of the parental strains. The isotype distribution of the H-Ig was 27%, 24%, 12%, 12%, 11%, 10%, 3% and 1% for IgG2a, IgM, IgG1, IgG3, IgG2b, IgD, IgA and IgE, respectively. H-Ig of the IgG2 subclass carried the Igh1b (C57BL) allotype in 98% and the Igh1a (CBA) allotype in 2% cases. Of the IgD H-Ig, 70% carried the Igh5b and 30% the Igh5a determinant. The Igh1 allotype distribution in the bone marrow and spleen plasma cells showed a large variation in the Igh1a/Igh1b ratio among old individual mice and often also between bone marrow and spleen within a single animal with or without a H-Ig component. The categorization of the paraproteinaemias on the basis of their origin showed that 10% of the H-Ig were the result of a transient monoclonal B-cell proliferation; multiple myeloma or lymphoma was found to be responsible for about 1% of the paraproteinaemias; H-Ig fulfilling the criteria for IP were detected in about 42% of cases. The origin of the remaining old age paraproteinaemias could not be determined. These data indicate that the F1 mice develop monoclonal proliferative disorders in a manner more similar to the C57BL than to the CBA parental strain. The allotype associated genetic material from the parental C57BL strain was shown to be mainly responsible for the development of IP in ageing F1 mice.     

Idiopathic paraproteinaemia. IV. The role of genetic factors in the development of monoclonal B cell proliferative disorders--a study in the ageing C57BL/KaLwRij and CBA/BrARij mouse radiation chimeras

Mouse radiation chimeras, employing strains with a low (CBA/BrARij) and a high (C57BL/KaLwRij) frequency of idiopathic paraproteinaemia (IP), were used in a study on genetic influences in the development of IP, a benign B cell monoclonal proliferative disorder. Taking advantage of the different Igh1 allotypic markers between the two strains, the development of IP with increasing age was investigated by agar electrophoresis, immunoelectrophoresis and immunofixation. Four of 18 CBA recipients transplanted with C57BL bone marrow cells were shown to develop IP of the IgG2a isotype and the Igh1b (donor) allotype during their life. In contrast, none of the 23 C57BL recipients of CBA bone marrow developed an IgG2a paraprotein of the Igh1a allotype. However, in three of these 23 chimeras, an IgG2a and Igh1b (recipient) allotype paraprotein appeared with age; two of these mice proved to be reversals at 12 months and one at 15 months of age. The frequencies of homogeneous immunoglobulins of the donor type in the chimeras corresponded roughly to those of normal mice of the donor strain. Histopathological examination excluded a malignant origin of these monoclonal proliferations. These findings support the view that intrinsic cellular genetic factors are of major importance in the development of IP, a benign B cell neoplasia.     

Antiviral T-cell-independent type 2 antibody responses induced in vivo in the absence of T and NK cells

Polyomavirus (PyV) infection induces protective T-cell-independent (TI) IgM and IgG responses in T-cell-deficient (TCR beta x delta-/-) mice. In this study, we show that PyV is a TI -2 antigen: B cells with a mutated Bruton's tyrosine kinase (Xid mutants) do not respond to PyV with antibody secretion in the absence of T cells. We also demonstrate that NK-cell-mediated "help" is not absolutely required for the induction of the TI-2 antibodies to PyV; thus for the first time, we provide evidence for protective IgM and IgG responses against a viral infection induced in mice lacking T and NK cells (CD3Etg). Comparison of the antibody responses observed in T- and NK-cell-deficient mice with those of mice lacking only T cells, however, suggests that NK cells may promote isotype switching to IgG2a. This effect is probably mediated by IFN gamma secretion. In support of this idea, studies on the antibody responses of PyV-infected SCID mice that had been reconstituted with IFN gamma R-/- B cells or wild-type B cells demonstrated the IFN gamma dependence of PyV-specific TI IgG2a secretion and provided evidence that IFN gamma acting directly on B cells plays an important role in TI pathways of isotype switching to IgG2a in vivo.     

Apoptosis of epitope-specific antiretroviral cytotoxic T lymphocytes via Fas ligand-Fas interactions

C57BL/6 (B6; H-2b) mice are capable of mounting a vigorous AKR/Gross Murine Leukemia Virus (MuLV)-specific cytotoxic T lymphocyte (CTL) response to AKR/Gross MuLVs whereas AKR.H- 2b congenic mice, although carrying the responder H-2b major histocompatibility haplotype, are specifically nonresponsive. Furthermore, when viable AKR.H-2b spleen cells are cocultured with primed responder B6 antiviral precursor CTLs, the AKR.H-2b cells function as "veto" cells that actively mediate the inhibition by apoptosis of B6 antiviral CTL generation in a contact-dependent, MHC-restricted, and veto cell Fas ligand (FasL)/responder T cell Fas-dependent manner. In the present study we show that antigen-specific, antiviral CTLs that survive apoptotic inhibition by AKR.H-2b veto cells display a less activated cell surface phenotype, and are less able to bind specific MHC-peptide tetramers, including on a per-T cell receptor (TcR) basis. In addition, surviving antiviral CTLs also appeared to be functionally deficient, based on both their reduced ability to lyse specific target cells and to produce interferon (IFN)-gamma. Carboxyfluorescein diacetate succinimidyl ester staining confirmed that AKR/Gross MuLV-specific CTLs proliferated less extensively when AKR.H-2b veto cells were included in cocultures. AKR/Gross MuLV-specific effector CTLs as well as memory CTLs were each efficiently targeted for inhibition by AKR.H-2b veto cells. Attempts to enhance the quality of the priming by multiple in vivo immunizations did not alter the capacity of the AKR.H-2b cells to inhibit the antiviral CTL response. These results further characterize the nature of the interaction between veto cells and antiviral CTLs, and underscore the efficiency of veto cell-mediated inhibition of the CTL response.     

Pore-forming protein in individual cytotoxic T lymphocytes: the effect of senescence provides a probe for understanding the lytic mechanism.

The senescent decline of cytolytic T lymphocyte (CTL) activity was examined (a) to learn more about the effect of aging on the immune system, and (b) to probe the mechanism of cell-mediated cytolysis. The effect of age on the generation of pore-forming protein (Pfp) was examined at the cellular level in a murine model using CTL stimulated in allogeneic mixed lymphocyte culture (MLC). Pfp expression was analyzed by immunocytochemistry and enzyme-linked immunosorbent assay (ELISA). Immunocytochemical analyses of Pfp in MLC-stimulated splenic T cells from a large number of mice revealed that although stimulated cells from aged mice exhibited fewer Pfp-producing cells than those from young, the diminution in the proportion of Pfp+ cells was small compared to the age-related decrease in lytic activities (approximately 2-fold vs. approximately 7.4-fold, respectively). Time-course analysis disclosed similar kinetics for the generation of Pfp+ cells among responding cells from young and aged mice. No significant age-related difference in the proportion of Pfp+ cells was observed in MLC-stimulated lymph node cells despite a large and significant difference in lytic activity (approximately 6.5-fold). Purified CD8+ T cells demonstrated a large age-related difference in CTL activity (approximately 3-11-fold) and accounted for virtually all the Pfp. Although little difference in the proportion of Pfp+ CD8+ T cells could be detected between age groups, stimulated CD8+ cells or whole splenic T cells from old mice consistently exhibited a striking reduction in both the intensity of Pfp staining and the apparent numbers of granules per cell. This difference in Pfp was examined by ELISA and total Pfp levels were found to be approximately 12-fold greater in CTL generated from splenic T cells of young compared to aged mice. The results demonstrate that Pfp levels are reduced in CTL from aged compared to young mice at the level of the individual cells and suggest the possibility that a threshold level of Pfp may be required for potency of effector cell function.     

Study of diverse mechanisms of cell-mediated cytotoxicity in gene-targeted mice using flow cytometric cytotoxicity assay

Cytotoxic lymphocytes kill tumor or virus-infected target cells utilizing two mechanisms-(1) release of lytic granules (containing perforin and granzymes), and (2) Fas ligand (FasL)/Fas or TNF-initiated apoptosis. We have examined mechanisms of target cell lysis by effector T cells from gene-targeted and mutant mice using a new Flow Cytometric Cytotoxicity Assay (FC Assay). Target cells were labeled with PKH67 dye. Cell death was estimated by 7-AAD inclusion and annexin V-PE binding. A direct correlation has been found between the percentage of dead target cells in FC Assay and the results of 111In release cytotoxicity assay when effector T cells from either Pfp -/- (perforin knockout) or gld (non-functional Fas Ligand) mice were used. As shown by the 4 h FC assay, the granule-mediated mechanism was utilized by T cells from gld mice. In contrast, T cells from Pfp -/- mice used death receptor-mediated lysis. Therefore, cytotoxic cells from gene-targeted and mutant mice can serve as valuable tools for studying different mechanisms of cell-mediated cytotoxicity, and the FC assay could be applied irrespective of which cytotoxic effector pathway is involved.     

Antiviral T-Cell-Independent Type 2 Antibody Responses Induced in Vivo in the Absence of T and NK Cells

Polyomavirus (PyV) infection induces protective T-cell-independent (TI) IgM and IgG responses in T-cell-deficient (TCR βxδ−/−) mice. In this study, we show that PyV is a TI -2 antigen: B cells with a mutated Bruton's tyrosine kinase (Xid mutants) do not respond to PyV with antibody secretion in the absence of T cells. We also demonstrate that NK-cell-mediated “help” is not absolutely required for the induction of the TI-2 antibodies to PyV; thus for the first time, we provide evidence for protective IgM and IgG responses against a viral infection induced in mice lacking T and NK cells (CD3Etg). Comparison of the antibody responses observed in T- and NK-cell-deficient mice with those of mice lacking only T cells, however, suggests that NK cells may promote isotype switching to IgG2a. This effect is probably mediated by IFNγ secretion. In support of this idea, studies on the antibody responses of PyV-infected SCID mice that had been reconstituted with IFNγR−/− B cells or wild-type B cells demonstrated the IFNγ dependence of PyV-specific TI IgG2a secretion and provided evidence that IFNγ acting directly on B cells plays an important role in TI pathways of isotype switching to IgG2a in vivo.     

Experimental Borrelia burgdorferi infection in inbred mouse strains: antibody response and association of H-2 genes with resistance and susceptibility to development of arthritis

We have investigated the specific humoral immune response and its correlation to the development of disease after experimental inoculation of B. burgdorferi in different inbred strains of mice. All mouse strains tested showed high levels of specific IgM antibodies during the initial 10 days of infection. Specific IgG antibodies predominantly of the IgG2a, IgG2b and IgG3 isotypes were found in increasing amounts by 14 days post infection. Antibody titers peaked at days 65 and 110. Particularly low titers of specific IgM and/or IgG antibodies were detected in sera of AKR/N and B10.BR mice. Antibodies specific for numerous B. burgdorferi antigens including the outer surface proteins A (31 kDa) and B (34 kDa) and a protein(s) of molecular mass of approximately 40 kDa, most probably 41 kDa (flagellin) and/or 39 kDa (p39), were induced in all inbred mouse strains within 2 weeks inoculation albeit in varying concentrations. Later during infection, the patterns of antibody specificities were much more complex. With regard to development of disease all strains of mice tested fall into three groups: (a) mice of H-2k haplotype (AKR/N, C3H/HeJ, C3H/HeN, B10.BR) developed a chronic progressive arthritis in the tibiotarsal joints, (b) mice of H-2 haplotypes, H-2b (C57BL/6), H-2j (B10.WB), H-2r (B10.R111) and H-2s (B10.S) developed arthritis of variable duration and intensity which was not progressive and (c) mice of H-2d haplotype (BALB/c, DBA/2, C.B-17, B10.D2, Cal.20), irrespective of their background genes or Igh allotype, showed no clinical signs of arthritis at any time point following inoculation of B. burgdorferi organisms. The finding of similar patterns of apparently protective antibodies in all mouse strains tested together with the striking association between the H-2d haplotype and resistance, and between the H-2k haplotype and the occurrence of B. burgdorferi-induced arthritis suggest a critical role of T cells in the development of the disease in mice.     

Breakdown of T cell tolerance to IgG2ab in Igha mice by de novo emerging anti-IgG2ab T cells and not anergy reversion

The intrinsic T cell activity of Igha mice against IgG2ab (IgG2a from the Ighb haplotype) can be subjected to profound specific tolerance. In utero followed by post-natal exposure of Igha mice to soluble IgG2ab results in the loss of the capacity of their T splenocytes to induce specific and chronic IgG2ab allotype suppression in histocompatible Igha/b recipients. However, this full T cell tolerance has not been definitively acquired as it is spontaneously reversed when investigated 3-6 months after the end of the tolerogen treatment. Even when the IgG2ab tolerogen treatment was prolonged to 3, 6 or 9 months of age, T cell tolerance to IgG2ab vanished and the capacity of Igha T splenocytes to induce IgG2ab suppression in Igha/b recipients was systematically restored. The marked but partial thymus involution in 15- month-old Igha mice suggests the existence of some residual thymic output, capable of repopulating the anti-IgG2ab peripheral T pool subsequent to tolerogen clearance. In the present study, we showed that the mechanisms of this tolerance and its reversion involve, at the end of tolerogen treatment, the physical elimination or the irreversible inactivation of natural anti-IgG2ab T cell clones and their replacement, but neither the establishment of reversible anergy nor the recruitment of T cells which could actively maintain tolerance. The spontaneous breakdown of this T cell unresponsiveness was effectively prevented when de novo T cell maturation was inhibited by thymectomy at the end of tolerogen administration. Moreover, tolerance reversion did not occur in peripheral mature Igha T cells, parked in vivo, for up to 20 weeks in histocompatible tolerogen-free nu/nu mice.      

Effects of IgM Allotype Suppression on Serum IgM Levels,B-1 and B-2 Cells,and Antibody Responses ir Allotype Heterozygous F1 Mice

IgM allotype heterozygous F1 mice were independently suppressed for Igh6a or Igh6b to evaluate the contribution of B-1 and B-2 cells to natural serum IgM levels and Ab responses. B-2 B cells expressing IgM of the suppressed allotype were evident in the spleens of suppressed mice 4 to 6 weeks after cessation of the suppression regimen, whereas B-1 B cells of the suppressed allotype were undetectable for up to 9 months. Although serum IgM of the suppressed allotype was initially depleted in mice suppressed for either allotype, by 7 months of age, there were detectable levels of IgM of the suppressed allotype in the serum; however, the levels were significantly below that found in nonsuppressed mice. When mice were immunized with either the T-independent or T-dependent form of phosphorylcholine, those suppressed for either allotype, and consequently depleted of B-1 B cells of that allotype, did not respond with phosphorylcholine-specific IgM of the suppressed allotype. In contrast, when mice were immunized with α1-3 dextran, the Igh6a allotype-suppressed mice were able to produce dextran-specific IgM of that allotype. These results show that allotype-bearing B-1 cells of both allotypes can be effectively suppressed by this suppression protocol and this produces long-lasting effects on B-1 cell levels and serum IgM of the suppressed allotype. These observations reflect the derivation of the majority of B-1 cells from fetal-neonatal precursors, which cannot be replaced by newly emerging B-2 cells of adult origin. Their ablation by antibody treatment results in permanent alterations to the adult B-cell repertoire.     

Differences in putative minor histocompatibility but not IgH genes can prevent T-cell priming and T--B co-operation in the response of mice to sheep erythrocytes

A positive association has been observed in Igh allotype "congenic' mice between skin graft rejection and a block to effective T--B co-operation in the development of both IgM and IgG responses to sheep erythrocytes. Mismatch of Igh alone is insufficient for such a block to become apparent since pairs of Igh-allotype congenic strains of mice which reciprocally accept skin grafts for at least 5 weeks, show successful positive co-operation (help) between T and B cells. The observed block is manifest both during the education (priming) of T cells in irradiated (first stage) recipients and during co-operation between primed T cells and unprimed B cells in second stage irradiated "syngeneic' recipients.     

The T/B cell interaction involved in induction of the mouse IgG2ah suppression is restricted by major histocompatibility complex class I,but not class II molecules

To determine the major histocompatibility complex (MHC) restriction of the T/B cell interaction involved in a negative regulation of Ig production, we used mouse model of T cell-induced IgG2a^b suppression in vivo. Normal or specifically triggered T splenocytes from mice of the Igh^a haplotype, when neonatally transferred into histocompatible Igh^a/b heterozygotes, are able to induce a specific and total suppression of the IgG2a^b allotype. Nevertheless, only transfer of IgG2a^b-primed Igh^a T splenocytes induces this suppression in Igh^b/b homozygous congenic mice in which the whole IgG2a isotype production is inhibited. This suppression is chronically maintained by CD8⁺ T cells, but can be experimentally reversed. We have established that the suppression induction required a CD4⁺CD8⁺ T cell cooperation and operated via the recognition by the involved TCR of Cγ2a^b-derived peptides presented by the target B cells in an MHC haplotype-restricted manner. Here, by using Igh^b mice genetically deficient for MHC class I (β2-microglobulin^%, or β2m^%) or class II (I-Aβ^%) molecules, we demonstrate functionally that the suppression induction implicates an MHC class I-, but not class II-restricted interaction. Indeed, the anti-IgG2a^b T cells transferred into Igh^b H-2^b I-Aβ^% mice carry out the suppression process normally, while in Igh^b H-2^b β2m^% recipients, their suppression induction capacity is significantly inhibited. Moreover, the Cγ2a^b 103–118 peptide, identified as the sole Cγ2a^b-derived peptide able to amplify the anti-IgG2a^b T cell reactivity in Igh^a H-2^b mice, is also able to stabilize the H-2D^b, but not the H-2K^b class I molecules at the surface of RMA-S (TAP2^?, H-2^b) cells. These results indicate that, despite the CD4⁺/CD8⁺ T cell cooperation during the induction phase of suppression only MHC class I molecule expression is required at the surface of IgG2a^b+ B cells for suppression establishment.     

The immunization of A2/K(b) transgenic mice with the KMP11-HSP70 fusion protein induces CTL response against human cells expressing the T. cruzi KMP11 antigen: identification of A2-restricted epitopes

Cytotoxic T lymphocyte response against Jurkat-A2/K(b) cells expressing the T. cruzi KMP11 protein has been evaluated after immunization of C57BL/6-A2/K(b) transgenic mice with the KMP11 and KMP11-HSP70 recombinant proteins. The results show that mice immunized with KMP11 covalently fused to the T. cruzi HSP70 protein, but not mice immunized with KMP11 alone, elicit a CTL response against the Jurkat-A2/K(b) cells expressing the KMP11 protein. The data also show that spleen cells from mice immunized with the fusion protein and stimulated with the K1 peptide induce lysis of both the Jurkat-A2/K(b) cells transfected with the KMP11 coding gene and the Jurkat-A2-K(b) cells pulsed with the K1 peptide. Splenocytes stimulated with the K3 peptide induce lysis of the Jurkat-A2/K(b) cells loaded with the K3 peptide but they do not recognize the target cells expressing the KMP11 protein. Similar results were obtained using lymph node from mice immunized with the peptides. Thus, we believe there are two cytotoxic T cell epitopes restricted to the A2 molecule (K1(KMP11) (4-12) and K3(KMP11) (41-50)) in the KMP11 protein, and suggest that the K1 peptide could be considered an immunodominant antigen whilst the K3 peptide may be regarded as a cryptic epitope. The fact that the CTL lines induced in B6-A2/K(b) mice recognize human cells expressing KMP11 protein, indicates that the KMP11 antigen fused to HSP70 could be a good candidate for the induction of immunoprotective cytotoxic responses against T. cruzi natural infection.