Role of I-A molecules in early stages of B cell maturation.

The role of the Ia molecule in the early phase of B cell development remains controversial. In contrast to previous studies, we have detected minute amounts of Ia (I-A) molecule on early B lineage (B220+IgM-) cells from normal bone marrow, using ELISA. The presence of the I-A molecule even on pro-B cells was deduced from experiments in which a monoclonal anti-I-A antibody completely blocked the generation of pre-B cells from B progenitor (B220-) cells in stromal cell-dependent B cell culture. Inasmuch as this antibody did not inhibit the maturation of pre-B cells to IgM+ B cells in culture, the I-A molecule on early B lineage cells probably plays a role in their maturation. We also examined the role of the I-A molecule in early B cell development, using transgenic mice harboring the antisense DNA to I-A beta-chain gene. The amount of I-A molecule on splenic B cells from the young transgenic mice decreased in the presence of abundant amounts of the antisense RNA. B cell development was perturbed in spleen from the transgenic mice. Stromal cell-dependent B cell cultures from these mice clearly showed that the maturation of B lineage cells was delayed at a very early stage of development (B220- to B220+). We propose that the I-A molecule on early B lineage cells may play an essential role in their maturation.     

MHC class II A alpha and E alpha molecules determine the clonal deletion of V beta 6+ T cells. Studies with recombinant and transgenic mice

Interactions between MHC class II genes and minor lymphocyte stimulating (Mls) associated products are responsible for clonally deleting self-reactive T cells in mice. Here we demonstrate the role of the intact I-A and I-E molecules as well as the individual A alpha and E alpha chains in the deletion of cells bearing the V beta 6 TCR. DBA/1 (H-2q, Mls-1a) mice were crossed with various inbred congenic, recombinant, and transgenic strains and the F1's were screened for V beta 6 expression. All I-E+ strains were fully permissive in deleting V beta 6+ T cells. I-E- strains expressing I-A b,f,s,k,p permitted only partial deletion, while I-Aq strains showed no deletion. Recombinant I-Aq and I-Af strains which expressed E kappa alpha chain in the absence of E beta chain showed a decrease in V beta 6+ T cells as compared to their H-2q and H-2f counterparts. Furthermore, transgenic mice expressing E kappa alpha Aq beta gene in an H-2q haplotype (E kappa alpha Aq beta?) gave similar results to that of the recombinants in deleting V beta 6 T-cells. The role of the 1-A molecule was also shown by the partial deletion of V beta 6+ T cells in H-2q mice expressing transgenic I-Ak molecules. These results demonstrate that the E alpha chain is important in the deletion of V beta 6 T-cells in Mls-1a mice. The role of A alpha chain is also implied by the permissiveness of E kappa alpha Aq beta but not Aq alpha Aq beta molecules in the deletion of V beta 6+ T cells.     

T cell tolerance to Mlsa encoded antigens in T cell receptor V beta 8.1 chain transgenic mice.

To study T cell tolerance, transgenic mice were generated that expressed the Mlsa-reactive T cell receptor (TCR) beta chain V beta 8.1 (cDNA) under the control of the H-2Kb promoter/immunoglobulin heavy chain enhancer on approximately 90% of peripheral T cells. In transgenic mice bearing Mlsa, thymocytes expressing the TCR at a high density were deleted and the percentage of Thy 1.2+ lymph node cells was reduced. The CD4/CD8 ratio of mature T cells was reversed in Mlsa and Mlsb transgenic mice independent of the H-2. RNA analysis and immunofluorescence with TCR V beta-specific antibodies revealed that expression of endogenous TCR beta genes was suppressed. Both Mlsa and Mlsb TCR beta chain transgenic mice mounted a T-cell-dependent IgG response against viral antigens, whereas the capacity to generate alloreactive and virus-specific cytotoxic T cells was impaired in TCR beta chain transgenic Mlsa, but not in transgenic Mlsb mice.     

Co-dominant restriction by a mixed-haplotype I-A molecule (alpha k beta b) for the lysozyme peptide 52-61 in H-2k x H-2b F1 mice

Helper (CD4+) T lymphocytes recognize protein Ag as peptides associated to MHC class II molecules. The polymorphism of class II alpha- and beta-chains has a major influence on the nature of the peptides presented to CD4+ T lymphocytes. For instance, T cell responses in H-2k and H-2b mice are directed at different epitopes of the hen egg lysozyme (HEL) molecule. The current studies were undertaken with the aim of defining the role of mixed haplotype I-A (alpha k beta b and alpha b beta k) molecules in T cell responses to HEL in (H-2k x H-2b)F1 mice, as well as the nature of the immunogenic peptides of HEL recognized in the context of I-A alpha k beta b and I-A alpha b beta k. A series of HEL-reactive T cell lines and hybridomas derived from MHC class II heterozygous (C57BL/6 x C3H F1) mice were established. Their responsiveness to HEL and synthetic HEL peptides was analyzed with the use of L cells transfected with either I-A alpha k beta b or I-A alpha b beta k as APC. Out of 28 clonal T cell hybridomas tested, 13 (46%) only responded to HEL presented by I-A alpha k beta b, 11 (40%) by I-A alpha b beta k (and to a minor extent I-A alpha k beta k), only 4 (14%) were primarily restricted by I-Ak, and none by I-Ab. All the I-A alpha k beta b-restricted T cell hybridomas responded to the HEL peptide 46-61 and to its shorter fragment 52-61, even at concentrations as low as 0.3 nM. As this determinant has been previously defined as immunodominant for I-Ak but not for I-Ab mice, these results suggest a role for the I-A alpha k chain in the selection and immunodominance of HEL 52-61 in H-2k mice. The fine specificity of I-A alpha k beta b-restricted T cell hybridomas for a series of different HEL peptides around the sequence 52 to 61 suggests that peptide 52-61 binds to I-A alpha k beta b with higher affinity than to I-A alpha k beta k. The peptides recognized in the context of I-A alpha b beta k and I-A alpha k beta k were not identified.     

A alpha and A beta class II I-A determinants of antigen-specific T-helper factor and its antigen-nonbinding chain

Antigen-specific T-helper factor (ThF) of CBA (H-2k) origin in the picryl (TNP) contact sensitivity system (Mr 60-70 kDa) was reduced with dithiothreitol under mild conditions. Affinity chromatography on antigen yielded an antigen-binding chain (Mr 20-30 kDa) and an antigen-nonbinding chain (Mr 40-50 kDa). Both chains were glycoproteins and were bound by lentil lectin. Affinity chromatography on anti-I-A monoclonal antibodies showed that I-A determinants occurred on the complete molecule and on the antigen-nonbinding, but not on the antigen-binding, chain. In contrast, five different monoclonal antibodies to I-E alpha failed to absorb ThF. Moreover, the complete molecule and the I-A+ antigen-nonbinding chains had determinants of the alpha and beta chains of I-A and conformational determinants which are based on both chains. Sequential absorption and elution showed that A alpha and A beta determinants occurred on the same molecular complex. These data suggest a minimal model of ThF as a two-chain disulfide-bonded structure with an antigen-binding chain and a separate I-A+ antigen-nonbinding chain which behaves as a single unit in phosphate-buffered saline and has elements of both A alpha and A beta.     

Genetic control of experimental autoimmune myasthenia gravis in mice. III. Ia molecules mediate cellular immune responsiveness to acetylcholine receptors

When MHC congenic and recombinant mice are inoculated with Torpedo acetylcholine receptors (AChR) with adjuvants, the magnitude of autoantibody responses to muscle AChR and the defect of neuromuscular transmission closely parallel in vitro lymphocyte proliferative responses to Torpedo AChR. All of these responses are controlled by gene(s) at the I-A subregion of the H-2 complex. Data presented in this report confirm in back-cross mice that T lymphocyte proliferative responses to AChR are controlled by a Mendelian dominant gene linked to H-2, at the I-A subregion. Lymphocyte responses were eliminated by blocking Ia antigens on lymph node cell surfaces with appropriate anti-I-A alloantisera and by removal of adherent cells. A spontaneous mutation at the I-A subregion in the B6 strain, which resulted in structural alteration of the A beta chain of Ia, converted high responsiveness to AChR to a state of low responsiveness. These data implicate a macrophage-associated Ia molecule in induction of autoimmune responses to AchR, probably in the presentation of AChR to helper T lymphocytes that thereby help B lymphocytes to differentiate into anti-AChR antibody-forming cells.     

Expression patterns of H2-O in mouse B cells and dendritic cells correlate with cell function

In the endosomes of APCs, the MHC class II-like molecule H2-M catalyzes the exchange of class II-associated invariant chain peptides (CLIP) for antigenic peptides. H2-O is another class II-like molecule that modulates the peptide exchange activity of H2-M. Although the expression pattern of H2-O in mice has not been fully evaluated, H2-O is expressed by thymic epithelial cells, B cells, and dendritic cells (DCs). In this study, we investigated H2-O, H2-M, and I-A(b)-CLIP expression patterns in B cell subsets during B cell development and activation. H2-O was first detected in the transitional 1 B cell subset and high levels were maintained in marginal zone and follicular B cells. H2-O levels were down-regulated specifically in germinal center B cells. Unexpectedly, we found that mouse B cells may have a pool of H2-O that is not associated with H2-M. Additionally, we further evaluate H2-O and H2-M interactions in mouse DCs, as well as H2-O expression in bone marrow-derived DCs. We also evaluated H2-O, H2-M, I-A(b), and I-A(b)-CLIP expression in splenic DC subsets, in which H2-O expression levels varied among the splenic DC subsets. Although it has previously been shown that H2-O modifies the peptide repertoire, H2-O expression did not alter DC presentation of a number of endogenous and exogenous Ags. Our further characterization of H2-O expression in DCs, as well as the identification of a potential free pool of H2-O in mouse splenic B cells, suggest that H2-O may have a yet to be elucidated role in immune responses.     

Acquisition of functional MHC class II/peptide complexes by T cells during thymic development and CNS-directed pathogenesis

This study provides evidence that both rat and mouse thymic and splenic T cells express significant levels of MHC class II glycoproteins (MHCII) in vivo. Derivation of rat and mouse chimeras revealed that a major source of MHCII on thymic T cells was acquired from radioresistant host APC. Expression of MHC on thymic T cells appeared physiologically relevant because presentation of rat myelin basic protein (RMBP) by nonadherent, radiosensitive thymic T cells was associated with the adoptive transfer of tolerance. Mature MBP-specific effector T cells isolated from the CNS in both rat and mouse models of EAE also expressed significant levels of MHCII. Adoptive transfer of activated B10.PL MBP/I-A(u)-restricted TCR transgenic T cells into F1(C57BL/6 x B10.PL) mice revealed acquisition of allogeneic I-A(b) on encephalitogenic CNS-derived T cells. Overall, this study indicates that immature and mature T cells in rats and mice acquire functional MHCII in vivo during thymic development and pathogenic inflammation.     

The I-A beta b region (65-85) is a binding site for the superantigen, staphylococcal enterotoxin A

Ia antigen is a receptor for the superantigen staphylococcal enterotoxin A (SEA). Peptides I-A beta b(30-60), I-A beta b(50-70), I-A beta b(65-85), and I-A beta b(80-100) of the MHC class II antigen beta chain on mouse (H-2b) accessory cells were synthesized. Only I-A beta b(65-85) inhibited SEA binding to the mouse B-cell lymphoma line, A20 (H-2d) and the human Burkitt's lymphoma line, Raji (HLA-DR). The I-A beta b(65-85) sequence is a predicted alpha-helix along the hypothetical antigen binding cleft of the Ia molecule. I-A beta b(65-85) also directly and specifically bound both the intact SEA molecule and its Ia binding site, represented by the peptide SEA(1-45). The results suggest that I-A beta b region (65-85) is a necessary site for Ia molecular interaction with the superantigen SEA. Further, the data suggest that the same helical region of other Ia antigens binds SEA irrespective of haplotype and species.     

Assignment of antigenic determinants to separated I-A kappa chains

The alpha- and beta-chains of the I-A kappa antigen from the AKTB-1b B cell lymphoma were separated by ion-exchange chromatography on CM-Sephadex in the presence of propionic acid and urea. Removal of the denaturants by dialysis produced isolated chains that regained a significant amount of their native configuration. These materials were used with a battery of monoclonal antibodies in a direct binding assay to localize specific alloantigenic determinants to the A alpha kappa or A beta kappa chains. This method allowed the assignment of the nominal specificity Ia. 17 and at least one epitope of the specificity Ia.2 to the A beta kappa chain. Finally, the I-A kappa antigen from the B cell lymphoma AKTB-1b was shown to be identical, by the criterion of tryptic peptide analysis, to that derived from normal B10.BR splenocytes. This constitutes the first demonstration that the polypeptide portion of a tumor-derived class II MHC antigen is identical to that derived from a normal tissue.     

Cell-surface expression and alloantigenic function of a human nonclassical class I molecule (HLA-E) in transgenic mice

We have introduced the gene (E*01033) encoding the heavy chain of the human nonclassical MHC class I Ag, HLA-E, into the mouse genome. Two founder mice carry a 21-kb fragment, the others bear an 8-kb fragment. Each of the founder mice was mated to mice of an already established C57BL/10 transgenic line expressing human beta2-microglobulin (beta2m). Cell surface HLA-E was detected on lymph node cells by flow cytometry only in the presence of endogenous human beta2m. However, HLA-E-reactive mouse CTL (H-2-unrestricted) lysed efficiently the target cells originating from HLA-E transgenic mice without human beta2m, showing that the HLA-E protein can be transported to the cell surface in the absence of human beta2m, presumably by association with murine beta2m. Rejection of skin grafts from HLA-E transgenic mice demonstrates that HLA-E behaves as a transplantation Ag in mice. HLA-E transgenic spleen cells are effective in stimulating an allogeneic CTL response in normal and human classical class I (HLA-B27) transgenic mice. Furthermore, results from split-well analysis indicate that the majority of the primary in vivo-induced CTL recognizes HLA-E as an intact molecule (H-2-unrestricted recognition) and not as an HLA-E-derived peptide presented by a mouse MHC molecule, although a small fraction (ranging from 4 to 21%) of the primary in vivo-induced CTL is able to recognize HLA-E in an H-2-restricted manner. Based on these observations, we conclude that HLA-E exhibits alloantigenic properties that are indistinguishable from classical HLA class I molecules when expressed in transgenic mice.     

Cell surface expression and alloantigenic function of a human class I MHC heavy chain gene (HLA-B7) in transgenic mice

We have introduced the gene encoding the heavy chain of the human MHC class I Ag HLA-B7 into transgenic mice. The gene was shown to be expressed at both the RNA and protein level. Cell surface HLA-B7 was detected on whole spleen cells by immunoprecipitation and on purified T cells by flow cytometry (FACS). Normal mice immunized with H-2-syngeneic B7-transgenic spleen cells generated CTL capable of killing transgenic cells and B7-expressing human JY cells. Anti-HLA mAb blocked the killing of JY cells. These results indicate that the human class I Ag HLA-B7 can be expressed at the surface of transgenic spleen cells in the absence of human beta 2-microglobulin, and that a significant fraction exists in a form recognizable by nontransgenic CTL as a major histocompatibility Ag unrestricted by H-2.     

Expansion of myelopoietic precursors and inhibition of B-cell precursors in mice that express a T-cell receptor gamma (V gamma 1.1J gamma 4C gamma 4) transgene.

Knowledge of the genetic determinants that can affect renewal of multipotential stem cells and their commitment to specific cell lineages is essential to our understanding of multicellular development. However, despite the vast amount of accumulated knowledge in this area, genetic determinants that affect renewal and commitment of precursor cells are unknown. In this study, we demonstrate that three independently derived founder mouse strains, transgenic for the TcR V gamma 1.1J gamma 4C gamma 4 (TcR gamma 4) chain gene, differed significantly from normal mice in their development of T and B cells as well as myelopoietic precursor cells. Ontogenic programs consistent with an acceleration of T-cell development and a delayed appearance and suppressed levels of pre-B- and B-cell precursors were evident in these transgenic mice. In addition, TcR gamma 4 transgenic mice possessed a significantly elevated level of myelopoietic pluripotential precursors. 3H-thymidine cell suicide studies suggest that higher percentages of pluripotent precursors from the bone marrow of the TcR gamma 4 transgenic mice were in the S phase of the cell cycle. These modulations of the lymphoid and myelopoietic compartments, however, were not found in other T-cell receptor transgenic mice (e.g., TcR V gamma 1.2J gamma 2C gamma 2, TcR gamma 2; or V beta 8.1D beta J beta 2.4C beta 2, TcR beta) constructed with the same or similar cDNA expression vector. The results suggest that the expression of a specific T-cell receptor gamma chain gene, and/or an elevated level of particular subset of TcR gamma delta cells, may affect the proliferation and relative proportions of haemopoietic and lymphoid precursors.     

Regulation of type 1 diabetes by a self-MHC class II peptide: role of transforming growth factor beta (TGF-beta).

The present study was undertaken to analyze the regulatory T cells generated in response to class I derived self-I-A beta(g7) (54-76) peptide. It was observed T cells from young unprimed type 1 diabetes (T1D) prone NOD mice did not respond to self-I-A beta(g7) (54-76) peptide although T cells from primed young NOD mice showed a strong response. T cells from young unprimed BALB/c mice responded to self-I-A beta(d) (62-78) peptide. However, a breakdown of tolerance to these peptides was observed with age in both the strains. Culture supernatant from I-A beta(g7) (54-76) peptide-primed cells secreted large amounts of TGF-beta and inhibited T cell responses in allogeneic-MLR. Further, I-A beta(g7) (54-76) peptide specific T cell lines from young (I-A.Y) and diabetic (I-A.D) NOD mice were established. I-A.Y secreted IL-4, TGF-beta and IL-10 while I-A.D T cell line secreted IL-10 and IFN-gamma. We found that I-A.D T cell line induced diabetes when transferred in NOD/SCID mice but I-A.Y T cell line did not induce disease. These results show that immunization of NOD mice with I-A beta(g7) (54-76) peptide at a younger age induces a regulatory T cell response suggesting that correcting the defects in immunoregulatory mechanisms using self-MHC peptides may be one of the approaches to prevent autoimmune diseases like T1D.     

hβ2m/HLA-B2704双转基因小鼠的制备及β2m对HLA-B2704表达的影响

制备hβ2m HLA B2 70 4双转基因小鼠 ,研究hβ2m对HLA B2 70 4表达的影响 .通过hβ2m转基因小鼠和HLA B2 70 4转基因小鼠交配 ,出生动物及后代经PCR初步筛选 ,采用Southern杂交对经PCR初步筛选的hβ2m HLA B2 70 4双转基因阳性小鼠基因组DNA标本作进一步鉴定 .阳性者进行RT PCR和流式细胞光度术检测其在mRNA和蛋白水平的表达 .hβ2m阳性小鼠和HLA B2 70 4阳性小鼠交配 ,生仔鼠 6 7只 ,其中 2 8只仔鼠同时整合hβ2m和HLA B2 70 4基因 .Southern杂交证实 ,阳性鼠同时都含有hβ2m和HLA B2 70 4基因 .阳性小鼠的皮肤、结肠、睾丸和脾脏组织中均有HLA B2 70 4和hβ2m基因的mRNA表达 ,其外周血淋巴细胞膜上HLA B2 70 4基因的蛋白表达为 35 87% ,在HLA B2 70 4单转基因小鼠外周血淋巴细胞膜上HLA B2 70 4基因的蛋白表达为 7 87% (Histogramsta tistics) .成功地制备了hβ2m HLA B2 70 4双转基因小鼠 .在hβ2m HLA B2 70 4双转基因小鼠的外周血淋巴细胞膜上 ,HLA B2 70 4基因在蛋白水平表达较高 ,而在HLA B2 70 4单转基因小鼠中则表达不明显 .hβ2m可与HLA B2 70 4重链分子结合 ,稳定和增高其在淋巴细胞膜上的表达     

A variant alpha-chain in an Ia molecule from the I-A subregion of the mouse major histocompatibility complex: a possible intragenic recombination

The recombinant MHC haplotype t1, present in mouse strain A.TL and B10.TL, encodes an I-A molecule with a variant alpha-chain that was recognized when tryptic peptide digests from t1 and the nominal parental haplotype (a1 or k) were compared by double-label reverse phase HPLC. The t1 I-A alpha-chain possesses a tryptic peptide absent from a1 and k I-A alpha-chains, and lacks several peptides present in a1 and k. The peptide that differs in t1 is not a mannose-bearing peptide, and thus its altered mobility is probably not due to carbohydrate modification. The alteration in t1 could result from mutation or intragenic recombination, but the unique t1 peptide migrates in a position identical to a peptide found in haplotype s, a partner in the (s X a1) cross that generated the t1 recombinant. If this apparently shared peptide indicates an intragenic recombination, this places the I-A alpha-gene centromeric to the other I-A subregion gene, and together with the data of Jones, suggests a gene order of I-A alpha, I-A beta, I-E beta (A alpha, A beta, Ae).     

Effects of in vivo monoclonal anti-I-A antibody treatment in neonatal mice on intrathymic and peripheral class II antigen expression

Intrathymic, Ia-bearing antigen-presenting cells (APC) are believed to play an important role in the development of a mature, functional T-cell repertoire. We used chronic in vivo treatment of neonatal mice with anti-I-A monoclonal Ab (MAb) to examine the expression of I-A and I-E antigens on intrathymic and peripheral APC. Three weeks after continuous treatment with anti-I-A MAb, FACS analysis of unfractionated spleen cells revealed a 75-90% reduction in the number of I-A bearing cells. Splenic antigen-presenting capacity measured by the ability of unseparated or density gradient-enriched APC to stimulate I-A- or I-E-reactive T-cell hybridomas was also greatly reduced. In contrast to the expression of I-A and I-E molecules in the splenic APC, anti-I-A MAb treatment resulted in decreased thymic APC I-A expression without significant changes in I-E as measured by FACS analysis. This was confirmed in functional studies in which allo-I-A- or auto-I-A-reactive T-cell hybridomas could not be stimulated by treated thymic APC. Unlike splenic APC, anti-I-A-treated thymic APC did not differ significantly from normals in their ability to stimulate allo-I-E-reactive T hybridomas. This lack of linkage or comodulation of I-A and I-E expression on thymic but not splenic APC may allow us to study the role of I-A molecules and I-E molecules on the development and expansion of functional, mature T-cell repertoires.     

Identity of molecules bearing murine Ia alloantigenic specificities Ia.7 and Ia.22: evidence for a single type of I-E molecule in homozygotes

In homozygous mice bearing I regions derived from haplotype k, only a single type of Ia molecule bearing the alloantigenic specificities Ia.7 and Ia.22 was found using techniques of sequential immune precipitation and tryptic peptide analysis. As suggested at the fourth Ir Gene Workshop (Sachs 1978), Ia.7 is considered here to be an antigenic determinant associated with I-E-subregion-encoded molecules, i.e., it is excluded from the I-C subregion. The I-C subregion is currently defined mainly by functional traits. It is now known that the I-E molecules are composed of an alpha chain encoded in the I-E subregion, and a beta chain encoded in the I-A subregion. Since the I-C subregion is not involved with the determination of these Ia molecules, and since in homozygotes there is apparently only a single type of molecule bearing both specificities Ia.7 and Ia.22, the term "I-E/C" molecule should probably be dropped in favor of the simpler designation I-E.     

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.