IL-1 receptor accessory protein and ST2 comprise the IL-33 receptor complex

IL-33 (IL-1F11) is a recently described member of the IL-1 family of cytokines that stimulates the generation of cells, cytokines, and Igs characteristic of a type 2 immune response. IL-33 mediates signal transduction through ST2, a receptor expressed on Th2 and mast cells. In this study, we demonstrate that IL-33 and ST2 form a complex with IL-1R accessory protein (IL-1RAcP), a signaling receptor subunit that is also a member of the IL-1R complex. Additionally, IL-1RAcP is required for IL-33-induced in vivo effects, and IL-33-mediated signal transduction can be inhibited by dominant-negative IL-1RAcP. The implications of this shared usage of IL-1RAcP by IL-1(alpha and beta) and IL-33 are discussed.

Paired immunoglobulin-like receptors and their MHC class I recognition

The immunoglobulin-like receptors provide positive and negative regulation of immune cells upon recognition of various ligands, thus enabling those cells to respond properly to extrinsic stimuli. Murine paired immunoglobulin-like receptor (PIR)-A and PIR-B, a typical receptor pair of the immunoglobulin-like receptor family, are expressed on a wide range of cells in the immune system, such as B cells, mast cells, macrophages and dendritic cells, mostly in a pair-wise fashion. The PIR-A requires the homodimeric Fc receptor common gamma chain for its efficient cell-surface expression and for the delivery of an activation signal. In contrast, PIR-B inhibits receptor-mediated activation signals in vitro upon engagement with other activating-type receptors, such as the antigen receptor on B cells and the high-affinity Fc receptor for immunoglobulin E on mast cells. Recent identification of major histocompatibility complex (MHC) class I molecules as the physiological ligands for PIR has enabled us to attribute various immunological phenotypes observed in PIR-B-deficient mice to the consequences of the absence of a balanced interaction between PIR and MHC class I molecules expressed ubiquitously. Thus, PIR-A and PIR-B constitute a novel and physiologically important MHC class I recognition system.

A novel mutation in IFN-gamma receptor 2 with dominant negative activity: biological consequences of homozygous and heterozygous states

We identified two siblings homozygous for a single base pair deletion in the IFN-gammaR2 transmembrane domain (791delG) who presented with multifocal Mycobacterium abscessus osteomyelitis (patient 1) and disseminated CMV and Mycobacterium avium complex infection (patient 2), respectively. Although the patients showed no IFN-gammaR activity, their healthy heterozygous parents showed only partial IFN-gammaR activity. An HLA-identical bone marrow transplant from the mother led patient 1 to complete hemopoietic reconstitution, but only partial IFN-gammaR function. We cloned and expressed fluorescent fusion proteins of the wild-type IFN-gammaR2, an IFN-gammaR2 mutant previously described to produce a complete autosomal recessive deficiency (278del2), and of 791delG to determine whether the intermediate phenotype in the 791delG heterozygous state was caused by haploinsufficiency or a dominant negative effect. When cotransfected together with the wild-type vector into IFN-gammaR2-deficient fibroblasts, the fusion protein with 791delG inhibited IFN-gammaR function by 48.7 +/- 5%, whereas fusion proteins with 278del2 had no inhibitory effect. Confocal microscopy of 791delG fusion proteins showed aberrant diffuse intracellular accumulation without plasma membrane localization. The fusion protein created by 791delG did not complete Golgi processing, and was neither expressed on the plasma membrane, nor shed extracellularly. The mutant construct 791delG exerts dominant negative effects on IFN-gamma signaling without cell surface display, suggesting that it is acting on pathways other than those involved in cell surface recognition of ligand.

Analysis of cDNAs coding for immunologically dominant antigens from an oncosphere-specific cDNA library of Echinococcus multilocularis

A cDNA library based on mRNA from oncospheres of Echinococcus multilocularis was constructed and screened with an oncosphere-specific rabbit serum. cDNA sequences of three clones that were isolated out of this library are discussed: one codes for a serpin-like proteinase inhibitor, the first isolated from cestodes. Two other clones code for dominant oncosphere antigens and represent homologues of known genes: one is known from several taeniid cestodes as a protective antigen containing fibronectin III domains, the second is related to genes of small heat shock proteins. It contains an internal duplication that might be specific for platyhelminths.

Effect of human leukocyte antigen heterozygosity on infectious disease outcome: the need for allele-specific measures

BACKGROUND

Doherty and Zinkernagel, who discovered that antigen presentation is restricted by the major histocompatibility complex (MHC, called HLA in humans), hypothesized that individuals heterozygous at particular MHC loci might be more resistant to particular infectious diseases than the corresponding homozygotes because heterozygotes could present a wider repertoire of antigens. The superiority of heterozygotes over either corresponding homozygote, which we term allele-specific overdominance, is of direct biological interest for understanding the mechanisms of immune response; it is also a leading explanation for the observation that MHC loci are extremely polymorphic and that these polymorphisms have been maintained through extremely long evolutionary periods. Recent studies have shown that in particular viral infections, heterozygosity at HLA loci was associated with a favorable disease outcome, and such findings have been interpreted as supporting the allele-specific overdominance hypothesis in humans.

METHODS

An algebraic model is used to define the expected population-wide findings of an epidemiologic study of HLA heterozygosity and disease outcome as a function of allele-specific effects and population genetic parameters of the study population.

RESULTS

We show that overrepresentation of HLA heterozygotes among individuals with favorable disease outcomes (which we term population heterozygote advantage) need not indicate allele-specific overdominance. On the contrary, partly due to a form of confounding by allele frequencies, population heterozygote advantage can occur under a very wide range of assumptions about the relationship between homozygote risk and heterozygote risk. In certain extreme cases, population heterozygote advantage can occur even when every heterozygote is at greater risk of being a case than either corresponding homozygote.

CONCLUSION

To demonstrate allele-specific overdominance for specific infections in human populations, improved analytic tools and/or larger studies (or studies in populations with limited HLA diversity) are necessary.

Characterization of a CD40-dominant inhibitory receptor mutant

CD40 is an important mediator of immune and inflammatory responses. It is a costimulatory molecule for B cell proliferation and survival. Blockade of CD40 has been shown to induce tolerance and its role in other pathogenic conditions has led to the proposal that CD40 inhibition could be valuable therapeutically. As a first step to this end, we have characterized a CD40-dominant negative receptor. This inhibitory mutant lacks the identified CD40 signaling domains. It inhibits both cotransfected and endogenous CD40 activation of NF-kappaB. This mutant is specific, as it does not affect TNF or latent membrane protein 1 signaling. Its potential usefulness is illustrated by its ability to inhibit the CD40 ligand-stimulated increases of HLA and CD54 expression, molecules involved in Ag recognition and lymphocyte recruitment leading to organ rejection. The inhibitory mutant has no TNFR-associated factor 2-binding capabilities and inhibits the recruitment of TNFR-associated factor 2 to the CD40 signaling complex after stimulation. These studies show that the CD40 inhibitory receptor molecule is effective, specific, and useful both for research and potentially as a clinical tool. And furthermore, it is likely that similar dominant inhibitory receptors can be generated for all of the members of the TNFR superfamily.

Suppression of thymic development by the dominant-negative form of Gads

Gads, a hematopoietic-lineage-specific Grb2 family member, is involved in the signaling mediated by the TCR through its interactions with SLP-76 and LAT. Here, we generated transgenic mice expressing Grf40-dSH2, an SH2-deleted dominant-negative form of Gads, which is driven by the lck proximal promoter. The total number of thymocytes was profoundly reduced in the transgenic mice, whereas in the double-negative (CD4(-)CD8(-)) thymocyte subset, in particular the CD25(+)CD44(-) pre-T cell population, it was significantly increased. However, CD5 expression, which is mediated by pre-TCR stimulation, was significantly suppressed on the CD4(-)CD8(-) thymocytes of the transgenic mice. Furthermore, the SLP-76-dependent signaling was markedly suppressed as well. These data suggest that Gads plays an important role in the pre-TCR as well as TCR signaling in thymocytes.

The major and a minor class II beta-chain (B-LB ) gene flank the Tapasin gene in the B-F /B-L region of the chicken major histocompatibility complex

We have identified the major histocompatibility complex class II beta-chain (B-LB) genes present in the B-F/B-L region of the B complex of nine well-characterized lines of chickens and have cleared up much of the confusion concerning numbers and location of B-LB genes in this region. By amplifying DNA sequences between adjacent genes, we found two B-LB genes that lie on either side of Tapasin. The dominantly expressed 'major' B-LB gene in all haplotypes lies between Tapasin and RING-3, and belongs to the B-LBII family of class II beta-chain genes. The poorly expressed 'minor' B-LB gene in all haplotypes lies between B-lec1 and Tapasin, and belongs either to the B-LBII family or to the previously unmapped B-LBVI family of class II beta-chain genes. The data suggest that the B-LBII and B-LBVI genes are two lineages of B-LB genes and we propose that they all be termed B-LB genes. The location of a third B-LB gene in the B12 haplotype (and possibly other haplotypes as well) has yet to be determined. The structural organization and expression of the class II beta-chain genes in the B-F/B-L region is similar to that of chicken class I (B-F) genes, one functional result of which is differential resistance to disease and response to vaccines.

The role of CD8 alpha' in the CD4 versus CD8 lineage choice

During thymic development the recognition of MHC proteins by developing thymocytes influences their lineage commitment, such that recognition of class I MHC leads to CD8 T cell development, whereas recognition of class II MHC leads to CD4 T cell development. The coreceptors CD8 and CD4 may contribute to these different outcomes through interactions with class I and class II MHC, respectively, and through interactions with the tyrosine kinase p56lck (Lck) via their cytoplasmic domains. In this paper we provide evidence that an alternatively spliced form of CD8 that cannot interact with Lck (CD8 alpha') can influence the CD4 vs CD8 lineage decision. Constitutive expression of a CD8 minigene transgene that encodes both CD8 alpha and CD8 alpha' restores CD8 T cell development in CD8 alpha mutant mice, but fails to permit the development of mismatched CD4 T cells bearing class I-specific TCRs. These results indicate that CD8 alpha' favors the development of CD8-lineage T cells, perhaps by reducing Lck activity upon class I MHC recognition in the thymus.

Systematic mutagenesis of TCR complementarity-determining region 3 residues: a single conservative substitution dramatically improves response to both multiple HLA-DR alleles and peptide variants

To define the relative contributions of HLA and peptide contacts with TCR complementarity-determining region (CDR) 3 residues in T cell recognition, systematic mutagenesis and domain swapping was conducted on two highly similar TCRs that both respond to the influenza hemagglutinin (HA) peptide, HA307-319, but with different HLA restrictions. Despite the primary sequence similarity of these TCRs, exchange of as little as two CDR3 residues between them completely abrogated responsiveness. At position 95 within CDR3alpha, various substitutions still allowed for some degree of recognition. One modest substitution, alanine for glycine (essentially the addition of a methyl group), significantly broadened the specificity of the TCR. Transfectants expressing this mutant TCR responded strongly in the context of multiple HLA-DR alleles and to HA peptide variants with substitutions at each TCR contact residue. These results suggest that the conformations of CDR3 loops are crucial to TCR specificity and that it may not be reliable to extrapolate from primary sequence similarities in TCRs to similarities in specificity. The ease with which a broad specificity is induced in this mutant TCR has implications for the mechanisms and frequency of alloreactivity and promiscuity in T cell responses.

Expression of multiple unique rejection antigens on murine leukemia BALB/c RLmale symbol1 and the role of dominant Akt antigen for tumor escape

Using the pRL1a Ag-loss RLmale symbol1 tumor variant cell line RM2-1, we demonstrated the presence of tumor Ags other than pRL1a that were recognized by CTLs on RLmale symbol1 cells. Semiallogeneic CB6F1 or syngeneic BALB/c CTLs generated against RM2-1 lysed RM2-1 and RLmale symbol1 cells to a similar extent, but no killing was observed with any other tumor or normal cells examined. Clonal analysis and sensitization with reversed phase-HPLC fractions revealed that there were Dd- and Ld-binding peptides recognized by RM2-1 CTLs. Lysis by bulk CTLs stimulated against RLmale symbol1 and limiting dilution analysis suggested that the pRL1a peptide was dominantly recognized to the RM2-1 peptides by CTLs on RLmale symbol1 cells. The rejection response against the parental RLmale symbol1 tumor was much less than that against RM2-1 cells in either CB6F1 or BALB/c mice, suggesting that the presence of altered Akt molecules from which the dominant pRL1a peptide was derived inhibited the rejection response against RLmale symbol1. Depletion of CD4 T cells caused the regression of RLmale symbol1 at the doses in which the tumor grew in untreated mice. The generation of pRL1a CTLs was inhibited in RLmale symbol1-bearing mice. Thus, immunoregulatory CD4 T cells were most likely activated by the altered Akt molecules and inhibited the efficient generation of CTLs against the dominant pRL1a Ag in RLmale symbol1.

Absence of imprinting of HLA class Ia genes leads to co-expression of biparental alleles on term human trophoblast cells upon IFN-gamma induction

Human trophoblast cells have developed various efficient regulatory mechanisms to prevent cell surface expression of the classical HLA-A, -B, and (but not always) -C class I molecules. This allows them to escape maternal alloimmune attack during pregnancy. However, recent results have demonstrated that such a lack of expression could be reversed in villous cytotrophoblast cells purified from term placenta by in vitro IFN-gamma treatment. In this context, we investigated whether both maternal and paternal HLA class Ia antigens were co-dominantly expressed in such trophoblast cells. Using polymerase chain reaction sequence-specific primers for HLA-A and HLA-C alleles, we detected transcripts of both paternal and maternal origins, showing that these genes were not affected by genomic imprinting, at least in term placenta. After in vitro IFN-gamma treatment, the polymorphic HLA-A and HLA-B antigens of both parental origins become detectable at the cell surface, as assessed by flow cytometry and/or complement-dependent microtoxicity test. Appearance of paternal antigens on trophoblast cells upon IFN-gamma induction raises the question of the in vivo biological consequences of this phenomena, in term of materno-fetal tolerance and in particular of a potential allogeneic cytotoxic immune response.

Apoptosis induced by a chimeric Fas/FLICE receptor: lack of requirement for Fas- or FADD-binding proteins

Current models for Fas (CD95)-mediated apoptosis suggest that FLICE/caspase-8 is recruited and activated, which results in cell death. However, the role of additional molecules in Fas signaling and FLICE activation is not clear. A chimeric Fas/FLICE (F/F) receptor, containing the extracellular/transmembrane portion of Fas and the caspase region of FLICE, mediated anti-Fas apoptosis. FLICE protease subunits were generated from the F/F precursor. Killing induced by Fas, but not F/F, was blocked by a dominant negative FADD. Apoptosis triggered through Fas and F/F was inhibited by coexpression of CrmA and p35, but not Bcl-xL. F/F bypassed Fas resistance in COS-7 cells and blocking by the death effector domain (DED)-containing viral protein MC159. These results show that: 1) F/F induces cell death, indicating that FLICE activation is sufficient for apoptosis and does not require additional Fas- or FADD-binding proteins; and 2) F/F bypasses proximal defects in Fas signaling that prevent FLICE recruitment or activation.

A peptide binding motif for HLA-DQA1*0102/DQB1*0602, the class II MHC molecule associated with dominant protection in insulin-dependent diabetes mellitus

HLA-DQA1*0102/DQB1*0602 (DQ0602) is observed at a decreased frequency in insulin-dependent diabetes mellitus in different ethnic groups, suggesting a protective role for DQ0602. Analysis of overlapping peptides from human insulin found that insulin B(1-15) bound well to DQ0602 and exhibited a high degree of allelic specificity. Truncation analysis of insulin B(1-15) identified insulin B(5-15) as the minimal peptide for DQ0602 binding. Insulin B(5-15) bound to DQ0602 with an apparent KD of 0.7 to 1.0 microM and peptide binding reached equilibrium at 96 h. Single arginine substitutions at each position of the insulin B(5-15) peptide identified amino acids 6, 8, 9, 11, and 14 (relative positions P1, P3, P4, P6, and P9) as important for binding. Extensive substitutions for each of these amino acids revealed that amino acids 11 and 14 (P6 and P9) exhibited the highest specificity. Amino acid 11 (P6) preferred large aliphatic amino acids, while amino acid 14 (P9) preferred smaller aliphatic and hydroxyl amino acids. Binding of an overlapping series of peptides from a randomly chosen protein, the herpes simplex virus-2 tegument protein UL49, correlated completely with the presence or absence of the DQ0602 peptide binding motif. Peptides 11 amino acids long were selected from GAD65, IA-2, and proinsulin, that contained the DQ0602 peptide binding motif. Of these, 79% (19 of 24) were able to bind DQ0602. This study identifies a peptide binding motif for DQ0602 and peptides from insulin-dependent diabetes mellitus autoantigens that bind DQ0602 in vitro.

TCR-delta gene rearrangement and selection during fetal thymocyte development

TCR delta-chain gene rearrangements were analyzed at different stages of thymic ontogeny. The VDJ delta junctional sequences of the dominantly expressed TCR delta-chain V7 subfamily are highly conserved in fetal and neonatal thymocytes. They are equally conserved in C delta-targeted mice lacking cell surface expression of gamma delta receptors, indicating evolutionary selection acting at the level of DNA rearrangement. Yet, in C delta-mutant mice, the frequency of in-frame transcripts is reduced to 61%, from 88% in wild-type mice, suggesting cellular selection of this DV7-overexpressing gamma delta thymocyte subset. In contrast, in genomic DNA rearrangements, no difference was found in the frequency of productive rearrangements between mutant (26%) and wild-type mice (31%). This in-frame rate, characteristic of random rearrangements, indicates that positive selection is not required for thymic maturation of gamma delta T cells. The results are discussed with regard to models of alpha beta/gamma delta lineage commitment.

Evidence for cooperation between TCR V region and junctional sequences in determining a dominant cytotoxic T lymphocyte response to herpes simplex virus glycoprotein B

TCR repertoire availability has the potential to influence the immune response to foreign antigens. Here we have analysed how changes in V region availability influence the H-2b-restricted cytotoxic T lymphocyte (CTL) response to a dominant peptide determinant derived from the herpes simplex virus glycoprotein B (gB). We have previously shown that C57BL/6 mice mount a gB-specific, Kb-restricted CTL response which is dominated by a TCRBV10+ population and a TCRBV8S1+ subpopulation, both containing highly conserved CDR3 elements. We find that this dominant gB-specific CTL pool is lost in C57/L mice which have a different TCRBV haplotype. A population of CTL with diverse TCRBV and junctional sequence usage, which otherwise represents a minor subset in the gB-specific response, appears to emerge as a consequence of this TCRBV gene variation. The loss of preferential V region-encoded complementarity determining regions (CDR) 1- and/or CDR2-ligand interactions in this emerging population also results in a change in CDR3 sequence usage and a corresponding focusing of an otherwise promiscuous pattern of cross-reactivity with a panel of gB498-505 substitution analogues. This suggests that the difference between the two distinct TCR populations is the relative contributions of the CDR towards ligand recognition. Therefore, preferential V region-ligand interaction, at the expense of CDR3 peptide recognition, appears to control the dominant TCR selection in the C57BL/6 response to this peptide determinant.

Class I-deficient hemopoietic cells and nonhemopoietic cells dominantly induce unresponsiveness of natural killer cells to class I-deficient bone marrow cell grafts

NK cells in normal mice reject bone marrow transplants from class I-deficient mice. In contrast, class I-deficient mice do not reject autologous cells, suggesting that NK cell tolerance is acquired. We employed fetal liver irradiation chimeras to assess two potential mechanisms that could account for the tolerance of NK cells in class I-deficient mice to class I-deficient cells: 1) a positive model, in which recognition of class I+ cells molecules by NK cells is necessary to induce functional NK cell maturation; and 2) a negative model, in which interactions of NK cells with class I-deficient cells induce tolerance. In class I+ chimeras reconstituted with mixtures of class I+ and class I-deficient fetal liver cells, the rejection of class I-deficient bone marrow cell grafts was significantly impaired, supporting the negative model. We further addressed whether nonhemopoietic cells are also able to induce NK cell tolerance. Class I- mice reconstituted with class I+ fetal liver cells were tolerant of class I-deficient cells, favoring this idea. Furthermore, class I-deficient mice reconstituted with a mixture of class I-deficient and class I+ fetal liver cells were more tolerant to class I-deficient cells than were class I+ mice reconstituted with the same fetal liver cell mixture. These results suggest that maximal tolerance induction requires the presence of class I-deficient nonhemopoietic cells.

The influence of the In(Lu) gene on expression of CDw75 antigens on human red blood cells

The influence of the In(Lu) gene on human red blood cell (RBC) expression of CDw75 antigens was examined. CDw75 antigens were increased in expression on Lu(a-b-) cells of the dominant inhibitor type in comparison with red cells from donors of other Lutheran (Lu) phenotypes. In contrast, CD44 epitopes detected with F10-44-2, A3D8 and BU52 monoclonal antibodies (mAb) were decreased in expression on Lu(a-b-) red cells. Among normal blood donors of the common phenotype Lu(a-b+) there was a wide range of expression of CDw75 antigens on red cells. The results show that CDw75 is a quantitative polymorphism of human red cells and, among antigens influenced by the In(Lu) gene, is unique in being up-regulated in expression.

Murine splenic null cell compartment contains distinct haemopoietic subpopulations: enlargement of a myeloid and an undifferentiated subset with the development of splenomegaly in New Zealand black mice

We have previously reported that non-T, non-B 'null' cells increase with age in New Zealand Black (NZB) mice resulting in splenomegaly. Using a panel of monoclonal antibodies recognizing lineage-specific cell surface antigens we demonstrate four distinct subsets within this null cell compartment: (1) undifferentiated; (2) T lineage with undetectable Thy-1.2; (3) myeloid/erythroid; and (4) a pre-B/plasma cell type. All four subsets also occur in non-autoimmune mice. The frequency of these populations are similar in the young mice of all the strains examined, although the total number of null cells is higher in NZB. The elevation of null cells in young NZB mice is controlled by a single dominant gene in the genetic cross with New Zealand White (NZW) mice and does not appear closely related to the subsequent development of autoimmune disease. The proportion of myeloid/erythroid null cells increases with age in NZB as splenomegaly develops.

An autoimmuno-dominant thyroglobulin epitope characterized by a monoclonal antibody

It has become evident in recent years that autoimmune thyroglobulin (Tg) antibodies of Graves disease and Hashimoto's thyroiditis show a restricted epitope repertoire compared to Tg heteroantibodies. We have produced monoclonal antibodies (Mab) against human Tg by the hybridoma technique and the epitope specificity was determined by crossblocking experiments. Six noncrossreactive Mabs were used in a double determinant IRMA system for plasma Tg measurements. Sensitivity of the assays was between 1 and 2 ng/ml, intraassay variation less than 5%. Recovery experiments with added Tg were performed in 25 Graves sera with elevated Tg autoantibodies. Monoclonal antibody Tg13 showed an unusual strong interference with autoantibodies resulting in a very low recovery in all sera (median: less than 10%). In further studies Tg was digested by trypsin and after Western blotting, the resulting fragments were incubated with different Mab antibodies, a polyclonal antibody and 10 different Graves sera with high Tg autoantibodies. In contrast to all other mabs only Mab Tg13 showed several low molecular weight bands between 17 and 50 KD. The major bands recognized by Mab Tg13 corresponded to bands obtained by the autoimmune sera, which showed a very homogeneous band pattern. We conclude that Mab Tg13 is specific for an autoimmunodominant B cell epitope of human Tg.

Analysis of the genetic encoding of oestradiol suppression of delayed-type hypersensitivity in (NZB x NZW) F1 mice

Oestrogen (E2) has been suggested to be responsible for the female preponderance for systemic lupus erythematosus (SLE) and for exacerbations of disease during pregnancy. In lupus-prone (NZB x NZW) F1 (NZB/W) mice, sex hormones also influence disease progression, thus long-term treatment of NZB/W mice with high doses of oestradiol increases the mortality in immune-complex mediated disease. We have previously demonstrated that E2 suppression of delayed-type hypersensitivity (DTH) to oxazolone (OXA) in NZB/W mice is inherited from the healthy NZW (H-2z) and not from the autoimmune NZB (H-2d) parental strain. In this paper we have analysed the influence of E2 on DTH and antibody responses to OXA in backcrosses of NZB/W mice and the NZB and NZW parental strains. Suppressed DTH was found in 15/16 (94%) of female (NZB/W x NZW) F1 (NZB/W/W) mice treated with E2. In contrast, only 32/36 (51%) of (NZB/W x NZB)F1 (NZB/W/B) mice treated with E2 displayed suppressed DTH reactivity. These two findings are compatible with a single, rather than multiple, dominant gene inherited from the NZW strain encoding for E2-mediated suppression of DTH in NZB/W mice. FACS analysis, using a monoclonal antibody recognizing the H-2z but not the H-2d locus, identified the H-2 expression (H-2dd and H-2dz) of the NZB/W/B backcrosses and revealed that E2 suppression of DTH is not linked to the H-2 haplotype of the backcrosses. Furthermore, E2 treatment of NZB/W/W mice, but not of NZB/W/B mice, significantly enhanced the serum levels of anti-OXA antibodies of both IgG and IgM classes. Based on our results it is tempting to speculate whether similar genetic factors for E2 sensitivity of the immune system may be of importance for the female predominance of human SLE.