Qa alloantigen expression on functional T lymphocytes from spleen and thymus

CD4-positive/heat-stable antigen-positive thymocytes cause graft-versus-host disease across non-major histocompatibility complex incompatibilities

Single-positive thymocytes are the immediate precursors of peripheral recent thymic emigrants (RTE) which develop into mature peripheral T cells. The functional ability of RTE is unclear but their state of differentiation may be relevant to the development of tolerance to peripheral "self" antigens. Since RTE are difficult to analyze, precursor CD4+/8- thymocytes were assessed in a model in vivo to determine their functional capability and their susceptibility to tolerance induction. The ability of both heat-stable antigen-positive (HSA+) (immature) and HSA- (mature) single-positive thymocytes to cause graft-versus-host disease (GVHD) across non-major histocompatibility complex differences were examined. Both HSA- and HSA+ CD4+/8- thymocytes from C3H mice caused lethal GVHD in AKR recipients as did CD4+ peripheral T cells in controls. Further, neonatal C3H thymocytes also caused lethal GVHD in AKR recipients. Since CD4+/8- thymocytes are the precursors of RTE, these results suggest that RTE are not susceptible to tolerance induced to "minor" antigens and may have a normal immune function in vivo. This would suggest that peripheral tolerance may be dependent upon the manner of antigen presentation rather than T cell maturity.

Antigenic heterogeneity of Qa-2 antigens in C57BL/6

The Qa-2 antigens are class I-like molecules encoded by genes mapped telomeric to the H-2D region on chromosome 17 in the mouse. A panel of 8 new monoclonal anti-Qa-2 antibodies derived from a C3H.KBR anti-C3H. SW immunization was studied. Immunoprecipitation of 125I-labeled C57BL/6 splenocyte antigens showed that all of these antibodies precipitated 40 kDa molecules which could be completely precleared by the monoclonal antibody 20-8-4, which had previously been shown to crossreact with Qa-2. One of the monoclonal antibodies (1-12-1), however, was found not to completely preclear Qa-2 antigens precipitable by the other 7 antibodies or by 20-8-4, suggesting the existence of at least two different species of Qa-2 molecules. Cell lines transfected with Q7 or Q9 genes were reactive with all 9 antibodies and the Qa-2 antigens expressed on surface membranes of these cells were completely precleared by both 20-8-4 and 1-12-1. Therefore, the observed heterogeneity of these molecules cannot be explained by an antigenic difference between the Q7 and Q9 gene products. 2D gel analyses showed identical pI spectra between Qa-2 molecules precipitated with 20-8-4 and 1-12-1. In addition, all of the monoclonal antibodies reacted with labeled antigen preparations following treatment with Endo F or neuraminidase, indicating that carbohydrate moieties are probably not responsible for the antigenic difference between the two species of Qa-2 antigen.

Physical and molecular genetic analysis of Qa-2 antigen expression: multiple factors controlling cell surface levels

We have examined the surface expression of Qa-2 on lymphocyte subpopulations and on splenocytes from inbred mouse strains by a radioactive binding assay using purified anti-Qa-2 antibodies and antibody fragments (Fab). Quantitative measurements by Scatchard analysis revealed that spleen cells from Qa-2high mice express (4-5) x 10(4) Qa-2 molecules/cell, whereas T lymphocytes have as high as (7-8) x 10(4) molecules/cell. In addition, it was determined that B lymphocytes express (5-6) x 10(3) molecules on their cell surface. The Qa-2 levels on anti-CD3-activated T cells is 1.0 x 10(5) molecules/cell. Previous experiments have shown that the quantity of Qa-2 varies in a strain-specific fashion and may be classified into three groups: Qa-2high, Qa-2medium and Qa-2low. Our results indicated that Qa-2high strains express (4-5) x 10(4) Qa-2 molecules/cell, Qa-2medium strains (B6-K2, B10.A, A/J, BALB/c and DBA/2) express (1-1.7) x 10(4) molecules/cell, and Qa-2low strains (SWR/J and DBA/1) express no more than 6 x 10(3) molecules/cell. Detection of Q7 or Q9 mRNA by the polymerase chain reaction revealed that Qa-2high strains express two functional Qa-2 enconding genes, Q7 and Q9, whereas Qa-2medium and Qa-2low strains express either Q7 or Q9. These results strongly suggest that Qa-2 gene dosage contributes in part to the variation of Qa-2 levels on the cell surface.

Genetic polymorphisms of Q region genes from wild-derived mice: implications for Q region evolution

Both serological and DNA sequence analyses were performed to determine the extent of genetic polymorphism in Q region genes. A panel of Qa-2-specific monoclonal antibodies (mAbs) was tested on 35 wild-derived and inbred mouse strains. Members of this reagent panel recognize multiple and distinct epitopes on the Qa-2-bearing molecule(s). Although quantitative variations in Qa-2 levels were observed, no structural polymorphisms were detected. All strains were either entirely positive or entirely negative with the complete set of reagents. Moreover, cell surface Qa-2 expression was not significantly affected by differences in age or sex of the mouse or cell cycle status. To confirm this apparent lack of genetic polymorphism, the polymerase chain reaction (PCR) technique was used to amplify a portion of the 3' end of the Q region genes, Q4 to Q9, from several independent wild-derived strains of mice. Sequence analysis of the amplified material revealed very little evidence of nucleotide divergence. All strains tested had a Q even DNA sequence identical to that of Q6/Q8 in the B10 strain. Likewise, all tested strains had a Q odd DNA sequence identical to Q7/Q9 in the B10 strain. Two strains showed additional Q even sequences, while all strains tested possessed additional Q odd sequences. The observed lack of polymorphism suggests that the Q genes have evolved in a different manner from H-2K and H-2D. Moreover, duplications of these genes appear to have arisen prior to nucleotide sequence divergence.

Clonal deletion and clonal anergy in the thymus induced by cellular elements with different radiation sensitivities

The present study demonstrates that immune tolerance can be achieved in the thymus both by clonal deletion and by clonal inactivation, but that the two tolerant states are induced by cellular elements with different radiation sensitivities. TCR engagement of self antigens on bone marrow-derived, radiation-sensitive (presumably dendritic) cells induces clonal deletion of developing thymocytes, whereas TCR engagement of self antigens on radiation-resistant cellular elements, such as thymic epithelium, induces clonal anergy. The nondeleted, anergic thymocytes can express IL-2-Rs but are unable to proliferate in response to either specific antigen or anti-TCR antibodies, and do develop into phenotypically mature cells that emigrate out of the thymus and into the periphery.

In vivo effects of monoclonal antibodies to distinct epitopes of Qa-2 antigens

The effects of in vivo treatment with anti-Qa-2 mAbs on in vivo and in vitro parameters of T cell immunity have been examined. Two anti-Qa-2 mAbs of the same isotype and with similar avidities but directed against distinct epitopes of the same Qa-2 molecules were studied. mAb 1-1-2 was found to induce rapid T cell depletion, with maximal effect observed within 2-3 d, while administration of mAb 1-9-9 caused little or no depletion in the first few days, and reached maximal effect only by day 8. Surprisingly, administration of both antibodies resulted in a depletion pattern similar to that of the nondepleting antibody 1-9-9. Consistent with these effects on T cell depletion, treatment with 1-1-2 caused significant prolongation of survival of allogeneic skin grafts placed 1 d after antibody administration, while treatment with 1-9-9 or with the combination of both antibodies caused no prolongation. In an attempt to determine the mechanism of this phenomenon, we examined Qa-2 expression on the cell surface by flow microfluorometry after treatment with each of the two mAbs. Our data indicate that mAb 1-9-9 mediates significantly greater modulation of Qa-2 expression from the surface of peripheral T cells within 1 d than does mAb 1-1-2. Apparently, therefore, modulation occurs more rapidly than cell clearance, and the efficiency of T cell depletion and consequent immune suppression is correlated inversely with the ability of each mAb to cause modulation. The ability of 1-9-9 to cause Qa-2 modulation suggests that it may react with a determinant on this molecule of physiological relevance to the natural ligand interactions of Qa-2 antigens.

A single gene encodes soluble and membrane-bound forms of the major histocompatibility Qa-2 antigen: anchoring of the product by a phospholipid tail

The H-2, Qa, and Tla genes of the murine major histocompatibility complex are related to each other by DNA sequence homology. The H-2 genes encode ubiquitously expressed transplantation antigens that serve as recognition structures for cytotoxic T cells. The identities of the Qa and Tla products, their sites of expression, and their functions are largely unknown. We report here that the Qa region gene Q7 encodes a membrane-bound as well as a secreted form of the serologically defined antigen Qa-2. The Q7 gene introduced into liver-derived cells is expressed as a membrane-bound and as a secreted molecule. In transfected L cells it is expressed only as a soluble protein. Biochemical analysis suggests that the Q7 product is anchored to the liver cell membranes by a phospholipid tail. This feature may be responsible for cell type-specific expression of the two forms of the Qa-2 molecules.

Tissue-specific expression of the mouse Q10 H-2 class-I gene during embryogenesis

We have studied the pattern of expression of the Q10 gene, a H-2 class-I gene located in the major histocompatibility complex which encodes a soluble class-I molecule, in the mid-gestation mouse embryo, and compared it to those of two other class-I genes, namely Kd and 37, the latter gene located in the thymus leukemia region. We found that the steady-state amount of these different mRNAs gradually increased from day 13 to day 18. By comparison with the level of expression of these genes in adult liver, the increase during gestation was fairly more marked for Q10 mRNA than for the others. Furthermore, we found that the Q10 gene is transiently expressed in the endoderm layer of the visceral yolk sac and in the fetal heart. Expression in the latter tissue decreases abruptly while increasing in the liver. It has been proposed that the Q10 protein is involved in immune tolerance. However, the time course of expression of Q10 mRNA and its tissue distribution during embryogenesis suggest that the Q10 protein could play a role in the differentiation of hematopoietic stem cells.