Self recognition in allogeneic radiation bone marrow chimeras. A radiation- resistant host element dictates the self specificity and immune response gene phenotype of T-helper cells

doi:10.1084/jem.153.5.1286

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Self recognition in allogeneic radiation bone marrow chimeras. A radiation- resistant host element dictates the self specificity and immune response gene phenotype of T-helper cells

A Singer, KS Hathcock, and RJ Hodes

The specificity of the self-recognition repertoire in fully allogeneic (A {arrow} B), semiallogeneic (A {arrow} A x B and A x B {arrow} A), and double donor (A + B {arrow} A) radiation bone marrow chimeras was assessed by the ability of their spleen cells to generate in vitro primary plaque-forming cell (PFC) responses to trinitrophenyl- keyhole limpet hemocyanin. In contrast to spleen cells from semiallogeneic and double donor chimeras, intact spleen cells from fully allogeneic BI0 {arrow} B10.A and B10.A {arrow} B10 chimeras were not capable of generating responses to trinitrophenyl (TNP)-keyhole limpet hemocyanin. However, cultures containing a mixture of both B10 {arrow} B10.A and B10.A {arrow} B10 spleen cells did respond, demonstrating that all the cell populations required for the in vitro generation of T-dependent PFC responses were able to differentiate into functional competence in a fully allogeneic major histocompatibility complex (MHC) environment. The self recognition repertoire of T-helper cells from fully allogeneic A {arrow} B chimeras was determined to be specific for the recognition of host, not donor, MHC determinants in that they were able to collaborate with cells expressing only host MHC determinants but not with cells expressing only donor MHC determinants, even though the functional lymphocytes in these chimeras were shown to be of donor origin. Experiments utilizing double donor A + B {arrow} A chimeras further demonstrated that the ability of chimeric T cells to recognize allogeneic MHC determinants as self structures was a function of a radiation-resistant host element and not simply a consequence of the tolerization of T cell precursors to allogeneic MHC determinants, because strain A lymphocytes isolated from A + B {arrow} A chimeras were tolerant to both A and B MHC determinants but were restricted to the self recognition of syngeneic host type A MHC determinants.

Finally, the Ir gene phenotype expressed by B10 {arrow} B10.A and B10.A {arrow} B10 chimeric lymphocytes was determined by their ability to function in the Ir gene controlled response to TNP-poly-L-(Tyr,Glu)-poly-D,L-Ala-poly- L-Lys [(T,G)-A--L]. The ability of lymphocytes to function in TNP-(T,G)-A--L responses was not determined by their genotype but rather paralleled the specificity of their self recognition repertoire for high responder (H-2 (b)) determinants. The possible degeneracy of the MHC-specific self recognition repertoire is discussed, and a model is proposed for Ir gene regulation in which expression of Ir gene function by lymphocytes is an antigen-nonspecific consequence of the specificity and cross-reactivity of their self recognition repertoire.
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