ALBERT

Notes: Abstract In contrast with the study of alphabeta T cells, that of gammadelta T cells is relatively recent and stems from the discovery of their rearranged genes, rather than from any knowledge of their biological function. Thus, experiments designed to characterize their specificity and function have drawn heavily on our knowledge of alphabeta T cells. During the past few years, many studies, especially with mice lacking either alphabeta or gammadelta T cells, have demonstrated that gammadelta T cells can contribute to immune competence, but they do so in a way that is distinct from alphabeta T cells. It is also evident that gammadelta T cells may not recognize antigen the same way as do alphabeta T cells. Analysis of three protein antigens-the murine MHC class II IEk, the nonclassical MHC T10/T22, and the Herpes virus glycoprotein gI-indicates that gammadelta T cell recognition does not require antigen processing and that the proteins are recognized directly. In all three cases, recognition by these T cell clones involves neither peptides bound to these proteins nor peptides derived from them. Moreover, a group of small phosphate-containing nonpeptide compounds derived from mycobacterial extracts has been found to stimulate a major population of human peripheral gammadelta T cells in a T cell receptor (TCR)-dependent manner. This indicates that gammadelta T cells can respond to ligands that are different from those of alphabeta T cells. Analysis of complementarity determining region (CDR3) length distributions of gamma and delta chains indicates that they are more similar to those of immunoglobulins than to TCR alpha and beta. This further supports the idea that gammadelta and alphabeta T cells recognize antigens differently and suggests that gammadelta T cells may be more like immunoglobulins in their recognition properties. gammadelta T cells share many cell surface proteins with alphabeta T cells and are able to secrete lymphokines and express cytolytic activities in response to antigenic stimulation. These, together with the results cited above, indicate that gammadelta T cells can mediate cellular immune functions without a requirement for antigen processing. Thus, pathogens, damaged tissues, or even B and T cells can be recognized directly, and cellular immune responses can be initiated without a requirement for antigen degradation or specialized antigen-presenting cells. This would give gammadelta T cells greater flexibility than the more classical type of alphabeta T cell-mediated cellular immunity.