Michael P. Crowley scite author profile

In contrast with the study of alpha beta T cells, that of gamma delta 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 alpha beta T cells. During the past few years, many studies, especially with mice lacking either alpha beta or gamma delta T cells, have demonstrated that gamma delta T cells can contribute to immune competence, but they do so in a way that is distinct from alpha beta T cells. It is also evident that gamma delta T cells may not recognize antigen the same way as do alpha beta 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 gamma delta 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 gamma delta T cells in a T cell receptor (TCR)-dependent manner. This indicates that gamma delta T cells can respond to ligands that are different from those of alpha beta 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 gamma delta and alpha beta T cells recognize antigens differently and suggests that gamma delta T cells may be more like immunoglobulins in their recognition properties. gamma delta T cells share many cell surface proteins with alpha beta 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 gamma delta 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 gamma delta T cells greater flexibility than the more classical type of alpha beta T cell-mediated cellular immunity.

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A Population of Murine γδ T Cells That Recognize an Inducible MHC Class Ib Molecule

Crowley

Fahrer²,

Baumgarth

et al. 2000

Science

173

134

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Although gammadelta T cells are implicated in regulating immune responses, gammadelta T cell-ligand pairs that could mediate such regulatory functions have not been identified. Here, the expression of the major histocompatibility complex (MHC) class Ib T22 and the closely related T10 molecules is shown to be activation-induced, and they confer specificity to about 0.4% of the gammadelta T cells in normal mice. Thus, the increased expression of T22 and/or T10 might trigger immunoregulatory gammadelta T cells during immune responses. Furthermore, the fast on-rates and slow off-rates that characterize this receptor/ligand interaction would compensate for the low ligand stability and suggest a high threshold for gammadelta T cell activation.

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The Recognition of the Nonclassical Major Histocompatibility Complex (MHC) Class I Molecule, T10, by the γδ T Cell, G8

Crowley

Reich

Mavaddat

et al. 1997

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Recent studies have shown that many nonclassical major histocompatibility complex (MHC) (class Ib) molecules have distinct antigen-binding capabilities, including the binding of nonpeptide moieties and the binding of peptides that are different from those bound to classical MHC molecules. Here, we show that one of the H-2T region–encoded molecules, T10, when produced in Escherichia coli, can be folded in vitro with β2-microglobulin (β2m) to form a stable heterodimer in the absence of peptide or nonpeptide moieties. This heterodimer can be recognized by specific antibodies and is stimulatory to the γδ T cell clone, G8. Circular dichroism analysis indicates that T10/β2m has structural features distinct from those of classical MHC class I molecules. These results suggest a new way for MHC-like molecules to adopt a peptide-free structure and to function in the immune system.

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Combined pseudo-merohedral twinning, non-crystallographic symmetry and pseudo-translation in a monoclinic crystal form of the γδ T-cell ligand T10

Rudolph

Wingren

Crowley

et al. 2004

Acta Crystallogr D Biol Cryst

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T10 is a non-classical class Ib-like major histocompatibility complex (MHC) cell-surface antigen which binds directly to certain gammadelta T-cell receptors in the absence of any exogenous and endogenous ligands, such as peculiar lipids or glycolipids. The crystal structure at 2.5 A resolution of murine T10 was determined by molecular replacement using data from an almost perfectly twinned monoclinic crystal. The space group is P2(1), with unit-cell parameters a = 78.2, b = 70.0, c = 139.2 A, beta = 106.8 degrees. Self-rotation function analysis and various intensity statistics revealed the presence of pseudo-merohedral twinning, but these tests underestimated the true twin fraction of alpha approximately 0.46. Native Patterson analyses pointed to the presence of pseudo-translation among the four molecules present in the asymmetric unit. Data analysis, structure determination and model refinement are discussed.

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