Impact of early expression of TCR alpha chain on thymocyte development

CD4(-)CD8(-) thymocytes expressing a transgenic T cell receptor (TCR) alpha chain have decreased capacity to give rise to CD4(+)CD8(+) thymocytes when compared with wild-type thymocytes. This inefficient CD4(-)CD8(-) to CD4(+)CD8(+) maturation is mediated by the transgenic TCR alpha chain pairing with endogenous TCR beta chain but not with endogenous TCR gamma chain. Comparison between TCR alpha chain-transgenic mice with or without a functional pre-TCR alpha (pT alpha ) chain reveals that the formation of transgenic alpha/endogenous beta TCR on CD4(-)CD8(-) thymocytes inhibits the formation of pre-TCR, but at the same time mediates CD4(-)CD8(-) to CD4(+)CD8(+) maturation in the absence of pre-TCR, albeit inefficiently. These results indicate that alpha beta TCR and pre-TCR provide different signals for thymocyte development. They also suggest that the precise regulation of the sequential rearrangements of TCR beta and alpha loci and the cellular expansion induced by the pre-TCR may both be evolved to ensure the efficient generation of mature alpha beta T cells.     

Identification of a novel pre-TCR isoform in which the accessibility of the TCR beta subunit is determined by occupancy of the 'missing' V domain of pre-T alpha

We have identified a novel pre-TCR isoform that is structurally distinct from conventional pre-TCR complexes and whose TCR beta chains are inaccessible to anti-TCR beta antibodies. We term this pre-TCR isoform the MB (masked beta)-pre-TCR. Pre-T alpha (pT alpha) subunits of MB-pre-TCR complexes have a larger apparent mol. wt due to extensive modification with O:-linked carbohydrates; however, preventing addition of O-glycans does not restore antibody recognition of the TCR beta subunits of MB-pre-TCR complexes. Importantly, accessibility of TCR beta chains in MB-pre-TCR complexes is restored by filling in the 'missing' variable (V) domain of pT alpha with a V domain from TCR alpha. Moreover, the proportion of pre-TCR complexes in which the TCR beta subunits are accessible to anti-TCR beta antibody varies with the cellular context, suggesting that TCR beta accessibility is controlled by a trans-acting factor. The way in which this factor might control TCR beta accessibility as well as the physiologic relevance of TCR beta masking for pre-TCR function are discussed.     

Distinct signals mediate maturation and allelic exclusion in lymphocyte progenitors.

Successful in-frame rearrangement of immunoglobulin heavy chain genes or T cell antigen receptor (TCR) beta chain genes in lymphocyte progenitors results in formation of pre-BCR and pre-TCR complexes. These complexes signal progenitor cells to mature, expand in cell number, and suppress further rearrangements at the immunoglobulin heavy chain or TCRbeta chain loci, thereby ensuring allelic exclusion. We used transgenic expression of a constitutively active form of c-Raf-1 (Raf-CAAX) to demonstrate that activation of the Map kinase pathway can stimulate both maturation and expansion of B and T lymphocytes, even in the absence of pre-TCR or pre-BCR formation. However, the same Raf signal did not mediate allelic exclusion. We conclude that maturation of lymphocyte progenitors and allelic exclusion require distinct signals.     

The connecting peptide domain of pT alpha dictates weak association of the pre-T cell receptor with the TCR zeta subunit.

Signals delivered through the pre-TCR, a heterodimer of pT alpha and TCR beta chains, are crucial for the maturation and proliferation of immature alphabeta lineage thymocytes from the CD4- CD8- to the CD4+ CD8+ stage. To gain insight into the structural and functional properties of the pre-TCR, chimeric TCR alpha chains were generated by replacing domains of the alpha chain cytoplasmic, transmembrane and constant regions with homologous domains from the pT alpha chain. All chimeric TCR could be expressed stably at the cell surface and induce Ca2+ mobilization as well as phosphorylation of several protein substrates on tyrosine residues. However, chimeras wherein the connecting peptide of TCR alpha chain was substituted by the one from pT alpha, were weakly associated with the TCR zeta chain, showing that functional but not physical interactions were preserved in such chimeras. In contrast, introduction of the connecting peptide of TCR alpha in the pT alpha chain was insufficient to confer stable association with the TCR zeta chain. These results demonstrate that the inability of the pre-TCR to interact strongly with TCR zeta is attributable to amino acid residues present throughout the region comprised between the intrachain Cys and the transmembrane domain. It remains to be determined whether the weak physical interaction between the pre-TCR alphand the zeta2 homodimer prevents the activation of specific TCR zeta-dependent signaling pathways, and thus confers unique signaling properties upon the pre-TCR. In addition, this structural difference between the pT alpha/beta and alphabeta TCR might constitute a means to regulate the expression of these receptors at the surface of thymocytes, at different stages of their maturation.     

Unique CD4(+) T cells in TCR alpha chain-deficient class I MHC-restricted TCR transgenic mice: role in a superantigen-mediated disease process.

Mice carrying a transgenic TCR with targeted disruption of the TCR alpha chain (H-Y alpha(-/-)) possess CD4(+) T cells which express the transgenic TCR beta without the alpha chain. These mice developed the murine acquired immunodeficiency syndrome (MAIDS) after infection with LP-BM5 retroviruses, a process which requires CD4(+) T cells. These cells are negative for TCR delta chain and pre-TCR alpha chain expression, and thus express a unique surface receptor with the TCR beta chain as a component. The cells respond to MAIDS virus-associated superantigen and concanavalin A, but not to protein antigens such as ovalbumin. Thus, this novel surface receptor appears to play an important role in the pathogenesis of MAIDS.     

Absolute requirement for the pre-T cell receptor alpha chain during NK1.1+ TCRalphabeta cell development.

Most natural killer T (NKT) cells express a highly skewed alphabeta TCR repertoire, consisting of an invariant V alpha14-J alpha281 chain paired preferentially with a polyclonal Vbeta8.2 chain. This repertoire is positively selected by the monomorphic CD1d molecule expressed on cells of hematopoietic origin. The origin of NKT cells and their lineage relationship to conventional T cells is controversial. We show here that the development of NKT cells is absolutely dependent on expression of the pre-TCRalpha chain, in marked contrast to conventional T cells which arise in significant numbers even in the absence of a functional pre-TCR. Distinct developmental requirements for pre-TCR expression in the NKT and T cell lineages may reflect differences in the ability of the TCRalphabeta to substitute functionally for the pre-TCR in immature precursor cells.