Mutagenic analyses have identified structural motifs important for TCR-mediated signaling in the antigen-binding chains, CD3 and zeta subunits of the TCR complex. In this study, we altered selected residues in the transmembrane and extracellular constant regions of the TCR beta chain and expressed the mutants in a T hybridoma line bearing endogenous receptor. We measured cytokine production and apoptosis in response to antigen or antibody. We found that mutation of one or both of the transmembrane tyrosine residues in the TCR beta chain caused a marked reduction in responsiveness. Mutation of the transmembrane serine to alanine also reduced responses, although less markedly. Immunoprecipitation analyses showed that the TCR beta mutations did not alter association with zeta. These experiments identify a signaling role for the transmembrane domain of the TCR beta chain.
The T cell receptor (TCR) beta chain transmembrane domain contains two evolutionarily conserved tyrosines (Y). In this study, the functional basis for the evolutionary conservation is addressed by mutation of the residues, expression of the mutants in hybridoma and primary T cells, and examination of TCR signaling function. We find that the phenotype of the mutants, both surface expression and ability to signal for IL-2 production, is highly variable in different mouse T hybridoma lines. Although we have not been able to determine the basis for these differences in the hybridomas, expression of the mutants in primary T cells provides a definitive assessment of mutant phenotype. We show that mutation of the N-terminal Y to either leucine (L) or alanine (A) results in low surface expression in primary T cells, while mutation of both N- and C-terminal Y to A or L abrogates surface expression. However, the more conservative mutation of both transmembrane Y to phenylalanine maintained receptor surface expression and assembly while severely disrupting signaling in primary T cells. Our data demonstrate that TCR beta chain transmembrane Y are essential for TCR signal transduction as well as complex assembly. These findings suggest that protein-protein interactions involving membrane-spanning domains are likely relevant for TCR signal transduction mechanisms.
This laboratory module familiarizes students with flow cytometry while acquiring quantitative reasoning skills during data analysis. Leukocytes, also known as coelomocytes (including hyaline and granular amoebocytes, and chloragocytes), from Eisenia hortensis (earthworms) are isolated from the coelomic cavity and used for phagocytosis of fluorescent Escherichia coli. Students learn how to set up in vitro cellular assays and become familiar with theoretical principles of flow cytometry. Histograms based on fluorescence and scatter properties combined with gating options permit students to restrict their analyses to particular subsets of coelomocytes when measuring phagocytosis, a fundamentally important innate immune mechanism used in earthworms. Statistical analysis of data is included in laboratory reports which serve as the primary assessment instrument.
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