Abstract
The pre-T cell receptor (TCR), which consists of a TCR-beta chain paired with pre-TCR-alpha (pTalpha) and associated with CD3/zeta components, is a critical regulator of T cell development. For unknown reasons, extremely low pre-TCR levels reach the plasma membrane of pre-T cells. By transfecting chimeric TCR-alpha-pTalpha proteins into pre-T and mature T cell lines, we show here that the low surface expression of the human pre-TCR is pTalpha chain dependent. Particularly, the cytoplasmic domain of pTalpha is sufficient to reduce surface expression of a conventional TCR-alpha/beta to pre-TCR expression levels. Such reduced expression cannot be attributed to qualitative differences in the biochemical composition of the CD3/zeta modules associated with pre-TCR and TCR surface complexes. Rather, evidence is provided that the pTalpha cytoplasmic tail also causes a reduced surface expression of individual membrane molecules such as CD25 and CD4, which are shown to be retained in the endoplasmic reticulum (ER). Native pTalpha is also observed to be predominantly ER localized. Finally, sequential truncations along the pTalpha cytoplasmic domain revealed that removal of the COOH-terminal 48 residues is sufficient to release a CD4-pTalpha chimera from ER retention, and to restore native CD4 surface expression levels. As such a truncation in pTalpha also correlates with enhanced pre-TCR expression, the observed pTalpha ER retention function may contribute to the regulation of surface pre-TCR expression on pre-T cells.
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