SummaryReeent studies have demonstrated that the CD3-~ subunlt of the T eell antigen reeeptor (TCR) eomplex Is involved In signal transduetlon. However, the funetlon of the remalnlng Invariant subunits, CD3-y, -ö, and e, Is still poorly understood. To examine thelr role In TCR funetlon, we have eonstrueted TCR/CD3 eomplexes devold of tunetlonal ~ subunlt and showed that they are still able to trigger the produellon of Interleukln-2 in response to antigen or superantigen. These data, together with previous results, Indleate that the TCR/ CD3 eomplex Is eomposed of at least two parallel Iransduelng unlts, made 01 the YÖE and ~ ehalns, respeetlvely, Furthermore, the analysis 01 partially truneated ~ ehains has led us to Indlvlduallze a lunetlonal domaln that may have eonstltuted the buildlng block of most of the transduelng subunlts assoelated wlth antigen reeeptors and some Fe receptors. IntroduetionThe T cell antigen receptor (TCR) is a multisubunit complex composed of the products of at least six distinct genes. The TCR a and TCR ß subunits exist as disulfidelinked heterodimers, possess short cytoplasmic tails, and contain clonally variable regions that determine the antigenic specificity of the complex. The remaining subunits, termed CD3-y, -ö, -E, -~, and -1], are invariant, noncovalently associated with the TCR aß dimer, and possess large intracytoplasmic domains thought to be responsible for coupling antigen recognition to various signal transductlon pathways. The evolutionarily related y, Ö, and e subunits are expressed as noncovalently associated ye and OE pairs (Koning et al., 1990;Blumberg et al. , 1990; De la Herra et al. , 1991), and display immunoglobulin-like extracellular domains (Gold et al., 1987). In contrast, the ~ and 1] subunlts contaln an extracellular domain of only 9 residues and constitute the prototype of a new protein family that includes the y chain of the high affinity IgE receptor (FceRI)
Epithelial cells have separate apical and basolateral plasma membrane domains with distinct compositions. After delivery to one surface, proteins can be endocytosed and then recycled, degraded or transcytosed to the opposite surface. Proper sorting into the transcytotic pathway is essential for maintaining polarity, as most proteins are endocytosed many times during their lifespan. The polymeric immunoglobulin receptor (pIgR) transcytoses polymeric IgA (pIgA) from the basolateral to the apical surface of epithelial cells and hepatocytes. However, the molecular machinery that controls polarized sorting of pIgR-pIgA and other receptors is only partially understood. The retromer is a multimeric protein complex, originally described in yeast, which mediates intracellular sorting of Vps10p, a receptor that transports vacuolar enzymes. The yeast retromer contains two sub-complexes. One includes the Vps5p and Vps17p subunits, which provide mechanical force for vesicle budding. The other is the Vps35p-Vps29p-Vps26p subcomplex, which provides cargo specificity. The mammalian retromer binds to the mannose 6-phosphate receptor, which sorts lysosomal enzymes from the trans-Golgi network to the lysosomal pathway. Here, we show a function for the mammalian Vps35-Vps29-Vps26 retromer subcomplex in promoting pIgR-pIgA transcytosis.
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