Hormone binding and localization of the c-erb-A protein suggest that it is a receptor for thyroid hormone, a nuclear protein that binds to DNA and activates transcription. In contrast, the product of the viral oncogene v-erb-A is defective in binding the hormone but is still located in the nucleus.
These observations demonstrate that RPTPalpha functions as a physiological upstream activator of Src-family kinases in fibroblasts and establish this tyrosine phosphatase as a newly identified regulator of integrin signalling.
Several recent observations, such as the identification of the cellular homologue of the v-erb-A oncogene as a thyroid-hormone receptor, have strongly implicated nuclear oncogenes in transcriptional control mechanisms. The v-erb-A oncogene blocks the differentiation of erythroid cells, and changes the growth requirements of fibroblasts and erythroblasts. Mutations in v-erb-A protein have led to the loss of its affinity for thyroid hormones but do not affect its DNA-binding ability, a property required for biological activity. We report here the identification of a novel thyroid-hormone response element (TRE) in the long terminal repeat of Moloney murine leukaemia virus that binds the c-erb-A-alpha protein. The v-erb-A protein abolishes the responsiveness of this TRE to thyroid hormone, although it has a lower affinity than the normal receptor for the TRE. The data indicate that overexpressed v-erb-A protein negatively interferes with normal transcriptional-control mechanisms, and that amino-acid substitutions have altered its DNA-binding properties.
Cell motility on ECM critically depends on the cellular response to force from the matrix. We find that force-dependent reinforcement of αv/β3-integrin–mediated cell–matrix connections requires the receptor-like tyrosine phosphatase α (RPTPα). RPTPα colocalizes with αv-integrins at the leading edge during early spreading, and coimmunoprecipitates with αv-integrins during spreading on fibronectin and vitronectin. RPTPα-dependent activation of Src family kinases, in particular activation of Fyn, is required for the force-dependent formation of focal complexes and strengthening of αv/β3-integrin–cytoskeleton connections during the initial phase of ECM contact. These observations indicate that Src family kinases have distinct functions during adhesion site assembly, and that RPTPα is an early component in force-dependent signal transduction pathways leading to the assembly of focal complexes on both fibronectin and vitronectin.
Protein-tyrosine phosphatases (PTPs) are vital for regulating tryosine phosphorylation in many processes, including growth and differentiation. The regulation of receptor-like PTP (RPTP) activity remains poorly understood, but based on the crystal structure of RPTPalpha domain 1 we have proposed that dimerization can negatively regulate activity, through the interaction of an inhibitory 'wedge' on one monomer with the catalytic cleft of domain 1 in the other monomer. Here we show that dimerization inhibits the activity of a full-length RPTP in vivo. We generated stable disulphide-bonded full-length RPTPalpha homodimers by expressing mutants with single cysteines at different positions in the ectodomain juxtamembrane region. Expression of wild-type RPTPalpha and Phe135Cys and Thr141Cys mutants in RPTPalpha-null mouse embryo cells increased dephosphorylation and activity of Tyr 529 in the protein tyrosine kinase c-Src; in contrast, expression of a Pro137Cys mutant did not. Mutation of Pro 210/211 to leucine in the inhibitory wedge of the Pro137Cys mutant restored its ability to activate c-Src, indicating that dimerization may inhibit full-length RPTPalpha activity in a manner stereochemically consistent with RPTPalpha crystal structures. Our results suggest that RPTPalpha activity can in principle be negatively regulated by dimerization in vivo.
The receptor-like protein tyrosine phosphatases (RPTP) mu and RPTP kappa have a modular ectodomain consisting of four fibronectin type III-like repeats, a single Ig-like domain, and a newly identified N-terminal MAM domain. The function of the latter module, which comprises about 160 amino acids and is found in diverse transmembrane proteins, is not known. We previously reported that both RPTP mu and RPTP kappa can mediate homophilic cell interactions when expressed in insect cells. Here we show that despite their striking structural similarity, RPTP mu and RPTP kappa fail to interact in a heterophilic manner. To examine the role of the MAM domain in homophilic binding, we expressed a mutant RPTP mu lacking the MAM domain in insect Sf9 cells. Truncated RPTP mu is properly expressed at the cell surface but fails to promote cell-cell adhesion. Homophilic cell adhesion is fully restored in a chimeric RPTP mu molecule containing the MAM domain of RPTP kappa. However, this chimeric RPTP mu does not interact with either RPTP mu or RPTP kappa. These results indicate that the MAM domain of RPTP mu and RPTP kappa is essential for homophilic cell-cell interaction and helps determine the specificity of these interactions.
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