The product of rat gene 33 was identified as an ErbB-2-interacting protein in a two-hybrid screen employing the ErbB-2 juxtamembrane and kinase domains as bait. This interaction was reproduced in vitro with a glutathione S-transferase fusion protein spanning positions 282 to 395 of the 459-residue gene 33 protein.Activation of ErbB-2 catalytic function was required for ErbB-2-gene 33 physical interaction in living cells, whereas ErbB-2 autophosphorylation was dispensable. Expression of gene 33 protein was absent in growtharrested NIH 3T3 fibroblasts but was induced within 60 to 90 min of serum stimulation or activation of the ErbB-2 kinase and decreased sharply upon entry into S phase. New differentiation factor stimulation of mitogen-deprived mammary epithelial cells also caused accumulation of gene 33 protein, which could be found in a complex with ErbB-2. Overexpression of gene 33 protein in mouse fibroblasts inhibited (i) cell proliferation driven by ErbB-2 but not by serum, (ii) cell transformation induced by ErbB-2 but not by Ras or Src, and (iii) sustained activation of ERK 1 and 2 by ErbB-2 but not by serum. The gene 33 protein may convey inhibitory signals downstream to ErbB-2 by virtue of its association with SH3-containing proteins, including GRB-2, which was found to associate with gene 33 protein in living cells. These data indicate that the gene 33 protein is a feedback inhibitor of ErbB-2 mitogenic function and a suppressor of ErbB-2 oncogenic activity. We propose that the gene 33 protein be renamed with the acronym RALT (receptor-associated late transducer).Protein-protein interactions play a crucial role in the regulation of signal transduction pathways activated by receptor tyrosine kinases (RTKs) (58). SH2 (Src homology 2) and PTB (phosphotyrosine [PTyr] binding) domains recognize PTyr residues in the context of specific peptide sequences and can therefore bind to autophosphorylated receptors or to tyrosinephosphorylated RTK substrates (58,74). Modules based on PTyr-independent molecular recognition such as EH, PDZ, SH3, and WW domains (58,74) are also involved in signaling downstream to activated RTKs. In general, protein-protein interaction modules are found both in polypeptides possessing intrinsic catalytic properties and in adapter-scaffold proteins. In the former case protein-protein interactions may modulate the function of a given enzyme by simply regulating its subcellular distribution or by allosteric activation (58). Adapter-scaffold proteins, on the other hand, are essentially made up of protein-protein interaction domains that allow for the assembly of multiprotein complexes in which the functions of different enzymes are integrated both spatially and temporally (57).Upon ligand activation, RTKs target not only positive effectors but also enzymes involved in negative regulation of receptor signaling, such as tyrosine phosphatases (39), the Ras GTPase-activating protein (15), and c-Cbl (8,37,44). Adapter proteins such as Slap (67) and the SOCS gene family products (55) are also im...
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