Rho and Rac family members participate in coordinated cellular responses to extracellular stimuli (11,28). Their action is important in promoting the formation of cytoskeletal structures, the activation of serine/threonine kinase cascades, and the induction of gene expression (11,28). Rho proteins are regulated by the binding of guanosine nucleotides (1). In quiescent cells, these GTPases are bound to GDP molecules and are in an inactive state. Stimulation of cells via a number of extracellular stimuli leads to the exchange of GDP by GTP, a transition that allows the acquisition of a conformation optimal for the binding to their effector molecules (1). Because the intrinsic GDP-GTP exchange rate of these GTPases is low under physiological conditions, the activation of these proteins during signal transduction requires the participation of enzymes generically known as guanosine nucleotide exchange factors (GEFs) (1). To date, two families of Rho GEFs have been identified. The first group is composed of Rho GDP dissociation stimulators, a family of proteins distantly related to the Cdc25 homology regions present in Ras GEFs (1). The second group comprises an extensive number of enzymes containing Dbl homology (DH) domains with catalytic activity exclusively directed towards Rho and Rac GTPases (4).Although Rho GEFs have been extensively characterized biochemically and oncogenically, little information is available regarding the mechanism by which they become activated during signal transduction. To date, the best example for the participation of a DH-containing protein in receptor-mediated cell signaling is perhaps the product of the vav proto-oncogene, a protein preferentially expressed in the hematopoietic system (2). In addition to the DH and Pleckstrin homology (PH) regions commonly found in Rho and Rac GEFs, Vav contains other structural motifs, including a calponin homology (CH) region, an acidic (Ac) motif, a zinc finger (ZF) domain, two SH3 regions, and one SH2 domain (2). Vav becomes tyrosinephosphorylated during the signaling of many membrane receptors, and binds to a number of cytoplasmic molecules via its SH2 and SH3 domains (2). Recently, biochemical experiments have demonstrated that the phosphorylation of Vav on tyrosine residues leads to the activation of its GDP/GTP exchange activity towards Rac-1 in vitro (7). In agreement with such observations, it has been shown that several elements of the Rac-1 pathway, including Rac-1 itself and JNK, are activated in vivo by wild type Vav protein upon tyrosine phosphorylation (7,26). Deletion of vav via gene targeting leads to decreased proliferation of prothymocytes (31), to defective positive and negative selection of immature T cells (15,27) and to ineffective functional responses of mature T and B cells (25, 31). In T lymphocytes, this phenotype is linked to abnormal actin clustering upon receptor engagement (10,14). Vav appears to provide therefore a direct connection between membrane receptors and Rac-1, a pathway that is essential for the generation ...
