The v-Crk oncogene enhances cell survival and induces activation of protein kinase B/Akt.

The v-Crk oncogene encodes an adaptor protein containing an SH2 domain and an SH3 domain. v-Crk-transformed fibroblast cells display enhanced tyrosine phosphorylation levels, and the v-Crk protein localizes in focal adhesions, suggesting that transformation may be due to enhanced focal complex signaling. Here we investigated the mechanism of transformation and found that v-Crk-transformed NIH 3T3 cells display growth rates and serum requirements similar to control cells. However, v-Crk enhanced survival in conditions of serum starvation. Both an intact SH2 and SH3 domain are required; moreover, SH2 mutants displayed dominant interfering properties, enhancing cell death. Using other cell death-inducing stimuli, it appeared that v-Crk in general inhibits apoptosis and enhances cell survival. In search of the signaling pathways involved, we found that v-Crk-transformed cells show constitutively higher levels of phospho-protein kinase B (PKB)/Akt and PKB/Akt activity, especially in conditions of serum starvation. These data strongly suggest involvement of the phosphatidylinositol 3-kinase/PKB survival pathway in the v-Crk-induced protection against apoptosis. In accordance, inhibition of this pathway by wortmannin or LY924002 reduced protection against starvation-induced apoptosis. In addition to the phosphatidylinositol 3-kinase/PKB pathway, a MEK-dependent pathway and an unknown additional pathway are also implicated in resistance against apoptosis. Activation of survival pathways may be the most important function of v-Crk in its oncogenic properties.

Factor VIIa/tissue factor-induced signaling via activation of Src-like kinases, phosphatidylinositol 3-kinase, and Rac.

Tissue factor (TF), apart from activating the extrinsic pathway of the blood coagulation, is a principal regulator of embryonic angiogenesis and oncogenic neoangiogenesis, but also influences inflammation, leukocyte diapedesis and tumor progression. The intracellular domain of TF lacks homology to other classes of receptors and hence the signaling mechanism is poorly understood. Here we demonstrate that factor VIIa (the natural ligand for TF) induces the activation of the Src family members c-Src, Lyn, and Yes, and subsequently phosphatidylinositol 3-kinase (PI3K), followed by stimulation of c-Akt/protein kinase B as well as the small GTPases Rac and Cdc42. In turn Rac mediates p38 mitogen-activated protein (MAP) kinase activation and cytoskeletal reorganization, whereas factor VIIa-induced p42/p44 MAP kinase stimulation required PI3K enzymatic activity but was not inhibited by dominant negative Rac proteins. We propose that this Src family member/PI3K/Rac-dependent signaling pathway is a major mediator of factor VIIa/TF effects in pathophysiology.

Invasion of T-lymphoma cells: cooperation between Rho family GTPases and lysophospholipid receptor signaling.

Rho-like GTPases orchestrate distinct cytoskeletal changes in response to receptor stimulation. Invasion of T-lymphoma cells into a fibroblast monolayer is induced by Tiam1, an activator of the Rho-like GTPase Rac, and by constitutively active V12Rac1. Here we show that activated V12Cdc42 can also induce invasion of T-lymphoma cells. Activated RhoA potentiates invasion, but fails by itself to mimic Rac and Cdc42. However, invasion is inhibited by the Rho-inactivating C3 transferase. Thus, RhoA is required but not sufficient for invasion. Invasion of T-lymphoma cells is critically dependent on the presence of serum. Serum can be replaced by the serum-borne lipids lysophosphatidic acid (LPA) and sphingosine-1-phosphate (S1P) (10(-7)-10(-6) M), which act on distinct G protein-linked receptors to activate RhoA and phospholipase C (PLC)-Ca2+ signaling. LPA- and S1P-induced invasion is preceded by Rho-dependent F-actin redistribution and pseudopodia formation. However, expression of both V14RhoA and V12Rac1 does not bypass the LPA/S1P requirement for invasion, indicating involvement of an additional signaling pathway independent of RhoA. The PLC inhibitor U-73122, but not the inactive analog U-73343, abolishes invasion. Our results indicate that T-lymphoma invasion is driven by Tiam1/Rac or Cdc42 activation, and is dependent on LPA/S1P receptor-mediated RhoA and PLC signaling pathways which lead to pseudopod formation and enhanced infiltration.

Targeting of Tiam1 to the plasma membrane requires the cooperative function of the N-terminal pleckstrin homology domain and an adjacent protein interaction domain.

The Rho-like GTPases Cdc42, Rac, and Rho play key roles in the regulation of the actin cytoskeleton and are implicated in transcriptional activation and cell transformation. We have previously identified the invasion-inducing Tiam1 gene, which encodes an activator of Rac. In fibroblasts, Tiam1 induces Rac-mediated membrane ruffling, which requires the N-terminal pleckstrin homology (PHn) domain. Here we show that this PHn domain is part of a protein interaction domain, which mediates membrane localization of Tiam1. After subcellular fractionation, up to 50% of Tiam1 is recovered in the Triton X-100-insoluble high speed pellet that contains small protein complexes. The regions in Tiam1 that are responsible for these protein interactions comprise the PHn domain, an adjacent putative coiled coil region (CC), and an additional flanking region (Ex). Deletions in each of these regions abolish membrane localization of Tiam1 and membrane ruffling, suggesting that they function cooperatively. Indeed, only polypeptides encompassing the PHn-CC-Ex region, and not the PHn-CC or the Ex region, localize at the membrane. These results indicate that the N-terminal PH domain is part of a larger functional Tiam1 domain that mediates protein complex formation and membrane localization of Tiam1.

Regulated membrane localization of Tiam1, mediated by the NH2-terminal pleckstrin homology domain, is required for Rac-dependent membrane ruffling and C-Jun NH2-terminal kinase activation.

Rho-like GTPases, including Cdc42, Rac, and Rho, regulate signaling pathways that control actin cytoskeletal structures and transcriptional activation. The Tiam1 gene encodes an activator of Rac1, and similarly to constitutively activated (V12)Rac1, overexpression of Tiam1 in fibroblasts induces the formation of membrane ruffles. Tiam1 contains a Dbl homology (DH) domain and adjacent pleckstrin homology (PH) domain, hallmarks for activators of Rho-like GTPases. Unique for Tiam1 are an additional PH domain and a Discs-large homology region in the NH2-terminal part of the protein. Here we show that both in fibroblasts and COS cells, membrane localization of Tiam1 is required for the induction of membrane ruffling. A detailed mutational analysis, in combination with confocal laser scanning microscopy and immunoelectron microscopy, demonstrates that the NH2-terminal PH domain of Tiam1, but not the DH-adjacent PH domain, is essential for membrane association. This NH2-terminal PH domain of Tiam1 can be functionally replaced by the myristoylated membrane localization domain of c-Src, indicating that the primary function of this PH domain is to localize the protein at the membrane. After serum starvation, both membrane association of Tiam1 and ruffling can be induced by serum, suggesting that receptor stimulation induces membrane translocation of Tiam1. Similar to V12Rac1, Tiam1 stimulates the activity of the c-Jun NH2-terminal kinase (JNK). This Rac-dependent stimulation of JNK also requires membrane association of Tiam1. We conclude that the regulated membrane localization of Tiam1 through its NH2-terminal PH domain determines the activation of distinct Rac-mediated signaling pathways.

A role for Rac in Tiam1-induced membrane ruffling and invasion.

Rho-like GTPases have been implicated in the regulation of the actin cytoskeleton which controls the morphology, adhesion and motility of cells. Like Ras proteins, they become activated when bound GDP is exchanged for GTP, a process catalysed by GDP-dissociation stimulator (GDS) proteins. Several GDS proteins specific for Rho-like GTPases have been identified. Most of these contain a conserved catalytic domain, the DBL-homology (DH) domain, and activate Cdc42 or Rho but not Rac. We have isolated the invasion-inducing Tiam1 gene, which also encodes a protein with a DH domain. Here we show that Tiam1 is a GDS protein for Rho-like GTPases in vitro. In fibroblasts, Tiam1 induces a similar phenotype as constitutively activated (V12)Rac1, including membrane ruffling, and this is inhibited by dominant negative (N17)Rac1. Moreover, T-lymphoma cells expressing V12Rac1 become invasive, indicating that the Tiam1-Rac signalling pathway could be operating in the invasion and metastasis of tumour cells.

Sequence of the human invasion-inducing TIAM1 gene, its conservation in evolution and its expression in tumor cell lines of different tissue origin.

By means of proviral tagging in combination with in vitro selection for invasive T-lymphoma variants, we have previously identified the murine invasion- and metastasis-inducing Tiam1 gene. Tiam1 encodes a novel protein which shares a Dbl-homology (DH) domain with GDP dissociation stimulator-(GDS) proteins that activate Rho-like GTPases. We have cloned the human TIAM1 coding sequence and studied its evolutionary conservation and expression pattern. TIAM1 is highly conserved among vertebrates. The close similarity between human TIAM1 and the mouse homologue is indicated by 88% and 95% identity of nucleotides and predicted sequences, respectively. The murine gene is highly expressed in brain and testis and at low or moderate levels in almost all other normal tissues. Interestingly, Tiam1 transcripts were found in virtually all analysed tumor cell lines of human and rodent origin including B- and T-lymphomas, neuroblastomas, melanomas and carcinomas. The evolutionary conservation as well as the broad expression pattern of Tiam1 in most normal tissues, suggests a general function in cellular signaling processes presumably by activation of a Rho-like GTPase that regulates the cytoskeletal organization.

Identification of an invasion-inducing gene, Tiam-1, that encodes a protein with homology to GDP-GTP exchangers for Rho-like proteins.

Using proviral tagging in combination with in vitro selection for invasiveness, we have identified a gene, designated Tiam-1, that affects invasion. In the selected invasive T lymphoma variants, proviral insertions were found within coding exons of the Tiam-1 gene, resulting in both truncated 5'-end and 3'-end transcripts that give rise to N- and C-terminal Tiam-1 protein fragments. In one invasive variant, amplification of the Tiam-1 locus was observed with concomitant increase in the amount of normal Tiam-1 protein. Cell clones that were invasive in vitro produced experimental metastases in nude mice, and transfection of truncated Tiam-1 cDNAs into noninvasive cells made these cells invasive. The predicted Tiam-1 protein harbors a Dbl- and Pleckstrin-homologous domain, which it shares with GDP-GTP exchangers for Rho-like proteins that have been implicated in cytoskeletal organization.

Efficient isolation of the linear DNA killer plasmid of Kluyveromyces lactis: evidence for location and expression in the cytoplasm and characterization of their terminally bound proteins.

Differential centrifugation of an osmotic lysate of K. lactis protoplasts showed that the linear DNA killer plasmids of K. lactis, pGKL1 and pGKL2, are almost exclusively present in the cytoplasmic fraction. This fractionation procedure allows the rapid isolation of large amounts of plasmid DNA without contamination by chromosomal and mitochondrial DNA. With these DNA preparations the size of the terminally bound proteins was estimated to be 28 and 36 kDal for pGKL1 and pGKL2, respectively. The entire pGKL1 sequence (except for 21 base pairs at the right terminus) was cloned in a shuttle vector that permits autonomous replication in the nucleus of K. lactis. However, killer gene expression could not be established in transformants. In connection with the observed cytoplasmic localization, this result suggests that gene expression of the killer DNA plasmids is entirely cytoplasmic.