Magdalena Chrzanowska-Wodnicka

Oncogenic ras activation of Raf/mitogen-activated protein kinase-independent pathways is sufficient to cause tumorigenic transformation

Substantial evidence supports a critical role for the activation of the Raf-1/MEK/mitogen-activated protein kinase pathway in oncogenic Ras-mediated transformation. For example, dominant negative mutants of Raf-1, MEK, and mitogen-activated protein kinase all inhibit Ras transformation. Furthermore, the observation that plasma membrane-localized Raf-1 exhibits the same transforming potency as oncogenic Ras suggests that Raf-1 activation alone is sufficient to mediate full Ras transforming activity. However, the recent identification of other candidate Ras effectors (e.g., RalGDS and phosphatidylinositol-3 kinase) suggests that activation of other downstream effector-mediated signaling pathways may also mediate Ras transforming activity. In support of this, two H-Ras effector domain mutants, H-Ras(12V, 37G) and H-Ras(12V, 40C), which are defective for Raf binding and activation, induced potent tumorigenic transformation of some strains of NIH 3T3 fibroblasts. These Raf-binding defective mutants of H-Ras induced a transformed morphology that was indistinguishable from that induced by activated members of Rho family proteins. Furthermore, the transforming activities of both of these mutants were synergistically enhanced by activated Raf-1 and inhibited by the dominant negative RhoA(19N) mutant, indicating that Ras may cause transformation that occurs via coordinate activation of Raf-dependent and -independent pathways that involves Rho family proteins. Finally, cotransfection of H-Ras(12V, 37G) and H-Ras(12V, 40C) resulted in synergistic cooperation of their focus-forming activities, indicating that Ras activates at least two Raf-independent, Ras effector-mediated signaling events.

Focal adhesion assembly

The GTP-binding protein Rho regulates the assembly of focal adhesions and their associated bundles of actin filaments. Two different lines of research have converged to reveal how Rho might regulate assembly of these structures. One approach has been the identification of downstream effectors of Rho, whereas the other has been the exploration of the role of contractility in promoting assembly. It is now apparent that Rho is a key regulator of actomyosin-based contractility in nonmuscle cells and that contractility, combined with adhesion to a rigid substrate, leads to the formation of both stress fibres and focal adhesions.

Microtubule Depolymerization Induces Stress Fibers, Focal Adhesions, and DNA Synthesis via the GTP-Binding Protein Rho

Microtubule depolymerization has multiple consequences that include actin stress fiber and focal adhesion assembly, increased tyrosine phosphorylation and DNA synthesis. Similar effects induced by serum, or agents such as lysophosphatidic acid, have previously been shown to be mediated by the GTP-binding protein Rho. We have investigated whether the effects of microtubule depolymerization are similarly mediated by Rho and show that they are blocked by the specific Rho inhibitor, C3 transferase. Because microtubule depolymerization induces these effects in quiescent cells, in which Rho is largely inactive, we conclude that microtubule depolymerization leads to activation of Rho. The activation of Rho in response to microtubule depolymerization and the consequent stimulation of contractility suggest a mechanism by which microtubules may regulate microfilament function in various motile phenomena. These range from growth cone extension to the development of the contractile ring during cytokinesis, in which there are interactions between the microtubule and microfilament systems.

Dbl and Vav mediate transformation via mitogen-activated protein kinase pathways that are distinct from those activated by oncogenic Ras.

Vav and Dbl are members of a novel class of oncogene proteins that share significant sequence identity in a approximately 250-amino-acid domain, designated the Dbl homology domain. Although Dbl functions as a guanine nucleotide exchange factor (GEF) and activator of Rho family proteins, recent evidence has demonstrated that Vav functions as a GEF for Ras proteins. Thus, transformation by Vav and Dbl may be a consequence of constitutive activation of Ras and Rho proteins, respectively. To address this possibility, we have compared the transforming activities of Vav and Dbl with that of the Ras GEF, GRF/CDC25. As expected, GRF-transformed cells exhibited the same reduction in actin stress fibers and focal adhesions as Ras-transformed cells. In contrast, Vav- and Dbl-transformed cells showed the same well-developed stress fibers and focal adhesions observed in normal or RhoA(63L)-transformed NIH 3T3 cells. Furthermore, neither Vav- or Dbl-transformed cells exhibited the elevated levels of Ras-GTP (60%) observed with GRF-transformed cells. Finally, GRF, but not Vav or Dbl, induced transcriptional activation from Ras-responsive DNA elements (ets/AP-1, fos promoter, and kappa B). However, like Ras- and GRF-transformed cells, both Vav- and Dbl-transformed cells exhibited constitutively activated mitogen-activated protein kinases (MAPKs) (primarily p42MAPK/ERK2). Since kinase-deficient forms of p42MAPK/ERK2 and p44MAPK/ERK1 inhibited Dbl transformation, MAPK activation may be an important component of its transforming activity. Taken together, our observations indicate that Vav and Dbl transformation is not a consequence of Ras activation and instead may involve the constitutive activation of MAPKs.

Mas Oncogene Signaling and Transformation Require the Small GTP-Binding Protein Rac

ABSTRACT The Mas oncogene encodes a novel G-protein-coupled receptor that was identified originally as a transforming protein when overexpressed in NIH 3T3 cells. The mechanism and signaling pathways that mediate Mas transformation have not been determined. We observed that the foci of transformed NIH 3T3 cells caused by Mas were similar to those caused by activated Rho and Rac proteins. Therefore, we determined if Mas signaling and transformation are mediated through activation of a specific Rho family protein. First, we observed that, like activated Rac1, Mas cooperated with activated Raf and caused synergistic transformation of NIH 3T3 cells. Second, both Mas- and Rac1-transformed NIH 3T3 cells retained actin stress fibers and showed enhanced membrane ruffling. Third, like Rac, Mas induced lamellipodium formation in porcine aortic endothelial cells. Fourth, Mas and Rac1 strongly activated the JNK and p38, but not ERK, mitogen-activated protein kinases. Fifth, Mas and Rac1 stimulated transcription from common DNA promoter elements: NF-κB, serum response factor (SRF), Jun/ATF-2, and the cyclin D1 promoter. Finally, Mas transformation and some of Mas signaling (SRF and cyclin D1 but not NF-κB activation) were blocked by dominant negative Rac1. Taken together, these observations suggest that Mas transformation is mediated in part by activation of Rac-dependent signaling pathways. Thus, Rho family proteins are common mediators of transformation by a diverse variety of oncogene proteins that include Ras, Dbl family, and G-protein-coupled oncogene proteins.

G2A is an oncogenic G protein-coupled receptor

G2A is a heptahelical cell surface protein that has recently been described as a potential tumor suppressor, based on its ability to counteract transformation of pre-B cells and fibroblasts by Bcr-Abl, an oncogenic tyrosine kinase. We have isolated cDNAs encoding G2A in the course of screening libraries for clones that cause oncogenic transformation of NIH3T3 fibroblasts. When expressed at high levels in NIH3T3 cells by retroviral transduction, G2A induced a full range of phenotypes characteristic of oncogenic transformation, including loss of contact inhibition, anchorage-independent survival and proliferation, reduced dependence on serum, and tumorigenicity in mice. When expressed by transfection, G2A greatly enhanced the ability of a weakly oncogenic form of Raf-1 to transform NIH3T3 cells. These results demonstrate that G2A is potently oncogenic both on its own and in cooperation with another oncogene. Expression of G2A in fibroblasts and endothelial cells resulted in changes in cell morphology and cytoskeleton structure that were equivalent to those induced by the G protein subunit Gα13. Transformation of NIH3T3 cells via G2A expression was completely suppressed by co-expression of LscRGS, a GTPase activating protein that suppresses signaling by Gα12 and Gα13. Hyperactivity of Gα12 or Gα13 has previously been shown to result in activation of Rho GTPases. G2A expression resulted in activation of Rho, and transformation via G2A was suppressed by a dominant negative form of RhoA. These results indicate that G2A may be directly coupled to Gα13, and that it is the activation of this Rho-activating Gα protein which is responsible for the ability of G2A to transform fibroblasts.