UMLS:C0178874 - FACTA Search

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Query: UMLS:C0178874 (tumor progression)
40,807 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

ARHI (Ras homologue member I) encodes a 26-kDa GTPase with 50-60% amino acid homology to Ras and Rap. ARHI and Ras share similar GTP/GDP binding domains, but exert opposite functions. ARHI is one of the first reported tumor suppressors in the ras superfamily. ARHI is expressed consistently in normal breast and ovarian epithelial cells, but not in breast or ovarian cancers. The loss of ARHI can be related to tumor progression. Reexpression of ARHI induces apoptosis of breast and ovarian cancer cells by a caspase-independent, calpain-dependent pathway. ARHI is consistently expressed in normal breast and ovarian epithelial cells but is dramatically downregulated in more then 70% of breast and ovarian cancers. ARHI is maternally imprinted with methylation of the three CpG islands in the maternal allele of normal cells. ARHI is expressed only from the paternal allele whose three CpG islands are not methylated. Loss of ARHI expression can occur through a genetic event, with loss of heterozygosity observed in 40% of breast, ovarian, and pancreatic cancers; but it can also occur through epigenetic mechanisms, including DNA methylation, histone deacetylation, histone methylation, and transcriptional regulation. Our data suggest that acetylation and methylation of chromatin associated with the ARHI promoter leads to loss of both ARHI expression and the ability to suppress tumor growth. Changes in chromatin that silence ARHI may be driven by methylation-dependent and -independent pathways. Reactivation of both the silenced paternal and imprinted maternal alleles can be achieved by demethylation and inhibition of histone deacetylation.
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PMID:Epigenetic regulation of ARHI in breast and ovarian cancer cells. 1272 31

The RhoGTPases constitute a large family of small GTP binding proteins that police many sensitive crossroads in diverse cellular functions. Therefore, it would not be surprising if aberrant RhoGTPase function led to perturbed growth and differentiation, including carcinogenesis and cancer progression. The evidence for a causative connection between RhoGTPases and primary human cancers is still weak but there are increasing findings to support this link. An appreciation of this connection is timely and important to alert readers to the possibilities of new disease mechanisms and new ways to diagnose and treat cancer.
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PMID:RhoGTPases and their role in cancer. 1272 21

Activating mutations of Ras have been implicated in approximately 30% of human cancers. In every case, the biochemical consequence of such mutations is to disrupt the GTPase activity of Ras and to render Ras resistant to the actions of GTPase activating proteins. Consequently, oncogenic Ras mutants are "locked" in a GTP-bound active state. We detected a potent activity in Escherichia coli extract that can efficiently convert mutationally activated GTP-bound Ras to the inactive GDP-bound form. Purification of the protein responsible for this activity led to the identification of the enzyme nucleoside diphosphate kinase (Ndk). The human orthologue of Ndk is the NM23 metastasis suppressor, which we found to exhibit a similar activity. Purified Ndk effectively inactivates several of the oncogenic forms of Ras that are seen frequently in human cancers, including RasD12, the most commonly detected Ras mutation. Significantly, Ndk does not detectably affect wild-type Ras or an activated form of the Ras-related Rho GTPase. These results demonstrate that it is possible, through biochemical means, to specifically inactivate oncogenic Ras as a potential therapeutic approach to tumors that harbor Ras mutations. Moreover, the results suggest that the loss of NM23 expression that is commonly observed during tumor progression could lead to increased potency of oncogenic Ras proteins.
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PMID:Specific biochemical inactivation of oncogenic Ras proteins by nucleoside diphosphate kinase. 1287 11

Ca2+ sensitivity of smooth muscle and nonmuscle myosin II reflects the ratio of activities of myosin light-chain kinase (MLCK) to myosin light-chain phosphatase (MLCP) and is a major, regulated determinant of numerous cellular processes. We conclude that the majority of phenotypes attributed to the monomeric G protein RhoA and mediated by its effector, Rho-kinase (ROK), reflect Ca2+ sensitization: inhibition of myosin II dephosphorylation in the presence of basal (Ca2+ dependent or independent) or increased MLCK activity. We outline the pathway from receptors through trimeric G proteins (Galphaq, Galpha12, Galpha13) to activation, by guanine nucleotide exchange factors (GEFs), from GDP. RhoA. GDI to GTP. RhoA and hence to ROK through a mechanism involving association of GEF, RhoA, and ROK in multimolecular complexes at the lipid cell membrane. Specific domains of GEFs interact with trimeric G proteins, and some GEFs are activated by Tyr kinases whose inhibition can inhibit Rho signaling. Inhibition of MLCP, directly by ROK or by phosphorylation of the phosphatase inhibitor CPI-17, increases phosphorylation of the myosin II regulatory light chain and thus the activity of smooth muscle and nonmuscle actomyosin ATPase and motility. We summarize relevant effects of p21-activated kinase, LIM-kinase, and focal adhesion kinase. Mechanisms of Ca2+ desensitization are outlined with emphasis on the antagonism between cGMP-activated kinase and the RhoA/ROK pathway. We suggest that the RhoA/ROK pathway is constitutively active in a number of organs under physiological conditions; its aberrations play major roles in several disease states, particularly impacting on Ca2+ sensitization of smooth muscle in hypertension and possibly asthma and on cancer neoangiogenesis and cancer progression. It is a potentially important therapeutic target and a subject for translational research.
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PMID:Ca2+ sensitivity of smooth muscle and nonmuscle myosin II: modulated by G proteins, kinases, and myosin phosphatase. 1450 7

Accumulating evidence suggests that p21(Cip1) located in the cytoplasm might play a role in promoting transformation and tumor progression. Here we show that oncogenic H-RasV12 contributes to the loss of actin stress fibers by inducing cytoplasmic localization of p21(Cip1), which uncouples Rho-GTP from stress fiber formation by inhibiting Rho kinase (ROCK). Concomitant with the loss of stress fibers in Ras-transformed cells, there is a decrease in the phosphorylation level of cofilin, which is indicative of a compromised ROCK/LIMK/cofilin pathway. Inhibition of MEK in Ras-transformed NIH3T3 results in restoration of actin stress fibers accompanied by a loss of cytoplasmic p21(Cip1), and increased phosphorylation of cofilin. Ectopic expression of cytoplasmic but not nuclear p21(Cip1) in Ras-transformed cells was effective in preventing stress fibers from being restored upon MEK inhibition and inhibited phosphorylation of cofilin. p21(Cip1) was also found to form a complex with ROCK in Ras-transformed cells in vivo. Furthermore, inhibition of the PI 3-kinase pathway resulted in loss of p21(Cip1) expression accompanied by restoration of phosphocofilin, which was not accompanied by stress fiber formation. These results suggest that restoration of cofilin phosphorylation in Ras-transformed cells is necessary but not sufficient for stress fiber formation. Our findings define a novel mechanism for coupling cytoplasmic p21(Cip1) to the control of actin polymerization by compromising the Rho/ROCK/LIMK/cofilin pathway by oncogenic Ras. These studies suggest that localization of p21(Cip1) to the cytoplasm in transformed cells contributes to pathways that favor not only cell proliferation, but also cell motility thereby contributing to invasion and metastasis.
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PMID:Cytoplasmic p21Cip1 is involved in Ras-induced inhibition of the ROCK/LIMK/cofilin pathway. 1455 14

While advances in molecular genetics have provided new insights into molecular alterations that lead to the development of many tumors, including breast carcinoma, the genetic and epigenetic alterations that result in metastatic spread of the disease, from which afflicted patients ultimately succumb, are much more poorly understood. Important biologic processes in the development of metastasis include increased migration and invasion of tumor cells. While the regulation of these processes is complex, they are controlled in part by small G proteins of the Rho family, including Rho, Rac, and Cdc42, that are involved in cytoskeletal organization. These proteins, active when bound to GTP, are, in turn, regulated by guanine nucleotide exchange factors (GNEFs) and guanine nucleotide activating proteins. The GNEF Tiam1 catalyzes nucleotide exchange for Rac in vivo, and Rac, Cdc42 and Rho in vitro. Tiam1 was identified first in 1994 by in vitro selection for invasiveness in T-lymphoma cells. Accordingly, Tiam1 has been shown to increase invasion in T-lymphoma cells, as well as to increase cellular migration in fibroblasts, and to promote motility in some neuronal cells. In contrast, Tiam1 has been demonstrated to increase cellular adhesion in some epithelial cell populations. Thus, Tiam1 has multiple roles in regulating cellular functions, likely dependent on the cell type, the substratum, transformation status of the cells, and the activation state of small G proteins in a given cell. Increasing evidence has focused on Tiam1's regulation, as well as Tiam1's role in cancer progression and metastasis. Recent results from other laboratories and ours have demonstrated that increased Tiam1 expression correlates with grade of breast cancer in humans and metastatic potential of human breast carcinoma cell lines in nude mice. This review will discuss Tiam1's cellular functions and methods of regulation, and will highlight Tiam1's contribution to cancer progression and metastasis.
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PMID:The role of the guanine nucleotide exchange factor Tiam1 in cellular migration, invasion, adhesion and tumor progression. 1499 51

beta2-Chimerin is a member of the "non-protein kinase C" intracellular receptors for the second messenger diacylglycerol and the phorbol esters that is yet poorly characterized, particularly in the context of signaling pathways involved in proliferation and cancer progression. beta2-Chimerin possesses a C-terminal Rac-GAP (GTPase-activating protein) domain that accelerates the hydrolysis of GTP from the Rac GTPase, leading to its inactivation. We found that beta2-chimerin messenger levels are significantly down-regulated in human breast cancer cell lines as well as in breast tumors. Adenoviral delivery of beta2-chimerin into MCF-7 breast cancer cells leads to inhibition of proliferation and G(1) cell cycle arrest. Mechanistic studies show that the effect involves the reduction in Rac-GTP levels, cyclin D1 expression, and retinoblastoma dephosphorylation. Studies using the mutated forms of beta2-chimerin revealed that these effects were entirely dependent on its C-terminal GAP domain and Rac-GAP activity. Moreover, MCF-7 cells stably expressing active Rac (V12Rac1) but not RhoA (V14RhoA) were insensitive to beta2-chimerin-induced inhibition of proliferation and cell cycle progression. The modulation of G(1)/S progression by beta2-chimerin not only implies an essential role for Rac in breast cancer cell proliferation but also raises the intriguing possibility that diacylglycerol-regulated non-protein kinase C pathways can negatively impact proliferation mechanisms controlled by Rho GTPases.
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PMID:Rac-GAP-dependent inhibition of breast cancer cell proliferation by {beta}2-chimerin. 1586 13

Galectin-3 (Gal-3), a pleiotropic carbohydrate-binding protein, is a selective binding partner of activated K-Ras-GTP. Because both proteins are antiapoptotic and associated with cancer progression, we questioned the possible functional role of Gal-3 in K-Ras activation. We found that overexpression of Gal-3 in human breast cancer cells (BT-549/Gal-3) coincided with a significant increase in wild-type (wt) K-Ras-GTP coupled with loss in wt N-Ras-GTP, whereas the nononcogenic Gal-3 mutant proteins [Gal-3(S6E) and Gal-3(G182A)] failed to induce the Ras isoform switch. Only wt Gal-3 protein coimmunoprecipitated and colocalized with oncogenic K-Ras, resulting in its activation with radical alterations in Ras signaling pathway, whereby the activation of AKT and Ral was suppressed and shifted to the activation of extracellular signal-regulated kinase (ERK). Specific inhibitors for Ras or mitogen-activated protein/ERK kinase (farnesylthiosalicylic acid and UO126, respectively) inhibited Gal-3-mediated apoptotic resistance and anchorage-independent growth functions. In conclusion, this study shows that Gal-3 confers on BT-549 human breast carcinoma cells several oncogenic functions by binding to and activation of wt K-Ras, suggesting that some of the molecular functions of Gal-3 are, at least in part, a result of K-Ras activation.
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PMID:Galectin-3 regulates a molecular switch from N-Ras to K-Ras usage in human breast carcinoma cells. 1610 80

Ras-homologous (Rho) GTPases play a pivotal role in the regulation of numerous cellular functions associated with malignant transformation and metastasis. Rho GTPases are localized at membranes and become activated upon stimulation of cell surface receptors. In their GTP-bound (=active) state, Rho proteins bind to effector proteins, thereby triggering specific cellular responses. Members of the Rho family of small GTPases are key regulators of actin reorganization, cell motility, cell-cell and cell-extracellular matrix (ECM) adhesion as well as of cell cycle progression, gene expression and apoptosis. Each of these functions is of importance for the development and progression of cancer. Furthermore, Rho guanine exchange factors (GEFs) are often oncogenic and the expression level of Rho GTPases frequently increases with malignancy. Rho proteins also affect cellular susceptibility to DNA damaging agents, including antineoplastic drugs and ionizing radiation (IR). Thus, modulation of Rho driven mechanisms may influence the therapeutic efficiency and/or the side effects of conventional antineoplastic therapy. Because of their pleiotropic functions, Rho proteins appear to be promising targets for the development of novel anticancer drugs. Experimental approaches to inhibit Rho (and Ras) have focused on the attenuation of their C-terminal isoprenylation. This is because C-terminal lipid modification is required for correct intracellular localization and function of Rho/Ras. Inhibitors of farnesyltransferase (FTI), geranylgeranyltransferase (GGTI) as well as of HMG-CoA-reductase (i. e. statins) have been investigated with respect to their usefulness in tumor therapy. The studies showed that these compounds affect tumor progression and furthermore have impact on the frequency of cell death induced by tumor therapeutics. A possible drawback of inhibitors of isoprenylation is their poor selectivity for individual Rho GTPases. Therefore, specific inhibitors of individual Rho functions (notably RhoA-, RhoB-, Rac1- or Cdc42-related functions) are predicted to be of great therapeutic benefit. Indeed, compounds developed as specific inhibitors of the RhoA-effector molecule Rho-kinase (ROK) have been demonstrated to exert anti-metastatic activity in vivo.
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PMID:Rho GTPases: promising cellular targets for novel anticancer drugs. 1647 73

The Rho family GTPase Cdc42 regulates cytoskeletal organization and membrane trafficking in physiological processes such as cell proliferation, motility and polarity. Aberrant activation of Cdc42 results in pathogenesis, such as tumorigenesis and tumor progression, cardiovascular diseases, diabetes, and neuronal degenerative diseases. The activation of Cdc42 in response to upstream signals is mediated by guanine nucleotide exchange factors (GEFs), which converse GDP-bound inactive form to the GTP-bound active form of Cdc42. The activated Cdc42 transduces signals to downstream effectors and generates cellular effects. This review will discuss the molecular mechanism of activation of Cdc42 and postulate that signaling specificity of Cdc42 is conferred by the GEF/GTPase/Effector (GGE) complexes in response to external stimuli.
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PMID:Cellular signaling for activation of Rho GTPase Cdc42. 1855 78

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