The tumor-suppressor gene ARHI (DIRAS3) suppresses ovarian cancer cell migration through inhibition of the Stat3 and FAK/Rho signaling pathways

Ovarian cancers migrate and metastasize over the surface of the peritoneal cavity. Consequently, dysregulation of mechanisms that limit cell migration may be particularly important in the pathogenesis of the disease. ARHI is an imprinted tumor-suppressor gene that is downregulated in >60% of ovarian cancers, and its loss is associated with decreased progression-free survival. ARHI encodes a 26-kDa GTPase with homology to Ras. In contrast to Ras, ARHI inhibits cell growth, but whether it also regulates cell motility has not been studied previously. Here we report that re-expression of ARHI decreases the motility of IL-6- and epidermal growth factor (EGF)-stimulated SKOv3 and Hey ovarian cancer cells, inhibiting both chemotaxis and haptotaxis. ARHI binds to and sequesters Stat3 in the cytoplasm, preventing its translocation to the nucleus and localization in focal adhesion complexes. Stat3 siRNA or the JAK2 inhibitor AG490 produced similar inhibition of motility. However, the combination of ARHI expression with Stat3 knockdown or inhibition produced greatest inhibition in ovarian cancer cell migration, consistent with Stat3-dependent and Stat3-independent mechanisms. Consistent with two distinct signaling pathways, knockdown of Stat3 selectively inhibited IL-6-stimulated migration, whereas knockdown of focal adhesion kinase (FAK) preferentially inhibited EGF-stimulated migration. In EGF-stimulated ovarian cancer cells, re-expression of ARHI inhibited FAK(Y397) and Src(Y416) phosphorylation, disrupted focal adhesions, and blocked FAK-mediated RhoA signaling, resulting in decreased levels of GTP-RhoA. Re-expression of ARHI also disrupted the formation of actin stress fibers in a FAK- and RhoA-dependent manner. Thus, ARHI has a critical and previously uncharacterized role in the regulation of ovarian cancer cell migration, exerting inhibitory effects on two distinct signaling pathways.     

GTPase activating proteins.

Since Ras proteins negotiate many signalling pathways leading to cell growth or differentiation, the regulation of Ras activity is vital to cellular health. Ras activity, which derives from a collaboration between Ras and GTP, is terminated by the GTPase activating protein (GAP)-catalyzed hydrolysis of the GTP. Hence, a simple regulatory scheme emerges: extracellular signals control Ras activity via membrane receptors and GAPs. However, the signalling scenario is probably not so simple. In looking for factors which interpret Ras activity, researchers have been led to the same factors which also regulate Ras activity, namely the GAPs. Therefore, it may be that Ras proteins are actually regulators of GAPs.     

抑癌基因ARHI研究进展

ARHI（aplasia ras homologue member I）/NOEY2是1999年新发现的一个母源性抑癌印迹基因,位于人染色体1p31,编码一个相对分子量为26kD的小GTP结合蛋白。ARHI属ras/rap超家族成员,与该家族成员有50%～60%的同源性并且两者具有相似的GTP/GDP结合域,但与该家族其它成员不同,ARHI发挥抑癌基因作用,是该家族第一个被报道的肿瘤抑制基因。ARHI基因编码的蛋白在人类多种组织表达,而该基因在人卵巢癌、乳腺癌、胰腺癌、肝癌等多种肿瘤中表达下调或缺失,提示其与上述肿瘤的发生、发展密切相关。ARHI可能通过作用于cyclin D1,使其不能与CDK结合形成活性激酶,从而使细胞停止于G1期来参与细胞周期调控;可能通过依赖caspase和calpain两条途径参与信号通路传导诱发细胞凋亡;另外,该基因可通过抑制STAT3的激活而发挥抑癌基因功能,也可以调节自体吞噬和肿瘤细胞休眠。目前研究显示,ARHI基因的表达缺失主要通过遗传事件和表观遗传学机制发生,包括DNA甲基化异常、杂合性丢失,乙酰化组蛋白的低水平表达及基因突变有关,但有待进一步深入研究。可以预见,ARHI基因的深入研究必将为早期肿瘤的基因诊治提供新的思路和理论依据。      

肿瘤抑制基因ARHI的生物学功能及研究进展

肿瘤是一种基因病,抑癌基因在抵御肿瘤发生、发展中起着重要作用。ARHI(aplysia ras hom olog I)/NOEY2 是一个新发现的抑癌基因,是 ras/rap超家族成员之一,与 ras家族有50%~60%的同源性,位于人染色体1p31,属小GTP结合蛋白,是该家族第1个被报道的肿瘤抑制基因。ARHI基因编码的蛋白在人类多种组织表达,其中正常卵巢的ARHI表达最高。ARHI是一个印迹基因,印迹机制可能与其CpG岛的差异甲基化有关。ARHI 参与细胞周期调控可能作用于cyclin D1 ,使其不能与 CDK结合形成活性激酶,从而使细胞停止于 G1 期。AR HI可能通过依赖caspase和 calpain两条途径参与信号通路传导诱发细胞凋亡。该基因的异常表达跟多种肿瘤的发生、发展有关。ARHI基因参与了乳腺癌的发生和发展,该基因的表达缺失可能与乳腺癌的转移机制有关。卵巢癌、乳腺癌存在广泛的1p31缺失,其中 ARHI 基因是最常见的一个缺失区域。ARHI基因和蛋白在胰腺癌组织中有较高比例的缺失,提示该基因和蛋白在胰腺癌的发生中起一定作用。ARHI基因在膀胱癌、肝癌、前列腺癌等其他肿瘤中也有不同程度的表达异常。     

Increased Ras GTPase activity is regulated by miRNAs that can be attenuated by CDF treatment in pancreatic cancer cells

Ras gene is frequently mutated, and also associated with increased Ras expression and its GTPase activity (activity) in pancreatic cancer (PC), which could in part be due to deregulated expression of microRNAs (miRNAs) contributing to tumor aggressiveness. Here we report, for the first time, that Ras expression and its activity were significantly higher in MIAPaCa-2 cells compared to COLO-357 and BxPC-3 cell lines, which was correlated with loss of let-7 family and miR-143 expression in MIAPaCa-2 cells compared to COLO-357 and BxPC-3 cells. Whereas the expression of miR-21, a frequently up-regulated miRNA in solid tumors was up-regulated in MIAPaCa-2 cells and it was correlated with increased Ras expression and its activity. The miRNAs, let-7i and miR-143 was found to target Ras, and forced re-expression of let-7i and miR-143 inhibited Ras activity, cell proliferation and colony formation in vitro. We also found that the treatment of cells in vitro or treatment of MIAPaCa-2 induced tumors in vivo with CDF, a novel synthetic analog of curcumin, led to the re-expression of let-7 and miR-143, and down-regulated miR-21 expression, which was consistent with attenuation of Ras expression and its activity. Moreover, re-expression of let-7iin vivo resulted in decreased tumor growth and Ras activity. These results suggest that the loss of expression of let-7 and miR-143, and increased expression of miR-21 leads to increased expression of Ras and its GTPase activity, which could be attenuated by CDF treatment and, thus CDF could become a novel therapeutic agent for the treatment of PC.     

Decreased GTPase activity of K-ras mutants deriving from human functional adrenocortical tumours

Our previous studies have shown that seven out of 15 patients with adrenocortical tumours contained K-ras gene mutation. In addition, the mutation type was a multiple-site mutation, and the hot spots were located at codons 15, 16, 18 and 31, which were different from those reported before (codons 12, 13 and 61). To understand whether the mutation hot spots in human adrenocortical tumours were associated with activation of K-Ras oncogene and the alterations of its biocharacteristics, mutant K-Ras genes were cloned from tumour tissues and then constructed with expression vector pBKCMV. Mutant K-Ras genes were expressed at high levels in Escherichia coli and the resultant K-Ras proteins were shown to be functional with respect to their well-known specific, high-affinity, GDP/GTP binding. The purified K-Ras protein from E. coli were then measured for their intrinsic GTPase activity and the GTPase activity in the presence of GTPase-activating protein for Ras. The results showed that the wild-type cellular K-Ras protein (p21BN) exhibits about ten times higher intrinsic GTPase activity than the activated protein (p21BM3) encoded by mutant K-Ras gene, which mutated at codon 60. With regards to the codon 15, 16, 18 and 31 mutant K-Ras proteins (p21BM2), the GTPase activity in the presence of GAP is much lower than that of the normal K-Ras protein, whereas the intrinsic GTPase activity is nearly the same as that of the normal K-Ras protein. These results indicated that mutations at these hot spots of K-Ras gene were indeed activated K-Ras oncogene in adrenocortical tumours; however, their association with tumors needs further experiments to prove.     

Human breast cancer MDA-MB-231 cells fail to express the neurofibromin protein, lack its type I mRNA isoform and show accumulation of P-MAPK and activated Ras

Neurofibromin is a tumor suppressor protein, which is similar in function to the GTPase activating protein (GAP), p120GAP, in that it accelerates inactivation of Ras. Mutations in the NF1 gene cause neurofibromatosis type 1, NF1, an autosomal dominant disease with a diverse spectrum of clinical manifestations, including neurofibromas. Ras activation (GTP binding) is induced by the GTP exchange factor Sos and its inactivation is regulated through the GAPs (p120GAP and neurofibromin). Strikingly, neurofibromin was nearly absent in MB-231 human breast cancer cells and present in the remaining four cell lines studied, with higher levels in BT-474 and MB-453 than in MCF-7 and BT-20 cells, as tested with polyclonal antibodies to both the N-terminal as well as the C-terminal peptides. Coordinated with the near absence of neurofibromin, these cells also presented with much greater levels of P-MAPK and activated Ras. Further, RT-PCR analysis demonstrated the absence of expression of NF1 mRNA type I isoform only in the MB-231 cell lines. This result documents for the first time an altered NF1 expression at the protein and mRNA levels in MDA-MB-231 breast cancer cells.     

RASSF6 is a novel member of the RASSF family of tumor suppressors

RASSF family proteins are tumor suppressors that are frequently downregulated during the development of human cancer. The best-characterized member of the family is RASSF1A, which is downregulated by promoter methylation in 40-90% of primary human tumors. We now identify and characterize a novel member of the RASSF family, RASSF6. Like the other family members, RASSF6 possesses a Ras Association domain and binds activated Ras. Exogenous expression of RASSF6 promoted apoptosis, synergized with activated K-Ras to induce cell death and inhibited the survival of specific tumor cell lines. Suppression of RASSF6 enhanced the tumorigenic phenotype of a human lung tumor cell line. Furthermore, RASSF6 is often downregulated in primary human tumors. RASSF6 shares some similar overall properties as other RASSF proteins. However, there are significant differences in biological activity between RASSF6 and other family members including a discrete tissue expression profile, cell killing specificity and impact on signaling pathways. Moreover, RASSF6 may play a role in dictating the degree of inflammatory response to the respiratory syncytial virus. Thus, RASSF6 is a novel RASSF family member that demonstrates the properties of a Ras effector and tumor suppressor but exhibits biological properties that are unique and distinct from those of other family members.     

Selective inhibition of growth of tuberous sclerosis complex 2 null cells by atorvastatin is associated with impaired Rheb and Rho GTPase function and reduced mTOR/S6 kinase activity

Inactivating mutations in the tuberous sclerosis complex 2 (TSC2) gene, which encodes tuberin, result in the development of TSC and lymphangioleiomyomatosis (LAM). The tumor suppressor effect of tuberin lies in its GTPase-activating protein activity toward Ras homologue enriched in brain (Rheb), a Ras GTPase superfamily member. The statins, 3-hydroxy-3-methylglutaryl CoA reductase inhibitors, have pleiotropic effects which may involve interference with the isoprenylation of Ras and Rho GTPases. We show that atorvastatin selectively inhibits the proliferation of Tsc2-/- mouse embryo fibroblasts and ELT-3 smooth muscle cells in response to serum and estrogen, and under serum-free conditions. The isoprenoids farnesylpyrophosphate (FPP) and geranylgeranylpyrophosphate (GGPP) significantly reverse atorvastatin-induced inhibition of Tsc2-/- cell growth, suggesting that atorvastatin dually targets a farnesylated protein, such as Rheb, and a geranylgeranylated protein, such as Rho, both of which have elevated activity in Tsc2-/- cells. Atorvastatin reduced Rheb isoprenylation, GTP loading, and membrane localization. Atorvastatin also inhibited the constitutive phosphorylation of mammalian target of rapamycin, S6 kinase, and S6 found in Tsc2-/- cells in an FPP-reversible manner and attenuated the high levels of phosphorylated S6 in Tsc2-heterozygous mice. Atorvastatin, but not rapamycin, attenuated the increased levels of activated RhoA in Tsc2-/- cells, and this was reversed by GGPP. These results suggest that atorvastatin may inhibit both rapamycin-sensitive and rapamycin-insensitive mechanisms of tuberin-null cell growth, likely via Rheb and Rho inhibition, respectively. Atorvastatin may have potential therapeutic benefit in TSC syndromes, including LAM.     

An essential role for Ran GTPase in epithelial ovarian cancer cell survival

Background  

We previously identified that Ran protein, a member of the Ras GTPase family, is highly expressed in high grade and high stage serous epithelial ovarian cancers, and that its overexpression is associated with a poor prognosis. Ran is known to contribute to both nucleocytoplasmic transport and cell cycle progression, but its role in ovarian cancer is not well defined.     

Rap1和SPA-1基因与恶性血液病

 Rap1（Ras-proximate 1）是Ras家族GTP酶中的一员,其在调节细胞增生和黏附中有重要作用。经研究发现,Rap1和它的调节子SPA-1在恶性血液病的发生及发展中起到一定的作用,现就其作用机制及研究现况作一简要概述。     

Ras and autophagy in cancer development and therapy

Autophagy, a process of self-degradation and turnover of cellular components, plays a complex role in cancer. Evidence exists to show that autophagy may support tumor growth and cell survival, whereas it can also contribute to tumor suppression and have anti-survival characteristics in different cellular systems. Numerous studies have described the effects of various oncogenes and tumor suppressors on autophagy. The small GTPase Ras is an oncogene involved in the regulation of various cell-signaling pathways, and is mutated in 33% of human cancers. In the present review, we discuss the interplay between Ras and autophagy in relation to oncogenesis. It appears that Ras can upregulate or downregulate autophagy through several signaling pathways. In turn, autophagy can affect the tumorigenicity driven by Ras, resulting in either tumor progression or repression, depending on the cellular context. Furthermore, Ras inhibitors were shown to induce autophagy in several cancer cell lines.     

Farnesylthiosalicylic acid (salirasib) inhibits Rheb in TSC2-null ELT3 cells: a potential treatment for lymphangioleiomyomatosis

The small GTPase proteins, Ras and Rheb, serve as molecular switches regulating cell proliferation, differentiation and apoptosis. Ras also regulates Rheb by inactivating the tuberous sclerosis complex (TSC), which includes products of the TSC1 and TSC2 genes encoding hamartin (TSC1) and tuberin (TSC2), respectively, and acts as a Rheb-specific GTPase-activating protein. Loss of function of TSC1 or TSC2 results in an increase in active Rheb.GTP with the consequent translational abnormalities and excessive cell proliferation characteristic of the genetic disorders, tuberous sclerosis and lymphangioleiomyomatosis (LAM). To determine whether inactivation of Rheb, Ras or both might be a potential treatment for LAM, we used TSC2-null ELT3 cells as a LAM model. The cells were treated with the Ras inhibitor S-trans,trans-farnesylthiosalicylic acid (FTS; salirasib), which mimics the C-terminal S-farnesyl cysteine common to Ras and Rheb. This C-terminus is critical for their attachment to cellular membranes and for their biological activities. Untreated, the ELT3 cells expressed significant amounts of Rheb but little Ras.GTP, and this phenotype was reversed by TSC2 reexpression. Treatment with FTS decreased Ras.GTP only slightly in the TSC2-null cells, but reduced their overactive Rheb as well as their proliferation, migration and tumor growth. Notably, TSC2 reexpression in these ELT3 cells rescued them from the inhibitory effect of FTS. Evidently, therefore, FTS blocks active Rheb in TSC2-null ELT3 cells and may have therapeutic potential for LAM.     

Ras in signal transduction.

Ras protein is a GTP-binding protein, and acts as a signal transducer in fibroblast, lymphoid, myeloid, and neuronal cells. In all cases, tyrosine kinases, intrinsic to or associated with receptors, seem to play an important role for the activation of Ras in response to extracellular stimulations. A GDP/GTP exchange regulator and a GTPase stimulatory protein are thought to mediate signals from the kinases. The active Ras.GTP can cause different phenotypes, that is, proliferation, transformation, activation, or differentiation, depending on cell types, although it is not yet clear what is the primary target of the active Ras-GTP or how the various phenotypes are determined downstream of Ras protein.     

The role of Gads in hematopoietic cell signalling

Gads is a member of the family of SH2 and SH3 domain containing adaptor proteins that is expressed specifically in hematopoietic cells and functions in the coordination of tyrosine kinase mediated signal transduction. Gads plays a critical role in signalling from the T cell receptor by promoting the formation of a complex between SLP-76 and LAT. This complex couples the T cell receptor to Ras through a novel pathway involving PLC-gamma1, Tec family kinases, and RasGRP. Studies with Gads-deficient mice have highlighted its importance for thymocyte proliferation during T cell maturation. Emerging evidence suggests that Gads may also play additional roles in antigen-receptor signalling and receptor tyrosine kinase mediated signalling in other hematopoietic lineages. Gads is a unique member of the Grb2 adaptor family, because its activity can be regulated by caspase cleavage. Gads nucleates multi-protein complexes that are required for tyrosine kinase-dependent signalling in immune cells and may also represent a point of modulation for these pathways through the activation of caspase-dependent signalling events.     

RASSF4/AD037 is a potential ras effector/tumor suppressor of the RASSF family

Activated Ras proteins interact with a broad range of effector proteins to induce a diverse series of biological consequences. Although typically associated with enhanced growth and transformation, activated Ras may also induce growth antagonistic effects such as senescence or apoptosis. It is now apparent that some of the growth-inhibitory properties of Ras are mediated via the RASSF family of Ras effector/tumor suppressors. To date, four members of this family have been identified (Nore1, RASSF1, RASSF2, and RASSF3). We now identify a fifth member of this group, RASSF4 (AD037). RASSF4 shows approximately 25% identity with RASSF1A and 60% identity with RASSF2. RASSF4 binds directly to activated K-Ras in a GTP-dependent manner via the effector domain, thus exhibiting the basic properties of a Ras effector. Overexpression of RASSF4 induces Ras-dependent apoptosis in 293-T cells and inhibits the growth of human tumor cell lines. Although broadly expressed in normal tissue, RASSF4 is frequently down-regulated by promoter methylation in human tumor cells. Thus, RASSF4 appears to be a new member of the RASSF family of potential Ras effector/tumor suppressors.