Cdc42 Levels Research Articles

A novel inhibitor, 16-hydroxy-cleroda-3,13-dien-16,15-olide, blocks the autophosphorylation site of focal adhesion kinase (Y397) by molecular docking

BackgroundFocal adhesion kinase (FAK) is a nonreceptor protein tyrosine plays an important role in a number of cell signaling pathways, including cell migration, proliferation, and cell survival. This study was aimed to identify novel and specific inhibitors from natural compounds via molecular docking of FAK (Y397). MethodsThe 3D structure of FAK (PDB ID: 2AL6) was used for docking 109 natural compounds. Based on high affinity and energy interaction, four of ten candidate compounds, 16-hydroxy-cleroda-3,13-dien-16,15-olide (HCD), curcumin, quercetin, and catechin hydrate, were hit, and the inhibitory activity against FAK was validated in these compounds in C6 glioma and N18 neuroblastoma cell lines. ResultsHCD showed a potential effect on cell viability by MTT assay and cell arrest in the G0–G1 phase, and a TUNEL assay confirmed further apoptosis. Treatment with HCD decreased anti-apoptotic proteins and increased pro-apoptotic proteins. Atomic force microscopy data depicted that the formation of filopodia on the intracellular surface decreased in treated cells compared with the control. Zymography showed that HCD inhibited the activity of MMP-2 and MMP-9. The protein levels of FAK, pFAK, Rac1 and Cdc42, which are the key regulators for the formation of filopodia, were decreased. Additionally, HCD regulated the expression of epithelial mesenchymal transition proteins. ConclusionsHCD effectively interacted at the autophosphorylation site of FAK and interaction analysis indicated an H-bond with the Arg 86 and Arg 125 residues. General significanceThis study suggests that HCD could be a potential inhibitor of FAK and could be used for anti-tumorigenesis and anti-metastasis treatments.

Abstract 2912: Inhibition of redox/Fyn/c-Cbl pathway function by Cdc42 controls tumor initiation capacity and tamoxifen sensitivity in basal-like breast cancer cells.

Abstract Two of the substantial challenges in cancer research are to identify means overcoming resistance of malignant cells to existing therapies and to eliminate the unique small population within bulk tumors, named tumor initiating cells or cancer stem cells which have been proposed to regenerate resistant relapsed tumors. In this study, we offer a novel therapeutic target relevant to both of these goals on basal-like (triple-negative) breast cancer (BLBC) cells, one of the most challenging cancers to treat with current regimens. Our findings emerged from examining the puzzling differences in regulation of activation of the E3 ubiqutin ligase c-Cbl in normal cells and in cancer cells by low microM concentrations of tamoxifen (TMX). In normal progenitor cells, TMX causes oxidation and sequential activation of Fyn kinase and the c-Cbl ubiquitin ligase. Activation of c-Cbl via this redox/Fyn/c-Cbl (RFC) pathway leads to accelerated degradation of receptor tyrosine kinases that are critical in cell survival and division (such as the epidermal growth factor (EGFR)). In BLBC cells, in contrast, TMX does not activate c-Cbl despite making the cells more oxidized and causing activation of Fyn. Moreover, BLBC cells exposed to TMX show no reduction in levels of EGFR. We found that TMX-induced activation of c-Cbl in BLBC cells was inhibited due to expression of Cdc42. Cdc42 sequestered c-Cbl, prevented its activation and prevented EGFR from being degraded. Restoration of c-Cbl function, by inhibiting activation of Cdc42, reduced EGFR levels in these cells. More critically, restoring c-Cbl function sensitized these cells to TMX both in vitro and in vivo through estrogen receptor-independent mechanisms. Analysis of tumor growth and formation in vivo showed that reducing the levels of Cdc42 reduced the size of tumors, increased sensitivity to TMX and decreased tumor forming capacity of these cells. The results provide a novel defense mechanism that BLBC cells utilize to prevent EGFR degradation, which may have high relevance to treatment of these tumors. Of particular importance is the ability of cdc42 to confer TMX sensitivity on these otherwise resistant tumor cells. Moreover, as use of low microM levels of TMX has been attempted for over a dozen different kinds of cancers, at least some of which express increased levels of Cdc42, this strategy may be relevant to the treatment of multiple different cancers. Citation Format: Hsing-Yu Chen, Yin Yang, Brett Stevens, Mark Noble. Inhibition of redox/Fyn/c-Cbl pathway function by Cdc42 controls tumor initiation capacity and tamoxifen sensitivity in basal-like breast cancer cells. [abstract]. In: Proceedings of the 104th Annual Meeting of the American Association for Cancer Research; 2013 Apr 6-10; Washington, DC. Philadelphia (PA): AACR; Cancer Res 2013;73(8 Suppl):Abstract nr 2912. doi:10.1158/1538-7445.AM2013-2912

Involvement of microRNA‐224 in cell proliferation, migration, invasion, and anti‐apoptosis in hepatocellular carcinoma

Changes in microRNA (miRNA) expression have been detected in a broad range of biological processes including cancer. Here we determined the role of miRNA dysregulation in hepatocellular carcinoma (HCC). We investigated the expression of nine cancer-related miRNAs in HCC. Among these, miR-224 was the most significantly uprgulated in HCC tissues (n = 18), compared with normal (n = 9) and HCC adjacent non-tumorous liver tissues (n = 18). After leading-in currently reported gene targets from Sanger miRBase, we characterized the expression profiles of target genes of miR-224 using cDNA microarray. The altered expression was subsequently validated by real-time polymerase chain reaction and Western blot. The phenotypic changes by miR-224 expression were identified by cell viability, apoptosis, and in vitro scratch assays. The microarray analysis and miRNA target prediction analysis allowed the identification of significant changes in 68 putative gene targets after overexpression of miR-224. The high-ranking genes CDC42, CDH1, PAK2, BCL-2, and MAPK1 were confirmed as important targets of miR-224 and involvement in hepatocarcinogenesis. Overexpression of miR-224 significantly in Hek293 and Huh7 cells altered the expression levels of CDC42, CDH1, PAK2, and BCL-2 at both mRNA and protein levels. Similar changes in the expression of the same genes were also observed in HCC tissues. Via functional analyses, cell proliferation, migration and anti-apoptosis were proved to be affected by miR-224 expression. The results suggest that miR-224 plays a role in cell proliferation, migration, invasion, and anti-apoptosis in HCC by directly binding to its gene targets, implicating this RNA in HCC development and progression.

Functional analysis of Zyxin in cell migration and invasive potential of oral squamous cell carcinoma cells

Zyxin is an evolutionarily conserved protein that has been implicated in the regulation of actin assembly and is mainly located at focal adhesions. However, the biological roles of Zyxin in cancer cells are incompletely understood. We analyzed the functions of Zyxin in cell migration and the invasive potential of OSCC. Zyxin expression was examined using eight OSCC cell lines with two different cell morphologies (6 epithelial type and 2 fibroblastic type). To knockdown Zyxin expression, OSCC cells were transfected with Zyxin siRNA and control siRNA. The cell lines were studied by western blot analysis, immunocytochemical analysis and cell migration and invasion assay. Epithelial type OSCC cells showed a high level of E-cadherin expression and a low level of Zyxin expression. N-cadherin as well as Zyxin were strongly expressed in fibroblastic type OSCC cells. Expression levels of LPP and TRIP6, members of the human Zyxin family, did not differ between epithelial type and fibroblastic type. Knockdown of Zyxin expression by siRNA in fibroblastic type OSCC cells was associated with cell morphological changes from spindle (fibroblastic) to polygonal (epithelial) shape and significantly inhibited cell growth as well as cell migration and invasion. Expression levels of Rac1 and Cdc42 were weaker in Zyxin siRNA-treated fibroblastic type OSCC cells than in control siRNA-treated cells, but the expression of RhoA did not differ significantly. Treatment of fibroblastic type OSCC cells with Rac1 inhibitor decreased the expression of Zyxin mRNA and protein. Zyxin is suggested to promote growth, migration and invasiveness of fibroblastic type OSCC cells by upregulating Rac1 and Cdc42.

Rho GTPase Expression in Human Myeloid Cells

Myeloid cells are critical for innate immunity and the initiation of adaptive immunity. Strict regulation of the adhesive and migratory behavior is essential for proper functioning of these cells. Rho GTPases are important regulators of adhesion and migration; however, it is unknown which Rho GTPases are expressed in different myeloid cells. Here, we use a qPCR-based approach to investigate Rho GTPase expression in myeloid cells.We found that the mRNAs encoding Cdc42, RhoQ, Rac1, Rac2, RhoA and RhoC are the most abundant. In addition, RhoG, RhoB, RhoF and RhoV are expressed at low levels or only in specific cell types. More differentiated cells along the monocyte-lineage display lower levels of Cdc42 and RhoV, while RhoC mRNA is more abundant. In addition, the Rho GTPase expression profile changes during dendritic cell maturation with Rac1 being upregulated and Rac2 downregulated. Finally, GM-CSF stimulation, during macrophage and osteoclast differentiation, leads to high expression of Rac2, while M-CSF induces high levels of RhoA, showing that these cytokines induce a distinct pattern. Our data uncover cell type specific modulation of the Rho GTPase expression profile in hematopoietic stem cells and in more differentiated cells of the myeloid lineage.

Neocortical dendritic complexity is controlled during development by NOMA-GAP-dependent inhibition of Cdc42 and activation of cofilin

Neocortical neurons have highly branched dendritic trees that are essential for their function. Indeed, defects in dendritic arborization are associated with human neurodevelopmental disorders. The molecular mechanisms regulating dendritic arbor complexity, however, are still poorly understood. Here, we uncover the molecular basis for the regulation of dendritic branching during cortical development. We show that during development, dendritic branching requires post-mitotic suppression of the RhoGTPase Cdc42. By generating genetically modified mice, we demonstrate that this is catalyzed in vivo by the novel Cdc42-GAP NOMA-GAP. Loss of NOMA-GAP leads to decreased neocortical volume, associated specifically with profound oversimplification of cortical dendritic arborization and hyperactivation of Cdc42. Remarkably, dendritic complexity and cortical thickness can be partially restored by genetic reduction of post-mitotic Cdc42 levels. Furthermore, we identify the actin regulator cofilin as a key regulator of dendritic complexity in vivo. Cofilin activation during late cortical development depends on NOMA-GAP expression and subsequent inhibition of Cdc42. Strikingly, in utero expression of active cofilin is sufficient to restore postnatal dendritic complexity in NOMA-GAP-deficient animals. Our findings define a novel cell-intrinsic mechanism to regulate dendritic branching and thus neuronal complexity in the cerebral cortex.

WNT-3a modulates platelet function by regulating small GTPase activity

Here we provide evidence that WNT-3a modulates platelet function by regulating the activity of four key GTPase proteins: Rap1, Cdc42, Rac1 and RhoA. We observe WNT-3a to differentially regulate small GTPase activity in platelets, promoting the GDP-bound form of Rap1b to inhibit integrin-αIIbβ3 adhesion, while concomitantly increasing Cdc42 and Rac1-GTP levels thereby disrupting normal platelet spreading. We demonstrate that Daam-1 interacts with Dishevelled upon platelet activation, which correlates with increased RhoA-GTP levels. Upon pre-treatment with WNT-3a, this complex disassociates, concurrent with a reduction in RhoA-GTP. Together these data implicate WNT-3a as a novel upstream regulator of small GTPase activity in platelets. Structured summary of protein interactionsDVL physically interacts with DAAM-1 by anti bait co-immunoprecipitation (View interaction)DVL and DAAM-1 colocalise by fluorescence microscopy (View interaction)

Abstract 769: Restoration of c-Cbl function, by inhibiting Cdc42, confers tamoxifen sensitivity on basal-like (triple negative) breast cancer cells

Abstract Our present work offers a new means by which cancer cells become resistant to anti-cancer treatments and mechanism-driven approaches for overcoming such resistance. Specifically, here we demonstrate a previously unrecognized mechanism of tamoxifen (TMX) resistance distinct from loss of estrogen receptor on basal-like (triple negative) breast cancer cells, which are among the most challenging tumors to treat with current therapies. Our present finding emerged from trying to understand the puzzling differences in regulation of receptor tyrosine kinase (RTK) degradation in normal progenitor cells and in breast cancer cells. When glial progenitor cells become slightly more (15-20%) oxidized, such as by exposing them to TMX, we find sequential activation of Fyn (a member of the Src-family of kinases) and c-Cbl (an E3 ubiquitin ligase) is activated. Phosphorylation of c-Cbl causes ubiquitylation of its target proteins and thus increases the degradation of its target proteins, such as particular RTKs, including the epidermal growth factor receptor (EGFR, our specific target in this study). In contrast to normal progenitor cells, basal-like breast cancer cells exposed to TMX show increased Fyn activation but no increase in c-Cbl phosphorylation. We now have found that oxidation-induced activation of c-Cbl in basal-like breast cancer cells is inhibited due to expression of Cdc42. Cdc42 sequestered c-Cbl, prevented its activation and prevented EGFR from being degraded. Restoration of c-Cbl function, by genetically or pharmacologically inhibiting Cdc42 activation, reduced EGFR levels in these cells. More critically, restoring c-Cbl function sensitized these cells to TMX both in vitro and in vivo. Analysis of tumor growth in vivo showed that reducing the levels of Cdc42 both reduced the size of tumors and made them more sensitive to TMX. The results provide a novel defense mechanism that basal-like breast cancer cells utilize to prevent EGFR degradation which may have high relevance to treatment of these tumors. Of particular importance is the ability of Cdc42 knockdown to confer TMX sensitivity on these otherwise resistant tumor cells. Citation Format: {Authors}. {Abstract title} [abstract]. In: Proceedings of the 103rd Annual Meeting of the American Association for Cancer Research; 2012 Mar 31-Apr 4; Chicago, IL. Philadelphia (PA): AACR; Cancer Res 2012;72(8 Suppl):Abstract nr 769. doi:1538-7445.AM2012-769

Overexpression of small GTPases directly correlates with expression of δ‐catenin and their coexpression predicts a poor clinical outcome in nonsmall cell lung cancer

δ-catenin can affect cytoskeletal assembly, and promote cell migration by regulating the activity of small GTPases. While many malignancies have been shown to be positive for δ-catenin, it is still unclear whether δ-catenin and small GTPases are coexpressed in tumor cells, and so is the relationship between their coexpression and prognosis in the tumor patients. In this study, immunohistochemistry was performed to examine expressive levels of δ-catenin, cdc42, and Rac1 in 135 cases of nonsmall cell lung cancer (NSCLC), including 60 cases with follow-up records. Thirty samples of paired lung cancer tissues and adjacent normal lung tissues were collected to analyze mRNA and protein expression of δ-catenin and small GTPases. The effects of δ-catenin on small GTPases expression and invasive ability of lung cancer cells were also evaluated. Compared with normal lung tissues, both mRNA and protein levels of δ-catenin and small GTPases were increased in lung cancer tissues (P < 0.05), and the expression of small GTPases directly correlated with that of δ-catenin (P < 0.001). In addition, δ-catenin and small GTPases tended to be coexpressed in lung adenocarcinoma, advanced stages, and primary tumors with lymph node metastasis (all P < 0.05). The patients with coexpression of δ-catenin and small GTPases had a shorter survival time than those without coexpression (P < 0.05). Furthermore, δ-catenin overexpression could enhance invasive ability of lung cancer cells by upregulating protein and transcriptional level of small GTPases. Therefore, δ-catenin likely upregulates the activity of small GTPases at transcriptional level, and their coexpression may predict a poor clinical outcome in NSCLC patients.

Arhgap24 inactivates Rac1 in mouse podocytes, and a mutant form is associated with familial focal segmental glomerulosclerosis

The specialized epithelial cell of the kidney, the podocyte, has a complex actin-based cytoskeleton. Dynamic regulation of this cytoskeleton is required for efficient barrier function of the kidney. Podocytes are a useful cell type to study the control of the actin cytoskeleton in vivo, because disruption of components of the cytoskeleton results in podocyte damage, cell loss, and a prototypic injury response called focal segmental glomerulosclerosis (FSGS). Searching for actin regulatory proteins that are expressed in podocytes, we identified a RhoA-activated Rac1 GTPase-activating protein (Rac1-GAP), Arhgap24, that was upregulated in podocytes as they differentiated, both in vitro and in vivo. Increased levels of active Rac1 and Cdc42 were measured in Arhgap24 knockdown experiments, which influenced podocyte cell shape and membrane dynamics. Consistent with a role for Arhgap24 in normal podocyte functioning in vivo, sequencing of the ARHGAP24 gene in patients with FSGS identified a mutation that impaired its Rac1-GAP activity and was associated with disease in a family with FSGS. Thus, Arhgap24 contributes to the careful balancing of RhoA and Rac1 signaling in podocytes, the disruption of which may lead to kidney disease.

Interleukin‐1α, ‐6, and ‐8 decrease Cdc42 activity resulting in loss of articular chondrocyte phenotype

Small GTPase proteins mediate changes in cellular morphology and other cellular functions. The aim of this study was to examine signaling of the small GTPase Cdc42 by stimulating chondrocytes grown in monolayer with long- (96 h) or short- (2 and 30 min) term exposure to interleukin-1α (IL-1α), IL-6, or IL-8. Quantitative PCR was used to determine changes in collagen type IIB (COL2A1), aggrecan (AGG), and matrix metalloproteinase-13 (MMP-13) gene expression after prolonged cytokine exposure. Effects of short-term treatment with IL-α, IL-6, or IL-8 on endogenous GTP-bound Cdc42 levels were assessed using an affinity assay, and on actin filament organization using confocal microscopy. Cytokine treatments significantly decreased COL2A1 and AGG expression and increased MMP-13 expression. Short exposure to IL-1α, IL-6, or IL-8 decreased endogenous GTP-Cdc42 and increased stress fibers, which were reversed with cytochalasin D treatment. These results show that IL-mediated Cdc42 signaling modifies chondrocyte phenotype and morphology. This may lend insight into the altered chondrocyte phenotype in catabolic conditions such as osteoarthritis.

Alteration of gene expression of IQGAP1 and Rho-family GTPases in the cadmium-induced ventral body wall defects in the chick model

Cadmium (Cd) induces ventral body wall defects (VBWD) in the chick embryo, with adherens junctions (AJs) breakdown at 4 h post treatment (4H). Signalling by which Cd disrupts AJs in this model remains unclear. IQGAP1 regulates AJs via binding to Cdc42 and Rac1, Rho-family GTPases. Activation of IQGAP1-Cdc42 interaction regulates AJs positively, whereas Rac1 activation inhibits AJs. We hypothesised that IQGAP1 and Cdc42 are downregulated and Rac1 is upregulated during embryogenesis in the Cd chick model. Chick embryos were explanted and treated with saline or Cd after 60 h incubation. Chicks were harvested at 1H, 4H and 8H post treatment and RT-PCR and immunohistochemistry were performed. Gene expression levels of IQGAP1 and Cdc42 were significantly downregulated and Rac1 was upregulated in Cd group compared to controls only at 4H. Immunoreactivity of IQGAP1 and Cdc42 was also markedly decreased, whereas Rac1 was increased in Cd group compared to controls at 4H. Alteration of IQGAP and Rho-family GTPases may cause VBWD in Cd chick model by inducing the dissociation of cadherin-mediated AJs.

The Calcium-Sensing Receptor-Dependent Regulation of Cell–Cell Adhesion and Keratinocyte Differentiation Requires Rho and Filamin A

Extracellular Ca(2+) (Ca(2+)(o)) functioning through the calcium-sensing receptor (CaR) induces E-cadherin-mediated cell-cell adhesion and cellular signals mediating cell differentiation in epidermal keratinocytes. Previous studies indicate that CaR regulates cell-cell adhesion through Fyn/Src tyrosine kinases. In this study, we investigate whether Rho GTPase is a part of the CaR-mediated signaling cascade regulating cell adhesion and differentiation. Suppressing endogenous Rho A expression by small interfering RNA (siRNA)-mediated gene silencing blocked the Ca(2+)(o)-induced association of Fyn with E-cadherin and suppressed the Ca(2+)(o)-induced tyrosine phosphorylation of β-, γ-, and p120-catenin and formation of intercellular adherens junctions. Rho A silencing also decreased the Ca(2+)(o)-stimulated expression of terminal differentiation markers. Elevating the Ca(2+)(o) level induced interactions among CaR, Rho A, E-cadherin, and the scaffolding protein filamin A at the cell membrane. Inactivation of CaR expression by adenoviral expression of a CaR antisense complementary DNA inhibited Ca(2+)(o)-induced activation of endogenous Rho. Ca(2+)(o) activation of Rho required a direct interaction between CaR and filamin A. Interference of CaR-filamin interaction inhibited Ca(2+)(o)-induced Rho activation and the formation of cell-cell junctions. These results indicate that Rho is a downstream mediator of CaR in the regulation of Ca(2+)(o)-induced E-cadherin-mediated cell-cell adhesion and keratinocyte differentiation.

Abstract 3847: Cytoplasmic ECT2: Implications for invasion and migration and RAS-RAC cross-talk in glioma

Abstract Gliomas are a highly malignant primary brain tumour characterized by their adept ability to invade normal brain parenchyma. We have previously identified the cytoplasmic and normally nuclear sequestered pro-cytokinetic, small cytoskeletal GTPase ECT2 to be involved in the invasive process of malignant glioma. ECT2 shows dysregulated spatial regulation in malignant gliomas with increased cytoplasmic expression, in particular at the leading edge of invading primary glioma cells. This aberrant ECT2 plays a role in RAC1 and CDC42 activation, as shRNA mediated loss of ECT2 leads to no effect on cell cycle, but a less invasive phenotype and diminished RAC1 and CDC42 levels. Using immunoprecipitation and mass spectrometry we identified the novel RAS-GAP, RASAL2 as a significant cytoplasmic interactor with ECT2 in gliomas. We show this interaction represents a mechanism by which RAS (which is aberrantly activated in gliomas) can cross-talk with the RAC/RHO pathway and coordinate growth and invasion of gliomas. Over-expression of ECT2 leads to mesenchymal-amoeboid transition (MAT) in glioma cells. Cells expressing GFP-ECT2 show hyperactive cortical dynamics with the formation of membrane blebs, similar to an amoeboid phenotype. ECT2 localized to the cortical blebs during retraction in a similar manner to active RHOA in amoeboid cells. It is known that MAT relies on an antagonistic relationship between RHOA (pro-amoeboid) and RAC1 (promesenchymal). We tested whether our phenotype was mediated by RHOA or RAC1 by administration of the RHOA downstream inhibitor of ROCK, Y27632 and RAC1 NSC23766. RHOA pathway inhibition by Y27632 at 25uM was able to reverse this hypercortical activity and resulted in formation of lamellipodia, as seen with RAC1 activation. NSC23766 was unable to abolish the amoeboid phenotype in concentrations of up to 100uM. A proportion of GFP-ECT2 amoeboid cells were capable of migrating at velocities of up to 10 um/sec. Interestingly, although loss of ECT2 has no phenotypic changes in cells plated in a 2D context, loss of ECT2 by shRNA in cells plated within a collagen matrix show marked reduction in amoeboid phenotype. The ability of glioma cells to undergo MAT is a relatively new concept, however well documented in other cancer subtypes such as melanoma. The molecular switches involved in MAT remain elusive, however our data reveals a potential role for ECT2 in migratory phenotype switching. Importantly, when a stably expressing ECT2 shRNA glioma line is orthotopically injected into mouse brains, these ECT2 knockdown xenografts exhibit enhanced survival and diminished tumour engraftment as compared to controls. Taken together, this suggests that ECT2 is a viable target for malignant gliomas. Citation Format: {Authors}. {Abstract title} [abstract]. In: Proceedings of the 102nd Annual Meeting of the American Association for Cancer Research; 2011 Apr 2-6; Orlando, FL. Philadelphia (PA): AACR; Cancer Res 2011;71(8 Suppl):Abstract nr 3847. doi:10.1158/1538-7445.AM2011-3847

Syk Regulates Multiple Signaling Pathways Leading to CX3CL1 Chemotaxis in Macrophages

Several studies have clearly established the importance of the interaction between macrophages and CX3CL1 in the progression of disease. A previous study demonstrated that Syk was required for CX3CL1-mediated actin polymerization and chemotaxis. Here, we delineated the signaling cascade of Syk-mediated cell migration in response to CX3CL1. Inhibition of Syk in bone marrow-derived macrophages or reduction of Syk expression using siRNA in RAW/LR5 cells indicated that Syk was required for the activation of PI3K, Cdc42, and Rac1. Also, reduction in WASP or WAVE2 levels, common downstream effectors of Cdc42 or Rac1, resulted in impaired cell migration to CX3CL1. Syk indirectly regulated WASP tyrosine phosphorylation through Cdc42 activation. Altogether, our data identify that Syk mediated chemotaxis toward CX3CL1 by regulating both Rac1/WAVE2 and Cdc42/WASP pathways, whereas Src family kinases were required for proper WASP tyrosine phosphorylation.

Secondary neurulation: Fate‐mapping and gene manipulation of the neural tube in tail bud

The body tail is a characteristic trait of vertebrates, which endows the animals with a variety of locomotive functions. During embryogenesis, the tail develops from the tail bud, where neural and mesodermal tissues make a major contribution. The neural tube in the tail bud develops by the process known as secondary neurulation (SN), where mesenchymal cells undergo epithelialization and tubulogenesis. These processes contrast with the well known primary neurulation, which is achieved by invagination of an epithelial cell sheet. In this study we have identified the origin of SN-undergoing cells, which is located caudo-medially to Hensen's node of early chicken embryo. This region is distinctly fate-mapped from tail-forming mesoderm. The identification of the presumptive SN region has allowed us to target this region with exogenous genes using in ovo electroporation techniques. The SN-transgenesis has further enabled an exploration of molecular mechanisms underlying mesenchymal-to-epithelial transition during SN, where activity levels of Cdc42 and Rac1 are critical. This is the first demonstration of molecular and cellular analyses of SN, which can be performed at a high resolution separately from tail-forming mesoderm.

MiR‐137 targets Cdc42 expression, induces cell cycle G1 arrest and inhibits invasion in colorectal cancer cells

miRNAs have emerged as post-transcriptional regulators that are critically involved in the pathogenesis of a number of human cancers. Cdc42, one of the best characterized members of the Rho GTPase family, is found to be up-regulated in several types of human tumors and has been implicated in cancer initiation and progression. In the present study, we have identified miR-137 as a potential regulator of Cdc42 expression. A bioinformatics search revealed a putative target-site for miR-137 within the Cdc42 3' UTR at nt 792-798, which is highly conserved across different species. Expression of miR-137 in colorectal cancer cell lines was found inversely correlated with Cdc42 expression. miR-137 could significantly suppress Cdc42 3' UTR luciferase-reporter activity, and this effect was not detectable when the putative 3' UTR target-site was mutated. Consistent with the results of the reporter assay, ectopic expression of miR-137 reduced both mRNA and protein expression levels of Cdc42 and mimicked the effect of Cdc42 knockdown in inhibiting proliferation, inducing G1 cell cycle arrest, and blocking invasion of the colorectal cancer cells, whereas anti-miR-137 expression led to the opposite effect. Furthermore, expression of miR-137 suppressed the immediate downstream effector of Cdc42, PAK signaling. Our results suggest that miR-137 may have a tumor suppressor function by directly targeting Cdc42 to inhibit the proliferation and invasion activities of colorectal cancer cells. They raise an interesting possibility that Cdc42 activity and function can be controlled by miRNAs in addition to the classic regulators such as guanine nucleotide exchange factors and GTPase-activating proteins.

Geranylgeranyltransferase type I (GGTase-I) deficiency hyperactivates macrophages and induces erosive arthritis in mice

RHO family proteins are important for the function of inflammatory cells. They are modified with a 20-carbon geranylgeranyl lipid in a process catalyzed by protein geranylgeranyltransferase type I (GGTase-I). Geranylgeranylation is viewed as essential for the membrane targeting and activity of RHO proteins. Consequently, inhibiting GGTase-I to interfere with RHO protein activity has been proposed as a strategy to treat inflammatory disorders. However, here we show that mice lacking GGTase-I in macrophages develop severe joint inflammation resembling erosive rheumatoid arthritis. The disease was initiated by the GGTase-I-deficient macrophages and was transplantable and reversible in bone marrow transplantation experiments. The cells accumulated high levels of active GTP-bound RAC1, CDC42, and RHOA, and RAC1 remained associated with the plasma membrane. Moreover, GGTase-I deficiency activated p38 and NF-κB and increased the production of proinflammatory cytokines. The results challenge the view that geranylgeranylation is essential for the activity and localization of RHO family proteins and suggest that reduced geranylgeranylation in macrophages can initiate erosive arthritis.

MiR-185 targets RhoA and Cdc42 expression and inhibits the proliferation potential of human colorectal cells

Increasing evidence in the past few years has shown that miRNAs could serve functionally as “oncogenes” or “tumor suppressor genes” and regulate multiple cellular processes relevant to carcinogenesis and cancer progression. Both RhoA and Cdc42, two members of the Rho GTPase family, are found to be upregulated in several types of human tumors including colorectal cancer, and have been implicated in cancer initiation and progression. In the present studies, we found that miR-185 expression greatly inhibited the proliferation potential of Hela cells. An examination of the predicted targets of miR-185 revealed RhoA and Cdc42 among the putative targets that are crucial for cell proliferation. A genomic sequence analysis indicated that nt 1844–1852 of the RhoA 3′UTR and nt 1382–1396 of the cdc42 3′UTR encode for miR-185 target matching sequences and they are highly conserved across different species. Using a luciferase-reporter assay, we show that miR-185 expression significantly suppressed the RhoA and Cdc42 3′UTR activities, and the inhibitory effect was lost when the putative target sites for miR-185 were mutated. Consistent with these results, ectopic expression of miR-185 reduced protein levels of RhoA and Cdc42 in cells, indicating miR-185 functionally regulates RhoA and Cdc42 abundance. Similar to the effects of knocking down RhoA and/or Cdc42 expression, miR-185 effectively inhibited proliferation, induced G1 cell cycle arrest and apoptosis, and blocked invasion of colorectal cancer cells. Thus, miR-185 is a negative regulator of RhoA and Cdc42 and their cellular activities, and could inhibit proliferation and invasion of colorectal cancer cells.

Chronic Ethanol Exposure Alters the Levels, Assembly, and Cellular Organization of the Actin Cytoskeleton and Microtubules in Hippocampal Neurons in Primary Culture

The organization and dynamics of microtubules (MTs) and the actin cytoskeleton are critical for the correct development and functions of neurons, including intracellular traffic and signaling. In vitro ethanol exposure impairs endocytosis, exocytosis, and nucleocytoplasmic traffic in astrocytes and alters endocytosis in cultured neurons. In astrocytes, these effects relate to changes in the organization and/or function of MTs and the actin cytoskeleton. To evaluate this possibility in hippocampal cultured neurons, we analyzed if chronic ethanol exposure affects the levels, assembly, and cellular organization of both cytoskeleton elements and the possible underlying mechanisms of these effects by morphological and biochemical methods. In the experiments described below, we provide the first evidence that chronic alcohol exposure decreases the amount of both filamentous actin and polymerized tubulin in neurons and that the number of MTs in dendrites lowers in treated cells. Alcohol also diminishes the MT-associated protein-2 levels, which mainly localizes in the somatodendritic compartment in neurons. Ethanol decreases the levels of total Rac, Cdc42, and RhoA, three small guanosine triphosphatases (GTPases) involved in the organization and dynamics of the actin cytoskeleton and MTs. Yet when alcohol decreases the levels of the active forms (GTP bound) of Rac1 and Cdc42, it does not affect the active form of RhoA. We also investigated the levels of several effector and regulator molecules of these GTPases to find that alcohol induces heterogeneous results. In conclusion, our results show that MT, actin cytoskeleton organization, and Rho GTPase signaling pathways are targets for the toxic effects of ethanol in neurons.