ROCK-I and ROCK-II cooperatively regulate closure of eyelid and ventral body wall in mouse embryo

Rho GTPases in hepatocellular carcinoma

Rho GTPases are major regulators of signal transduction pathways and play key roles in processes including actin dynamics, cell cycle progression, cell survival and gene expression, whose deregulation may lead to tumorigenesis. A growing number of in vitro and in vivo studies using tumor-derived cell lines, primary tumors and animal cancer models strongly suggest that altered Rho GTPase signaling plays an important role in the initiation as well as in the progression of hepatocellular carcinoma (HCC), one of the deadliest human cancers in the world. These alterations can occur at the level of the GTPases themselves or of one of their regulators or effectors. The participation into the tumorigenic process can occur either through the over-expression of one of these components which presents an oncogenic activity as illustrated with RhoA and C or through the attenuation of the expression of a component presenting tumor suppressor activity as for Cdc42 or the RhoGAP, DLC-1. Consequently, these observations reflect the heterogeneity and the complexity of liver carcinogenesis. Recently, pharmacological approaches targeting Rho GTPase signaling have been used in HCC-derived models with relative success but remain to be validated in more physiologically relevant systems. Therefore, therapeutic approaches targeting Rho GTPase signaling may provide a novel alternative for anti-HCC therapy.

Downregulation of ROCK-I and ROCK-II gene expression in the cadmium-induced ventral body wall defect chick model

PURPOSE

In the chick embryo, administration of the heavy metal cadmium (Cd) after 60 h incubation induces the ventral body wall defect (VBW) with similarities to the human omphalocele. Rho-associated coiled-coil-containing protein kinase (ROCK) I and ROCK-II mediate signalling from Rho to the actin cytoskeleton in the Wnt non-canonical pathway. ROCK-I knockout (KO), ROCK-II KO, and ROCK-I/ROCK-II double heterozygous mice have been shown to cause failure of closure of the VBW. The exact mechanism by which Cd acts in the Wnt signalling pathway still remains unclear. We designed this study to test the hypothesis, that the gene expression levels of ROCK-I and ROCK-II are downregulated during the critical period of embryogenesis in the Cd-induced VBW defect chick model.

METHODS

Chick embryos were harvested 1 h (1H), 4 h (4H), and 8 h (8H) after treatment of cadmium and divided into two groups: control (n = 8 at each time point), and Cd (n = 8 at each time point). Real-time RT-PCR was performed to evaluate the relative mRNA levels of ROCK-I and ROCK-II expression in the Cd-induced VBW defect chick model. Differences between the two groups at each time point were tested by using Mann-Whitney's U test and statistical significance was accepted at P < 0.05.

RESULTS

The relative mRNA levels of ROCK-I and ROCK-II at 4H were significantly decreased in Cd group compared to controls (P < 0.01 and P < 0.001, respectively). The expression levels of ROCK-I and ROCK-II at 1H and 8H were not significantly different between Cd group and controls.

CONCLUSIONS

Our results provide evidence, for the first time, that the gene expression levels of ROCK-I and ROCK-II are significantly downregulated at 4 h after treatment of Cd in the VBW defect model of chick embryo. We speculate that the downregulation of ROCK-I and ROCK-II gene expressions during this narrow window of embryogenesis may cause VBW defect by disrupting Wnt non-canonical pathway.

ROCK1 mediates leukocyte recruitment and neointima formation following vascular injury

Although Rho-associated kinase (ROCK) activity has been implicated in cardiovascular diseases, the tissue- and isoform-specific roles of ROCKs in the vascular response to injury are not known. To address the role of ROCKs in this process, we generated haploinsufficient Rock1 (Rock1(+/-)) and Rock2 (Rock2(+/-)) mice and performed carotid artery ligations. Following this intervention, we found reduced neointima formation in Rock1(+/-) mice compared with that of WT or Rock2(+/-) mice. This correlated with decreased vascular smooth muscle cell proliferation and survival, decreased levels proinflammatory adhesion molecule expression, and reduced leukocyte infiltration. In addition, thioglycollate-induced peritoneal leukocyte recruitment and accumulation were substantially reduced in Rock1(+/-) mice compared with those of WT and Rock2(+/-) mice. To determine the role of leukocyte-derived ROCK1 in neointima formation, we performed reciprocal bone marrow transplantation (BMT) in WT and Rock1(+/-) mice. Rock1(+/-) to WT BMT led to reduced neointima formation and leukocyte infiltration following carotid ligation compared with those of WT to WT BMT. In contrast, WT to Rock1(+/-) BMT resulted in increased neointima formation. These findings indicate that ROCK1 in BM-derived cells mediates neointima formation following vascular injury and suggest that ROCK1 may represent a promising therapeutic target in vascular inflammatory diseases.

Applications for ROCK kinase inhibition

ROCK kinases, which play central roles in the organization of the actin cytoskeleton, are tantalizing targets for the treatment of human diseases. Deletion of ROCK I in mice revealed a role in the pathophysiological responses to high blood pressure, and validated ROCK inhibition for the treatment of specific types of cardiovascular disease. To date, the only ROCK inhibitor employed clinically in humans is fasudil, which has been used safely in Japan since 1995 for the treatment of cerebral vasospasm. Clinical trials, mostly focusing on the cardiovascular system, have uncovered beneficial effects of fasudil for additional indications. Intriguing recent findings also suggest significant potential for ROCK inhibitors in the production and implantation of stem cells for disease therapies.

Actin stress fibres

Animal cell movement is effected through a combination of protrusive and contractile events. Non-muscle cells contain stress fibres - bundles of actomyosin that are the major mediators of cell contraction and that can be compared to the highly organised actomyosin arrays of muscle cells. Recent studies have defined regulatory mechanisms that control stress fibre formation, placing the ROCK protein kinase at the centre of a complex signalling network controlling actomyosin contractility and stress fibre assembly. As we uncover the details of stress fibre construction, it is becoming clear that different categories of stress fibres exist. Some of these structures are less suited for cell motility and more suited to static contraction. In keeping with this, many specialised contractile cell types use stress fibres to remodel tissues and extracellular matrix.

Omphalocele induction in the chick embryo by administration of cadmium

BACKGROUND

Ventral body wall (VBW) defects occur in 1:2000 live births. We examined the association of VBW defect with somite abnormality and lordosis in the chick using in vitro and in ovo methods.

METHODS

Explanted chick embryos were treated at 60 hours with 50 microL sodium acetate or 0.001% cadmium acetate solution to produce VBW defects. Mortality and abnormality rates were assessed. A further cohort of chicks was treated in ovo by dropping 50 microL 0.001% to 0.01% cadmium acetate onto the embryo and allowing development to 16.5 days for further assessment of the defect and skeletal staining with alcian blue and alizarin red.

RESULTS

Cadmium treatment at 24 hours induced VBW defects in chicks treated in both shell-less culture and in ovo. Material herniating through the VBW defects was covered by a membrane in all fresh specimens. Membrane removal revealed large defects containing liver and bowel. These criteria clearly indicate that the defect observed is an omphalocele. Affected embryos had reduced somite numbers within 24 hours. Chicks exhibiting exomphalos at 16.5 days invariably had lumbosacral lordosis.

CONCLUSIONS

The cadmium-treated chick embryo is a reliable model for exomphalos. A positive association was found between exomphalos and lumbar lordosis in the chick.

Genetic and pharmacological inhibition of Rho-associated kinase II enhances adipogenesis

Rho-associated kinase (ROCK) regulates reorganization of actin cytoskeleton. During adipogenesis, the structure of filamentous actin is converted from long stress fibers to cortical actin, suggesting that the ROCK is involved in adipogenesis. Two ROCK isoforms have been identified: ROCK-I and ROCK-II. However, pharmacological inhibitors of ROCK cannot distinguish two ROCK isoforms. In the present study, we examined the role of ROCK in adipogenesis and actin cytoskeleton using genetic and pharmacological approaches. Y-27632, which inhibits the activity of both ROCK isoforms, enhanced adipogenesis through the up-regulation of adipogenic transcription factors in 3T3-L1 cells. Furthermore, Y-27632 restored inhibition of adipogenesis by lysophosphatidic acid, which activates Rho. Regarding actin cytoskeleton, Y-27632 disrupted stress fibers in 3T3-L1 preadipocytes. Next, we analyzed adipogenesis of mouse embryonic fibroblasts (MEFs) derived from ROCK-I and ROCK-II knock-out mice, respectively. Adipogenesis of ROCK-II (-/-) MEFs was markedly enhanced compared with wild-type MEFs while that of ROCK-I (-/-) MEFs was not. In contrast to pharmacological approaches, no obvious alteration was found in actin cytoskeleton of ROCK-II (-/-) MEFs compared with wild-type MEFs. In 3T3-L1 cells, knockdown of ROCK-II by RNA interference enhanced the expression of adipogenic transcription factors while that of ROCK-I did not. Moreover, Y-27632 inhibited IRS-1 serine phosphorylation and enhanced Akt phosphorylation in 3T3-L1 preadipocytes. Similarly, Akt phosphorylation in ROCK-II (-/-) MEFs was augmented compared with wild-type MEFs. In conclusion, inhibition of ROCK-II, not ROCK-I, enhances adipogenesis accompanied by the up-regulation of adipogenic transcription factors. Augmentation of insulin signaling may contribute to the enhancement of adipogenesis.

ROCK2 and its alternatively spliced isoform ROCK2m positively control the maturation of the myogenic program

Signal transduction cascades involving Rho-associated kinases (ROCK), the serine/threonine kinases downstream effectors of Rho, have been implicated in the regulation of diverse cellular functions including cytoskeletal organization, cell size control, modulation of gene expression, differentiation, and transformation. Here we show that ROCK2, the predominant ROCK isoform in skeletal muscle, is progressively up-regulated during mouse myoblast differentiation and is highly expressed in the dermomyotome and muscle precursor cells of mouse embryos. We identify a novel and evolutionarily conserved ROCK2 splicing variant, ROCK2m, that is preferentially expressed in skeletal muscle and strongly up-regulated during in vivo and in vitro differentiation processes. The specific knockdown of ROCK2 or ROCK2m expression in C2C12 myogenic cells caused a significant and selective impairment of the expression of desmin and of the myogenic regulatory factors Mrf4 and MyoD. We demonstrate that in myogenic cells, ROCK2 and ROCK2m are positive regulators of the p42 and p44 mitogen-activated protein kinase-p90 ribosomal S6 kinase-eucaryotic elongation factor 2 intracellular signaling pathways and, thereby, positively regulate the hypertrophic effect elicited by insulin-like growth factor 1 and insulin, linking the multifactorial functions of ROCK to an important control of the myogenic maturation.

GTP-binding proteins of the Rho/Rac family: regulation, effectors and functions in vivo

Rho/Rac proteins constitute a subgroup of the Ras superfamily of GTP hydrolases. Although originally implicated in the control of cytoskeletal events, it is currently known that these GTPases coordinate diverse cellular functions, including cell polarity, vesicular trafficking, the cell cycle and transcriptomal dynamics. In this review, we will provide an overview on the recent advances in this field regarding the mechanism of regulation and signaling, and the roles in vivo of this important GTPase family.

Molecular characterization of the effects of Y-27632

Many key cellular functions, such as cell motility and cellular differentiation are mediated by Rho-associated protein kinases (ROCKs). Numerous studies have been conducted to examine the ROCK signal transduction pathways involved in these motile and contractile events with the aid of pharmacological inhibitors such as Y-27632. However the molecular mechanism of action of Y-27632 has not been fully defined. To assess the relative contribution of these Rho effectors to the effects of Y-27632, we compared the cytoskeletal phenotype, wound healing and neurite outgrowth in cells treated with Y-27632 or subjected to knockdown with ROCK-I, ROCK-II or PRK-2- specific siRNAs. Reduction of ROCK-I enhances the formation of thin actin-rich membrane extensions, a phenotype that closely resembles the effect of Y-27632. Knockdown of ROCK II or PRK-2, leads to the formation of disc-like extensions and thick actin bundles, respectively. The effect of ROCK-I knockdown also mimicked the effect of Y-27632 on wound closer rates. ROCK-I knockdown and Y-27632 enhanced wound closure rates, while ROCK-II and PRK-2 were not appreciably different from control cells. In neurite outgrowth assays, knockdown of ROCK-I, ROCK-II or PRK-2 enhances neurite lengths, however no individual knockdown stimulated neurite outgrowth as robustly as Y-27632. We conclude that several kinases contribute to the global effect of Y-27632 on cellular responses.

Rho kinase in the regulation of cell death and survival

Rho kinase (ROCK) belongs to a family of serine/threonine kinases that are activated via interaction with Rho GTPases. ROCK is involved in a wide range of fundamental cellular functions, such as contraction, adhesion, migration, and proliferation. Recent studies have shown that ROCK plays an important role in the regulation of apoptosis in various cell types and animal disease models. Two ROCK isoforms, ROCK1 and ROCK2, are assumed to be function redundant, this based largely on kinase construct overexpression and chemical inhibitors (Y27632 and fasudil) which inhibit both ROCK1 and ROCK2. Gene targeting and RNA interference approaches allow further dissection of distinct cellular, physiological, and patho-physiological functions of the two ROCK isoforms. This review, based on recent molecular, cellular, and animal studies, focuses on the current understanding of ROCK signaling in the regulation of apoptosis and highlights new findings from recently generated ROCK-deficient mice.

Somatic excision demonstrates that c-Jun induces cellular migration and invasion through induction of stem cell factor

Cancer cells arise through sequential acquisition of mutations in tumor suppressors and oncogenes. c-Jun, a critical component of the AP-1 complex, is frequently overexpressed in diverse tumor types and has been implicated in promoting cellular proliferation, migration, and angiogenesis. Functional analysis of candidate genetic targets using germ line deletion in murine models can be compromised through compensatory mechanisms. As germ line deletion of c-jun induces embryonic lethality, somatic deletion of the c-jun gene was conducted using floxed c-jun (c-jun(f/f)) conditional knockout mice. c-jun-deleted cells showed increased cellular adhesion, stress fiber formation, and reduced cellular migration. The reduced migratory velocity and migratory directionality was rescued by either c-Jun reintroduction or addition of secreted factors from wild-type cells. An unbiased analysis of cytokines and growth factors, differentially expressed and showing loss of secretion upon c-jun deletion, identified stem cell factor (SCF) as a c-Jun target gene. Immunoneutralizing antibody to SCF reduced migration of wild-type cells. SCF addition rescued the defect in cellular adhesion, cellular velocity, directional migration, transwell migration, and cellular invasion of c-jun(-/-) cells. c-Jun induced SCF protein, mRNA, and promoter activity. Induction of the SCF promoter required the c-Jun DNA-binding domain. c-Jun bound to the SCF promoter in chromatin immunoprecipitation assays. Mutation of the c-Jun binding site abolished c-Jun-mediated induction of the SCF promoter. These studies demonstrate an essential role of c-Jun in cellular migration through induction of SCF.

Fibronectin matrix assembly requires distinct contributions from Rho kinases I and -II

Extracellular matrix is integral to tissue architecture and regulates many aspects of cell behavior. Fibronectin matrix assembly involves the actin cytoskeleton and the small GTPase RhoA, but downstream signaling is not understood. Here, down-regulation of either rho kinase isoform (ROCK I or -II) by small interfering RNA treatment blocked fibronectin matrix assembly, although the phenotypes were distinct and despite persistence of the alternate kinase. Remnant fibronectin on ROCK-deficient fibroblasts was mostly punctate and more deoxycholate soluble compared with controls. Fibronectin matrix assembly defects in ROCK-deficient cells did not result from decreased synthesis/secretion, altered fibronectin mRNA splicing, metalloproteinase activity, or alpha5beta1 integrin dysfunction. Rescue could be effected by ROCK protein restoration or phosphomimetic myosin light chain expression. However, the effect of ROCK I deficiency on fibronectin matrix assembly was secondary to altered cell surface morphology, rich in filopodia, resulting from high GTP-Cdc42 levels. Total internal reflection microscopy revealed that a submembranous pool of myosin light chain in control cells was missing in ROCK II-deficient cells and replaced by stress fibers. Together, two rho kinases contribute to fibronectin matrix assembly in a different manner and cortical myosin II-driven contractility, but not stress fibers, may be critical in this activity.

A new serine/threonine protein kinase, Omphk1, essential to ventral body wall formation

Here, we report a new serine/threonine protein kinase of the SNF1 subfamily Omphk1. Two Omphk homologues exist in each vertebrate species, and one homologue exists in Drosophila and Caenorhabditis elegans; the kinase domain is highly conserved among these homologues, and several domains are conserved among vertebrate Omphk. Omphk1 expression dynamically changes in the developing central nervous system, is found ubiquitously in epidermis, and is present uniquely in several other tissues. Its expression is also found in each tissue associated with the ventral body wall closure: the primary body wall composed of primitive ectoderm and each component of the secondary body wall. Concomitantly, its null mutant exhibits omphalocele with a failure in closure of the secondary body wall. There are no apparent gross morphological defects in brain, however, despite the unique Omphk1 expression in this tissue.

Nuclear Rho kinase, ROCK2, targets p300 acetyltransferase

Rho-associated coiled-coil protein kinase (ROCK) is an effector for the small GTPase Rho and plays a pivotal role in diverse cellular activities, including cell adhesion, cytokinesis, and gene expression, primarily through an alteration of actin cytoskeleton dynamics. Here, we show that ROCK2 is localized in the nucleus and associates with p300 acetyltransferase both in vitro and in cells. Nuclear ROCK2 is present in a large protein complex and partially cofractionates with p300 by gel filtration analysis. By immunofluorescence, ROCK2 partially colocalizes with p300 in distinct insoluble nuclear structures. ROCK2 phosphorylates p300 in vitro, and nuclear-restricted expression of constitutively active ROCK2 induces p300 phosphorylation in cells. p300 acetyltransferase activity is dependent on its phosphorylation status in cells, and p300 phosphorylation by ROCK2 results in an increase in its acetyltransferase activity in vitro. These observations suggest that nucleus-localized ROCK2 targets p300 for phosphorylation to regulate its acetyltransferase activity.