Project description:Liver-specific deletion of ROCK1 leads to a significant decrease in gene expression of key molecules invovled in lipid systhesis. The study was designed to determine whether hepatic ROCK1 plays a role in the regulation of fatty acid synthesis

Project description:ROCK1 KD in U87 cells Samples were collected at 24h or 48h after siRNA ROCK1 transfection or control siRNA (NSC) in U87 cells

Project description:Rho-associated kinase (ROCK) and zipper-interacting protein kinase (ZIPK) have been implicated in diverse physiological functions, including smooth muscle contraction, cell proliferation, cell adhesion, apoptosis, cell migration and inflammation. Many aspects of regulation via ROCK and ZIPK, however, remain unclear. In this study, we utilized an siRNA approach to knock down ROCK1 and ZIPK in cultured human arterial smooth muscle cells. Microarray analysis was performed, using a whole-transcript expression chip, to identify changes in gene expression profiles induced by ROCK1 and ZIPK knockdown. ROCK1 knockdown affected the expression of 553 genes (355 down-regulated and 198 up-regulated), while ZIPK knockdown affected the expression of 390 genes (219 down-regulated and 171 up-regulated). A high incidence of up- and down-regulation of transcription regulator genes was observed in both ROCK1 and ZIPK knockdowns. Other markedly affected groups included transporters, kinases, peptidases, transmembrane and G protein-coupled receptors, growth factors, phosphatases and ion channels. Three microRNAs (mir-145, mir-199 and mir-622) were up-regulated by ROCK1 knockdown, whereas ZIPK knockdown had no effect on microRNA expression. 76 differentially expressed genes were common to ROCK1 and ZIPK knockdown, of which 41 were down-regulated and 26 up-regulated by both treatments, while the other 9 genes were differentially up/down-regulated. Ingenuity Pathway Analysis identified five pathways shared between the two knockdowns, which are mainly involved in cell cycle regulation. Marked differences in the effects of ROCK1 and ZIPK knockdown on the genes involved in cell cycle regulation suggested that ROCK1 and ZIPK regulate the cell cycle by different mechanisms. ROCK1, but not ZIPK knockdown significantly reduced the viability of vascular SMC. ROCK1 knockdown also affected several cytokine signaling pathways with up-regulation of 5 and down-regulation of 4 cytokine genes, in contrast to ZIPK knockdown, which affected the expression of only two cytokine genes (both down-regulated). IL-6 gene expression and secretion of IL-6 protein were up-regulated by ROCK1 knockdown, whereas ZIPK knockdown reduced IL-6 mRNA expression and IL-6 protein secretion and ROCK1 protein expression, suggesting that ROCK1 may inhibit IL-6 secretion. IL-1β mRNA and protein levels were increased in response to ROCK1 knockdown. Finally, ROCK1 but not ZIPK knockdown inhibited proliferation of vascular smooth muscle cells. We conclude that ROCK1 and ZIPK have diverse, but predominantly distinct regulatory functions in vascular smooth muscle cells.

Project description:Rho-associated kinase (ROCK) and zipper-interacting protein kinase (ZIPK) have been implicated in diverse physiological functions, including smooth muscle contraction, cell proliferation, cell adhesion, apoptosis, cell migration and inflammation. Many aspects of regulation via ROCK and ZIPK, however, remain unclear. In this study, we utilized an siRNA approach to knock down ROCK1 and ZIPK in cultured human arterial smooth muscle cells. Microarray analysis was performed, using a whole-transcript expression chip, to identify changes in gene expression profiles induced by ROCK1 and ZIPK knockdown. ROCK1 knockdown affected the expression of 553 genes (355 down-regulated and 198 up-regulated), while ZIPK knockdown affected the expression of 390 genes (219 down-regulated and 171 up-regulated). A high incidence of up- and down-regulation of transcription regulator genes was observed in both ROCK1 and ZIPK knockdowns. Other markedly affected groups included transporters, kinases, peptidases, transmembrane and G protein-coupled receptors, growth factors, phosphatases and ion channels. Three microRNAs (mir-145, mir-199 and mir-622) were up-regulated by ROCK1 knockdown, whereas ZIPK knockdown had no effect on microRNA expression. 76 differentially expressed genes were common to ROCK1 and ZIPK knockdown, of which 41 were down-regulated and 26 up-regulated by both treatments, while the other 9 genes were differentially up/down-regulated. Ingenuity Pathway Analysis identified five pathways shared between the two knockdowns, which are mainly involved in cell cycle regulation. Marked differences in the effects of ROCK1 and ZIPK knockdown on the genes involved in cell cycle regulation suggested that ROCK1 and ZIPK regulate the cell cycle by different mechanisms. ROCK1, but not ZIPK knockdown significantly reduced the viability of vascular SMC. ROCK1 knockdown also affected several cytokine signaling pathways with up-regulation of 5 and down-regulation of 4 cytokine genes, in contrast to ZIPK knockdown, which affected the expression of only two cytokine genes (both down-regulated). IL-6 gene expression and secretion of IL-6 protein were up-regulated by ROCK1 knockdown, whereas ZIPK knockdown reduced IL-6 mRNA expression and IL-6 protein secretion and ROCK1 protein expression, suggesting that ROCK1 may inhibit IL-6 secretion. IL-1β mRNA and protein levels were increased in response to ROCK1 knockdown. Finally, ROCK1 but not ZIPK knockdown inhibited proliferation of vascular smooth muscle cells. We conclude that ROCK1 and ZIPK have diverse, but predominantly distinct regulatory functions in vascular smooth muscle cells. Human coronary artery smooth muscle cells were transfected with siRNA targeting ROCK1 or ZIPK or with negative control siRNA that does not target any gene product. 48 h later, total RNA was isolated, reverse transcribed, amplified, labeled with the Ambion WT Express kit and hybridized to Human Gene 1.0 ST arrays (Affymetrix) at 45 oC for 16 h. The probe arrays were washed and stained on an Affymetrix GeneChip Fluidics-450 and scanned on an Affymetrix GeneChip Scanner 3000 7G System. Triplicates were prepared under all three conditions for microarray analysis.

Project description:The objective of this study is to explore gene expression profiles of liver tissues in response to choline defficient diet by DNA microarray data analysis. Male CD-1mice (5 weeks) were fed either a choline-deficient diet (F2CDD, Oriental Yeast) or F2CDD plus 0.2% choline bitartrate for 3 weeks. Liver tissue from control versus choline-deficient samples were analyzed for gene expression on an Agilent Whole Mouse Genome Microarray.

Project description:Transcriptional profiling of human hepatoellular carcinoma (HCC) cell line: MHCC-97H comparing control untreated MHCC-97H cells with MHCC-97H cells overexpressed ROCK1 protein. Goal was to determine the effect of ROCK1 on global MHCC-97H cell mRNA and lncRNA expression. Transcriptional profiling of human hepatoellular carcinoma (HCC) cell line: MHCC-97H comparing control untreated MHCC-97H cells with MHCC-97H cells overexpressed ROCK2 protein. Goal was to determine the effect of ROCK2 on global MHCC-97H cell mRNA and lncRNA expression. Transcriptional profiling of human hepatoellular carcinoma (HCC) cell line: MHCC-97H comparing MHCC-97H cells overexpressed ROCK1 with MHCC-97H cells overexpressed ROCK2 protein. Goal was to determine the distinction of ROCK1 & 2 on global MHCC-97H cell mRNA and lncRNA expression.

Project description:Gene expression profile of liver obtained from liver-specific Me1-deficient mice challenged with high-fat diet

Project description:Cytoplasmic long non coding RNAs have been shown to act at many different levels to control post-transcriptional gene expression; though their role in translational control is still poorly understood. Here we show that lnc-31 is a translational activator of Rock1, a negative regulator of myogenesis which prevents the exit of myoblasts from the cell cycle. This activity well correlates with the described role of lnc-31 in supporting myoblast proliferation. We show that lnc-31 binds the translational regulator YB-1 and targets the Rock1 mRNA by direct base pair interaction. We present evidences that lnc-31 stabilizes YB-1 on the Rock1 mRNA; this effect would in turn allow the YB-1-dependent remodelling of the Rock1 5’UTR and the promotion of its translation.

Project description:Expression profiles of skeletal muscle from transgenic mouse with liver specific overexpression

Project description:To identify kinases in immune cells of patients with SR-GVHD we isolated leukocytes and specifically enriched kinases via kinet-beads-technology. Rho Kinase Type 1 (ROCK1) was identified as the most abundant kinase in SR-GVHD.