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Target Concepts:
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Query: EC:3.4.23.15 (
renin
)
35,795
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
It is known that mechanical stress directly changes the conformation of the functional proteins, or directly activates enzymes such as phospholipase in the plasma membrane. The integrin-cytoskeleton complex may be an alternative candidate structure for a mechanoreceptor and a transducer. The cytoskeleton has been also shown to play an important role in secretion. Mechanical stress may stimulate the secretion of some cytokines or angiotensin II, which may generate multiple intracellular signals as a secondary event. External stimuli are generally transduced into the nucleus through the activation of protein kinase cascade. Stretching of cardiac myocytes stimulates the activity of PKC,
Raf-1
kinase, MAP kinase kinase. MAP kinase and S6 kinase. In cardiac myocytes, mechanical stress directly induces gene expression as well as protein synthesis. Immediate early genes are first induced, and then fetal-type genes are reinduced. Both in hypertrophied hearts and in the experimental model of cardiac hypertrophy induced by pressure overload. Ca(2+)-ATPase content of cardiac myocytes is depressed. Reduced function of sarcoplasmic reticulum causes insufficient decrease of intracellular calcium in diastole and induces slowing of ventricular relaxation. In the interstitium of pressure overloaded hearts, the accumulation of collagen fiber is increased. The abnormal deposit leads to increased chamber stiffness and diastolic dysfunction. Furthermore, TGF-beta and tissue
renin
-angiotensin system are up-regulated in pressure overloaded hearts, both of which accelerate the interstitial fibrosis.
...
PMID:Interaction of cardiac myocytes and non-myocytes in mechanical stress-induced hypertrophy. 777 62
Angiotensin II is the major effector peptide of the
renin
-angiotensin system, and it exerts its physiologic functions via a G protein-coupled cell surface receptor called AT1. We found that in rat aortic smooth muscle cells, angiotensin II stimulated the formation of Ras-GTP, Ras-
Raf-1
complex formation, and the tyrosine phosphorylation of two important Ras GTPase-activating proteins (GAPs), p120 Ras-GAP and p190 Rho-GAP. Electroporation of anti-pp60c-src antibody into cultured, adherent smooth muscle cells blocked the angiotensin II stimulation of Ras-GAP and Rho-GAP tyrosine phosphorylation. In contrast electroporation of antibodies against c-Yes or c-Fyn had no effect. Anti-pp60c-src antibody also blocked angiotensin II-stimulated Ras activation and Ras-
Raf-1
complex formation. These data strongly suggest that a G protein-coupled receptor such as the AT1 receptor can activate the Ras protein cascade via the tyrosine kinase pp60c-src.
...
PMID:Angiotensin II controls p21ras activity via pp60c-src. 862 2
Mechanical stretch is an initial factor for cardiac hypertrophy in response to haemodynamic overload (high blood pressure). Stretch of cardiomyocytes activates second messengers such as phosphatidylinositol, protein kinase C,
Raf-1
kinase and extracellular signal-regulated protein kinases (ERKs), which are involved in increased protein synthesis. The cardiac
renin
-angiotensin system is linked to the formation of pressure-overload hypertrophy. Angiotensin II increases the growth of cardiomyocytes by an autocrine mechanism. Angiotensin II-evoked signal transduction pathways differ among cell types. In cardiac fibroblasts, angiotensin II activates ERKs through a pathway including the Gbetagamma subunit of Gi protein, Src family tyrosine kinases, Shc, Grb2 and Ras, whereas Gq and protein kinase C are important in cardiac myocytes. In addition, mechanical stretch enhances the endothelin-1 release from the cardiomyocytes. Further, the Na+ -H+ exchanger mediates mechanical stretch-induced
Raf-1
kinase and ERK activation followed by increased protein synthesis in cardiomyocytes. Not only mechanical stress, but also neurohumoral factors induce cardiac hypertrophy. The activation of protein kinase cascades by norepinephrine is induced by protein kinase A through beta-adrenoceptors as well as by protein kinase C through alpha-adrenoceptors.
...
PMID:Signalling pathways for cardiac hypertrophy. 988 20
In an in vivo study, spontaneously hypertensive rats (SHR) were treated with an angiotensin II (Ang II) type 1 receptor antagonist of candesartan or hydralazine. Untreated SHR progressively developed severe hypertension, and treatment with candesartan or hydralazine decreased blood pressure. Candesartan reduced left ventricular (LV) weight, LV wall thickness, transverse myocyte diameter, the relative amount of V3 myosin heavy chain, and interstitial fibrosis, while treatment with hydralazine slightly prevented an increase in LV wall thickness, but did not exert a significant reduction on other parameters. In an in vitro study, neonatal rat cardiomyocytes were cultured on deformable silicone dishes. Stretching cardiomyocytes activated second messengers such as protein kinase C,
Raf-1
kinase, and mitogen-activated protein (MAP) kinase, increasing protein synthesis, enhancing endothelin (ET)-1 release, activating the Na+/H+ ion exchanger. Moreover, pretreatment with candesartan diminished an increase in phenylalanine incorporation, MAP kinase activity, and c-fos gene expression induced by the stretching of cardiomyocytes. This suggests that the cardiac
renin
-angiotensin system is linked to the formation of pressure-overload hypertrophy and that Ang II increases the growth of cardiomyocytes by an autocrine mechanism. Finally, we examined the signalling pathways leading to MAP kinase activation both in cardiac myocytes and in cardiac fibroblasts. Ang II-evoked signal transduction pathways differed between cell types. In cardiac fibroblasts, Ang II activated MAP kinase through a pathway including the Gbetagamma subunit of Gi protein, Src, Shc, Grb2, and Ras, while Gq and protein kinase C were important in cardiac myocytes.
...
PMID:Role of tissue angiotensin II in myocardial remodelling induced by mechanical stress. 1007 20
Cardiac hypertrophy is an adaptive process to an increased hemodynamic overload. When cardiomyocytes cultured on silicone dishes were stretched, second messengers such as protein kinase C (PKC),
Raf-1
kinase, and mitogen-activated protein (MAP) kinases were activated, which were followed by increased protein synthesis. Moreover, pretreatment with an angiotensin II (AngII) type 1 receptor antagonist dimished an increase in protein synthesis, MAP kinase activity, and c-fos gene expression induced by the stretching of cardiomyocytes. These suggest the linkage of the cardiac
renin
-angiotensin system to the formation of pressure-overload hypertrophy. Indeed, in the stretch-conditioned medium the levels of AngII concentration were increased. Also, mechanical stretch enhanced endothelin (ET)-1 release from the cardiomyocytes and activated the Na(+)/H(+) exchanger independently of these vasoactive peptides. In the second part, we examined AngII-induced signaling pathways both in cardiac myocytes and in cardiac fibroblasts. AngII-evoked signal transduction pathways differed between cell types. In cardiac fibroblasts AngII activated MAP kinases through a pathway including the Gbetagamma subunit of Gi protein, Src, Shc, Grb2, and Ras, while Gq and PKC activation was necessary in cardiac myocytes. We further explored norepinephrine (NE)-induced signaling pathways in cardiac myocytes. NE activated
Raf-1
kinase and MAP kinases and increased amino acid uptake in cardiomyocytes of neonatal rats. beta-adrenoceptor (AR) stimulation as well and alpha1-AR stimulation was involved in NE-induced MAP kinase activation. It is noteworthy that unlike in other cell types not only PKC activation but also protein kinase A (PKA) activation increased the activities of
Raf-1
kinase and MAP kinases in cardiac myocytes and induced cell growth. Finally, we observed that beta-AR-induced activation of MAP kinases is dependent on both Gs/cAMP/PKA and Gi/Src/Ras signaling pathways and that phosphorylation of beta-AR is critical to the cross talk between these signaling pathways.
...
PMID:Molecular basis of cardiac hypertrophy. 1066 10
