Cardiomyopathy Mutations in the Tail of β-Cardiac Myosin Modify the Coiled-coil Structure and Affect Integration into Thick Filaments in Muscle Sarcomeres in Adult Cardiomyocytes

It is unclear why mutations in the filament-forming tail of myosin heavy chain (MHC) cause hypertrophic or dilated cardiomyopathy as these mutations should not directly affect contraction. To investigate this, we first investigated the impact of five hypertrophic cardiomyopathy-causing (N1327K, E1356K, R1382W, E1555K, and R1768K) and one dilated cardiomyopathy-causing (R1500W) tail mutations on their ability to incorporate into muscle sarcomeres in vivo. We used adenoviral delivery to express full-length wild type or mutant enhanced GFP-MHC in isolated adult cardiomyocytes. Three mutations (N1327K, E1356K, and E1555K) reduced enhanced GFP-MHC incorporation into muscle sarcomeres, whereas the remainder had no effect. No mutations significantly affected contraction. Fluorescence recovery after photobleaching showed that fluorescence recovery for the mutation that incorporated least well (N1327K) was significantly faster than that of WT with half-times of 25.1 ± 1.8 and 32.2 ± 2.5 min (mean ± S.E.), respectively. Next, we determined the effects of each mutation on the helical properties of wild type and seven mutant peptides (7, 11, or 15 heptads long) from the myosin tail by circular dichroism. R1382W and E1768K slightly increased the α-helical nature of peptides. The remaining mutations reduced α-helical content, with N1327K showing the greatest reduction. Only peptides containing residues 1301–1329 were highly α-helical suggesting that this region helps in initiation of coiled coil. These results suggest that small effects of mutations on helicity translate into a reduced ability to incorporate into sarcomeres, which may elicit compensatory hypertrophy.     

FOG2 Protein Down-regulation by Transforming Growth Factor-β1-induced MicroRNA-200b/c Leads to Akt Kinase Activation and Glomerular Mesangial Hypertrophy Related to Diabetic Nephropathy

Glomerular hypertrophy is a hallmark of diabetic nephropathy. Akt kinase activated by transforming growth factor-β1 (TGF-β) plays an important role in glomerular mesangial hypertrophy. However, the mechanisms of Akt activation by TGF-β are not fully understood. Recently, miR-200 and its target FOG2 were reported to regulate the activity of phosphatidylinositol 3-kinase (the upstream activator of Akt) in insulin signaling. Here, we show that TGF-β activates Akt in glomerular mesangial cells by inducing miR-200b and miR-200c, both of which target FOG2, an inhibitor of phosphatidylinositol 3-kinase activation. FOG2 expression was reduced in the glomeruli of diabetic mice as well as TGF-β-treated mouse mesangial cells (MMC). FOG2 knockdown by siRNAs in MMC activated Akt and increased the protein content/cell ratio suggesting hypertrophy. A significant increase of miR-200b/c levels was detected in diabetic mouse glomeruli and TGF-β-treated MMC. Transfection of MMC with miR-200b/c mimics significantly decreased the expression of FOG2. Conversely, miR-200b/c inhibitors attenuated TGF-β-induced decrease in FOG2 expression. Furthermore, miR-200b/c mimics increased the protein content/cell ratio, whereas miR-200b/c inhibitors abrogated the TGF-β-induced increase in protein content/cell. In addition, down-regulation of FOG2 by miR-200b/c could activate not only Akt but also ERK, which was also through PI3K activation. These data suggest a new mechanism for TGF-β-induced Akt activation through FOG2 down-regulation by miR-200b/c, which can lead to glomerular mesangial hypertrophy in the progression of diabetic nephropathy.     

Effects of jaw adductor hypertrophy on buccal expansions during feeding of air breathing catfishes (Teleostei,Clariidae)

Some species of Clariidae (air breathing catfishes) have extremely well developed (hypertrophied) jaw closing muscles that increase the maximal biting force of these species. As these enlarged jaw muscles tightly cover the suspensoria, which are firmly connected to the neurocranium, we expect diminished lateral expansions during suction for species with hypertrophied jaw muscles. In turn, this could imply a reduced suction performance for these species. Compared to Clarias gariepinus, which has relatively small jaw closers, Clariallabes longicauda shows a clear hypertrophy of the jaw adductors. A kinematic analysis of prey capture in these two species is presented here. As predicted, Clariallabes longicauda shows less lateral expansion (average abduction of the hyoids of 19.0°) than Clarias gariepinus (abduction of 31.1°). However, our data indicate that the decrease in lateral expansion capacity in the species with excessive adductor development is compensated for by a larger and faster ventral expansion of the buccal cavity by depression of the hyoid.     

Forskolin fails to activate L-type calcium current in hypertrophied cardiomyocytes of chronically hypoxic rats

We have shown that the contractile, cytosolic calcium ([Ca2+]i) and cyclic AMP (cAMP) responses to beta-adrenoceptor stimulation are attenuated in ventricular myocytes of chronically hypoxic (CH) rats. The aim of this study was to examine the effect of forskolin on the L-type Ca2+ current in CH hypertrophied ventricular myocytes. Patch-clamp recording of the L-type Ca2+ current was measured in right ventricular myocytes of normoxic control and CH rats exposed to 10% inspired oxygen for 4 weeks. The breadth, but not the length, of CH myocytes was significantly greater than that of the control group. Activation of beta-adrenoceptor with isoproterenol (0.1 microM) increased the peak Ca2+ current by 83% in the normoxic control but the increase of peak Ca2+ current was not significant in the CH myocytes. Forskolin (0.1 - 1 microM), an activator of adenylyl cyclase, increased the peak Ca2+ current by 49% - 102% in the normoxic controls but it did not cause significant change of the peak Ca2+ current in CH myocytes. These results suggest an absence of forskolin-induced activation of Ca2+ current in hypertrophied ventricular myocytes during chronic hypoxia. The failure of activation of the Ca2+ current is consistent with the idea that adenylyl cyclase function is down-regulated in CH hypertrophied myocytes.     

Mechano-electric feedback and arrhythmias

The mechanical state of the heart feeds back to modify cardiac rate and rhythm. Mechanical stretch of myocardial tissue causes immediate and chronic responses that lead to the common end point of arrhythmia. This review provides a brief summary of the author's personal choice of contributions that she considers have fostered our understanding of the role of mechano-electric feedback in arrhythmogenesis.

Acute mechanical stretch reversibly depolarises the cell membrane and shortens the action potential duration. These electrophysiological changes are related to the activation of mechano-sensitive ion channels. Several different ion channels are involved in the sensing of stretch, among them K⁺-selective, Cl⁻-selective, non-selective, and ATP-sensitive K⁺ channels. Sodium and Ca²⁺ entering the cells via non-selective ion channels are thought to contribute to the genesis of stretch-induced arrhythmia. Mechano-sensitive channels have been cloned from non-vertebrate and vertebrate species.

Chronic stress on the heart activates gene expression in cardiomyocytes and non-myocytes. The signal transduction involves atrial natriuretic peptides and growth factors that initiate remodelling processes leading to hypertrophy which in turn may contribute to the electrical instability of the heart by increasing the responsiveness of mechano-sensitive channels. Selective block of these channels could provide some new form of treatment of mechanically induced arrhythmias, although at present there are no drugs available with sufficient selectivity. Detailed understanding of how mechanical strain on myocardial cells is translated into channel activation will allow to identify new targets for putative antiarrhythmic drugs.     

Integrin-linked kinase is a central mediator in angiotensin II type 1- and chemokine receptor CXCR4 signaling in myocardial hypertrophy

Inflammation and pro-hypertrophic signaling are important for development and progression of myocardial hypertrophy (LVH) and chronic heart failure (CHF). Here we investigated the relevance of integrin-linked kinase (ILK) for chemokine receptor CXCR4- and angiotensin II type 1-triggered signaling and its regulation and role in cardiac remodeling.Using ELISA, real-time-PCR, and Western blotting, the present study demonstrates that SDF-1 and its receptor CXCR4 are up-regulated in plasma and left ventricles, respectively, in mouse models of cardiac hypertrophy (transaortic constriction, transgenic cardiac-specific overexpression of rac1) and in human CHF in association with increased cardiac ILK-expression. In isolated cardiomyocytes, ILK is activated by CXCR4-ligation and necessary for SDF-1-triggered activation of rac1, NAD(P)H oxidase, and release of reactive oxygen species. Importantly, the pro-hypertrophic peptide angiotensin II induces ILK-activation dependent on rac1 in cardiomyocytes, where ILK is necessary for angiotensin II-mediated stimulation of hypertrophy genes and protein synthesis.We conclude that in both SDF-1- and angiotensin II-triggered signaling, ILK is a central mediator of rac1-induced oxidative stress and myocardial hypertrophy.     

Growth pattern switch of renal cells and expression of cell cycle related proteins at the early stage of diabetic nephropathy

Renal hypertrophy, partly due to cell proliferation and hypertrophy, has been found correlated to renal function deterioration in diabetes mellitus. We screened the up-regulated cell cycle related genes to investigate cell growth and the expression of cell cycle regulating proteins at the early stage of diabetic nephropathy using STZ-induced diabetic rats. Cyclin E, CDK(2) and P(27) were found significantly up-regulated in diabetic kidney. Increased cell proliferation in the kidney was seen at day 3, peaked at day 5, and returned to normal level at day 30. Cyclin E and CDK(2) expression also peeked at day 5 and P(27) activity peaked at day 14. These findings indicate that a hyperplastic growth period of renal cells is followed by a hypertrophic growth period at the early stage of diabetes. The growth pattern switch may be regulated by cell cycle regulating proteins, Cyclin E, CDK(2), and P(27).     

压力后负荷增高大鼠心肌肥厚向心力衰竭的转变

目的观察单纯腹主动脉缩窄造成的心肌肥厚能否转变成为心力衰竭。方法实验选用8周龄的Wistar大鼠,使用7-0号尼龙线对其肾上腹主动脉进行缩窄手术,造成后负荷性心肌肥厚模型(LVH,n=10),同时设置假手术组(Sham,n=10)和正常组(Con,n=10)作为对照。术后第20周和第38周使用超声多普勒和多导生理仪对大鼠血流动力学进行检测。解剖后取出心脏,计算心脏/体重比,并通过HE染色和天狼猩红染色观察心脏形态和纤维化程度。结果腹主动脉结扎后第20周,LVH组大鼠心室壁肥厚,舒张功能下降(E/Aratio:LVH组:1.0±0.25,Con组:1.6±0.12)。术后38周,左心室壁肥厚程度有所下降,但是心室腔扩大,心脏收缩和舒张功能明显下降(EF:LVH组:44.8±8.42,Con组:70.9±5.19;MaxdP/dt:LVH组:4916±1267.3,Con组:14225±932.1;MindP/dt:LVH组:-3246±1217.3,Con组:-12138±725.2)。腹主动脉缩窄术后的动物心脏重量明显增加(3.58±0.32vs.2.34±0.15),HE染色和天狼猩红染色显示LVH组大鼠在术后38周心脏纤维化明显。结论腹主动脉缩窄造成的后负荷增高动物模型首先出现向心性心肌肥厚,伴以舒张功能下降,进而收缩功能下降,发展为心力衰竭。