Tetsuji Shinohara scite author profile

Diabetes, a disease in which carbohydrate and lipid metabolism are regulated improperly by insulin, is a serious worldwide health issue. Insulin is secreted from pancreatic beta cells in response to elevated plasma glucose, with various factors modifying its secretion. Free fatty acids (FFAs) provide an important energy source as nutrients, and they also act as signalling molecules in various cellular processes, including insulin secretion. Although FFAs are thought to promote insulin secretion in an acute phase, this mechanism is not clearly understood. Here we show that a G-protein-coupled receptor, GPR40, which is abundantly expressed in the pancreas, functions as a receptor for long-chain FFAs. Furthermore, we show that long-chain FFAs amplify glucose-stimulated insulin secretion from pancreatic beta cells by activating GPR40. Our results indicate that GPR40 agonists and/or antagonists show potential for the development of new anti-diabetic drugs.

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A Small Molecule That Blocks Fat Synthesis By Inhibiting the Activation of SREBP

Kamisuki

Mao

Abu-Elheiga

et al. 2009

Chemistry & Biology

233

217

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Sterol regulatory element binding proteins (SREBPs) are transcription factors that activate transcription of the genes involved in cholesterol and fatty acid biosynthesis. In the present study, we show that a small synthetic molecule we previously discovered to block adipogenesis is an inhibitor of the SREBP activation. The diarylthiazole derivative, now called fatostatin, impairs the activation process of SREBPs, thereby decreasing the transcription of lipogenic genes in cells. Our analysis suggests that fatostatin inhibits the ER-Golgi translocation of SREBPs through binding to their escort protein, the SREBP cleavage-activating protein (SCAP), at a distinct site from the sterol-binding domain. Fatostatin blocked increases in body weight, blood glucose, and hepatic fat accumulation in obese ob/ob mice, even under uncontrolled food intake. Fatostatin may serve as a tool for gaining further insights into the regulation of SREBP.

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Small-Conductance Calcium-Activated Potassium Channel and Recurrent Ventricular Fibrillation in Failing Rabbit Ventricles

Chua

Chang

Maruyama

et al. 2011

Circulation Research

154

211

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Rationale Fibrillation-defibrillation episodes in failing ventricles may be followed by action potential duration (APD) shortening and recurrent spontaneous ventricular fibrillation (SVF). Objective We hypothesized that activation of apamin-sensitive small-conductance Ca2+-activated K+ (SK) channels are responsible for the postshock APD shortening in failing ventricles. Methods and Results A rabbit model of tachycardia-induced heart failure was used. Simultaneous optical mapping of intracellular Ca2+ and membrane potential (Vm) was performed in failing and non-failing ventricles. Three failing ventricles developed SVF (SVF group), 9 did not (no-SVF group). None of the 10 non-failing ventricles developed SVF. Increased pacing rate and duration augmented the magnitude of APD shortening. Apamin (1 μmol/L) eliminated recurrent SVF, increased postshock APD80 in SVF group from 126±5 ms to 153±4 ms (p<0.05), in no-SVF group from147±2 ms to 162±3 ms (p<0.05) but did not change of APD80 in non-failing group. Whole cell patch-clamp studies at 36°C showed that the apamin-sensitive K+ current (IKAS) density was significantly larger in the failing than in the normal ventricular epicardial myocytes, and epicardial IKAS density is significantly higher than midmyocardial and endocardial myocytes. Steady-state Ca2+ response of IKAS was leftward-shifted in the failing cells compared with the normal control cells, indicating increased Ca2+ sensitivity of IKAS in failing ventricles. The Kd was 232 ± 5 nM for failing myocytes and 553 ± 78 nM for normal myocytes (p = 0.002). Conclusions Heart failure heterogeneously increases the sensitivity of IKAS to intracellular Ca2+, leading to upregulation of IKAS, postshock APD shortening and recurrent SVF.

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Continuous Low-Level Vagus Nerve Stimulation Reduces Stellate Ganglion Nerve Activity and Paroxysmal Atrial Tachyarrhythmias in Ambulatory Canines

et al. 2011

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Background We hypothesize that left sided low-level vagus nerve stimulation (LL-VNS) can suppress sympathetic outflow and reduce atrial tachyarrhythmias in ambulatory dogs. Methods and Results We implanted in 12 dogs a neurostimulator to stimulate left cervical vagus nerve and a radiotransmitter for continuous recording of left stellate ganglion nerve activities (SGNA), vagal nerve activities (VNA) and electrocardiograms. Group 1 dogs (N=6) underwent 1 week continuous LL-VNS. Group 2 dogs (N=6) underwent intermittent rapid atrial pacing followed by active or sham LL-VNS on alternate weeks. Integrated SGNA was significantly reduced during LL-VNS (7.8 mV-s; 95% confidence interval [CI] 6.94 to 8.66] vs. 9.4 mV-s [CI, 8.5 to 10.3] at baseline, P=0.033) in Group 1.The reduction was most apparent at 8 AM, along with a significantly reduced heart rate (P=0.008). LL-VNS did not change VNA. The density of tyrosine hydroxylase-positive nerves in the left stellate ganglion one week after cessation of LL-VNS were 99684 µm2/mm2 (CI, 28850 to 170517) in LL-VNS dogs and 186561 µm2/ mm2 (CI, 154956 to 218166; P=0.008) in normal dogs. In Group 2, the frequencies of paroxysmal atrial fibrillation and tachycardia during active LL-VNS were 1.4/day (CI, 0.5/day to 5.1/day) and 8.0/day (CI, 5.3/day to 12.0/day), respectively, significantly lower than during sham stimulation (9.2/day [CI, 5.3/day to 13.1/day], P=0.001 and 22.0/day [CI, 19.1/day to 25.5/day], P<0.001, respectively). Conclusions LL-VNS suppresses SGNA and reduces the incidences of paroxysmal atrial tachyarrhythmias in ambulatory dogs. Significant neural remodeling of the left stellate ganglion is evident one week after cessation of chronic LL-VNS.

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