Kazushi Minami

Effect of Exercise Training and Food Restriction on Endothelium-Dependent Relaxation in the Otsuka Long-Evans Tokushima Fatty Rat, a Model of Spontaneous NIDDM

We investigated whether endothelial function may be impaired in the Otsuka Long-Evans Tokushima Fatty (OLETF) rat, a model of spontaneous NIDDM. The effect of exercise training and food restriction on endothelial function was also studied. OLETF rats were divided into three groups at age 16 weeks: sedentary, exercise trained, and food restricted (70% of the food intake of sedentary rats). Otsuka Long-Evans Tokushima rats were used as the age-matched nondiabetic controls. Endothelium-dependent relaxation of the thoracic aorta induced by histamine was significantly attenuated in the sedentary or food-restricted rats, and exercise training improved endothelial function. Relaxation induced by sodium nitroprusside, a donor of nitric oxide, did not differ significantly among groups. Both exercise training and food restriction significantly suppressed plasma levels of glucose and insulin and serum levels of triacylglycerol and cholesterol and reduced the accumulation of abdominal fat. Insulin sensitivity, as measured by the hyperinsulinemic- euglycemic clamp technique, was significantly decreased in sedentary rats but was enhanced in exercise- trained and food-restricted rats. The urinary excretion of nitrite was significantly decreased in sedentary and food-restricted rats compared with nondiabetic rats and was significantly increased in exercise-trained rats. These results indicate that exercise training, but not food restriction, prevents endothelial dysfunction in NIDDM rats, presumably due to the exercise-induced increase in the production of nitric oxide.

Mechanism of activation of the Ca2+-activated K+ channel by cyclic AMP in cultured porcine coronary artery smooth muscle cells

Abstract Activation of the Ca 2+ -activated K + channel (K Ca -channel) by adenosine 3′, 5′-cyclic monophosphate (cAMP) and cAMP-dependent protein kinase (A-kinase) in cultured smooth muscle cells from porcine coronary artery was investigated using the patch-clamp technique. In cell-attached patches, the K Ca -channel was activated when forskolin (10 μM) was applied to the bath. In excised inside-out patches, application of 50 μM cAMP to the bath activated the K Ca -channel in the presence of A-kinase (10 units/ml) and ATP (1 mM). In addition, the K Ca -channel was activated directly by application of cAMP to the cytoplasmic side of the membrane in the absence of A-kinase. The activation by cAMP or by A-kinase required intracellular Ca 2+ , and was enhanced by increase of intracellular Ca 2+ . At a low concentration (3×10 −7 M) of Ca 2+ , more than 2 mM cAMP was required for activation of the K Ca -channel, but with 10 −6 M Ca 2+ , 100 μM cAMP was sufficient for activation. These results suggest that there are two mechanisms of activation of the K Ca -channel by cAMP : direct activation, and indirect activation via phosphorylation of the channel by A-kinase.

Protein kinase c-independent inhibition of the Ca2+-activated K+ channel by angiotensin II and endothelin-1

We previously reported that the Ca(2+)-activated K+ channel (KCa-channel) in cultured smooth muscle cells from porcine coronary artery was inhibited by protein kinase C (C-kinase). In this study, inhibition of the KCa-channel by receptor-mediated vascular contractile agonists, such as angiotensin II (ANG II) and endothelin-1 (ET-1), was investigated by the patch-clamp technique. In cell-attached patches, addition of ANG II (500 nM) or ET-1 (50 nM) to the bath inhibited the KCa-channel activated by the calcium ionophore A23187 (10-20 microM). Phorbol 12-myristate 13-acetate (PMA, 1 microM), a C-kinase activator, also decreased the open probability of the KCa-channel. The PMA-induced decrease in the open probability was reversed by subsequent application of staurosporine (1 nM), a C-kinase inhibitor, but the ANG II- and ET-1-induced decreases were not reversed by subsequent application of staurosporine (> 30 nM). Pretreatment of smooth muscle cells with 30 nM staurosporine, a protein kinase inhibitor, or 1 mM neomycin, an inhibitor of phospholipase C, also did not abolish the inhibition of the KCa-channel by ANG II. Furthermore, ANG II inhibited the KCa-channel in cells in which C-kinase was down-regulated. These results indicate that, in porcine coronary artery smooth muscle cells, ANG II and ET-1 inhibit the KCa-channel by a C-kinase-independent mechanism.

Dynamics of iron-ascorbate-induced lipid peroxidation in charged and uncharged phospholipid vesicles

Peroxidation of egg yolk phosphatidylcholine (egg PC) liposomes was induced by addition of ascorbic acid (AsA) and Fe(II) in the presence of a trace of autoxidized egg PC (PC−OOH), but not in the absence of PC−OOH. PC−OOH was degraded upon addition of AsA and Fe(II) but not of either one alone. The results suggest that PC−OOH is necessary to initiate lipid peroxidation by AsA/Fe(II). AsA oxidation in the bulk water phase was also associated with an increase in lipid peroxidation by AsA/Fe(II) in the presence of PC−OOH, but not in the absence of PC−OOH. Furthermore, the spin probe 12-NS [12-(N-oxyl-4,4′-dimethyloxazolidin-2-yl)stearic acid], which labels the hydrophobic region of dimyristoyl phosphatidylcholine (DMPC) liposomal membranes, was degraded upon addition of AsA and Fe(II) in the presence of PC−OOH, but not in the absence of PC−OOH. These results indicate that the “induction message” that is associated with decreases of PC−OOH and AsA in the initiation step of lipid peroxidation must be transferred from the membrane surface to the inner hydrophobic membrane region. AsA in the bulk phase was oxidized faster and more extensively upon its addition together with Fe(II) to egg PC liposomes than to DMPC liposomes, though the initial content of PC−OOH in the former was 5–10 times lower than in the latter. This suggests that, in egg PC liposomes, the OOH-groups of new PC−OOH generated in the inner membrane regions must become accessible from the surface, enabling reaction with AsA/Fe(II) which in turn would result in an extensive decrease in AsA. By contrast, in DMPC liposomes, that do not generate PC−OOH, AsA is only oxidized slightly in connection with the degradation of the PC−OOH initially present. The effect of surface charges on the membrane surface was also studied to obtain further information on the initiation step of lipid peroxidation. The rate of lipid peroxidation by AsA/Fe(II) or Fe(III) decreased in the order, egg PC liposomes ≫negatively charged egg PC liposomes containing dicetylphosphate>positively charge egg PC liposomes containing stearylamine. The rate of associated AsA oxidation was in the order, egg PC liposomes≫egg PC/stearylamine liposomes>egg PC/dicetylphosphate liposomes. However, in DMPC liposomes that do not generate PC−OOH, the rates of AsA oxidation associated with the reductive cleavage of PC−OOH by AsA/Fe(II) and coupled with the reduction of Fe(III) to Fe(II) were in the order, DMPC liposomes =DMPC/stearylamine liposomes≫DMPC/dicetylphosphate liposomes. These differences in the rates of lipid peroxidation, depending on differences in membrane charge, are discussed in relation to two properties of AsA: (i) its antioxidant property through trapping of lipid radicals and (ii) its prooxidant properties (a) by being an effective iron chelator thus altering the reactivity of iron with oxygen and peroxides and (b) by being an iron reductant and providing a source of Fe(II).

Regulation of a non-selective cation channel of cultured porcine coronary artery smooth muscle cells by tyrosine kinase

A non-selective cation channel was found in primary cultured porcine coronary artery smooth muscle cells. In patch-clamp studies in the cell-attached mode, this channel was activated by bath application of genistein, a specific inhibitor of tyrosine kinase, but not by daidzein, which is similar in structure to genistein but has no inhibitory effect on tyrosine kinase. This channel discriminated poorly between Na+ and K+ (permeability ratio PNa/PK=1.03), and also transported Ca2+. The single-channel conductance measured with a pipette solution containing 150mM Na+ was 139±24 pS (mean ± SD, n=5), and that for the inward current measured with 100 mM Ca2+ solution was 25±9 pS (n=3). This non-selective cation channel was also activated by staurosporine, a non-specific protein kinase inhibitor, but not by H-7, an inhibitor of protein serine/ threonine kinase. These results suggest that the activity of the non-selective cation channel is negatively regulated by tyrosine kinase activity, and thus a decrease of the enzyme activity in porcine coronary artery smooth muscle cells may result in membrane depolarization and Ca2+ entry.

Biphasic Action of Phenylephrine on the Ca2+-Activated K+ Channel of Human Prostatic Smooth Muscle Cells

The elevation of cytosolic Ca²⁺ ([Ca²⁺]_i) is known to regulate smooth muscle contractility. A physiological concentration of phenylephrine induced the elevation in [Ca²⁺]_i of human prostatic smooth muscle cells; however, contraction of prostatic tissues in vitro needs a higher concentration of phenylephrine than the physiological level. To investigate this discrepancy, we investigated the functional importance of the Ca²⁺-activated K⁺ channel (K_Ca channel) of human prostatic smooth muscle cells in phenylephrine-induced contraction. Using the patch-clamp technique, the K_Ca channel of human prostatic smooth muscle cells was activated by phenylephrine at a physiological concentration (10^–7–10^–5 M) but was inhibited at a higher concentration (10^–4–10^–3 M). Phenylephrine (10^–3 M) also inhibited the K_Ca channel which was activated by 10 µM A23187, a calcium ionophore. Similar inhibition was obtained with 1 µM phorbol 12-myristate 13-acetate, an activator of protein kinase C (C-kinase). Both inhibitions were reversed by subsequent application of 1 nM staurosporine, a protein kinase inhibitor. These results suggested that C-kinase mediated the phenylephrine-induced inhibition of the K_Ca channel. In this study, a physiological concentration of phenylephrine induced activation of the K_Ca channel of human prostatic smooth muscle cells, which brought about membrane hyperpolarization and relaxation of human prostatic smooth muscle cells. The regulation of the K_Ca channel by phenylephrine may explain the need of a high concentration of phenylephrine for the contraction of prostatic tissue.