Diabetic dyslipidemia and exercise affect coronary tone and differential regulation of conduit and microvessel K+ current.

Spontaneous transient outward K(+) currents (STOCs) elicited by Ca(2+) sparks and steady-state K(+) currents modulate vascular reactivity, but effects of artery size, diabetic dyslipidemia, and exercise on these differentially regulated K(+) currents are unclear. We studied the conduit arteries and microvessels of male Yucatan swine assigned to one of three groups for 20 wk: control (C, n = 7), diabetic dyslipidemic (DD, n = 6), or treadmill-trained DD animals (DDX, n = 7). Circumflex artery blood flow velocity obtained with intracoronary Doppler and lumen diameters obtained by intravascular ultrasound enabled calculation of absolute coronary blood flow (CBF). Ca(2+) sparks were determined in pressurized microvessels, and perforated patch clamp assessed K(+) current in smooth muscle cells isolated from conduits and microvessels. Baseline CBF in DD was decreased versus C. In pressurized microvessels, Ca(2+) spark activity was significantly lower in DD versus C and DDX (P < 0.05 vs. DDX). STOCs were pronounced in microvessel (approximately 35 STOCs/min) in sharp contrast to conduit cells ( approximately 2 STOCs/min). STOCs were decreased by 86% in DD versus C and DDX in microvessels; in contrast, there was no difference in STOCs across groups in conduit cells. Steady-state K(+) current in microvessels was decreased in DD and DDX versus C; in contrast, steady-state K(+) current in conduit cells was decreased in DDX versus DD and C. We conclude that steady-state K(+) current and STOCs are differentially regulated in conduit versus microvessels in health and diabetic dyslipidemia. Exercise prevented diabetic dyslipidemia-induced decreases in baseline CBF, possibly via STOC-regulated basal microvascular tone.

Exercise training attenuates coronary smooth muscle phenotypic modulation and nuclear Ca2+ signaling.

Physical inactivity is an independent risk factor for coronary heart disease, yet the mechanism(s) of exercise-related cardioprotection remains unknown. We tested the hypothesis that coronary smooth muscle after exercise training would have decreased mitogen-induced phenotypic modulation and enhanced regulation of nuclear Ca(2+). Yucatan swine were endurance exercise trained (EX) on a treadmill for 16-20 wk. EX reduced endothelin-1-induced DNA content by 40% compared with sedentary (SED) swine (P < 0.01). EX decreased single cell peak endothelin-1-induced cytosolic Ca(2+) responses compared with SED by 16% and peak nuclear Ca(2+) responses by 33% (P < 0.05), as determined by confocal microscopy. On the basis of these results, we hypothesized that sarco(endo)plasmic reticulum Ca(2+)-ATPase (SERCA) and intracellular Ca(2+) stores in native smooth muscle are spatially localized to dissociate cytosolic Ca(2+) and nuclear Ca(2+). Subcellular localization of SERCA in living and fixed cells revealed a distribution of SERCA near the sarcolemma and on the nuclear envelope. These results show that EX enhances nuclear Ca(2+) regulation, possibly via SERCA, which may be one mechanism by which coronary smooth muscle cells from EX are less responsive to mitogen-induced phenotypic modulation.

Differences in K+ current components in mesenteric artery myocytes from WKY and SHR.

Previous studies have documented increased K+ permeability of arterial smooth muscle in hypertension and suggested a role in altered arterial contractile function. To characterize the mechanisms responsible for these alterations, we determined the contribution of K+ current (IK) components to whole cell IK in freshly dispersed myocytes and tetraethylammonium (TEA)-induced contractile responses in mesenteric arteries of Wistar-Kyoto (WKY) and spontaneously hypertensive rats (SHR). Tetraethylammonium produced a larger tonic contractile response in SHR with a lower threshold compared to WKY (ie, 0.1 v 1 mmol/L), which was due in part to the larger Ca2+ current in SHR. Whole cell IK recorded by perforated patch methods was similar at a holding potential (HP) of -60 mV (IK60), but were larger in SHR when recorded from a HP of -20 mV (IK20). The selective blocker iberiotoxin (IbTX) was used to separate the contribution of voltage- (Kv) and calcium-dependent (KCa) components of IK60. The IK60 and IK20 component inhibited by 100 nmol/L IbTX (ie, KCa) was larger in SHR than in WKY myocytes, whereas the IbTX-insensitive IK60 component (ie, Kv) was larger in WKY. In the presence of IbTX, 1 and 10 mmol/L TEA inhibited a larger fraction of IK60 in SHR myocytes compared with WKY. The activation properties of the TEA-sensitive and TEA-insensitive Kv components determined by fitting a Boltzmann activation function to the current-voltage data, exhibited both group and treatment differences in the half maximal activation voltage (V0.5). The V0.5 of the TEA-sensitive Kv component was more positive than that of the TEA-insensitive component in both groups, and values for the V0.5 of both TEA-sensitive and TEA-insensitive components were more negative in SHR than WKY. These results show that SHR myocytes have larger KCa and smaller Kv current components compared with WKY. Furthermore, SHR myocytes have a larger TEA-sensitive Kv component. These differences may contribute to the differences in TEA contractions, resting membrane potential, Ca2+ influx, and KCa current reported in hypertensive arteries.

Calcium buffering in coronary smooth muscle after chronic occlusion and exercise training.

OBJECTIVE: Exercise promotes "sarcoplasmic reticulum (SR) Ca2+ unloading" in porcine coronary smooth muscle, resulting in decreased agonist-induced Ca2+ release. We studied Ca2+ handling in healthy, non-occluded right coronary artery cells from hearts chronically occluded at the circumflex artery. METHODS: Myoplasmic free Ca2+ (Ca(m)) was assessed with fura-2 in cells from sedentary (n=8) and aerobically exercise-trained (n=6) female Yucatan pigs after 6-month circumflex artery ameroid occlusion (OCC) and in cells from non-occluded, sedentary pigs (SED, n=5). First, Ca influx was induced by 80 mM KCl depolarization (priming step) followed by 5 mM caffeine to elicit maximal Ca2+ release and depletion. The SR was Ca-loaded again by depolarization and then exposed to caffeine after 2- or 11-min recovery to compare SR Ca2+ unloading. RESULTS: Baseline Ca(m), caffeine-induced peak Ca(m), and depolarization-induced maximum Ca(m) were decreased, and depolarization-induced time-to-half-maximum was increased in OCC vs. SED pigs, suggesting a tonic Ca2+ buffering (lowering) effect of occlusion. Exercise did not alter these effects. SR Ca2+ unloading occurred only in SED, as evidenced by decreased caffeine-induced Ca2+ release after 11 min of recovery, and was inhibited by low extracellular Na+. CONCLUSIONS: SR Ca2+ unloading can be demonstrated in coronary smooth muscle from sedentary pigs using a novel SR Ca2+ unloading protocol, and Ca2+ unloading partly depends on Na+-Ca2+ exchange activity. Furthermore, SR Ca2+ unloading in cells from non-occluded right coronary arteries of chronically circumflex-occluded pig hearts was not altered by exercise, perhaps due to enhanced tonic Ca2+ extrusion versus cells from normal, sedentary animals.

Temporal profile of neurochemical recovery following injury by transient cerebral ischemia.

The effects of transient cerebral ischemia by the four-vessel occlusion model on balance beam performance and regional activity of glutamic acid decarboxylase (GAD) and choline acetyltransferase (ChAT) and muscarinic binding (MusBnd) were evaluated over a six-month postischemia period in 6- and 24-month-old rats. Cerebral ischemia resulted in an early reduction in balance beam performance in young and old rats that partially recovered. GAD in young and old animals and ChAT in old animals and MusBnd in young and old animals were also significantly altered by ischemia. There was partial recovery of each neurochemical marker noted. In some cases the recovery was partially accounted for by the absence of any age-associated changes in the ischemic group. The results of the present study suggest an age-dependent vulnerability to ischemic injury occurs and that aged brain's gamma-aminobutyric and cholinergic systems are capable of measurable recovery.

Effects of deferoxamine and a diet deficient in vitamin E on isoelectric electroencephalographic responses associated with ischemia by the four vessel occlusion method.

This study reports the effects of subchronic administration of the iron chelator deferoxamine (4.2 mg/day by osmotic minipump for 6 days) and a diet deficient in Vitamin E (15% RDA for 60 days) on the isoelectric electroencephalographic responses associated with 15 minutes of global transient cerebral ischemia in rats. Brain levels of thiobarbiturate-reacting substance (TBARS), a measure of lipid peroxidation, were lower in deferoxamine-treated animals and higher in Vitamin E deficit animals suggesting the treatments altered free radical activity at the time of ischemia. During ischemia, all test animals were observed to lose the righting reflex and enter a quiescent state. Fifty percent of the animals in two control groups (N = 15 per group) demonstrated an isoelectric electroencephalographic pattern (defined as 10% or less of pre-ischemia total EEG power) with a mean onset of 5.44 minutes. One third of the animals treated with deferoxamine (N = 15) experienced an isoelectric encephalogram with a mean onset of 8.6 minutes and 73% of the Vitamin E-deficient group (N = 15) experienced an isoelectric EEG with a mean onset of 3.43 minutes. Following reperfusion, EEG patterns returned to power levels within 20% of pre-ischemia levels in all animals. Control animals obtained this EEG power level within 1.34 minutes, deferoxamine-treated animals within 1.25 minutes and animals provided a diet deficient in Vitamin E within 5.03 minutes. Compared to mean total EEG power prior to the onset of ischemia, mean total EEG power five days after reperfusion was reduced 14% in the control groups and 59% in the Vitamin E-deficient group and increased 123% in the deferoxamine group. Results are discussed in relation to the possible involvement of free radicals in the ischemic and postischemic process.