Kathryn G. Lamping

Understanding the coronary circulation through studies at the microvascular level.

Studies of the coronary circulation have divided vascular resistances into three large components: large vessels, small resistance vessels, and veins. Studies of the epicardial microcirculation in the beating heart using stroboscopic illumination have suggested that resistance is more precisely controlled in different segments of the circulation. Measurements of coronary pressure in different sized arteries and arterioles have indicated that under normal conditions, 45–50% of total coronary vascular resistance resides in vessels larger than 100 μm. This distribution of vascular resistance can be altered in a nonuniform manner by a variety of physiological (autoregulation, increases in myocardial oxygen consumption, sympathetic stimulation) and pharmacological stimuli (norepinephrine, papaverine, dipyridamole, serotonin, vasopressin, nitroglycerin, adenosine, and endothelin). Studies of exchange of macromolecules in the microcirculation using fluorescent-labeled dextrans have also identified the size of the small pore (35–50 AÅ) in coronary microvessels that can be altered by myocardial ischemia. Studies of the coronary microcirculation have demonstrated that the control of vascular resistance is extremely complex, and mechanisms responsible for these heterogeneous responses need further examination.

Cholinergic dilation of cerebral blood vessels is abolished in M 5 muscarinic acetylcholine receptor knockout mice

The M5 muscarinic receptor is the most recent member of the muscarinic acetylcholine receptor family (M1-M5) to be cloned. At present, the physiological relevance of this receptor subtype remains unknown, primarily because of its low expression levels and the lack of M5 receptor-selective ligands. To circumvent these difficulties, we used gene targeting technology to generate M5 receptor-deficient mice (M5R−/− mice). M5R−/− mice did not differ from their wild-type littermates in various behavioral and pharmacologic tests. However, in vitro neurotransmitter release experiments showed that M5 receptors play a role in facilitating muscarinic agonist-induced dopamine release in the striatum. Because M5 receptor mRNA has been detected in several blood vessels, we also investigated whether the lack of M5 receptors led to changes in vascular tone by using several in vivo and in vitro vascular preparations. Strikingly, acetylcholine, a powerful dilator of most vascular beds, virtually lost the ability to dilate cerebral arteries and arterioles in M5R−/− mice. This effect was specific for cerebral blood vessels, because acetylcholine-mediated dilation of extra-cerebral arteries remained fully intact in M5R−/− mice. Our findings provide direct evidence that M5 muscarinic receptors are physiologically relevant. Because it has been suggested that impaired cholinergic dilation of cerebral blood vessels may play a role in the pathophysiology of Alzheimers disease and focal cerebral ischemia, cerebrovascular M5 receptors may represent an attractive therapeutic target.

Atherosclerosis, Vascular Remodeling, and Impairment of Endothelium-Dependent Relaxation in Genetically Altered Hyperlipidemic Mice

We examined the vascular structure and endothelium-dependent relaxation in two genetic models of hypercholesterolemia: apolipoprotein E (apoE)-knockout mice and combined apoE/LDL receptor-double-knockout mice. Intimal area was increased markedly in proximal segments of thoracic aortas from apoE/LDL receptor-knockout mice [0.13 +/- 0.03 (mean +/- SE) mm2] compared with normal (C57BL/6J) mice (0.002 +/- 0.002 mm2, P < .05). Despite intimal thickening, the vascular lumen was not smaller in the aortas of apoE/LDL receptor-knockout mice (0.52 +/- 0.03 mm2) than in normal mice (0.50 +/- 0.03 mm2). In apoE-deficient mice, intimal thickening was minimal or absent, even though the concentration of plasma cholesterol was only modestly less than that in the double-knockout mouse (14.9 +/- 1.1 vs 18.0 +/- 1.2 mmol/L, respectively, P < .05). Relaxation of the aorta was examined in vitro in vascular rings precontracted with U46619. In normal mice, acetylcholine produced relaxation, which was markedly attenuated by the nitric oxide synthase inhibitor NG-nitro-L-arginine (100 microM). Relaxation to acetylcholine and the calcium ionophore A23187 was normal in apoE-deficient mice (in which lesions were minimal) but greatly impaired in the proximal segments of thoracic aortas of apoE/LDL receptor-deficient mice, which contained atherosclerotic lesions. Vasorelaxation to nitroprusside was similar in normal and apoE-knockout mice, with modest but statistically significant impairment in atherosclerotic segments of apoE/LDL receptor-knockout mice. In distal segments of the thoracic aorta of apoE/LDL receptor-deficient mice, atherosclerotic lesions were minimal or absent, and the endothelium-dependent relaxation to acetylcholine and calcium ionophore was normal. Thus, in apoE/LDL receptor-knockout mice (a genetic model of hyperlipidemia), there is vascular remodeling with preservation of the aortic lumen despite marked intimal thickening, with impairment of endothelium-dependent relaxation to receptor- and nonreceptor-mediated agonists. Atherosclerosis may be accelerated in the apoE/LDL receptor-double-knockout mouse compared with the apoE-knockout strain alone. We speculate that other factors, such as the absence of LDL receptors, may contribute to the differences in the extent of atherosclerosis in these two models of hyperlipidemia.

Comparison of the effects of increased myocardial oxygen consumption and adenosine on the coronary microvascular resistance.

The purposes of this study were to determine if coronary dilation secondary to an increase in myocardial oxygen consumption (MVO2) affects the microcirculation in a homogeneous or heterogeneous manner and to determine if comparable degrees of coronary dilation produced by increasing MVO2 or exogenous (intravenous adenosine) or endogenous (intravenous dipyridamole) adenosine have similar effects In the coronary microcirculation. The epimyocardial coronary microcirculation was observed through an intravital microscope by stroboscopic epi-illumination in anesthetized open-chest dogs. Aortic pressure and heart rate were controlled by an aortic snare and atrioventricular sequential pacing, respectively, during experimental procedures. In group 1 (n = 15), coronary arterial microvessel diameters were measured under control condition and during rapid pacing at 300 beats/min, which doubled MVO2. Increases in MVO2 caused heterogeneous vasodilation in coronary arterial microvessels (40-380 μm). There was an inverse relation between control diameter and percent increase in diameter. In group 2 (n =15) or group 3 (n =10), adenosine or dipyridamole was infused intravenously to increase myocardial perfusion to the same level as that obtained with rapid pacing. Adenosine and dipyridamole did not change MVO2. Adenosine and dipyridamole also caused heterogeneous vasodilation, but the effects of adenosine and dipyridamole were restricted to arterial microvessels smaller than 150 μm. From these results, we conclude that increases in MVO2 produce widespread but heterogeneous vasodilation, that is, greater dilation in smaller arterial microvessels. Comparable increases in coronary flow produced by increasing MVO2 or endogenous and exogenous adenosine do not produce identical changes in the distribution of coronary microvascular resistance.

Role of ATP-sensitive potassium channels in coronary microvascular autoregulatory responses.

The purpose of the present study was to test the hypothesis that ATP-sensitive potassium channels mediate autoregulatory vasodilatation of coronary arterioles in vivo. Experiments were performed in 23 open-chest anesthetized dogs. Coronary arterial microvascular diameters were directly measured with fluorescence microangiography using an intravital microscope and stroboscopic epi-illumination synchronized to the cardiac cycle. A mild coronary stenosis (perfusion pressure = 60 mm Hg), a critical coronary stenosis (perfusion pressure = 40 mm Hg), and complete coronary artery occlusion were produced with an occluder around the left anterior descending coronary artery in the presence or absence of glibenclamide (10(-5) M, topically), which inhibits ATP-sensitive potassium channels, or of vehicle. During topical application of vehicle (0.01% dimethyl sulfoxide), there was dilatation of small (less than 100 microns diameter) arterioles during reductions in perfusion pressure (percent change in diameter: 6.7 +/- 1.5%, 11.7 +/- 3.5%, and 10.4 +/- 5.1% during mild stenosis, critical stenosis, and complete occlusion, respectively). In the presence of glibenclamide, arteriolar dilatations during coronary stenoses and occlusions were abolished. Glibenclamide did not affect responses of arterioles greater than 100 microns. Glibenclamide did not alter microvascular responses to nitroprusside. These data suggest that ATP-sensitive potassium channels play an important role in determining the coronary microvascular response to reductions in perfusion pressure.

Mechanisms responsible for the heterogeneous coronary microvascular response to nitroglycerin.

Nitroglycerin dilates large (greater than or equal to 100 microns) but not small coronary arterial microvessels, and a putative metabolite of nitroglycerin, S-nitroso-L-cysteine, has been shown in vitro to dilate both large and small coronary microvessels. Based on this evidence, we tested the hypothesis that the lack of response of small coronary microvessels was due to an inability of small coronary microvessels to convert nitroglycerin into its vasoactive metabolite and examined possible explanations for this phenomenon. We studied left ventricular epicardial microvessels in vivo using video microscopy and stroboscopic epi-illumination in anesthetized, open-chest dogs. Diameters were determined while the epicardium was suffused with nitroglycerin, S-nitroso-L-cysteine, or S-nitroso-D-cysteine (all 10 microM) and nitroglycerin in the presence of L- or D-cysteine (100 microM). None of the agents affected systemic hemodynamics. Nitroglycerin dilated large arterioles (20 +/- 2%) but not small arterioles (1 +/- 1%). Both S-nitroso-L-cysteine and S-nitroso-D-cysteine were potent dilators of all size classes of microvessels. Concomitant application of L-cysteine and nitroglycerin evoked dilation in small microvessels (22 +/- 4%, p less than 0.5 versus nitroglycerin alone) and larger microvessels (27 +/- 6%, p = NS versus nitroglycerin alone). D-Cysteine did not alter the microvascular response to nitroglycerin in either small (7 +/- 4%, p = NS versus nitroglycerin alone) or large (18 +/- 3%, p = NS versus nitroglycerin alone) microvessels. Neither L-cysteine nor D-cysteine had a direct effect on microvascular diameter. These findings suggest that 1) sulfhydryl groups are required for the conversion of nitroglycerin to its vasoactive metabolite; 2) the interaction between nitroglycerin and sulfhydryl residues is a stereospecific process, indicating either an intracellular mechanism or a membrane-associated enzymatic reaction; and 3) a lack of available sulfhydryl groups may be responsible for the lack of response of small coronary arterioles to nitroglycerin.

Cerebral vascular effects of angiotensin II: new insights from genetic models.

Very little is known regarding the mechanisms of action of angiotensin II (Ang II) or the consequences of Ang II-dependent hypertension in the cerebral circulation. We tested the hypothesis that Ang II produces constriction of cerebral arteries that is mediated by activation of AT1A receptors and Rho-kinase. Basilar arteries (baseline diameter ~130 µm) from mice were isolated, cannulated and pressurized to measure the vessel diameter. Angiotensin II was a potent constrictor in arteries from male, but not female, mice. Vasoconstriction in response to Ang II was prevented by an inhibitor of Rho-kinase (Y-27632) in control mice, and was reduced by ~85% in mice deficient in expression of AT1A receptors. We also examined the chronic effects of Ang II using a model of Ang II-dependent hypertension, mice which overexpress human renin (R+) and angiotensinogen (A+). Responses to the endothelium-dependent agonist acetylcholine were markedly impaired in R+ A+ mice (P < 0.01) compared with controls, but were restored to normal by a superoxide scavenger (PEG-SOD). A-23187 (another endothelium-dependent agonist) produced vasodilation in control mice, but no response or vasoconstriction in R+ A+ mice. In contrast, dilation of the basilar artery in response to a NO donor (NONOate) was similar in R+ A+ mice and controls. Thus, Ang II produces potent constriction of cerebral arteries via activation of AT1A receptors and Rho-kinase. There are marked gender differences in cerebral vascular responses to Ang II. Endothelial function is greatly impaired in a genetic model of Ang II-dependent hypertension via a mechanism that involves superoxide.

Heterogeneous changes in epimyocardial microvascular size during graded coronary stenosis. Evidence of the microvascular site for autoregulation.

The purpose of this study was to determine the coronary microvascular sites of autoregulation. The epimyocardial coronary microcirculation was observed through an intravital microscope by stroboscopic epi-illumination in anesthetized open-chest dogs (n = 20). Aortic pressure and heart rate were held constant by an aortic snare and atrial pacing, respectively. Distal pressure of the left anterior descending coronary artery was controlled by a screw occluder on the proximal left anterior descending coronary artery and monitored with a 24-gauge plastic cannula inserted into the branch or distal portion of the left anterior descending coronary artery. Distal pressure of the left anterior descending coronary artery was stepwisely reduced to 59 +/- 1 mm Hg (mild stenosis, n = 20) and 38 +/- 1 mm Hg (severe stenosis, n = 16). In the left circumflex coronary artery area, myocardial blood flow measured with radioactive microspheres to subepicardium, midmyocardium, and subendocardium did not change with the mild and severe stenosis from control. In the left anterior descending coronary artery area, myocardial blood flow to each layer remained at nearly control level with the mild stenosis but was reduced in midmyocardium and subendocardium with the severe stenosis. With the mild stenosis, diameters of coronary arterial microvessels less than 100 microns in diameter dilated, and those larger than 100 microns in diameter did not change. The magnitude of vasodilation in small arterial microvessels was inversely related to control diameter. With the severe stenosis, small arterial microvessels dilated, and simultaneously, large arterial microvessels constricted. Again, the magnitude of vasodilation in small arterial microvessels was inversely related to control diameter.(ABSTRACT TRUNCATED AT 250 WORDS)

Nonuniform vasomotor responses of the coronary microcirculation to serotonin and vasopressin.

Large-conduit coronary arteries respond to vasoactive stimuli differently than smaller coronary arterioles, but the quantitative effects of many vasoactive stimuli at various levels of the microvasculature remain unknown. To determine the site of constriction or dilation to serotonin and vasopressin in the coronary microcirculation, we studied microvascular responses in the left ventricle of anesthetized cats (n = 36). To compensate for motion due to contraction of the heart, the epicardium was visualized with stroboscopic epi-illumination controlled by a computer to flash once per cardiac cycle in mid-diastole, making the vessels appear stationary. Serotonin (16 micrograms/kg/min) or vasopressin (0.5 units/min) was infused into the left atrium while maintaining aortic pressure constant with a snare on the descending aorta or inferior vena cava. Myocardial blood flow was measured with radioactive microspheres. During infusion of serotonin, aortic pressure and heart rate did not change, but myocardial perfusion increased 90 +/- 38% (mean +/- SEM) from a control value of 159 +/- 27 ml/min.100 g. Arteries and arterioles larger than 90 microns constricted in response to serotonin (control 159 +/- 12 microns; percent change -18 +/- 3; range -41 to 10%) while arterioles less than 90 microns dilated to serotonin (control 54 +/- 7 microns; percent change 22 +/- 9; range -10 to 62%). During infusion of vasopressin, aortic pressure and heart rate did not change, and myocardial perfusion decreased 16 +/- 7% (control, 147 +/- 18 ml/min.100 g).(ABSTRACT TRUNCATED AT 250 WORDS)

Acute hypertension selectively potentiates constrictor responses of large coronary arteries to serotonin by altering endothelial function in vivo.

We tested the hypothesis that acute coronary artery hypertension may damage vascular endothelium and alter vasomotor responses to humoral agents. We examined effects of intracoronary infusion of the endothelium-dependent agent serotonin and two endothelium-independent agents, angiotensin II and methoxamine, on large coronary artery diameter in the blood perfused dog heart. Responses were examined before and 30 minutes after brief periods of coronary hypertension (200 mm Hg for 10 seconds to 15 minutes). In open-chest anesthetized dogs, the left anterior descending coronary artery was perfused at constant pressure. Coronary diameter (D) was measured with piezoelectric crystals. At a control perfusion pressure of 80 mm Hg, serotonin produced dose-dependent constriction of the large coronary artery (mean ± SEM; ΔD= -22 ± 10μm at 5 μg/min; -108 ± 50 μm at 50 μg/min). Increasing perfusion pressure to 200 mm Hg increased flow 515 ± 79% and coronary diameter 509 ± 9 μm. After 15 minutes of hypertension, when coronary diameter had returned to baseline values, the constriction of the large artery to serotonin was potentiated (ΔD = -89 ± 33μm at 5 μg/min; - 207 ± 45 μm at 50 μg/min; p<0.05). Hypertension for 1-5 minutes potentiated constrictor responses of large coronary arteries for at least 2± hours. Removal of endothelium prevented effects of hypertension on constrictor responses of large arteries to serotonin. Hypertension did not alter constrictor responses to angiotensin II (1 and 2.5 μg/min) or methoxamine (50 and 100 μg/min) or the dilator response to acetylcholine (40 μg/min). Acute hypertension altered endothelial morphology. There were small endothelial craters following 10 seconds of hypertension, and disruption of endothelial junctions with leukocyte adherence following 1-15 minutes of hypertension. We conclude that acute hypertension alters constrictor responses of large coronary arteries to serotonin by impairing endothelial function and not by directly affecting vascular smooth muscle. These effects of acute hypertension on vascular reactivity are selective in that they do not involve non-endothelium-dependent agents or the endothelium-dependent agent, acetylcholine. The effect of hypertension also persists long after pressure is restored to normotensive levels.