endothelin-1 and Hypercapnia

Brain plasticity following focal cerebral ischaemia has been observed in both stroke survivors and in preclinical models of stroke. Endogenous neurovascular adaptation is at present incompletely understood yet its potentiation may improve long-term functional outcome. We employed longitudinal MRI, intracranial array electrophysiology, Montoya Staircase testing, and immunofluorescence to examine function of brain vessels, neurons, and glia in addition to forelimb skilled reaching during the subacute stage of ischemic injury progression. Focal ischemic stroke (~100mm

Topics: Animals; Brain; Brain Ischemia; Brain Waves; Encephalitis; Endothelin-1; Hypercapnia; Magnetic Resonance Imaging; Male; Motor Skills; Neuroglia; Neurons; Physical Stimulation; Rats, Sprague-Dawley; Recovery of Function; Sensorimotor Cortex; Somatosensory Cortex; Stroke; Touch Perception; Vascular Remodeling

We reported previously that intermittent hypoxia with CO(2) to maintain eucapnia (IH-C) elevates plasma endothelin-1 (ET-1) and arterial pressure. In small mesenteric arteries (sMA; inner diameter = 150 microm), IH-C augments ET-1 constrictor sensitivity but diminishes ET-1-induced increases in intracellular Ca(2+) concentration, suggesting IH-C exposure increases both ET-1 levels and ET-1-stimulated Ca(2+) sensitization. Because Rho-associated kinase (ROK) can mediate Ca(2+) sensitization, we hypothesized that augmented vasoconstrictor sensitivity to ET-1 in arteries from IH-C-exposed rats is dependent on ROK activation. In thoracic aortic rings, ET-1 contraction was not different between groups, but ROK inhibition (Y-27632, 3 and 10 microM) attenuated ET-1 contraction more in IH-C than in sham arteries (50 +/- 11 and 78 +/- 7% vs. 41 +/- 12 and 48 +/- 9% inhibition, respectively). Therefore, ROK appears to contribute more to ET-1 contraction in IH-C than in sham aorta. In sMA, ROK inhibitors did not affect ET-1-mediated constriction in sham arteries and only modestly inhibited it in IH-C arteries. In ionomycin-permeabilized sMA with intracellular Ca(2+) concentration held at basal levels, Y-27632 did not affect ET-1-mediated constriction in either IH-C or sham sMA and ET-1 did not stimulate ROK translocation. In contrast, inhibition of myosin light-chain kinase (ML-9, 100 microM) prevented ET-1-mediated constriction in sMA from both groups. Therefore, IH-C exposure increases ET-1 vasoconstrictor sensitivity in sMA but not in aorta. Furthermore, ET-1 constriction is myosin light-chain kinase dependent and mediated by Ca(2+) sensitization that is independent of ROK activation in sMA but not aorta. Thus ET-1-mediated signaling in aorta and sMA is altered by IH-C but is dependent on different second messenger systems in small vs. large arteries.

Topics: Animals; Aorta; Dose-Response Relationship, Drug; Endothelin-1; Enzyme Activation; Hypercapnia; Hypoxia; Male; Mesenteric Arteries; Rats; Rats, Sprague-Dawley; rho-Associated Kinases; Sleep Apnea Syndromes; Vasoconstriction

Induction of hypercapnia by breathing high concentrations of carbon dioxide (CO(2)) may have beneficial effects on the pulmonary circulation. We tested the hypothesis that exposure to CO(2) would protect against chronic pulmonary hypertension in newborn rats. Atmospheric CO(2) was maintained at <0.5% (normocapnia), 5.5%, or 10% during exposure from birth for 14 days to normoxia (21% O(2)) or moderate hypoxia (13% O(2)). Pulmonary vascular and hemodynamic abnormalities in animals exposed to chronic hypoxia included increased pulmonary arterial resistance, right ventricular hypertrophy and dysfunction, medial thickening of pulmonary resistance arteries, and distal arterial muscularization. Exposure to 10% CO(2) (but not to 5.5% CO(2)) significantly attenuated pulmonary vascular remodeling and increased pulmonary arterial resistance in hypoxia-exposed animals (P < 0.05), whereas both concentrations of CO(2) normalized right ventricular performance. Exposure to 10% CO(2) attenuated increased oxidant stress induced by hypoxia, as quantified by 8-isoprostane content in the lung, and prevented upregulation of endothelin-1, a critical mediator of pulmonary vascular remodeling. We conclude that hypercapnic acidosis has beneficial effects on pulmonary hypertension and vascular remodeling induced by chronic hypoxia, which we speculate derives from antioxidant properties of CO(2) on the lung and consequent modulating effects on the endothelin pathway.

Topics: Animals; Animals, Newborn; Body Weight; Carbon Dioxide; Carboxylic Acids; Chronic Disease; Endothelin Receptor Antagonists; Endothelin-1; Female; Hematocrit; Hypercapnia; Hypertension, Pulmonary; Hypertrophy, Right Ventricular; Hypoxia; Indans; Oxidative Stress; Oxygen; Pregnancy; Pulmonary Artery; Pulmonary Circulation; Rats; Up-Regulation

Plasma endothelin elevations have been associated with cerebrovascular pathology. Mechanisms of stimulation, however, are unknown. Therefore, in healthy subjects a marked physiological cerebrovascular response was experimentally provoked by hypercapnia, hypocapnia, and alternating capneic conditions. During these challenges plasma immunoreactive-endothelin-1 (ir-ET-1) concentrations were determined using a radioimmunassay. Physiological effects were continuously recorded for pCO(2), cerebral blood flow velocity, pulse frequency, and arterial blood pressure. No alterations in plasma ET-1 levels were found upon any of the cerebrovascular stimuli. We conclude that massive cerebrovascular challenges in healthy individuals do not lead to high circulating ET-1 levels.

Topics: Adult; Blood Flow Velocity; Blood Pressure; Carbon Dioxide; Cerebrovascular Circulation; Endothelin-1; Humans; Hypercapnia; Hypocapnia; Male; Partial Pressure; Pulse; Radioimmunoassay; Reference Values; Ultrasonography, Doppler, Transcranial

Circulating and urinary levels of endothelin (ET), an endothelium-derived vasoconstrictive and mitogenic peptide have been reported to increase in patients with chronic obstructive pulmonary disease (COPD), but the mechanisms of these abnormalities are not fully understood. Our study objectives were to evaluate pulmonary and renal ET clearance in COPD patients during an acute exacerbation. Our participants included nine consecutive patients with moderate to severe COPD without signs of right heart failure admitted for acute exacerbation and ten healthy volunteers (HV) as controls. ET was detected by radioimmunoassay in venous and arterial blood as well as in a timed urine specimen. For each subject, arterial/venous immunoreactive ET ratio (ir-ETart/ir-ETven) was evaluated as an index of its pulmonary clearance. Creatinine clearance was employed in each case to obtain a corrected renal ir-ET clearance. Glomerular filtration rate (GFR) was also assessed by dynamic(99m)Tc-diethylenetriamine pentaacetic acid renal scintigraphy in six COPD patients during acute exacerbation and at recovery. The ratio ir-ETart/ir-ETven was comparable in COPD patients (0.75+/-0.12) and in HV (0.82+/-0.09). A significant difference was found with respect to 24 h ir-ET urinary excretion between COPD patients during exacerbation as well as at recovery (respectively 142.1+/-12.8 ng/24 h and 89.0+/-15.1 ng/24 h) and HV (65.1+/-10.1 ng/24 h). ET renal clearance was higher in COPD patients than in HV (29.2+/-5.2 ml min(-1)in COPD during exacerbation; 17.5+/-3.9 ml min(-1)at recovery and 13.6+/-2.4 ml min(-1)in HV, P<0.001). GFR was 69.4+/-10.0 ml min(-1)in COPD patients during exacerbation and it significantly increased at the recovery (95.5+/-20.9 ml min(-1)P<0.001). Corrected renal clearance of the peptide was significantly correlated to GFR values during the exacerbation (r=-0.81, P<0.05). Furthermore change in renal ET production resulted associated with changes in paCO(2)(r=0.83, P<0.001) and in paO(2)(r=-0.73, P<0.05). Acute exacerbation in COPD patients causes an increase in renal ET production which is partially reversible at the recovery, in the absence of significant changes in ET-1 circulating levels. ET might contribute to the renal response to hypoxaemia and hypercapnia in COPD.

Topics: Acute Disease; Aged; Endothelin-1; Glomerular Filtration Rate; Humans; Hypercapnia; Hypoxia; Kidney; Lung Diseases, Obstructive; Male; Middle Aged

To investigate the effects of hypoxemia, hypercapnia, and cardiovascular hormones (norepinephrine, endothelin-1, and atrial natriuretic factor) on blood pressure during acute respiratory failure.. Patients with chronic obstructive pulmonary disease and acute respiratory failure were divided into four groups of 10 patients each: hypoxemia-normocapnia, hypoxemia-hypercapnia, hypoxemia-hypocapnia, and normoxemia-hypercapnia. Plasma norepinephrine levels were determined by high-performance liquid chromatography with electrochemical detection. Plasma endothelin-1 and atrial natriuretic factor levels were radioimmunoassayed after chromatographic preextraction.. Systolic blood pressure and cardiovascular hormone levels were greater in patients with hypercapnia (whether or not they also had hypoxemia) than in those with normocapnia and hypoxemia. For example, in patients with hypercapnia and normoxemia, the mean (+/- SD) systolic blood pressure was 183+/-31 mm Hg and the mean norepinephrine level was 494+/-107 pg/mL, as compared with 150+/- 6 mm Hg and 243+/-58 pg/mL in those with normocapnia and hypoxemia (both P<0.05). Similar results were seen for endothelin-1 and atrial natriuretic factor levels, and for the comparisons of hypoxemic patients who were hypercapnic with those who were normocapnic.. These results suggest that blood carbon dioxide levels, rather than oxygen levels, are responsible for hypertension during acute respiratory failure, perhaps as a result of enhanced sympatho-adrenergic activity.

Topics: Acute Disease; Adult; Aged; Atrial Natriuretic Factor; Blood Pressure; Carbon Dioxide; Endothelin-1; Female; Heart Rate; Humans; Hypercapnia; Hypertension; Hypocapnia; Hypoxia; Lung Diseases, Obstructive; Male; Middle Aged; Norepinephrine; Oxygen; Respiratory Insufficiency; Severity of Illness Index

To investigate the effects of chronic hypoxic hypercapnia and ligustrazine on expression of endothelin-1 (ET-1) mRNA and the ultrastructure of pulmonary arterioles in rats.. Thirty rats were randomly divided into three groups: control group (A), hypoxic hypercapnic group (B), hypoxic hypercapnia + ligustrazine (lig.) group (C). ET-1 mRNA was observed in arterioles from rats by the technique of in situ hybridization. The average value of integral light density (LD) of ET-1 mRNA in pulmonary arterioles was detected by an image analysor and the relative content of ET-1 mRNA was calculated.. (1) mPAP was significantly higher in rats of B group than that of A group (P < 0.01) and it was much lower in rats of C group than that of B group (P < 0.01). Differences of mCAP were not significant in three groups (P > 0.05); plasma ET-1 concentration was significantly higher in rats of B group than that of A group (P < 0.01), plasma ET-1 concentration was significantly lower in rats of C group than that of B group (P < 0.01); (2) Light microscopy showed that WA/TA (vessel wall area/total area) and SMC (the density of medial smooth muscle cells) were significantly higher in rats of B group than those of A group (P < 0.01). WA/TA and SMC were significantly lower in rats of C group than those of B group (P < 0.01). Electron microscopy showed proliferation of medial smooth muscle cells and collageous fibers of pulmonary arterioles in rats of B group, and ligustrazine could reverse the changes mentioned above; (3) Hybridization in situ showed that LD of ET-1 mRNA in pulmonary arterioles was significantly higher in rats of B group than that of A group (P < 0.01); LD of ET-1 mRNA in pulmonary arterioles was significantly lower in rats of C group than that of B group (P < 0.01).. Increase of expression of ET-1 mRNA in pulmonary arterioles contributes to the development of pulmonary hypertension and structural remodeling of pulmonary arteries in chronic hypoxic hypercapnic rats. Ligustrazine can inhibit pulmonary hypertension by decreasing the expression of ET-1 mRNA in pulmonary arterioles.

Topics: Animals; Arterioles; Endothelin-1; Hypercapnia; Hypoxia; Male; Pulmonary Artery; Pyrazines; Random Allocation; Rats; Rats, Sprague-Dawley; RNA, Messenger

Recently generated knockout mice with disrupted genes encoding endothelin (ET)-1 showed an elevation of arterial blood pressure (AP) and supplied an evidence for intrinsic ET-1 as one of the physiological regulators of systemic AP. Little is yet known, however, why deficiency of ET-1, which was originally found as a potent vasoconstrictor, led to higher AP in these mice. To address this apparent paradox, we first developed a method to measure renal sympathetic nerve activity (RSNA) in mice using rats as reference and successively compared it between normal and ET-1 deficient mice. RSNA was successfully recorded in urethane-anesthetized and artificially ventilated mice by a slight modification of the method used for rats. At basal condition, mean AP (MAP) and RSNA in ET-1 deficient mice (105+/-2 mmHg and 9.71+/-1.49 muVs, n=20) were significantly higher than those in wild-type mice (96+/-2 mmHg and 5. 07+/-0.70 muVs, n=25). Basal heart rate (HR) and baroreflex-control of HR was not significantly different between the two. On the other hand, resting RSNA, RSNA range, and maximum RSNA were significantly greater in ET-1 deficient mice, and thus MAP-RSNA relationship was upwards reset. Hypoxia-induced increase in RSNA was not different between ET-1 deficient (73.4+/-9.4%) and wild-type mice (91.2+/-12.0%), while hypercapnia-induced one was significantly attenuated in ET-1 deficient mice (18.8+/-3.6 vs. 39.1+/-5.2% at 10% CO2). These results indicate that endogenous ET-1 participates in the central chemoreception of CO2 and reflex control of the RSNA. Baroreceptor resetting and normally preserved hypoxia-induced chemoreflex may explain a part of the elevation of AP in ET-1 deficient mice.

Topics: Animals; Blood Gas Analysis; Blood Pressure; Cardiovascular System; Chemoreceptor Cells; Endothelin-1; Hypercapnia; Hypertension, Renal; Kidney; Male; Medulla Oblongata; Mice; Mice, Knockout; Pressoreceptors; Rats; Rats, Sprague-Dawley; Receptors, Endothelin; Reflex; Respiration; Sympathetic Nervous System