Strong inward rectifying K + (K IR ) channels have been observed in vascular smooth muscle and can display negative slope conductance. In principle, this biophysical characteristic could enable K IR channels to 'amplify' responses initiated by other K + conductances. To test this, we have characterized the diversity of smooth muscle K IR properties in resistance arteries, confirmed the presence of negative slope conductance and then determined whether K IR inhibition alters the responsiveness of middle cerebral, coronary septal and third-order mesenteric arteries to K + channel activators. Our initial characterization revealed that smooth muscle K IR channels were highly expressed in cerebral and coronary, but not mesenteric arteries. These channels comprised K IR 2.1 and 2.2 subunits and electrophysiological recordings demonstrated that they display negative slope conductance. Computational modelling predicted that a K IR -like current could amplify the hyperpolarization and dilatation initiated by a vascular K + conductance. This prediction was consistent with experimental observations which showed that 30 μM Ba 2+ attenuated the ability of K + channel activators to dilate cerebral and coronary arteries. This attenuation was absent in mesenteric arteries where smooth muscle K IR channels were poorly expressed. In summary, smooth muscle K IR expression varies among resistance arteries and when channel are expressed, their negative slope conductance amplifies responses initiated by smooth muscle and endothelial K + conductances. These findings highlight the fact that the subtle biophysical properties of K IR have a substantive, albeit indirect, role in enabling agonists to alter the electrical state of a multilayered artery.
Hyperhomocyst(e)inemia is associated with an increased risk of coronary artery disease and myocardial infarction. Both genetic and environmental factors influence the plasma level of homocysteine. One of the metabolic pathways for homocysteine involves the enzyme methylenetetrahydrofolate reductase (MTHFR), which regulates the conversion of homocysteine to methionine. A thermolabile variant of MTHFR is associated with reduced enzyme activity and increased plasma homocysteine levels. Recently, the cause of this variant of MTFHR has been identified as a single base change altering an alanine to a valine residue in the protein. Using a PCR-based assay to distinguish the normal and thermolabile variants of MTHFR in this study, we investigated whether the thermolabile variant is a genetic risk factor for myocardial infarction. In a study of 532 subjects (310 myocardial infarction patients and 222 population-based controls), we found no difference in either MTHFR genotype distribution (p = 0.57) or allele frequencies (p = 0.68) between cases and controls. The allele frequencies of the thermolabile variant were 0.34 and 0.35 in cases and controls, respectively. The age- and sex-stratified odds ratio for risk of myocardial infarction associated with homozygosity for the thermolabile variant was 0.85 (95% CI 0.50-1.50, p = 0.57) and that with carriage of the thermolabile allele was 1.06 (95% CI 0.73-1.52, p = 0.76). The odds ratios remained non-significant when restricted to young subjects (< 60 years) or males, and were not influenced by several other risk factors for myocardial infarction considered either singly or in combination. Interestingly, in both cases and controls, there was a trend toward a higher prevalence of hypertension in subjects carrying the normal allele, although as this is a post-hoc finding it needs to be interpreted with caution. The thermolabile variant of MTHFR is not a major risk factor for myocardial infarction and is unlikely to explain a significant proportion of the reported association of hyperhomocyst(e)inemia with coronary artery disease.
These results indicate that allelic variation at the TGF-beta 1 gene contributes to the development of osteoporosis at the hip. The study also highlights the power of candidate gene analysis in twins, in whom loci having modest effects on disease risk can be identified.
1. Adrenomedullin is a recently discovered vasodilating and natriuretic peptide whose physiological and pathophysiological roles remain to be established. Like atrial natiuretic peptide adrenomedullin is expressed in the left ventricle. Ventricular expression of atrial natriuretic peptide is known to be markedly increased by volume or pressure overload. In this study we investigated whether ventricular expression of adrenomedullin is similarly stimulated under such conditions. 2. Ventricular adrenomedullin and atrial natriuretic peptide mRNA levels as well as those of a loading control mRNA (glyceraldehyde-3-phosphate dehydrogenase) were quantified by Northern blot analysis in (a) rats with severe post-infarction heart failure induced by left coronary ligation at 30 days post-surgery and (b) in rats with pressure-related cardiac hypertrophy induced by aortic banding at several time points (0.5, 1 and 4 h, and 1, 4, 7 and 28 days) after surgery. Levels were compared with those in matched sham-operated controls. 3. The mRNA level of atrial natriuretic peptide was markedly increased (8-10-fold) in the left ventricle of animals with post-infarction heart failure. In contrast, there was only a modest (40%) increase in the level of adrenomedullin mRNA. In rats with pressure-induced cardiac hypertrophy the ventricular level of atrial natriuretic peptide mRNA was again markedly increased (maximum 10-fold). The increase was first noticeable at 24 h post-banding and persisted until 28 days. In contrast, there was no change in adrenomedullin mRNA level compared with sham-operated rats at any time point. 4. Despite having similar systemic effects, the expression of adrenomedullin and atrial natriuretic peptide in the left ventricle is differently regulated. The findings imply distinct roles for the two peptides. The results do not support an important role for ventricular adrenomedullin expression in the remodelling process that occurs during the development of cardiac hypertrophy but suggest that ventricular adrenomedullin participates in the local and/or systemic response to heart failure.
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