In this study, changes produced in aorta and triceps surae muscle of Wistar rats as response to bee venom (BV) envenomation were analyzed by transmission electron microscopy and morphometry. A subchronic treatment of 30 days with daily doses of 700 μg BV/kg and an acute-lethal treatment with a single dose of 62 mg BV/kg were performed. The subchronic treatment resulted in endothelial cell retraction, a thicker subendothelial layer, and thinner elastic laminae and musculoelastic layers in aorta, and thicker endothelium and basal laminae in skeletal muscle. In both tissues polymorphous, swollen mitochondria with disrupted cristae were observed. The acute treatment produced extensive endothelial lesions, breakdown of the collagen layer and migration of muscle cells toward the intima in the aorta, and dilatation of endoplasmic reticulum in the skeletal muscle cells. Mitochondria were almost devoid of cristae or with few circular cristae in the smooth muscle cells while most of the mitochondria presented abnormal circular cristae in the skeletal muscle cells. Degenerative alterations in the aorta were of higher intensity in our experiments—both the intima and media strongly responded to BV, in contrast to those found at the level of the skeletal muscle cells where a moderate degenerative myopathy was recorded.

We hypothesized that hyperlipidaemia, diabetes and diabetic dyslipidaemia increase the contractility of coronary arteries in swine, and that exercise would prevent this enhanced contractility. We further hypothesized that this enhanced contractility is associated with elevated potassium (K+) channel activity, consistent with the idea that certain disease states, as in hypertension, result in a compensatory upregulation in K+ channels. Swine were assigned to one of the following groups: control, standard chow (C; n=6); hyperlipidaemic, high-fat chow (H; n=5); diabetic, standard chow (D; n=7); diabetic, high-fat chow (‘diabetic dyslipidaemic’, DD; n=12); or exercise-trained DD (DDX; n=9). High-fat chow consisted of standard pig chow with added cholesterol (2%) and coconut oil. Endothelium-denuded segments from D, DD and DDX animals showed enhanced contractility to prostaglandin F2α (PGF2α) compared with C, while segments from H, D and DD showed enhanced contractility to endothelin-1 (ET-1) compared with C and DDX (P<0.05). The enhanced contractility was not accompanied by differences in K+ channel contribution to force reduction. There was no effect of the treatments on expression of the endothelin receptor A or endothelin receptor B. A possible mechanism for the enhanced vasoreactivity of coronary arteries of H, D and DD swine is an alteration in the signalling pathways of ET-1- and PGF2α-induced contraction. Exercise prevented the increase in contractility to ET-1, but not to PGF2α, reinforcing the concept of vasoconstrictor specificity.

The motility of the avian cloaca is under neural control, but little is known about the neural network that accomplishes this function. This present study was designed to determine the distribution of nitric oxide-synthesising neurons in the pigeon cloaca by enzyme histochemistry for reduced nicotinamide adenine dinucleotide phosphate-diaphorase (NADPH-d). NADPH-d-positive staining was seen in the neurons and fibres in the cloaca. The highest density of nerve fibres was noted in the coprodeum and the lowest in the proctodeum. In the coprodeum, NADPH-d neurons were found singly, formed small groups of 2–10 neurons, or were seen in plexuses in the muscle layer, lamina propria, or around the arterioles. Several NADPH-d-positive neurons were also observed in the ganglia of the cloaca. NADPH-d fibres ran in the muscle layer, lamina muscularis mucosae and lamina propria, or surrounded blood vessels. The distribution pattern of acetylcholinesterase (AChE)-stained neurons and fibres in the cloaca was similar to that of NADPH-d. Double staining for NADPH-d and AChE showed colocalisation of the 2 enzymes in many neurons of the cloaca. Tyrosine hydroxylase (TH)-immunoreactive nerve fibres originating outside the cloaca were also noted. In the urodeum and proctodeum, neurons or fibres positive for NADPH-d, AChE or TH were scattered in the lamina propria. Nerve fibres immunoreactive for calcitonin-gene related peptide, galanin, methionine-enkephalin, substance P, and vasoactive intestinal peptide were found sparsely in the cloaca. Our results demonstrate that nitrergic neurons constitute a subpopulation which is closely associated with the cholinergic system in the pigeon cloaca.

The pulmonary arterial smooth muscle cell (SMC) cytoskeleton was studied in tissue from 36 piglets aged from within 5 min of birth to 21 d of age, and in 8 adults. An additional 16 piglets were made pulmonary hypertensive by exposure to hypobaric hypoxia (50.8 kPa) for 3 d. In conduit intrapulmonary elastic arteries α, β and γ actin, the 204, 200 and 196 kDa myosin heavy chain (MHC) isoforms and vinculin were localised by immunohistochemistry. The total actin content, the proportion of monomeric to filamentous α and γ actin and changes in the proportions of the MHC isoforms were determined biochemically. Dividing SMCs were localised and quantified using Ki-67. We found a transient reduction in immunohistochemical expression of γ actin, 204 kDa MHC isoform and vinculin at 3 and 6 d in the inner media, associated with a transient increase in Ki-67 labelling. The actin content also decreased at 3 and 6 d (P < 0.05), but there was a postnatal, permanent increase in monomeric actin, first the α then the γ isoform. The relative proportions of the MHC isoforms did not change between birth and adulthood in elastic pulmonary arteries but in muscular arteries the 200 kDa isoform increased between 14 d and adulthood. Pulmonary hypertension prevented both the immunohistochemical changes and the postnatal burst of SMC replication and prevented the transient postnatal reduction in actin content. These findings suggest that rapid remodelling of the actin cytoskeleton is an essential prerequisite of a normal postnatal fall in pulmonary vascular resistance.

The contractile response of smooth muscles to spasmogens can be divided into two components by modifying the extracellular Ca2+ concentration. The phasic component depends on the mobilization of Ca2+ from intracellular stores whereas the tonic component depends, to a large extent, on the influx of extracellular Ca2+. The present study was designed to investigate the effect of ketamine on the tonic response to carbachol or histamine in the guinea pig trachea. Tracheal spirals from female guinea pigs were mounted in organ baths filled with aerated physiological buffer, and their isometric tension was measured. The phasic response to 10−7m carbachol or 10−5m histamine in Ca2+ -free, ethylene glycol-bis(β-aminoethyl ether)-N, N,N',N'-tetraacetic acid-containing buffer and the tonic response to each spasmogen after restoring [Ca2+] in the buffer was measured in the absence or presence of ketamine. In the presence of normal physiological buffer, ketamine decreased the contractions induced by carbachol or histamine in a dose-dependent fashion. No measurable phasic response to either carbachol or histamine was obtained in our preparation. Ketamine (5 × 10−5m−10−3m) reduced the tonic response to 10−7m carbachol to 79.5±2.7−4.3±0.7% of the response without ketamine. Similarly, ketamine (5 × 10−4m−2 × 10−3m) decreased the tonic response to 10−5m histamine to 80.7±3.9−23.0±3.2% of the response in the absence of ketamine. Our findings support the hypothesis that ketamine inhibits the paracrine agent-induced contractions of smooth muscles by interfering with the influx of extracellular Ca2+ or with an intracellular event(s) requiring extracellular Ca2+.

Splicing of exons 2 and 3 of α-tropomyosin (TM) involves mutually exclusive selection of either exon 3, which occurs in most cells, or of exon 2 in smooth muscle (SM) cells. The SM-specific selection of exon 2 results from the inhibition of exon 3. At least two essential cis-acting elements are required for exon 3 inhibition, the upstream and downstream regulatory elements (URE and DRE). These elements are essential for repression of TM exon 3 in SM cells, and also mediate a low level of repression of exon 3 in an in vitro 5′ splice site competition assay in HeLa extracts. Here, we show that the DRE consists of at least two discrete components, a short region containing a number of UGC motifs, and an essential pyrimidine-rich tract (DY). We show that the specific sequence of the DY element is important and that DY is able to bind to factors in HeLa nuclear extracts that mediate a low background level of exon 3 skipping. Deletion of a sequence within DY identified as an optimal binding site for PTB impairs (1) regulation of splicing in vivo, (2) skipping of exon 3 in an in vitro 5′ splice site competition, (3) the ability of DY competitors to affect the 5′ splice site competition in vitro, and (4) binding of PTB to DY. Addition of recombinant PTB to in vitro splicing reactions is able to partially reverse the effects of the DY competitor RNA. The data are consistent with a model for regulation of TM splicing that involves the participation of both tissue-specific and general inhibitory factors and in which PTB plays a role in repressing both splice sites of exon 3.