The effects of an acetylcholine analogue, carbachol (CCh), and a purified irreversible nicotinic antagonist, α-bungarotoxin (BTX), on the frequency of the miniature endplate potentials (mEPPs) at the neuromuscular junction of the frog were tested at 20 and 10¡C. CCh (5 ± 10-6 m) reduced the frequency of mEPPs to about 60 %; this reduction was not affected by 1 ± 10-7 g ml-1 BTX. BTX also reversibly decreased the mEPP frequency by 40 %, but not in the presence of CCh or in Ringer solution with 0 or 8 mM Ca2+. The present data show that BTX, which inhibits a class of nicotinic ACh receptors, does not block the decrease of mEPP frequency evoked by CCh and can itself suppress the frequency of spontaneous quantal release.

Deuterium oxide (D2O) is known to cause a negative inotropic effect in muscle although the mechanisms associated with this response in cardiac muscle are not well understood. We studied the effects of D2O in single rat ventricular myocytes in order to characterise the mechanisms associated with its negative inotropic effect and to assess its possible use as an acute modulator of microtubules. D2O rapidly reduced the magnitude of contraction in rat ventricular myocytes, and there was some recovery of contraction in the presence of D2O. Colchicine, an agent known to depolymerise microtubules, did not modify the effect of D2O. D2O decreased the L-type Ca2+ current (ICa), measured under whole cell and perforated patch clamp conditions. Slowing of the time to peak and a delay in inactivation of ICa were observed. Intracellular calcium ([Ca2+]i) and sodium ([Na+]i) were measured using the fluorescent indicators fura-2 and SBFI, respectively. The fall in contraction upon exposure to D2O was not associated with a fall in the [Ca2+]i transient; this response is indicative of a reduction in myofilament Ca2+ sensitivity. Both the [Ca2+]i transient and [Na+]i increased during the partial recovery of contraction in the presence of D2O. We conclude that a decrease in the myofilament sensitivity for Ca2+ and a reduction in Ca2+ influx via ICa are principally responsible for the negative inotropic effect of D2O in cardiac muscle. We found no evidence to explain the negative inotropic effect of D2O in terms of microtubule proliferation. In addition we suggest that acute application of D2O is not a useful procedure for the investigation of the role of microtubules in excitation-contraction coupling in cardiac muscle.

We investigated the permeability of Cs+ and Na+ through various ion channels in rat atrial myocytes using the whole-cell voltage-clamp technique. With isotonic CsCl (140 mM) on both sides of the membrane and nominally [Ca2+]o-free conditions, depolarising clamp pulses induced an increase of outward currents which showed a biphasic time course. Repolarisation to the holding potential induced inward tail currents. With isotonic NaCl, depolarisation also induced outward currents which showed a monotonic decay, but inward tail currents were not observed. Both in NaCl and CsCl, currents were hardly affected by TEA (10 mM), 4-AP (5 mM) and DIDS (100 µM). Nicardipine (1 M) almost completely blocked time-dependent outward currents in isotonic NaCl solution, leaving only time-independent currents which showed linear I-V relationship. In isotonic CsCl conditions, nicardipine blocked outward current considerably, but there still remained time-dependent outward currents and inward tail currents. Addition of E-4031 (2-20 M) which is known as a specific blocker of the rapidly activating delayed rectifier K+ current (IKr) completely blocked these time-dependent outward and inward currents, leaving only a time-independent current. Time-independent currents recorded in the presence of nicardipine and E-4031 were inhibited by GdCl3, which is known to block non-selective cation (NSC) currents. From these results, it was suggested that NSC current in atrial myocytes can be investigated in isotonic Cs+ or Na+ solution in the presence of Ca2+ channel and IKr blockers.

The effects of osmotic stress on the cytosolic Ca2+ concentration ([Ca2+]i) in the endothelium of excised intact rat aorta were investigated using the indicator fura-2 and the patch clamp technique. Hyperosmotic stress evoked a reversible rise in endothelial [Ca2+]i in the presence but not absence of extracellular Ca2+, indicating that it evoked Ca2+ entry without release from intracellular stores. Hyposmotic stress was without significant effect. Cytochalasins B and D reduced the effect of hyperosmotic stress but not acetylcholine on endothelial [Ca2+]i. In endothelium isolated from underlying smooth muscle, hyperosmotic stress produced a rise in the [Ca2+]i and depolarisation of the endothelial membrane potential whereas hyposmotic stress was without effect. Mechanosensitive cationic channels recorded in cell-attached patches were activated by hyperosmotic solutions applied to the endothelium and inhibited by hyposmotic solutions. These data suggest that shrinkage of endothelial cells evokes an increase in [Ca2+]i by opening a pathway for Ca2+ entry from the extracellular space. The mechanosensitive ionic channels which we have previously described may be responsible for this response.

The effects of cAMP accumulation evoked by acetylcholine (ACh) stimulation were studied in rat submandibular acinar cells by observing the exocytotic events, swelling of intercellular canaliculi (IC) and intracellular Ca2+ concentration ([Ca2+]i), which were monitored using an optical microscope. ACh stimulation evoked transient increases followed by sustained increases in the frequency of exocytotic events and IC swelling, while isoproterenol (isoprenaline; IPR) stimulation evoked sustained increases in these parameters. BAPTA treatment reduced the frequency of exocytotic events evoked by 5 µM ACh in the absence of extracellular Ca2+, and further addition of Rp-cAMPS or H-89 (protein kinase A (PKA) inhibitors) eliminated the remaining ACh-evoked responses (50 %). Addition of PKA inhibitors in the presence of extracellular Ca2+ reduced the frequency of exocytotic events evoked by 500 µM ACh in non-BAPTA-loaded cells. However, IC swelling evoked by 5 µM ACh was not affected by addition of PKA inhibitors, and was eliminated in BAPTA-loaded cells perfused with Ca2+-free solution. These results indicate that the IC swelling is regulated by [Ca2+]i and the frequency of exocytotic events is regulated by both [Ca2+]i and [cAMP]i during ACh stimulation. Addition of H-89 inhibited the capacitative Ca2+ entry into ACh-stimulated acinar cells. Biochemical analysis revealed that ACh stimulation increased the cAMP content in perfused submandibular glands. These results indicate that ACh stimulates the accumulation of cAMP in submandibular acinar cells and that this accumulation of cAMP modulates Ca2+-regulated exocytosis.

Electrical stimulation of the parasympathetic auriculo-temporal nerve (40 Hz, 30 min), in the anaesthetized rat under α- and β-adrenoceptor blockade, increased [3H]thymidine and [3H]leucine uptake into the parotid glands by 80 and 263 %, respectively. The increase in response to parasympathetic stimulation was almost the same ([3H]thymidine 82 % and [3H]leucine 283 %) when atropine (2 mg kg-1 I.P. or I.V.) was included in the pretreatment. Neither intravenous infusion of vasoactive intestinal peptide (0.5-20 mg kg-1 min-1, 30 min) nor of bethanechol (10 mg kg-1 min-1, 30 min), under adrenoceptor blockade, increased the uptake of [3H]thymidine into the glands. However, these drugs increased [3H]leucine uptake, and in combination they interacted positively. Whereas vasoactive intestinal peptide is likely to be involved in the parasympathetic nerve-evoked protein synthesis, the nature of the non-adrenergic, non-cholinergic component(s) involved in the mitogenic response is presently unknown.

The role of the paraventricular nucleus (PVN) of the hypothalamus in the cardiovascular response induced by blood volume expansion was examined in anaesthetised rabbits, in which simultaneous recordings were made from a renal sympathetic nerve and one of other sympathetic nerves, the inferior cardiac nerve, a splanchnic nerve and an adrenal nerve. Activation of PVN neurones, by discrete injections (25-100 nl) of d,l-homocysteic acid (DLH, 0.2 M) produced one main pattern of sympathetic nerve activity accompanying a pressor response (57-86 % of PVN sites). This was a decrease in renal sympathetic activity (27 +/- 12 %) and an increase in splanchnic (60 +/- 12 %), adrenal (31 +/- 9 %) and cardiac (42 +/- 8 %) sympathetic activity. Sites in the PVN from which these combinations of nerve activity were obtained were not confined to a specific subnucleus. An increase in renal sympathetic activity which was reversed to a decrease by reducing the volume of DLH injected was obtained at 10 sites in the PVN. These sites were mainly located in the dorsal parvocellular subnucleus. Varying combinations of sympathetic activation were obtained at a minority of sites. It is concluded that the PVN can evoke a differential pattern of sympathetic discharge which may be functionally significant in the control of blood volume regulation, as it mimics that seen on acute volume expansion.

We have examined the effect of tenotomy on the expression of myosin heavy chains (MyHC) in regenerating fast and slow skeletal muscles. Degeneration/regeneration of the left soleus and plantaris of Wistar male rats was induced by an injection into the muscle belly of a myotoxin (snake venom: Notechis scutatus scutatus). MyHC isoform content of regenerating plantaris and soleus muscles were studied 21 days after muscle injury using an electrophoretic technique. Tenotomy of the regenerating plantaris (mechanical underload) did not alter its MyHC expression (P > 0.05). In contrast, tenotomy of the regenerating soleus increased its relative levels of MyHC-2b (P < 0.05) and MyHC-2x/d (P < 0.01), and decreased its relative level of MyHC-1 (P < 0.01). Tenotomy of the synergistic gastrocnemius (overload) tended to decrease the relative level of MyHC-2b in regenerating plantaris (P < 0.07). The effect of tenotomy of the synergistic gastronecmius on the regenerating soleus was different: a decrease in the relative levels of MyHC-1 (P < 0.05) and an increase in the relative level of MyHC-neonatal (P < 0.01). In conclusion, and in contrast to a regenerating slow muscle, a change of mechanical loading by tenotomy did not seem to markedly alter the expression of mature MyHC phenotype in a fast regenerating muscle.

Incrementally applied static stretch over 3 weeks resulted in a 72 % increase in the weight of the in situ latissimus dorsi muscle in rabbits. True growth rather than tissue oedema was confirmed by increases in the protein content (130 %), the cross-sectional area of the type I fibres (30 %) and the muscle length (i.e. number of sarcomeres in series increased 25 %). Despite an increase in the proportion of fibres staining positive for the enzyme succinate dehydrogenase (SDH), the myosin ATPase stain showed no appreciable fibre type transformation. While total power output in the stretched muscle was unchanged, its maximum mass specific power output, as determined by oscillatory work loops, was decreased by 50 %. The cross-sectional area that was occupied by connective tissue increased from 15 to 19 % in the stretched muscles, with a concomitant increase in passive energy dissipation. Some incrementally stretched muscles were then allowed an additional 3 weeks of maintained stretch to determine whether the adaptive changes would be preserved or reversed. Previous gains in muscle weight, length and area of type I fibres all remained. In contrast, the connective tissue content and the passive properties returned to control values during this period.

Intravenous injection of growth hormone in anaesthetized pigs has been shown to cause coronary vasoconstriction by antagonizing the vasodilatory effects of β2-adrenergic receptors. Because nitric oxide is believed to modulate or mediate β2-adrenergic effects, the present study was undertaken in the same experimental model to determine the role of nitric oxide in the above response to growth hormone. In fourteen pigs anaesthetized with sodium pentobarbitone, changes in left circumflex or anterior descending coronary blood flow caused by intravenous injection of 0.05 i.u. kg-1 of growth hormone at constant heart rate and arterial blood pressure were assessed using electromagnetic flowmeters. In a first control group of six pigs, growth hormone caused a decrease in coronary blood flow which averaged 13.1 % of the baseline values. In a second group of eight pigs, intravenous administration of Nω-nitro-L-arginine methyl ester (L-NAME) was used to block the endothelial release of nitric oxide. In these pigs, the subsequent injection of growth hormone did not cause any significant changes in coronary blood flow, even when performed after reversing the increase in arterial blood pressure and coronary vascular resistance caused by L-NAME with continuous intravenous infusion of papaverine. These results indicated that the coronary vasoconstricting effect of growth hormone, known to involve antagonism of β2-adrenergic vasodilatory effect, was mediated by inhibition of nitric oxide release.

We used implanted miniature data loggers to measure brain and arterial blood temperatures in three free-ranging zebras (Equus burchelli) in their natural habitat, every 5 min for 9 days. The animals experienced globe temperatures exceeding 40°C, and radiant heat load of about 1000 W m-2. Arterial blood exhibited a moderate amplitude (1.7°C) nychthemeral rhythm, with an acrophase at 19.00 h and a nadir late in the morning, at 10.00 h. Brain temperature consistently exceeded blood temperature, on average by 0.2-0.4°C, and changes in brain temperature closely tracked changes in blood temperature. There was no evidence of selective brain cooling, even during the hyperthermia which followed surgery or that associated with intense, short-duration exercise. The relationship between brain and arterial blood temperatures in free-ranging zebras was unlike that reported for horses in the laboratory. Our results do not support the view that mammals lacking a carotid rete can achieve selective brain cooling.

The purpose of this study was to describe the influence of body size and sex on the decline in maximum oxygen uptake (O2,max) in older men and women. A stratified random sample of 152 men and 146 women, aged 55-86 years, was drawn from the study population. Influence of age on O2,max, independent of differences in body mass (BM) or fat-free mass (FFM), was investigated using the following allometric model: O2,max = BMb (or FFMb) exp(a + (c ' age) + (d ' sex)) [epsilon]. The model was linearised and parameters identified using standard multiple regression. The BM model explained 68.8 % of the variance in O2,max. The parameters (± s.e.e., standard error of the estimate) for lnBM (0.563 ± 0.070), age (-0.0154 ± 0.0012), sex (0.242 ± 0.024) and the intercept (-1.09 ± 0.32) were all significant (P < 0.001). The FFM model explained 69.3 % of the variance in O2,max, and the parameters (± s.e.e) lnFFM (0.772 ± 0.090), age (-0.0159 ± 0.0012) and the intercept (-1.57 ± 0.36) were significant (P < 0.001), while sex (0.077 +/- 0.038) was significant at P = 0.0497. Regardless of the model used, the age-associated decline was similar, with a relative decline of 15 % per decade (0.984 exp(age)) in O2,max in older humans being estimated. The study has demonstrated that, for a randomly drawn sample, the age-related loss in O2,max is determined, in part, by the loss of fat-free body mass. When this factor is accounted for, the loss of O2,max across age is similar in older men and women.

Neural mediation of the human cardiac response to isocapnic (IC) steady-state hypoxaemia was investigated using coarse-graining spectral analysis of heart rate variability (HRV). Six young adults were exposed in random order to a hypoxia or control protocol, in supine and sitting postures, while end-tidal PCO2 (PET,CO2) was clamped at resting eucapnic levels. An initial 11 min period of euoxia (PET,O2 100 mmHg; 13.3 kPa) was followed by a 22 min exposure to hypoxia (PET,O2 55 mmHg; 7.3 kPa), or continued euoxia (control). Harmonic and fractal powers of HRV were determined for the terminal 400 heart beats in each time period. Ventilation was stimulated (P < 0.05) and cardiac dynamics altered only by exposure to hypoxia. The cardiac interpulse interval was shortened (P < 0.001) similarly during hypoxia in both body positions. Vagally mediated high-frequency harmonic power (Ph) of HRV was decreased by hypoxia only in the supine position, while the fractal dimension, also linked to cardiac vagal control, was decreased in the sitting position (P < 0.05). However, low-frequency harmonic power (Pl) and the HRV indicator of sympathetic activity (Pl/Ph) were not altered by hypoxia in either position. These results suggest that, in humans, tachycardia induced by moderate IC hypoxaemia (arterial O2 saturation Sa,O2 85 %) was mediated by vagal withdrawal, irrespective of body position and resting autonomic balance, while associated changes in HRV were positionally dependent.

A method of telemetric measurement of antroduodenal myoelectrical activity (EMG) in freely moving pigs has been developed. Silver bipolar electrodes were sutured on the antrum and duodenum and connected to a telemetry transmitter implanted extraperitoneally between the abdominal muscles. The EMG signals were collected by a receiver, filtered, amplified and archived by a computer. The telemetric EMG signal did not differ from that obtained with a conventional wire method. Substantial differences between day and night migrating myoelectric complex (MMC) patterns were found. The advantages of telemetric EMG recording make it a useful tool for long-term recording of antroduodenal EMG.