Effects of nonspecific beta-adrenergic stimulation and blockade on blood coagulation in hypertension.

A hypercoagulable state might contribute to increased atherothrombotic risk in hypertension. The sympathetic nervous system is hyperactive in hypertension, and it regulates hemostatic function. We investigated the effect of nonspecific beta-adrenergic stimulation (isoproterenol) and blockade (propranolol) on clotting diathesis in hypertension. Fifteen hypertensive and 21 normotensive subjects underwent isoproterenol infusion in two sequential, fixed-order doses of 20 and then 40 ng. kg(-1). min(-1) for 15 min/dose. Thirteen subjects were double-blind studied after receiving placebo or propranolol (100 mg/day) for 5 days each. In hypertensive subjects, isoproterenol elicited a dose-dependent increase in plasma von Willebrand factor (vWF) antigen [F(2,34) = 5.02; P = 0.032] and a decrease in D-dimer [F(2,34) = 4.57; P = 0.040], whereas soluble tissue factor remained unchanged. Propranolol completely abolished the increase in vWF elicited by isoproterenol [F(1,12) = 10.25; P = 0.008] but had no significant effect on tissue factor and D-dimer. In hypertension, vWF is readily released from endothelial cells by beta-adrenergic stimulation, which might contribute to increased cardiovascular risk. However, beta-adrenergic stimulation alone may not be sufficient to trigger fibrin formation in vivo.     

Spiral waves of spreading depression in the isolated chicken retina

Existence of the theoretically predicted spiral waves of excitation in intact two-dimensional networks of excitable elements has been experimentally confirmed in the isolated chicken retina. The preparation supports the waves of Leão's spreading depression (SD) the concentric propagation of which from the point of origin can be directly observed as a change of the optical properties of the retinal tissue. The propagation rate of 3.7 mm/min (35°C) decreased to 1.5 mm/min for SD waves elicited during relative refractory period. When a several-mm long segment of the SD wave had been blocked by anodal polarization, the laterally opened ends of the wavefront started to spread after termination of polarization into the previously blocked tissue, gradually turning around and penetrating into the region recovering from the original SD. One or two simultaneously generated spiral waves of SD continued to rotate for several cycles. Spiral SD could also be elicited by punctiform cathodal polarization (1 mA) applied to the SD wave-rear. Since the new SD wave could only spread into the recovering tissue it formed a laterally open wavefront, the free ends of which eventually turned around and started spiral SD. With continued reverberation the nucleus of the spiral SD wave gradually migrated across the retina until it approached an obstacle (e.g., pecten) which stopped further spiral propagation. Spiral SD waves were elicited in 31 retinal preparations and lasted for 4.5 cycles on the average. Average cycle duration was 4.7 min. Spontaneous spiral SD waves were observed in preparations incubated in Mg²⁺-free media. The spiral SD waves in retina are compared with mathematical models of analogous phenomena. It is argued that spiral SD waves probably exist in the cerebral cortex of rats and account for generation of repetitive SD waves sometimes elicited by overlapping stimulation of two cortical regions.     

Inhibition of the Electrically Evoked Release of [3H]Acetylcholine in Rat Striatal Slices: An Experimental Model for Drugs that Enhance Dopaminergic Neurotransmission

The activation by endogenous dopamine of the inhibitory 3,4-dihydroxyphenylethylamine (dopamine) receptors modulating the electrically evoked release of [3H]acetylcholine [( 3H]ACh) and [3H]dopamine in rat striatal slices is a function of the concentration of dopamine accumulated in the synaptic cleft during electrical stimulation. When the release of 3H-neurotransmitters was elicited with a 2-min period of stimulation at a frequency of 1 Hz, neither dopamine autoreceptors nor dopamine receptors modulating [3H]ACh were activated by endogenously released dopamine. On the other hand, exposure to (S)-sulpiride facilitated the release of [3H]dopamine and [3H]ACh elicited when the 2-min stimulation was carried out at a frequency of 3 Hz but this effect was not observed at a lower frequency of stimulation (1 Hz). In the presence of amphetamine the dopamine receptors modulating the electrically evoked release of [3H]ACh can be activated by endogenous dopamine even at the lower frequency of stimulation (1 Hz). Similar effects can be obtained if the neuronal uptake of dopamine is inhibited by cocaine or nomifensine. The inhibition by amphetamine of the release of [3H]ACh elicited by electrical stimulation at 1 Hz involves dopamine receptors and can be fully antagonized by clozapine, haloperidol, chlorpromazine, or pimozide. The stereoselectivity of this antagonism can be demonstrated with the optical enantiomers of sulpiride and butaclamol. This inhibitory effect of amphetamine on cholinergic neurotransmission appears to be the result of the stimulation of dopamine receptors of the D2 subtype, as they were resistant to blockade by the preferential D1 receptor antagonist SCH 23390.(ABSTRACT TRUNCATED AT 250 WORDS)     

[3H]Imipramine Is Accumulated but Not Released from Slices of the Rabbit Caudate and Hypothalamus

Abstract: Slices of rabbit caudate and hypothalamus take up and accumulate [³H]imipramine. In superfused slices of both structures electrical stimulation or exposure to tyramine failed to release recently taken up [³H]imipramine. De-polarization by exposure to 30–60 mm-potassium caused only a small release of [³H]imipramine that was not concentration-dependent. The release of [³H]imipramine by high potassium was independent of the presence of calcium ions in the superfusion medium. These results contrasted with those obtained for the release of [³H]dopamine from the caudate and [³H]noradrenaline from the hypothalamus, where tyramine, electrical stimulation, and high potassium caused a significant release of the labeled neurotransmitters. The release of [³H]dopamine from the caudate and [³H]noradrenaline from the hypothalamus elicited by electrical stimulation or high potassium was entirely calcium-dependent. It is concluded that [³H]imipramine is taken up into the two brain regions and is accumulated in a nonvesicular site from which it is not released by calcium-dependent depolarizing stimuli.     

Cyclic GMP Formation and Inositol Phosphate Accumulation Do Not Share Common Origins in Rat Brain Slices

Cyclic GMP formation and inositol phospholipid hydrolysis were studied in rat brain slices to determine if the two processes have common origins. Muscarinic cholinergic stimulation enhanced [3H]inositol phosphate ([ 3H]IP) accumulation from slices prelabelled with [3H]inositol but did not affect cyclic GMP formation in the cortex, striatum, or cerebellum. An elevated level of extracellular K+ stimulated accumulation of both cyclic GMP and [3H]IP in cortex slices. The former, but not the latter, was reduced by lipoxygenase and phospholipase A2 inhibition. Calcium channel activation enhanced and blockade reduced K+-stimulated [3H]IP formation without affecting the cyclic GMP level, and there were differences in the Ca2+ requirements for the two responses. Thus, there is no support for the concept that guanylate cyclase activation inevitably accompanies inositol phospholipid breakdown, and the evidence presented demonstrates that K+ stimulation promotes cyclic GMP and [3H]IP accumulation by different transducing pathways.     

THE EFFECT OF ELECTRICAL STIMULATION AND HIGH POTASSIUM CONCENTRATIONS ON THE EFFLUX OF [3H] γ-AMINOBUTYRIC ACID FROM BRAIN SLICES

Abstract— Brain slices were incubated with [³H]GABA in a medium containing aminooxyacetic acid to prevent metabolism of [³H]GABA by GABA-glutamate transaminase. The slices, which rapidly accumulated radioactivity, were then continuously perfused and the efflux of [³H]GABA from the tissue was measured. The spontaneous efflux of [³H]GABA consisted of an initial rapid phase followed by a much slower release of [³[H]GABA. After 40 min perfusion 90 per cent of the radioactivity remained in the tissue.
The slices were depolarized by electrical stimulation or by perfusion with a medium containing a high potassium concentration (40 mM). These procedures caused a striking increase in the efflux of [³H]GABA. The increased efflux produced by potassium, but not that produced by electrical stimulation, was dependent on calcium ions in the medium. The effect of electrical stimulation on [³H]GABA release was considerably reduced by a raised concentration (10 mM) of magnesium in the medium.
High potassium concentrations and electrical stimulation did not cause an increase in the efflux of [¹⁴C]urea, L-[³H]leucine or [¹⁴C]α-amino-isobutyric acid from brain slices. These results are consistent with the suggestion that GABA may be an inhibitory transmitter in the cerebral cortex.     

Potassium-Stimulated Release of [3HJTaurine from Cultured GABAergic and Glutamatergic Neurons

The effect of depolarizing concentrations of potassium (56 mM) on the release of [3H]taurine was examined in two types of cultured neurons from mouse brain: cerebral cortex neurons, which are largely GABAergic, and cerebellar neurons, which after treatment with kainate consist almost entirely of glutamatergic granule cells. The release of [3H]taurine was compared to that of gamma-[3H]aminobutyric acid [( 3H]GABA) in cortical neurons and to that of D-[3H]aspartate in granule cells. Cortical neurons responded to potassium stimulation (1 min or continuously) by an immediate increase in [3H]GABA efflux of more than six times over the basal efflux, followed by a sharp decline despite the persistence of the stimulatory agent. The potassium-induced release of [3H]GABA was largely calcium-dependent. The release of [3H]taurine was considerably less in magnitude, only doubling after the stimulus, with a time course delayed in both onset and decline. The release of [3H]taurine was partially calcium-dependent and was also decreased in low-chloride solutions. In cerebellar granule cells, exposure to potassium resulted in a large (sixfold) and prompt release of D-[3H]aspartate, largely calcium-dependent. A totally different pattern was observed for the release of [3H]taurine. A stimulatory effect occurred only when cells were exposed continuously to potassium. Taurine efflux was very delayed, with a broad stimulus plateau reached after 15-20 min of stimulation. Taurine release was unaffected by omission of calcium, but it was abolished in a low-chloride medium. These results suggest that taurine is released from cells handling other neuroactive amino acids as neurotransmitters.(ABSTRACT TRUNCATED AT 250 WORDS)     

Electron probe X-ray microanalysis of cellular ions in the eccrine secretory coil cells during methacholine stimulation

Summary Intracellular concentrations of Na, K, Cl ([Na], [K] and [Cl], respectively) and other elements were determined in isolated monkey eccrine sweat secretory coil cells using quantitative electron probe X-ray microanalysis of freeze dried cryosections. The validity of the methodology was partially supported by qualitative agreement of the X-ray microanalysis data with those obtained by micro-titration with a helium glow spectrophotometer. [Na], [K] and [Cl] of the cytoplasm were the same as those in the nucleus in both clear and dark cells. [Na], [K], and [Cl] of the clear cells were also the same as those of the dark cells at rest and after stimulation with methacholine (MCh), suggesting that these two cell types behave like a functional syncytium. MCh stimulation induced a pharmacologically specific, dose-dependent decrease in [K] and [Cl] (as much as 65%), and a 3.7-fold increase in [Na]. In myoepithelial cells, a similar change in [Na] and [K] was noted after MCh stimulation although the decrease in [Cl] was only 20%. The MCh-induced change in [Na], [K] and [Cl] was almost completely inhibited by removal of Ca²⁺ from the medium. 10^–4 m bumetanide inhibited the MCh-induced increase in [Na], reduced the decrease in [K] by about 50%, but slightly augmented the MCh-induced decrease in [Cl]. 10^–4 m ouabain increased [Na] and decreased [K] as did MCh; however, unlike MCh, ouabain increased [Cl] by 56% after 30 min of incubation. Thus the data may be best interpreted to indicate that Ca-dependent K efflux and (perhaps also Ca-dependent) Cl efflux are the predominat initial ionic movement in muscarinic cholinergic stimulation of the eccrine sweat secretory coils and that the ouabain-sensitive Na pump plays an important role in maintenance of intracellular ions and sweat secretion.     

Investigation of the preferred Mg(II)-adenine-nucleotide complex at the active site of ectonucleotidases in intact vascular cells using phosphorothioate analogues of ADP and ATP

In the presence of Mg2+ the ecto-(nucleoside diphosphatase) on intact vascular endothelial or smooth muscle cells in culture selectively catabolizes the PS diastereoisomer of adenosine 5'-[alpha-thio]diphosphate, (PS)-ADP [alpha S], and the ecto-(nucleoside triphosphatase) selectively catabolizes the PS isomer of adenosine 5'-[beta-thio]triphosphate, (PR)-ATP[beta S], but exhibits no selectivity towards ATP[alpha S] isomers. In the presence of Cd2+ selectivity to ADP[alpha S] and to ATP[beta S] isomers is reversed; in the presence of Co2+, selectivity is lost. We conclude that each enzyme preferentially recognises the lambda (screw-sense) bidentate Mg(II)-nucleotide complex at its active site.     

Inhibitory effect of azelastine hydrochloride on synthesis and release of platelet activating factor from human alveolar macrophages

The effect of azelastine hydrochloride (azelastine) on synthesis and release of platelet activating factor (PAF) in alveolar macrophages obtained from asthmatic and non-asthmatic subjects was examined. Alveolar macrophages (AMs) were preincubated with or without azelastine and stimulated with f-Met-Leu-Phe (fMLP, 10 μM) for 15 min. PAF activity was detected by aggregation of washed guinea pig platelets. PAF activity released from alveolar macrophages (AMs) from asthmatics without preincubation of azelastine was 15.97 [2.17] (mean [SD], ng/10⁷ cells) in supernatants and 42.52 [10.16] in cell pellets. After preincubation with 10⁻⁸, 10⁻⁶, and 10⁻⁴ M of azelastine, PAF activity reduced to 10.71 [2.73] (mean [SD], ng/10⁷ cells), 7.86 [0.94], and 3.52 [0.31] in the supernatants, and 35.58 [7.37], 21.57 [4.36], and 14.77 [0.99] (n = 15) in the cell pellets, respectively.PAF activity in non-asthmatic subjects without preincubation of azelastine was 8.55 [1.16] (mean [SD], ng/10⁷ cells) in supernatants and 32.64 [3.37] in cell pellets. After preincubation with 10⁻⁸, 10⁻⁶, and 10⁻⁴ M of azelastine, PAF activity reduced to 6.68 [0.78] (mean [SD], ng/10⁷ cells), 4.47 [0.51], and 2.97 [0.36] in the supernatants, and 29.53 [3.75], 14.78 [1.95], and 6.16 [0.55] (n = 20) in the cell pellets, respectively.Our results showed that preincubation with azelastine caused a dose-dependent inhibition of intra- and extracellular PAF activity from asthmatic and non-asthmatic macrophages in the same manner.     

NaHCO3-induced alkalosis reduces the phosphocreatine slow component during heavy-intensity forearm exercise.

During heavy-intensity exercise, the mechanisms responsible for the continued slow decline in phosphocreatine concentration ([PCr]) (PCr slow component) have not been established. In this study, we tested the hypothesis that a reduced intracellular acidosis would result in a greater oxidative flux and, consequently, a reduced magnitude of the PCr slow component. Subjects (n = 10) performed isotonic wrist flexion in a control trial and in an induced alkalosis (Alk) trial (0.3g/kg oral dose of NaHCO3, 90 min before testing). Wrist flexion, at a contraction rate of 0.5 Hz, was performed for 9 min at moderate- (75% of onset of acidosis; intracellular pH threshold) and heavy-intensity (125% intracellular pH threshold) exercise. 31P-magnetic resonance spectroscopy was used to measure intracellular [H+], [PCr], [Pi], and [ATP]. The initial recovery data were used to estimate the rate of ATP synthesis and oxidative flux at the end of heavy-intensity exercise. In repeated trials, venous blood sampling was used to measure plasma [H+], [HCO3-], and [Lac-]. Throughout rest and exercise, plasma [H+] was lower (P < 0.05) and [HCO3-] was elevated (P < 0.05) in Alk compared with control. During the final 3 min of heavy-intensity exercise, Alk caused a lower (P < 0.05) intracellular [H+] [246 (SD 117) vs. 291 nmol/l (SD 129)], a greater (P < 0.05) [PCr] [12.7 (SD 7.0) vs. 9.9 mmol/l (SD 6.0)], and a reduced accumulation of [ADP] [0.065 (SD 0.031) vs. 0.098 mmol/l (SD 0.059)]. Oxidative flux was similar (P > 0.05) in the conditions at the end of heavy-intensity exercise. In conclusion, our results are consistent with a reduced intracellular acidosis, causing a decrease in the magnitude of the PCr slow component. The decreased PCr slow component in Alk did not appear to be due to an elevated oxidative flux.     

Rapid accumulation and sustained turnover of inositol phosphates in cerebral-cortex slices after muscarinic-receptor stimulation.

The rapid kinetics of [3H]inositol phosphate accumulation and turnover were examined in rat cerebral-cortex slices after muscarinic-receptor stimulation. Markedly increased [3H]inositol polyphosphate concentrations were observed to precede significant stimulated accumulation of [3H]inositol monophosphate. New steady-state accumulations of several 3H-labelled products were achieved after 5-10 min of continued agonist stimulation, but were rapidly and effectively reversed by subsequent receptor blockade. The results show that muscarinic-receptor activation involves phosphoinositidase C-catalysed hydrolysis initially of polyphosphoinositides rather than of phosphatidylinositol. Furthermore, prolonged carbachol stimulation is shown not to cause receptor desensitization, but to allow persistent hydrolysis of [3H]phosphatidylinositol bisphosphate and permit sustained metabolic flux through the inositol tris-/tetrakis-phosphate pathway.     

Chloride concentration of rat parotid saliva evoked by electrical stimulation of parasympathetic or sympathetic nerves with or without antagonists

Chloride (Cl) of saliva evoked by electrical stimulation of the parasympathetic nerve to parotid gland was from two to seven times higher than that elicited with sympathetic nerve stimulation; [Cl] remained elevated (125-135 mEq/liter) for 60 min of parasympathetic nerve stimulation, whereas Cl of sympathetically evoked saliva decreased from high levels of 58 to 15 to 20 mEq/liter. The administration of propranolol, the beta-adrenergic antagonist, 20 min prior to initiation of sympathetic nerve stimulation resulted in saliva with Cl of 100 mEq/liter; when phentolamine, the alpha-adrenergic antagonist was administered prior to sympathetic nerve stimulation, [Cl] was 48-35 mEq/liter. Values with the beta-agonist, isoproterenol, were about 35 mEq/liter, whereas phenylephrine, an alpha-adrenergic agonist, evoked saliva with Cl ranging from 113 to 85 mEq/liter. Flow rate was very high with parasympathetic nerve stimulation and low with sympathetic nerve stimulation, but [Cl] with beta-blockade was not flow dependent: flow was very low but Cl high. Cl secretion is principally regulated by activation of cholinergic and alpha-adrenergic receptors.     

Modulation of [3H]dopamine release from rabbit retina

The calcium-dependent release of [3H]dopamine ([3H]DA) elicited by field stimulation or potassium is modulated through activation of stereoselective inhibitory DA autoreceptors of the D-2 subtype that are pharmacologically different from the D-1 DA receptor subtype linked to the stimulation of adenylate cyclase (EC 4.6.1.1). The D-2 DA autoreceptors appear to be endogenously activated by DA because DA receptor antagonists such as S-sulpiride increased the stimulation-evoked release of [3H]DA. Nanomolar concentrations of norepinephrine (NE) and epinephrine (E) inhibited in a concentration-dependent manner the electrical stimulation-evoked release of [3H]DA. The inhibitory effect of these catecholamines was not modified by S-sulpiride, which, on the contrary, selectively antagonized the inhibition of [3H]DA release elicited by exogenous DA. Phentolamine or (+/-)-propranolol did not affect the release of [3H]DA from rabbit retina. The alpha antagonist phentolamine competitively antagonized the inhibitory effect of both NE and E, which suggests that these catecholamines activate alpha receptors in retina. The decrease by catecholamines of the calcium-dependent release of [3H]DA appears not to involve beta adrenoceptors because their inhibitory effect was not modified by propranolol. Under identical experimental conditions (i.e., nomifensine, 30 microM), serotonin did not modify the stimulated release of [3H]DA. In conclusion, in the rabbit retina, DA autoreceptors of the D-2 subtype appear to modulate endogenously released DA whereas inhibitory presynaptic alpha receptors might be of pharmacological importance as sites of action for retinal or blood-borne catecholamines.     

Perception matches selectivity in the human anterior color center

Human ventral cortex contains at least two visual areas selective for color [1]: a posterior center in the lingual gyrus labeled V4 [2-4], V8 [5], or VO-1 [6] and an anterior center in the medial fusiform that has been labeled V4alpha[3, 4]. We examined the properties of the anterior color center using electrical recording and electrical stimulation in a subject with an electrode implanted over the anterior color center, as determined with BOLD fMRI in the same subject. Presentation of visual stimuli evoked local field potentials from the electrode. Consistent with fMRI, the potentials were larger for chromatic than achromatic stimuli. The potentials differed depending on stimulus color, with blue-purple colors evoking the largest response. The spatial receptive field of the electrode was central/parafoveal with a contralateral bias. In the absence of a visual stimulus, electrical stimulation of the electrode produced an artificial visual percept of a blue-purple color near the center of gaze. These results provide direct evidence of a tight link between selectivity and perception in ventral temporal cortex. Electrical stimulation of the anterior color center is sufficient to produce the conscious percept of a color whose identity is determined by the selectivity of the stimulated neurons.     

Nonsomatotopic Organization of the Higher Motor Centers in Octopus

Hyperredundant limbs with a virtually unlimited number of degrees of freedom (DOFs) pose a challenge for both biological and computational systems of motor control. In the flexible arms of the octopus, simplification strategies have evolved to reduce the number of controlled DOFs [1], [2] and [3]. Motor control in the octopus nervous system is hierarchically organized [4] and [5]. A relatively small central brain integrates a huge amount of visual and tactile information from the large optic lobes and the peripheral nervous system of the arms [6], [7], [8] and [9] and issues commands to lower motor centers controlling the elaborated neuromuscular system of the arms. This unique organization raises new questions on the organization of the octopus brain and whether and how it represents the rich movement repertoire. We developed a method of brain microstimulation in freely behaving animals and stimulated the higher motor centers—the basal lobes—thus inducing discrete and complex sets of movements. As stimulation strength increased, complex movements were recruited from basic components shared by different types of movement. We found no stimulation site where movements of a single arm or body part could be elicited. Discrete and complex components have no central topographical organization but are distributed over wide regions.     

Control of phosphatidylinositol turnover in adrenal glomerulosa cells

The purpose of the present experiments was to compare the effects on phosphatidylinositol metabolism of agents stimulating aldosterone secretion. Glomerulosa cells, isolated from rat adrenals, were incubated in the presence of one of the following stimuli: angiotensin II, elevated potassium concentration, corticotropin, dibutyryl cyclic AMP and prostaglandin E2. Of all these substances, only angiotensin II stimulated the incorporation of [32P]phosphate into phosphatidylinositol. The effect was already detected 2.5 min and was still maintained 60 min after the onset of stimulation. A slight enhancement of the incorporation into other phospholipids was observed in the first minutes of stimulation. Cycloheximide abolished the effect of angiotensin II on aldosterone production, but not on phosphatidylinositol synthesis. In cells prelabelled with [32P]phosphate, radioactivity in phosphatidylinositol relative to that in other phospholipids decreased in response to angiotensin II within 5 min. This indicates that angiotensin II induces a specific breakdown of phosphatidylinositol. Corticotropin failed to enhance the incorporation of [32P]phosphate into phosphatidylinositol and other phospholipids in isolated fasciculate-reticularis cells. The results suggests that although both angiotensin II and potassium are presumed to act through changes in calcium metabolism, angiotensin alone generates the calcium signal by increased phosphatidylinositol turnover.     

Persistent depolarization and Glu uptake inhibition operate distinct osmoregulatory mechanisms in the mammalian brain

The ways of coupling neuronal with glial compartments in natural physiology was investigated in microdialysis experiments by monitoring extracellular concentration of amino acids in the brain of anaesthetized rats. We hypothesized that extracellular [Glu], [Gln] and [Tau] patterns would be state-dependent. This was tested by stimulation of N-methyl-D-aspartate (NMDA) receptors, by inhibition of Glu uptake or by local depolarization with a high-K(+) dialysate, coupled with the addition of Co(2+) to block Ca(2+) influx. The results showed that (1) extracellular [Gln] was low whereas [Glu] and [Tau] were high during infusion of NMDA (0.5-1.0 mM) or high-K(+) (80 mM) in the hippocampus and ventrobasal thalamus, (2) hippocampal extracellular [Glu], [Gln] and [Tau] were increased in response to the Glu uptake inhibitor, L-trans-pyrrolidine-2, 4-dicarboxilic acid (tPDC, 0.5-3.0 mM), in a concentration-dependent manner, (3) high-K(+)-induced increase of extracellular [Glu] was partially blocked by the addition of 10 mM CoCl(2) with the high-K(+) dialysate in the hippocampus. Searching for main correlations between changes in [Glu], [Gln] and [Tau] by calculating partial correlations and with the use of factor analyses we found, the primary response of the mammalian brain to persistent depolarization is the neuronal uptake of [Gln] and release of [Tau] thereupon, acting independently of Glu changes. When glial and neuronal uptake of Glu is blocked, releases of Tau occur from neuronal as well as glial compartments accompanied by increases of [Gln] in the mammalian brain.     

Localization of the Repetitive Firing Generation Site Induced by 4-Aminopyridine at the Frog Neuromuscular Junction

In the neuromuscular junction, blockade of potassium channels can produce multiple discharges after single nerve stimulation. Multielectrode recording from the nerve trunk and myelinated and non-myelinated parts of the nerve ending demonstrated that repetitive presynaptic spikes elicited by 4-aminopyridine arise earliest within the part of the axon proximal to the motor nerve ending.     

Exercise induces lipoprotein lipase and GLUT-4 protein in muscle independent of adrenergic-receptor signaling.

Exercise increases the expression of lipoprotein lipase (LPL) and GLUT-4 in skeletal muscle. Intense exercise increases catecholamines, and catecholamines without exercise can affect the expression of both LPL and GLUT-4. To test the hypothesis that adrenergic-receptor signaling is central to the induction of LPL and GLUT-4 by exercise, six untrained individuals [age 28 +/- 4 (SD) yr, peak oxygen uptake 3.6 +/- 0.3 l/min] performed two exercise bouts within 12 days. Exercise consisted of cycling at approximately 65% peak oxygen uptake for 60 min with (block trial) and without (control trial) adrenergic-receptor blockade. Exercise intensity was the same during the block and control trials. Plasma catecholamine concentrations were significantly higher and heart rates were significantly lower during the block trial compared with the control trial, consistent with known effects of adrenergic-receptor blockade. However, blockade did not prevent the induction of either LPL or GLUT-4 proteins assayed in biopsies of skeletal muscle. LPL was significantly increased by 170-240% and GLUT-4 was significantly increased by 32-51% at 22 h after exercise compared with before exercise during both the control and block trials. These findings provide evidence that exercise increases muscle LPL and GLUT-4 protein content via signals generated by alterations in cellular homeostasis and not by adrenergic-receptor stimulation.