Intracellular Ca antagonist TMB-8 blocks catecholamine secretion evoked by caffeine and acetylcholine from perfused cat adrenal glands in the absence of extracellular Ca

Unlike acetylcholine, caffeine was much more effective in releasing catecholamine in the absence of extracellular Ca²⁺ than in its presence in perfused cat adrenal glands. The intracellular Ca²⁺ antagonist, TMB-8 (10⁻⁴ M), inhibited reversibly the catecholamine secretion evoked by caffeine (40 mM) and that induced by acetylcholine (10⁻⁴ M) in the presence of hexamethonium (10⁻³ M) during perfusion with Ca²⁺-free Locke solution containing EGTA (10⁻⁵ M). These results support our view that muscarinic receptor activation causes catecholamine secretion by mobilizing Ca²⁺ from an intracellular pool just as caffeine does.     

Circulating leucocyte subpopulations in sedentary subjects following graded maximal exercise with hypoxia

Summary Ten healthy sedentary subjects [age, 27.5 (SD 3.5) years; height, 180 (SD 5) cm; mass, 69.3 (SD 6.3) kg] performed two periods of maximal incremental graded cycle ergometer exercise in a supine position. Randomly ordered and using an open spirometric system, one exercise was carried out during normoxia [maximal oxygen consumption ( O_2max)=38.6 (SD 3.5) ml·min^–1·kg^–1; maximal blood lactate concentration, 9.86 (SD 1.85) mmol·l^–1; test duration, 22.6 (SD 2.7) min], the other during hypoxia [ O_2max=33.2 (SD 3.2) ml·min^–1· kg^–1; maximal blood lactate concentration, 10.38 (SD 2.02) mmol·l^–1; test duration, 19.7 (SD 2.8) min]. At rest, immediately (0 p) and 60 min (60 p) after exercise, counts of leucocyte subpopulations (flow cytometry), cortisol and catecholamine concentrations were determined. At 0 p in contrast to normoxia, during hypoxia there was no significant increase of granulocytes. There were no significant differences between normoxia and hypoxia in the increases from rest to 0 p in counts of monocytes, total lymphocytes and lymphocyte subpopulations [clusters of differentiation (CD), CD3⁺, CD4⁺CD45RO^–, CD4⁺CD45RO⁺, CD8⁺CD45RO^–, CD8⁺CD45RO⁺, CD3⁺HLA-DR⁺, CD3^–CD16/CD56⁺, CD3⁺CD16/CD56⁺, CD 19⁺] as well as adrenaline, noradrenaline and cortisol concentrations. The counts of CD3 ^–CD16/CD56⁺-and CD8 ⁺CD45RO⁺-cells increased most. At 60 p, CD3^–CD16/CD56⁺ and CD3⁺CD16/CD56⁺-cell counts were below pre-exercise levels and under hypoxia slightly but significantly lower than under normoxia. We concluded that the exercise-induced mobilization and redistribution of most leucocyte and lymphocyte subpopulations were unimpaired under acute hypoxia at sea level. Reduced increases of granulocyte counts during the study and reduced cell numbers of natural killer cells and cytotoxic, not major histocompatibility complex-restricted T-cells, only indicated marginal effects on the immune system.     

Chemical neuromodulation of frontal-executive functions in humans and other animals

Neuromodulation of frontal-executive function is reviewed in the context of experiments on rats, monkeys and human subjects. The different functions of the chemically identified systems of the reticular core are analysed from the perspective of their possible different interactions with the prefrontal cortex. The role of dopamine in spatial working memory is reviewed, taking account of its deleterious as well as facilitatory effects. Baseline-dependent effects of dopaminergic manipulation are described in rats on an attentional task, including evidence of enhanced function following infusions of D1 receptor agonists into the prefrontal cortex. The precise nature of the cognitive task under study is shown to be a powerful determinant of the effects of mesofrontal dopamine depletion in monkeys. Parallels are identified in human subjects receiving drugs such as the indirect catecholamine agonists L-dopa, methylphenidate and the dopamine D2 receptor blocker sulpiride. The effects of these drugs on different types of cognitive function sensitive to frontal lobe dysfunction are contrasted with those of a manipulation of 5-HT function, dietary tryptophan depletion. Hypotheses are advanced that accord the ascending systems a greater deal of specificity in modulating prefrontal cortical function than has hitherto been entertained, and clinical and theoretical implications of this hypothesis are discussed.     

Chronic social stress: effects on limbic brain structures

Different types of stressors are known to activate distinct neuronal circuits in the brain. Acute physiological stimuli that are life threatening and require immediate reactions lead to a rapid stimulation of brainstem and hypothalamus to activate efferent visceral pathways. In contrast, psychological stressors activate higher-order brain structures for further interpretations of the perceived endangerment. Common to the later multimodal stressors is that they need cortical processing and, depending on previous experience or ongoing activation, the information is assembled within limbic circuits connecting, e.g., the hippocampus, amygdala and prefrontal cortex to induce neuroendocrine and behavioral responses. In view of the fact that stressful life events often contribute to the etiology of psychopathologies such as depressive episodes, several animal models have been developed to study central nervous mechanisms that are induced by stress. The present review summarizes observations made in the tree shrew chronic psychosocial stress paradigm with particular focus on neurotransmitter systems and structural changes in limbic brain regions.     

An excitatory action of 5-Hydroxytryptamine on sympathetic preganglionic neurones

Summary Preganglionic neurones in the fourth thoracic segment of anaesthetized cats fired spontaneously at a rate of about 2/sec. The effects of micro-electrophoretic administration of 5-hydroxytryptamine, noradrenaline, acetylcholine and DL-homocysteic acid on this spontaneous firing were determined. Many cells were excited by 5-hydroxytryptamine (5HT) and DL-homocysteic acid (DLH), a few were depressed by noradrenaline (NAdr), but acetylcholine (ACh) was inactive. The data are consistent with the view that 5HT and NAdr may function as excitatory and inhibitory transmitters which are released from the terminals of descending pathways in the spinal cord.National Science Foundation Postdoctoral Fellow, Riker Fellow.     

Influence of pH and pCO2 on Alpha-Receptor Mediated Contraction in Brain Vessels

The response of isolated brain vessels to various pH levels or carbon dioxide tensions was analyzed. Reduction of the pH induced a slight relaxation of the vessel, whereas an increase in the pH produced a slight contraction. These effects were markedly exaggerated when the alpha-adrenergic receptors in the vascular wall were activated by noradrenaline. During these conditions the contractile response to noradrenaline was reduced by about 40 per cent at a pH of 7.01, while, on the other hand, the response was enhanced 3-fold at a pH of 7.80. Variations in carbon dioxide tension of the buffer solution between 16 mmHg and 64 mmHg produced no consistent change, provided the pH remained constant. The results indicate that an interaction between the perivascular pH and the adrenergic alpha-receptor mediated contraction in brain vessels may occur.     

Noradrenaline and neophobia

Lesions of the ascending noradrenergic bundles using the selective neurotoxin 6-hydroxydopamine increased neophobia to a number of novel tastes in rats. These lesions also increased some, but not all, measures of neophobia in novel environments. The results are discussed with reference to a recent hypothesis which suggests that the noradrenergic projections of the locus coeruleus mediate some aspects of fear and anxiety. Contrary to the prediction of this hypothesis, the noradrenergic lesions significantly increased rather than decreased neophobia. While these results point to an involvement of ascending noradrenergic systems in fear, at present the nature of this involvement cannot be specified in detail.     

Effect of training on hormonal responses to exercise in competitive swimmers

Summary The effects of 9 weeks of training on responses of plasma hormones to swimming were studied in eight competitive swimmers who had not trained for several months. Two types of swimming tests were used: (1) 200 yd, a high intensity, exhausting type of exercise in which maximal effort was required both before and after training, and (2) 1000 yd, a pace type of exercise in which subjects swam as fast as possible prior to training and at the same rate after training. Plasma levels of glucagon increased and of insulin decreased during 1000 yd of swimming, but were not altered by 200 yd of swimming. No training effects were apparent in responses of plasma insulin and glucagon to these short-term, high intensity exercise tests. During the 1000 yd swim, plasma adrenaline was 0.8 ng/ml before vs. 0.1 ng/ml after training. Plasma noradrenaline response decreased from 3.4 to 1.2 ng/ml as a result of training. In the 200 yd swim, adrenaline, but not noradrenaline, was lower after training.R. C. Hickson and R. K. Conlee were postdoctoral research trainees supported by NIH Training Grant AM-05341.J. M. Hagberg was a postdoctoral research trainee supported by NIH Training Grant HL-07081.     

Masked excitatory action of noradrenaline on rat islet β-cells via activation of phospholipase C

The effect of noradrenaline (NE) on rat islet -cells was examined. NE reduced insulin secretion from rat islets exposed to extracellular solutions containing glucose at 5.5 or 16.6 mM. In islets treated with pertussis toxin (PTX), however, NE increased insulin secretion. The NE-induced augmentation of insulin secretion was inhibited by prazosin. In intact islets, NE increased phospholipase C (PLC) activity, an effect that was prevented by treatment of islets with U-73122. NE elevated intracellular [Ca²⁺] ([Ca²⁺]_i) in isolated -cells independently of PTX. Although this NE effect was inhibited by prazosin, phenylephrine did not mimic it. The [Ca²⁺]_i response to NE was also prevented by the treatment of cells with U-73122. NE produced depolarization of -cells followed by nifedipine-sensitive action potentials. NE reduced the whole-cell membrane currents through ATP-sensitive K⁺ channels (K_ATP), responsible for the depolarization. This NE effect was prevented by treatment of -cells with U-73122 or BAPTA/AM. Although at least some of our results imply the presence of ₁-adrenoceptors, -cells were not stained by a polyclonal IgG antibody recognizing all adrenergic ₁-receptor subtypes so far identified. These results suggest that an interaction of NE with an unknown type of receptor activates rat islet -cells via a PLC-dependent signal pathway. This effect is, however, masked by the inhibitory action via a PTX-sensitive pathway also activated by NE.     

Pressor effects of the injection of noradrenaline into different cerebroventricular spaces in unanesthetized rats

Injection of noradrenaline (NA) into the lateral cerebral ventricle (i.c.v.) was reported to cause blood pressure increase in unanesthetized rats, blocked by i.v. injection of vasopressin antagonists. We report similar responses to NA injection into the III or IV ventricles, suggesting multiple sites of action for i.c.v. NA. These responses were blocked by i.v. pretreatment with vasopressin antagonist, suggesting a common mediation by vasopressin release into circulation. Selected ventricular spaces were occluded with Nivea^® cream plugs to identify ventricular areas responding to i.c.v. NA. III ventricle or aqueduct occlusions markedly reduced pressor responses to i.c.v. NA. Microinjection of NA into the periaqueductal gray matter (PAG) caused pressor responses that were similar to those of i.c.v. NA, reinforcing the idea of a site of action in the aqueduct. IV ventricle occlusion only partially blocked the response to i.c.v. NA. The results suggest at least two sites of action for i.c.v. NA in unanesthetized rats. A primary site located in the PAG and another on the IV ventricle wall.