Running-induced anxiety is dependent on increases in hippocampal neurogenesis.

Exercise, specifically voluntary wheel running, is a potent stimulator of hippocampal neurogenesis in adult mice. In addition, exercise induces behavioral changes in numerous measures of anxiety in rodents. However, the physiological underpinnings of these changes are poorly understood. To investigate the role of neurogenesis in exercise-mediated anxiety, we examined the cellular and behavioral effects of voluntary wheel running in mice with a reduction in hippocampal neurogenesis, achieved through conditional deletion of ataxia telangiectasia-mutated and rad-3-related protein (ATR), a cell cycle checkpoint kinase necessary for normal levels of neurogenesis. Following hippocampal microinjection of an adeno-associated virus expressing Cre recombinase to delete ATR, mice were exposed to 4 weeks of voluntary wheel running and subsequently evaluated for anxiety-like behavior. Wheel running resulted in increased cell proliferation and neurogenesis, as measured by bromodeoxyuridine and doublecortin, respectively. Wheel running also resulted in heightened anxiety in the novelty-induced hypophagia, open field and light-dark box tests. However, both the neurogenic and anxiogenic effects of wheel running were attenuated following hippocampal ATR deletion, suggesting that increased neurogenesis is an important mediator of exercise-induced anxiety.

Activity of adenosine deaminase in the sleep regulatory areas of the rat CNS.

There are data to support the notion that adenosine (ADO), a neuromodulator in the CNS, is an important regulator of sleep homeostasis. It has been demonstrated that ADO agonists and antagonists strongly impact upon sleep. In addition, the level of adenosine varies across the sleep/wake cycle and increases following sleep deprivation. Adenosine deaminase (ADA) is a key enzyme involved in the metabolism of ADO. We questioned, therefore, whether there are differences in adenosine deaminase activity in brain regions relevant to sleep regulation. We found that ADA exhibits a characteristic spatial pattern of activity in the rat CNS with the lowest activity in the parietal cortex and highest in the region of the tuberomammillary nucleus (15.0+/-4.8 and 63.4+/-28.0 nmoles/mg protein/15 min, mean+/-S.D., respectively). There were significant differences among the brain regions by one-way ANOVA (F=31.33, df=6, 123, P=0.0001). The regional differences in ADA activity correlate with variations in the level of its mRNA. This suggests that spatial differences in ADA activity are the result of changes in the expression of the ADA gene. We postulate that adenosine deaminase plays an important role in the mechanism that controls regional concentration of adenosine in the brain and thus, it is a part of the sleep-wake regulatory mechanism.

Respiratory activity in the facial nucleus in an in vitro brainstem of tadpole, Rana catesbeiana.

1. In studies of the central neural control of breathing, little advantage has been taken of comparative approaches. We have developed an in vitro brainstem preparation using larval Rana catesbeiana which generates two rhythmic neural activities characteristic of lung and gill ventilation. Based on the pattern of the facial (VII) nerve activity both lung and gill rhythm-related respiratory cycles were divided into three distinct phases. The purpose of this study was to characterize and classify membrane potential trajectories of respiratory motoneurons in the VII nucleus at intermediate stages (XII-XVII) of development. 2. Seventy-five respiratory-modulated neurons were recorded intracellularly within the facial motor nucleus region. Their resting membrane potential was between -40 and -80 mV. Sixty of them were identified as VII motoneurons and fifteen were non-antidromically activated. Membrane potentials of fifty-six of the seventy-five neurons were modulated with both lung (5-27 mV) and gill rhythms (3-15 mV) and the remaining nineteen neurons had only a modulation with lung rhythmicity (6-23 mV). No cells with gill modulation alone were observed. 3. All of the cells modulated with lung rhythmicity had only phase-bound depolarizing or hyperpolarizing membrane potential swings which could be categorized into four distinct patterns. In contrast, of the fifty-six cells modulated with gill rhythmicity, thirty-two were phasically depolarized during distinct phases of the gill cycle (four patterns were distinguished), whereas the remaining twenty-four were phase spanning with two distinct patterns. The magnitudes of lung and gill modulations were proportionally related to each other in the cells modulated with both rhythms. 4. In all sixteen neurons studied, a reduction or a reversal of phasic inhibitory inputs during a portion of the lung or gill respiratory cycle was observed following a negative current or chloride ion (Cl-) injection. The phasic membrane resistance modulation in relation to the gill rhythm was analysed in six neurons and a relative decrease in the somatic membrane resistance (0.7-8.1 M omega) was detected during the periods of hyperpolarization. 5. We propose that, at these intermediate stages of development: (a) both gill and lung respiratory oscillations in motoneurons are generated by respiratory premotor neurons having only a few distinct activity patterns; (b) these patterns delineate distinct portions of the centrally generated respiratory cycles; and (c) phasic synaptic inhibition, mediated by Cl-, contributes to shaping the membrane potential trajectories of respiratory motoneurons.

Role of chloride-mediated inhibition in respiratory rhythmogenesis in an in vitro brainstem of tadpole, Rana catesbeiana.

1. The isolated brainstem of larval Rana catesbeiana maintained in vitro generates neural bursts that correspond to the lung and gill ventilatory activity generated in the intact specimen. To investigate the role of chloride channel-dependent inhibitory mechanisms mediated by GABA(A) and/or glycine receptors on fictive lung and gill ventilation, we superfused the isolated brainstems with agonists, antagonists (bicuculline and/or strychnine) or a chloride-free solution while recording multi-unit activity from the facial motor nucleus. 2. Superfusion with the agonists (GABA or glycine) produced differential effects on frequency, amplitude and duration of the neural bursts related to lung and gill ventilation. At a GABA or glycine concentration of 1.0 mM, fictive gill bursts were abolished while fictive lung bursts persisted, albeit with reduced amplitude and frequency. 3. At the lowest concentrations used (1.0-2.5 microM), the GABA(A) receptor antagonist bicuculline produced an increase in the frequency of lung bursts. At higher concentrations (5.0-2.0 microM) bicuculline produced non-specific excitatory effects. The glycine antagonist strychnine, at concentrations lower than 5.0 microM, caused a progressive decrease in the frequency and amplitude of the gill bursts and eventually abolished the rhythmic activity. At higher concentrations (7.5 microM), non-specific excitatory effects occurred. Superfusion with bicuculline (10 microM) and strychnine (5 microM) combined abolished the neural output for gill ventilation but increased the frequency, amplitude and duration of lung bursts. 4. Superfusion with Cl(-)-free solution also abolished the rhythmic neural bursts associated with gill ventilation, while it significantly increased the amplitude (228 +/- 51%; P < 0.05) (mean +/- S.E.M.) and duration of the lung bursts (3.5 +/- 0.1 to 35.3 +/- 3.7 s; P < 0.05) and improved the regularity of their occurrence. 5. We conclude that different neural systems generate rhythmic activity for lung and gill ventilation. Chloride-mediated inhibition may be essential for generation of neural bursts associated with gill ventilation. In contrast, the burst associated with lung ventilation can be generated in the absence of Cl(-)-mediated inhibition although the latter plays a role in shaping the normal lung burst.

Role of lung inflation in control of air breath duration in African lungfish (Protopterus annectens).

Studies were conducted in the African lungfish (Protopterus annectens) to investigate the role of lung inflation on control of the duration of the lung breath. The studies were done in decerebrate spinalectomized animals. Two types of tests were performed: 1) a no-inflation test (airway occluded) in which the lungs were not inflated during an air breath, and 2) an inflation test in which the lungs were inflated at the onset of the lung breath to different levels of intrapulmonary pressure (2.5, 5.0, 7.5, and 10.0 cmH2O). Lung inflation shortened the duration of the lung breath. The relationship between intrapulmonary pressure and breath duration was curvilinear and similar to the relationship between tidal volume and inspiratory duration in mammals. Likewise, the relationship could be described by a hyperbola with a linear relationship between intrapulmonary pressure and the inverse of breath duration. This relationship was essentially not affected by changing the composition of the gas used to inflate the lungs: air, oxygen, or nitrogen. Vagotomy, however, largely abolished the effect of lung inflation on breath duration. Because there is such similarity between these results and effect of lung inflation on control of inspiratory time in mammals, it is postulated that neural circuits for control of respiratory timing were already developed and similar in the lungfish. Because the muscles used in the lungfish to ventilate the lung are totally different (buccal force pump) from those in mammals, the neural circuits for timing control and those for shaping the pattern of motor output appear to be separate.(ABSTRACT TRUNCATED AT 250 WORDS)

Control of interbreath interval in the African lungfish.

We have performed studies to examine the effect of variations in intrapulmonary pressure on the interval between lung breaths in the African lungfish. Studies were performed in two different preparations. In the first we produced changes in lung pressure using a controlled-infusion pump. Increases in intrapulmonary pressure prolonged the interval between lung breaths. At a pressure of 2.5 cmH2O the average interval was 2.6 +/- 1.8 min (mean +/- SD); at 5.0 cmH2O, 8.1 +/- 3.5 min; and at 7.5 cmH2O, 16.2 +/- 3.8 min. Inflations of the lung early in the interbreath interval had less of an effect on its duration than inflations later in the interval. In the second preparation we used a system in which gas flowed continuously through both lungs. Intrapulmonary pressure was varied by changing outlet pressure and O2 concentration by changing the composition of the gas mixture. This allowed separate control of both O2 concentration and intrapulmonary pressure. At a fixed O2 concentration intrapulmonary pressure increased the duration of the interval between lung breaths. At a fixed pressure, reductions in O2 concentration shortened the interval. There was no significant interactive effect of O2 and pressure. Lung inflation did not alter the frequency of gill ventilation. These results imply that a reflex highly similar to the Hering-Breuer expiratory-promoting reflex was already present in the African lungfish.

Response of stretch receptors to static inflations and deflations in an isolated tracheal segment.

It has been proposed on the basis of differing responses to static lung inflations that there are two types of pulmonary stretch receptor which are organized in series or in parallel with airway smooth muscle. However, in prior studies, in which we examined the responses of a few receptors in a number of animals, we were unable to confirm this finding. In the present study we sought to definitively address this question by examining the response of a reasonable sample of receptors (greater than or equal to 5) from a single airway with a controlled mechanical environment. We examined the firing patterns of slowly adapting receptors in a tracheal segment, isolated in vivo, during inflations and deflations to different static levels of pressure between -20 and +30 cm H2O. The relationship between afferent firing and intra-tracheal pressure under static conditions was determined. We did not observe any evidence to support the existence of two distinct subtypes of receptors. During these studies we also looked for abrupt changes in the variability of afferent firing during the period of adaptation after the end of an inflation or deflation. Such changes have been described for other receptors with branched endings capable of generating spike potentials. These changes occur when the region generating the spike train seen in the parent fiber switches from one branch to another (pace-maker switching) and reflect the difference in the intrinsic variability of each branch. In the majority of fibers studied we saw no evidence of such switching and thus of the presence of multiple encoders in the receptor structure.

Responses of pulmonary stretch receptors during ramp inflations of the lung.

Studies were conducted in anesthetized paralyzed dogs to determine how the dynamic and proportional sensitivity of pulmonary stretch receptors change during lung inflation. The firing of each receptor was examined at multiple levels of static transpulmonary pressure and during multiple identical inflations at each of several rates. The averaged response of the receptor was computed and receptor activity related to transpulmonary pressure. On the basis of a quantitative criterion, employed to distinguish type I from type II receptors, the receptors could not be divided into distinct subpopulations. Thus all receptors were treated as coming from a single population. For all receptors we observed that their proportional sensitivity (increases in firing produced by increases in lung expansion at a constant rate of inflation) declined as the lung was inflated. In contrast, the dynamic sensitivity (increases in firing produced by increased rates of inflation at constant transpulmonary pressure) increased or remained relatively constant with increasing lung expansion. Thus, as inflation volume increases, the pulmonary stretch receptor acts increasingly as a rate receptor. The rate of inflation may have a more important role in control of the inspiratory duration than previously realized.