隔区注射AVP和AVP抗血清对家兔温敏神经元放电的影响

精氨酸加压素可能是一种内源性退热剂,其抗热作用的最敏感点位于大脑边缘系统的隔区。为了研究ＡＶＰ抗热的作用的机理,本文观察了隔区注射ＡＶＰ和ＡＶＰ抗血清对家兔视前区－下丘脑前部温度敏感神经元放电活动的影响。实验结果如下：１（１）隔区注射ＡＶＰ能使ＰＯ－ＡＨ热敏神经元放电明显增加,冷敏神经元放电明显减少;而隔区注＝谢人工脑脊液对热敏神经元和冷敏神经元的放电均无明显影响。（２）隔区注射ＡＶＰ抗血清后,Ｐ     

Temperature-sensitive properties of rat suprachiasmatic nucleus neurons

The hypothalamic suprachiasmatic nucleus (SCN) contains a heterogeneous population of neurons, some of which are temperature sensitive in their firing rate activity. Neuronal thermosensitivity may provide cues that synchronize the circadian clock. In addition, through synaptic inhibition on nearby cells, thermosensitive neurons may provide temperature compensation to other SCN neurons, enabling postsynaptic neurons to maintain a constant firing rate despite changes in temperature. To identify mechanisms of neuronal thermosensitivity, whole cell patch recordings monitored resting and transient potentials of SCN neurons in rat hypothalamic tissue slices during changes in temperature. Firing rate temperature sensitivity is not due to thermally dependent changes in the resting membrane potential, action potential threshold, or amplitude of the fast afterhyperpolarizing potential (AHP). The primary mechanism of neuronal thermosensitivity resides in the depolarizing prepotential, which is the slow depolarization that occurs prior to the membrane potential reaching threshold. In thermosensitive neurons, warming increases the prepotential's rate of depolarization, such that threshold is reached sooner. This shortens the interspike interval and increases the firing rate. In some SCN neurons, the slow component of the AHP provides an additional mechanism for thermosensitivity. In these neurons, warming causes the slow AHP to begin at a more depolarized level, and this, in turn, shortens the interspike interval to increase firing rate.     

V1-Vasopressin Receptors in the Septum of the Rat Brain. Electrophysiological Evidence

Abstract

In slices from the rat brain, extracellular recordings were obtained from single neurones located in the lateral septum, an area known to receive a vasopressinergic innervation. Approximately half of the neurones tested responded to vasopressin by a concentration-dependent increase in firing rate, the lowest effective concentration being in the order of 2 nM. The effect of vasopressin was blocked by a synthetic structural analogue possessing vasopressor and oxytocic antagonistic properties on peripheral vasopressin and oxytocin receptors. Oxytocin had a weak effect in firing septal neurones, whereas a selective oxytocic agonist was totally ineffective. The action of vasopressin on neuronal firing was mimicked by a vasopressor agonist (Phe2-Orn8-VT) but not by a selective antidiuretic agonist (dDAVP). These results indicate that the vasopressin receptors present in rat septum are V1 (vasopressor type) rather than V2 (antidiuretic type) receptors. In addition, we conclude that these receptors, when occupied, lead to increased firing of lateral septal neurones.     

Differential effects of prostaglandin F2 alpha on oxytocinergic and non-oxytocinergic neurones in the paraventricular nucleus of the lactating rat

The effects of the prostaglandin F2 alpha (PGF2 alpha) given into the third cerebral ventricle on the unit activity of neurosecretory neurones in the paraventricular nucleus (PVN) were studied in urethane-anesthetized rats. The firing activity of PVN neurones was recorded extracellularly and 50 neurones were antidromically identified as neurosecretory neurones. Thirty of them were classified oxytocinergic neurones because they gave a burst of action potential 12-15 sec before reflex milk ejection and the remaining twenty PVN neurones which showed no response prior to reflex milk ejections were regarded as non-oxytocinergic ones. Twenty-five (83%) of the30 oxytocinergic neurones increased in the firing rate following the intraventricular (IVT) injection of PGF2 alpha (500ng in 1 microliter of isotonic saline) and the responses lasted for about 20-30 min. The remaining 5 (17%) oxytocinergic neurones showed no response in the firing rate to IVT PGF2 alpha. Fifteen (75%) of the 20 nonoxytocinergic neurones decreased in the firing activity in response to IVT PGF2 alpha, and the remaining 5 (25%) of them showed no response. IVT injection of isotonic saline (1 microliter) did not affect the firing activity of both the oxytocinergic and nonoxytocinergic cells. The intramammary pressure was slightly increased by the IVT administration of PGF2 alpha. These findings indicate that IVT PGF2 alpha has a differential action on oxytocinergic and non-oxytocinergic neurones in rats.     

Cyclic GMP alters the firing rate and thermosensitivity of hypothalamic neurons

The rostral hypothalamus, especially the preoptic-anterior hypothalamus (POAH), contains temperature-sensitive and -insensitive neurons that form synaptic networks to control thermoregulatory responses. Previous studies suggest that the cyclic nucleotide cGMP is an important mediator in this neuronal network, since hypothalamic microinjections of cGMP analogs produce hypothermia in several species. In the present study, immunohistochemisty showed that rostral hypothalamic neurons contain cGMP, guanylate cyclase (necessary for cGMP synthesis), and CNG A2 (an important cyclic nucleotide-gated channel). Extracellular electrophysiological activity was recorded from different types of neurons in rat hypothalamic tissue slices. Each recorded neuron was classified according to its thermosensitivity as well as its firing rate response to 2-100 microM 8-bromo-cGMP (a membrane-permeable cGMP analog). cGMP has specific effects on different neurons in the rostral hypothalamus. In the POAH, the cGMP analog decreased the spontaneous firing rate in 45% of temperature-sensitive and -insensitive neurons, an effect that is likely due to cGMP-enhanced hyperpolarizing K(+) currents. This decreased POAH activity could attenuate thermoregulatory responses and produce hypothermia during exposures to cool or neutral ambient temperatures. Although 8-bromo-cGMP did not affect the thermosensitivity of most POAH neurons, it did increase the warm sensitivity of neurons in other hypothalamic regions located dorsal, lateral, and posterior to the POAH. This increased thermosensitivity may be due to pacemaker currents that are facilitated by cyclic nucleotides. If some of these non-POAH thermosensitive neurons promote heat loss or inhibit heat production, then their increased thermosensitivity could contribute to cGMP-induced decreases in body temperature.     

Comparative study of the activity of medullary respiratory neurones during polypnea triggered by hypothalamic electrical stimulation or by hypothalamic heating (author's transl)

We have compared in "encéphale isolé bas" cats the activity of medullary respiratory neurones during polypnea triggered by electrical stimulation (PSt) or by heating (PTh) of the hypothalamus. The medullary respiratory neurones are classified according to:--their anatomical localization (dorsal or ventral respiratory nucleus);--their axon destination (spinal : bulbo-spinal respiratory neurones; non spinal : propriobulbar neurones);--their discharge pattern;--the correlation coefficient between the number of spikes delivered in each burst and the duration of the corresponding respiratory phase (HILAIRE et MONTEAU, 1975). 1. During the two polypneas (PSt and PTh), we observe:--a reduction of activity that preferentially affects some groups of neurones (propriobulbar neurones) (fig. 3);--an inversion of the discharge firing rate, which increases during inspiration in normopnea and decreases in polypnea (fig. 1; fig. 6);--a decrease of the maximal discharge firing rate for the neurones of different groups (Table V). 2. However, two differences exist : during PSt, the maximal discharge firing rate increases for the inspiratory bulbo-spinal neurones of the dorsal nucleus and for the early-burster inspiratory propriobulbar neurones. The recruitment of the bulbo-spinal inspiratory neurones seems to be different; they are activated earlier during PSt than during PTh (Table VI). 3. Some of the observed differences are probably quantitative and we think that polypnea triggered by hypothalamic electrical stimulation is a good model for thermal polypnea.     

侧脑室注射心房钠尿肽对大鼠室旁核单位放电...

We have applied microelectrode technique to record 118 spontaneously firing units from the hypothalamus in rats. Detection of the recording sites showed that 84 were in the paraventricular nucleus (PVN) and 34 were near the PVN (near-PVN). After intracerebroventricular (i.c.v.) administration of atrial natriuretic polypeptide (ANP), 91% (P less than 0.005) of the PVN neurones and 71% (P greater than 0.05) of near-PVN neurones sensitive to ANP showed a significant decrease in spontaneously firing rate. After i.c.v. administration of hypertonic NaCl solution, 64.7% (P less than 0.005) of the PVN neurones and 61.1% (P greater than 0.05) of near-PVN neurones showed a significant increase in firing rate. The results indicate that i.c.v. administration of ANP profoundly inhibits the electrical activity of the PVN neurones, but hypertonic NaCl solution markedly stimulates the PVN neurones.     

A discrete mode of the antipyretic action of AVP, alpha-MSH and ACTH.

The antipyretic effect of AVP, alpha-MSH and ACTH consists in lowering the thermoregulatory threshold and in shortening the time span of the fever. Thus, neuropeptides influence activity of hypothalamic neurones regulating body temperature. This was confirmed by recent experiments of Moravec (this volume) which indicate that spontaneous activity and thermosensitivity of neurones in hypothalamic slices can be influenced, by AVP. Why neuropeptides of different chemical structure such as AVT, on one hand, and alpha-MSH and ACTH, on the other hand, induce the same effect on thermoregulation remains to be elucidated.     

Effect of pentobarbital on neurones in the reticular formation of the brain stem: ionophoretic study in the rat

The effect of ionophoretically applied pentobarbital (PB) upon neurones in the nucleus reticularis gigantocellularis of the rat was studied. PB applied through a micropipette depressed the spontaneous activity of 81% of the neurones tested; the remaining neurones did not change their firing rates. Regardless of current intensities used for PB ejection (5-60 nA) there was no increase in the firing rate during PB administration. The depression was dependent upon both the control firing rate and the PB dose; a total depression of activity was observed at currents between 40 and 60 nA. EC50 (15.5 nA, about 5 X 10(-5) mol.l-1--the drug concentration was approximated theoretically) was assessed from the dose-response curve. Repeated application resulted in a shift of EC50 towards higher current values (desensitization). The Hill coefficient was calculated in conformity with the classical theory. From its value (1.4), it may be assumed that the occupation of only one subunit of the binding site is enough to give a response. Possible mechanisms of action of PB upon neurones are discussed.     

The effect of temperature changes on the spontaneous activity in the neural ganglia of the cockroach, Periplaneta americana

1. 1.|The effect of localized heating or protocerebrum (bp), the prothoracic (t₁), metathoracic (t₃) and the sixth abdominal (a₆) ganglion on the spontaneous neuronal firing rate in these ganglia was investigated in Periplaneta americana.

2. 2.|In almost every case heating the ganglion increased the firing rate. The most heat sensitive were bp, t₃ and t₁, a₆ was much less so.

3. 3.|In bp and t₁ the firing rate stayed on an increased level even 90 s after the thermal stimulus was over.

4. 4.|The differentiated thermosensitivity of the tested ganglia is discussed in terms of thermoregulatory behaviour of the cockroach.

Comparison of spontaneous activity of mesencephalic reticular neurones in the waking state and during pentobarbital anaesthesia.

In rats immobilized by d-Tubocurarine the spontaneous activity of 100 mesencephalic reticular neurones was recorded extracellularly and statistically evaluated before and after repeated intravenous administration of 15 mg/kg doses of Pentobarbital. Number of spontaneously active neurones decreases quasi-linearly with repeated 15 mg/kg Pentobarbital doses. After a 75 mg/kg cumulative dose practically all neurones ceased firing spontaneously, whereas cortical EEG activity fully disappeared after the 90 mg/kg Pentobarbital dose. The firing rate was characterized by the mean interval with its standard deviation. Mean value for the total sample of spontaneously active neurones was 146.7 +/- 192.3 msec without Pentobarbital and increased to 302.7 +/- 367.5 msec after 15 mg/kg and to 400.6 +/- 452.5 msec after 30 mg/kg cumulative dose of Pentobarbital. The 15 mg/kg dose increased the frequency of firing in 5% of neurones only. The most often encountered type of interval histogram in the mesencephalic reticular formation was the exponential type (59% in unanaesthetized state), which was also most sensitive to Pentobarbital. Synchronized activity in bursts, characterized by periodical peaks and dips frequently occurred in neurones with the exponential-like interspike interval density after Pentobarbital administration. On the contrary, neurones with gamma-like and especially with symmetrical-like types of density were less influenced by Pentobarbital. In many neurones a periodical increase in the firing rate (with intervals of tens of seconds) related to the occurrence of spindles was present in the cortical EEG activity.     

Characteristics of the neuronal reaction of the substantia nigra to nociceptive stimulation

The nature of neurone response of substance nigra (SN) to nociceptive stimulation of the cat's peroneal nerve has been studied. The recording of neurone SN firing rate revealed that the majority (71.0%) of the SN neurones responded to the nociceptive repetitive stimulation of the peroneal nerve. But the thresholds of nociceptive activation in SN neurones turned to be very high. As a result of it the number of SN neurones responding to repetitive peroneal stimulation was twice as many as the number of cells responding to single stimulation of the nerve. The intravenous injection of naloxone in dose 1.0 mg/kg changed both excitatory and inhibitory responses in majority (71.4%) of SN neurones responding to repetitive peroneal stimulation. Naloxone did not modify the firing rate of neurones nonresponsive to nociception.     

Electrophysiological responses of the chemoreceptor neurones in the antennal taste sensilla to plant alkaloids and glucosides in a granivorous ground beetle

The electrophysiological response of chemoreceptor neurones from the antennal chaetoid taste sensilla of the omnivorous ground beetle Pterostichus oblongopunctatus to several plant alkaloids and glucosides is investigated. A quinine‐sensitive neurone responding to quinine and quinine hydrochloride is found, most probably related to the granivorous feeding habit of P. oblongopunctatus. The response to quinine hydrochloride is concentration‐dependent at 0.001–50 mm , with the response threshold at 0.01 mm and a maximum rate of firing of 67 spikes/s at 50 mm . The stimulatory effect of caffeine is very weak, where the firing rate increases by only 1.4 spikes/s at a concentration of 10 mm compared with that evoked by a control stimulus. In addition, both quinine and quinine hydrochloride strongly inhibit spike production by the salt‐ and pH‐sensitive neurones when presented in mixtures with 10 mm NaCl. Several tested plant secondary compounds (i.e. salicin, sinigrin, caffeine and nicotine), which have only little or no effect on the firing rate of the quinine‐sensitive neurone, greatly reduce the responses of the salt‐ and pH‐sensitive neurones. The results of the present study suggest that the antennal taste sensilla of P. oblongopunctatus may detect plant defensive compounds both through the activation of a quinine‐sensitive neurone and via peripheral inhibition of other chemoreceptor neurones of the taste sensillum.     

Effects of angiotensin II and its selective antagonists on inferior olivary neurones.

On the basis of biochemical and autoradiographic studies it has been shown that the inferior olivary nucleus (ION) contains predominantly angiotensin II (Ang II) receptors of the subtype 2 (AT2). In the present investigation we used microiontophoretic techniques to test the effect of Ang II on the spontaneous firing rate of rat neurones in the ION in vivo. Ang II excited the majority of histologically identified ION neurones. Furthermore, the antagonism of this angiotensin-induced excitation by selective angiotensin receptor blockers of subtype 1 and 2 (AT1 and AT2) was examined. The excitation could be blocked by low doses of the AT2-antagonists PD 123177 and CGP 42112A, whereas the AT1-antagonist DuP 753 was ineffective even at high doses. On a few occasions, however, ejection of the AT1-antagonist resulted in a potentiation of angiotensin-induced excitation. The results suggest that Ang II has an excitatory effect on a considerable number of ION neurones and that this effect is mediated by AT2-receptors.     

Effect of thyroliberin on membrane potential and pattern of spontaneous activity of neurons of the respiratory center in rats in vitro

On frontal brainstem slices of rat by means of whole-clamp recordings, we investigated effects of TRH (10(-8) [symbol: see text]) on membrane potential and firing pattern of the neurones in ventrolateral area of the solitary tract nucleus and pre-Botzinger complex. TRH induced a membrane depolarisation and an increase in spontaneous activity of the respiratory centre neurones. After TRH administration, a shortening of time intervals between the beginning of bursts was found in bursting neurones of the pre-Botzinger complex. In some silent neurones, TRH elicited appearance of firing activity, so the silent neurones of the solitary tract nucleus were transformed into tonic while the silent pre-Botzinger complex neurones were transformed into bursting ones. Thus, there is a direct regulatory effect of TRH on the respiratory centre neurones at the level of their membrane.     

侧脑室注射心房钠尿肽对大鼠室旁核单位放电的影响

本实验利用微电极技术在大鼠下丘脑共记录到118个自发放电单位,其中84个位于室旁核(PVN)内,34个位于 PVN 邻近部位。侧脑室注入心房钠尿肽(ANP)后,受其影响的 PVN神经元和 PVN 邻近部位神经元,分别有91%(P<0.005)和71%(P>0.05)表现为自发放电频率减少;侧脑室注入高渗 NaCl 溶液则分别使64.7%(P<0.005)和61.1%(P>0.05)的神经元自发放电频率增加。结果表明,侧脑室注入 ANP 对 PVN 神经元自发放电活动具有明显的抑制作用。     

Interactions between p-tyramine, m-tyramine, or beta-phenylethylamine and dopamine on single neurones in the cortex and caudate nucleus of the rat

p-Tyramine, applied to cortical and caudate neurones with weak iontophoretic currents (0-10 nA), did not usually cause any alteration of base-line firing rate. However, neuronal responses to dopamine (DA) during such weak applications of p-tyramine were greatly enhanced. Cortical neurone responses to noradrenaline (NA) were similarly potentiated, but both cortical and caudate neurone responses to alpha-aminobutyric acid were unaffected by p-tyramine. In addition, weak background applications of DA which did not affect cell firing rate were also without effect on the neuronal responses to the standard application of DA. The responses of cortical neurones to DA were also potentiated by m-tyramine and beta-phenylethylamine applied with weak cationic currents. The results may suggest that trace amines can enhance NA and DA transmission in the central nervous system.     

Acute actions of marine toxin latrunculin A on the electrophysiological properties of cultured dorsal root ganglion neurones

The effects of latrunculin A, isolated from the nudibranch Chromodoris sp., on the excitability of neonatal rat cultured dorsal root ganglion neurones were investigated using patch-clamp recording and Ca(2+) imaging techniques. Under current-clamp conditions, acute application of latrunculin A (100 microM) reversibly induced multiple action potential firing and significantly increased action potential duration. No significant effects on action potential peak amplitude, threshold of action potential firing, resting membrane potential and input resistance were observed. Under voltage-clamp conditions, significant and dose-dependent suppression of K(+) current was seen with 10-100 microM latrunculin A. Additionally, a significant difference between inhibition of the current measured at the peak and the end of a 100 ms voltage step was seen with 100 microM latrunculin A. Fura-2 fluorescence Ca(2+) imaging revealed that latrunculin A (100 microM) significantly inhibited Ca(2+) transients evoked by KCl-induced depolarisation in all neurones. In 36% of DRG neurones, latrunculin A alone had no effect on intracellular Ca(2+). In 64% of neurones, latrunculin A alone evoked a transient rise in intracellular Ca(2+). Moreover, latrunculin A (10-100 microM) significantly inhibited the mean high voltage-activated Ca(2+) current. The effects of latrunculin A on action potential firing and K(+) currents were attenuated by intracellular phalloidin, an indication that these effects are mediated through actin disruption.     

Tryptamine and 5-hydroxytryptamine: actions and interactions of cortical neurones in the rat

The actions of iontophoretically applied tryptamine (T) and 5-hydroxytryptamine (5-HT) were compared on single neurones in the rat somatosensory cortex. The firing rate of the vast majority of neurones tested was depressed by T. However, 5-HT excited and depressed approximately equal numbers of neurones. Depressant effects of 5-HT could be profoundly enhanced by a very weak concurrent application of T (0–10 nA) which itself did not alter the baseline cell firing rate. Excitatory responses to 5-HT were consistently reversed into depressant responses during weak applications of T. These observations could support a modulatory role for endogenous T in 5-HT-mediated transmission in the central nervous system (CNS).     

Effect of nitrite on the excitability of brain neurons in helix

Incubation of the Helix brain in sodium nitrite (SN) decreased the firing threshold of silent neurones, increased firing rate and a response to stimulation, activated excitatory synaptic inputs of the neurones under study. The effects were stable but reversible. Rapid responses to the SN application were only shown for spontaneously active neurones. The SN effects were accompanied by a depolarisation and an increase in the input resistance. Inhibitor of the NO synthase exerted opposite effects to the NO donors and SN. A possible role of the NO and hypoxia in the SN effects, is discussed.