Comparison of central effects of noradrenaline and dopamine injected into the lateral brain ventricle in rats.

Noradrenaline and dopamine injected into the lateral brain ventricle exerted a significant effect on the behavior of rats. Both amines caused a slight rise in the basic locomotor activity which was significantly increased in the animals with inhibited monoamine oxidase activity. Besides that, they suppressed the behavior of rats in the open-field test, inhibited the conditioned avoidance response, decreased body temperature and increased amphetamine-induced motor hyperactivity. Noradrenaline, in contrast to dopamine, changed the intensity of amphetamine-induced stereotypy and prolonged the action of hypnotics. The central action of both catecholamines (in higher doses especially) seemed to have a biphasic course: in the first phase after administration depression was observed which was more pronounced after noradrenaline administration, in the second phase a stimulating effect b     

Behavioral activation by CRF: evidence for the involvement of the ventral forebrain

Rats injected intracerebroventricularly with corticotropin releasing factor (CRF) at the level of the lateral ventricle or cisterna magna showed a dose-dependent increase in locomotor activity. The increase in locomotor activity from injections of CRF into the cisterna magna was blocked by a cold cream plug in the cerebral aqueduct. An identical plug failed to block the increase in locomotor activity produced by CRF injected into the lateral ventricle. Intracerebral injections of CRF produced a site specific increase in locomotor activity with the largest increases observed from CRF injected into the substantia innominata/lateral preoptic area. Results suggest that the locomotor activating effects of CRF may be due to an activation of CRF receptors in the ventral forebrain, a region rich in CRF cell bodies and projections.     

Peptide S is a novel potent inhibitor of voluntary and fast-induced food intake in rats

Peptide S (NPS or PEPS) and its cognate receptor have been recently identified both in the central nervous system and in the periphery. NPS/PEPS promotes arousal and has potent anxiolytic-like effects when it is injected centrally in mice. In the present experiment, we tested by different approaches its central effects on feeding behaviour in Long-Evans rats. PEPS at doses of 1 and 10 microg injected in the lateral brain ventricle strongly inhibited by more than 50% chow intake in overnight fasted rats with effects of longer duration with the highest dose (P<0.0001). A similar decrease was observed for the spontaneous intake of a high-energy palatable diet (-48%; P<0.0001). This anorexigenic effect was comparable to that induced by corticotropin-releasing hormone in fasted rats at equimolar doses. However, peptide S did not modify food intake stimulated by neuropeptide Y (NPY) at equimolar doses. It also did not affect the fasting concentrations of important modulators of food intake like leptin, ghrelin, and insulin in circulation. This study therefore showed that peptide S is a new potent anorexigenic agent when centrally injected. Its inhibitory action appears to be independent of the NPY, ghrelin, and leptin pathways. Development of peptide S agonists could constitute a new approach for the treatment of obesity.     

Secretin: Hypothalamic Distribution and Hypothesized Neuroregulatory Role in Autism

1. This study aims (1) to determine whether secretin is synthesized centrally, specifically by the HPA axis and (2) to discuss, on the basis of the findings in this and previous studies, secretin's possible neuroregulatory role in autism. 2. An immunocytochemical technique with single-cell resolution was performed in 12 age/weight-matched male rats pretreated with stereotaxic microinjection of colchicine (0.6 microg/kg) or vehicle into the lateral ventricle. Following 2-day survival, rats were anesthetized and perfused for immunocytochemistry. Brain segments were blocked and alternate frozen 30-microm sections incubated in rabbit antibodies against secretin, vasoactive intestinal peptide, glucagon, or pituitary-adenylate-cyclase-activating peptide. Adjacent sections were processed for Nissl stain. Preadsorption studies were performed with members of the secretin peptide family to demonstrate primary antibody specificity. 3. Specificity of secretin immunoreactivity (ir) was verified by clear-cut preadsorption control data and relatively high concentrations and distinct topographic localization of secretin ir to paraventricular/supraoptic and intercalated hypothalamic nuclei. Secretin levels were upregulated by colchicine, an exemplar of homeostatic stressors, as compared with low constitutive expression in untreated rats. 4. This study provides the first direct immunocytochemical demonstration of secretinergic immunoreactivity in the forebrain and offers evidence that the hypothalamus, like the gut, is capable of synthesizing secretin. Secretin's dual expression by gut and brain secretin cells, as well as its overlapping central distribution with other stress-adaptation neurohormones, especially oxytocin, indicates that it is stress-sensitive. A neuroregulatory relationship between the peripheral and central stress response systems is suggested, as is a dual role for secretin in conditioning both of those stress-adaptation systems. Colchicine-induced upregulation of secretin indicates that secretin may be synthesized on demand in response to stress, a possible mechanism of action that may underlie secretin's role in autism.     

Effect of vasotocin on locomotor activity in bullfrogs varies with developmental stage and sex

Although neurohypophysial peptides are present in many regions of the developing and adult bullfrog (Rana catesbeiana) brain, the function of these peptides remains unclear. To investigate possible behavioral actions, we examined locomotor activity following peptide injection in bullfrogs at various developmental stages. An intraperitoneal (ip) injection of arginine vasotocin (AVT) in tadpoles (stages V, X, or XVII) produced an immediate and dose-dependent inhibition of locomotor activity. On the other hand, AVT stimulated activity when administered ip to juvenile or adult female bullfrogs, but did not influence activity in juvenile or adult males. The minimum effective dose of AVT, when injected directly into the brain of tadpoles, was 100-fold less than that observed when injected ip, suggesting a central nervous system site of action for this peptide. A vasopressin receptor antagonist (d(CH2)5[Tyr(Me)2]AVP administered ip or icv) significantly increased locomotor activity in tadpoles, compared to controls. Oxytocin, vasopressin, and AVP4-9 inhibited activity in tadpoles while mesotocin, des Gly(NH2)AVP, and pressinoic acid had no significant effect. Injection of PGF2 alpha also significantly decreased activity levels in tadpoles. However, pretreatment of tadpoles with indomethacin, a prostaglandin synthesis inhibitor, did not prevent the behavioral effects of AVT, suggesting that prostaglandin synthesis is not required for this response. In summary, AVT influenced locomotor activity in bullfrog tadpoles and female frogs. This effect shifted during development from an inhibitory action in tadpoles to a stimulatory effect in metamorphosed female frogs. The effect of AVT on juvenile and adult frog locomotion was sexually dimorphic, as this peptide altered female behavior but not male behavior.     

Central noradrenergic inhibition of gastric mucosal blood flow and acid secretion in rats

To investigate the role of central noradrenaline (NA) in gastric functions, changes in mucosal blood flow (MBF) and acid secretion following electrical stimulation of the lateral hypothalamic area (LHA) and the effects of NA on these parameters were examined in rats anesthetized with urethane. NA 10 μg/animal injected into the lateral ventricle decreased the basal value of both the gastric MBF and acid output, while the same dose of acetycholine or dopamine was without effect. Repetitive electrical stimulation of LHA at 10 cycles/sec, 0.5 mA, 2 msec for 10 min elicited a significant, reproducible increase in both gastric MBF and acid output. NA 10 μg/animal injected into the lateral ventricle completely blocked these increases induced by the electrical stimulation. These data suggest that a central noradrenergic inhibitory mechanism is involved in regulation of the gastric MBF and acid secretion.     

Neurophysiological effects of intracerebroventricular administration of urocortin.

The recently isolated Corticotropin Releasing Factor (CRF) related peptide, urocortin, has been reported to elicit a different behavioral profile than that of CRF. CRF is a potent anxiogenic agent and stimulant of motor activity whereas under similar conditions urocortin is a potent anorectic and mild locomotor stimulant. The neurophysiological effects of this newly synthesized peptide have not yet been examined. The present study evaluated the effects of intracerebroventricular administration of 3 doses of urocortin on the electroencephalogram (EEG) and on Event-Related Potentials (ERPs) in rats. Twenty male Wistar rats were implanted with electrodes in the amygdala and dorsal hippocampus, a cannula into the lateral ventricle, and skull surface electrodes over the frontal and parietal cortices. Following recovery from surgery, urocortin (0.01-1.0 microg) was infused into the lateral ventricle 5 min prior to the recording of EEG (10 min) and ERPs (10 min). Urocortin at any of the doses, did not produce any electrographic or behavioral signs of seizure activity. The predominant effect of urocortin infusion on EEG spectral activity was an increase in mean power in the 4-16 Hz range in the frontal cortex and a decrease in EEG stability in the frontal cortex and amygdala. Urocortin administration also decreased the latency of the P3 component of the ERP in the amygdala and hippocampus. These neurophysiological effects, that only partially overlap with those of CRF, are consistent with the behavioral profile described following urocortin administration in rats. Overall, these data further support the assertion that urocortin functions as a mild CNS stimulant enhancing arousal, as measured by EEG, and modulating the speed of stimulus evaluation as measured by ERPs.     

Application of Cortexin for correcting the consequences of hypoxic-ischemic damage in the brain of infant rats

To verify if the peptide preparation Cortexin can be used to correct pathological processes in the CNS during perinatal ontogenesis, a set of physiological parameters (EMG, ECG, respiration, vagosympathetic balance) were recorded and analyzed in a rat perinatal hypoxic-ischemic brain damage (PHIBD) model and control infant rats. In experimental 7-day-old animals, PHIBD was modeled under inhalation ether anesthesia by ligation of the left common carotid artery and subsequent exposure to a gas mixture of 8% oxygen and 92% nitrogen. 1 h after exposure, animals were first injected intraperitoneally with cortexin (1 mg/kg); the preparation was then injected at a daily basis for 10 days. Both control animals and those after surgery but non-treated were injected with physiological solution. After 10 and 30 days after surgery, animals exhibited a delayed body weight gain versus control and significant differences in EMG intensity and spectral structure. Cortexin treatment induced on day 10 a transient improvement in EMG spectral structure but not amplitude; by day 30, the positive effect of cortexin was no longer observed. The respiration rate both in treated and non-treated animals was higher than in control. No significant changes in the heart rate were revealed in animals with PHIBD, but non-treated animals exhibited on day 30 a tendency towards its decrease. The heart rate variability (HRV) analysis showed that 10 days after trauma both non-treated and cortexin-treated animals exhibited a statistically significant shift in the vagosympathetic balance towards a parasympathetic prevalence. On day 30, cortexin treatment yields positive effects, while in non-treated animals the vagosympathetic balance shifts towards a humoral-metabolic and sympathetic prevalence. Cortexin injection to intact rats leads to significant disturbances in the vagosympathetic balance, cardiac and, to a lesser extent, respiratory rhythms, and can cause stable disturbances in activity of the somatic and vegetative nervous systems.     

Diabetes-induced changes of nitric oxide influence on the cardiovascular action of secretin

The modulation by condition of the lack or the excess of nitric oxide (NO) on cardiovascular action of secretin in diabetic rats was investigated. In vitro the isolated heart function and in vivo, the systolic (SBP), diastolic (DSP) blood pressure and heart rate (HR) were measured. Secretin evoked inotropic positive effect and increased coronary outflow (CO), in vivo did not increase systemic pressure and the highest dose of the peptide increased the heart rate. NO synthase inhibitor, N(G) nitro-L-arginine methyl ester (L-NAME) deeply increased the systemic pressure and in vitro decreased coronary outflow. L-arginine and sodium nitroprusside (SNP) did not influence the isolated heart function and in vivo decreased the systemic pressure. L-NAME preserved the inotropic positive effect of secretin and the increase of the coronary outflow. In vivo co-administration of L-NAME+secretin evoked hypotensive effect and abolished the increase of the heart rate after the highest dose of the peptide. L-arginine abolished inotropic positive effect of the peptide and the increase of coronary outflow. In vivo co-administration of these substances caused hypotension and attenuated the increase of the heart rate after the highest dose of secretin. Co-injection of SNP and secretin preserved the inotropic effect of secretin and abolished the increase of the coronary outflow. In vivo infusion of SNP+secretin evoked hypotension and similarly to L-arginine, SNP abolished tachycardia induced by the highest dose of secretin. Both the lack and the excess of nitric oxide changed the cardiovascular action of secretin in diabetic rats.     

Secretin Stimulates Cyclic AMP Formation in the Rat Brain

The effects of secretin on cyclic AMP levels in the rat brain were determined. Incubation of rat brain frontal cortex slices with secretin or the structurally related peptides peptide histidine leucine (PHI) or vasoactive intestinal polypeptide (VIP) in the presence of 10 mM theophylline resulted in a dose-dependent increase in the cyclic AMP levels. The half-maximal increase in cyclic AMP occurred using a 1 microM dose of secretin or a 2 microM dose of PHI or VIP. Preincubation of slices with secretin-(5-27) produced a dose-dependent inhibition of the secretin but not VIP- or PHI-stimulated increase in the cyclic AMP content. Also, in receptor binding studies, secretin-(5-27) produced a dose-dependent inhibition (Ki = 400 nM) of 125I-secretin but not of 125I-VIP binding to rat brain membranes. Guanyl-5'-yl imidodiphosphate decreased the affinity of radiolabelled secretin binding as a result of an increased rate of dissociation of bound 125I-secretin. These data suggest that secretin receptors in the rat brain may be coupled to adenylate cyclase in a stimulatory manner and that secretin-(5-27) may function as a central secretin receptor antagonist.     

Opposite effects of intraventricular and intracisternal administration of vasopressin on blood pressure in rats

Lysine-8-vasopressin (LVP) was injected into the lateral ventricle (ICV) or into the cisterna magna (c.m.) of ether-anesthetized rats. ICV injection of LVP decreased the blood pressure (BP), whereas c.m. administration increased it. The opposite effects of ICV versus c.m. administration of the peptide might be related to differences in brainstem versus limbic-midbrain structures in the regulation of blood pressure, and suggest that both mechanisms can be influenced by vasopressin.     

Influence of secretin and L-NAME on vascular permeability in the coronary circulation of intact and diabetic rats

The permeability in the intact and diabetic rat coronary circulation after administration of secretin (3.0 micromol/kg i.v.), an inhibitor of NOS (nitric oxide synthase), and L-NAME (N(G)-nitro-L-arginine-methyl ester hydrochloride) (1 mg/kg i.v.), and both substances given together, were studied. To measure protein extravasation Evans blue dye was used as a marker of vascular permeability. The vascular permeability of the left ventricle did not differ in intact and diabetic rats. In the diabetes state increased permeability of atria was observed. Administration of secretin did not influence the coronary vascular permeability in either the intact or the diabetic rats. L-NAME increased the atria permeability and did not change left ventricle permeability. In diabetes, injection of L-NAME caused a decrease in the permeability in both the atria and left ventricle. In intact rats secretin diminished the L-NAME effect in the atria. In diabetic rats co-administration of secretin+L-NAME increased the permeability of the atria and left ventricle, but L-NAME administered alone decreased them. Secretin modified the effect of L-NAME on coronary permeability in intact and diabetic rats.     

Infusions of acetaldehyde into the arcuate nucleus of the hypothalamus induce motor activity in rats

AimsThe hypothalamic arcuate nucleus (ARH) is one of the brain regions with the highest levels of catalase expression. Acetaldehyde, metabolized from ethanol in the CNS through the actions of catalase, has a role in the behavioral effects observed after ethanol administration. In previous studies acetaldehyde injected in the lateral ventricles or in the substantia nigra reticulata (SNR) mimicked the behavioral stimulant effects of centrally administered ethanol.Main methodsIn the present study we assessed the effects of acetaldehyde administered either into the ARH into a dorsal control or into the third ventricle on locomotion and rearing observed in 30 min sessions in an open field.Key findingsAcetaldehyde injected into the ARH induced horizontal locomotion and rearing for 20 min. In contrast, administration of acetaldehyde into a control site dorsal to the ARH did not have any effect on locomotion. Although acetaldehyde administration into the third ventricle also induced locomotion, the time course for the effect in this area was different from the time course following ARH injections. Acetaldehyde in the ARH produced a long lasting induction of locomotion, while with intraventricular injections the effects disappeared after 5 min.SignificanceThe present results are consistent with previous studies demonstrating that acetaldehyde is an active metabolite of ethanol, which can have locomotor stimulant properties when administered in the ventricular system of the brain or into specific brain nuclei. Some brain nuclei rich in catalase (i.e.; SNR and ARH) could be mediating some of the locomotor stimulant effects of ethanol through its conversion to acetaldehyde.     

Effect of intraventricular oxytocin and vasopressin on self-stimulation in rats.

Oxytocin (500 mu u) and vasopressin (50 mu u) were injected into the lateral ventricle and its effect on hypothalamic self-stimulation has been studied. Oxytocin increased, while vasopressin decreased the self-stimulation rate tested 10-20 min following application. The hypothalamic and mesencephalic serotonin content decreased slightly while plasma corticosterone content did not change 20 min after oxytocin and vasopressin administration compared to the injected control animals. The data suggest that vasopressin and oxytocin have an opposite effect on self-stimulation and this action is not mediated through the brain serotoninergic or pituitary-adrenocortical axis.     

Systemic site of action for pressor effect of angiotensin II injected into the fourth cerebral ventricle of rats?

Angiotensin II (ANG II) causes a systemic pressor effect when injected into the cerebral ventricles. In the rat fourth ventricle, the effective doses for the ANG II pressor effect are over 100 times larger than in the systemic circulation. Considering the discrepancy of doses, the possibility that ANG II may reach the systemic circulation and promote pressor effects, following injection into the fourth ventricle, was investigated. The effects on blood pressure of different vasoactive peptides that produce pressor responses when injected into the central nervous system were compared. Dose-response curves were obtained for intravenous or fourth cerebroventricular injections of ANG II, lysyl-vasopressin (LVP), bradykinin (BK), or endothelin-1 (ET-1). The ED50 ratios for intracerebroventricular/intraveneous injections were 110 for ANG II, 109 for LVP, 0.01 for BK, and approximately 0.4 for ET-1. In cross-circulation preparations, pressor responses occurred in the donor rat following injection into the fourth cerebral ventricle of the recipient animal, showing that effective doses of ANG II, administered to the fourth cerebral, reach the systemic circulation. The same results were obtained for the microinjection of 4 nmol of LVP into the fourth cerebral ventricle of recipient animals. High-performance reverse-phase liquid chromatography analyses of arterial blood showed that approximately 1% of the [125I]ANG II injected into the fourth cerebral ventricle may be recovered from the systemic circulation a few seconds after the microinjection. The systemic administration of the ANG II receptor antagonist losartan blocked the response to ANG II injected into the fourth ventricle whereas antagonist administration in the same ventricle did not. Angiotensin injections into the lateral ventricle produced pressor responses that were reduced by antagonist administration to the same ventricle but not by systemic administration of the antagonist. The data suggest that the pressor effect resulting from ANG II or LVP injections into the fourth cerebral ventricle may be due to the action of this peptide in the systemic circulation. On the other hand, the pressor effect due to ANG II microinjection into the lateral ventricle apparently results from the direct stimulation of central periventricular structures.     

Neurotensin inhibits LH release

The present studies were designed to assess the effect of neurotensin on the release of LH, FSH, and prolactin in long-term castrated female rats. The animals were implanted in the lateral ventricle of the brain wih a cannula to allow the administration of either neurotensin or the vehicle. The peptide (30 microgram, dissolved in saline) or the control saline solution was injected intraventricularly in a volume of 10 microliter following pentobarbital anesthesia. Blood samples were collected at sacrifice 15, 30 and 60 min after injection. A significant decrease of serum LH levels was already present in neurotensin-treated animals at 15 min, and was maintained up to the end of the experiment. This decrease was not accompanied by any change in FSH or prolactin secretion. The results suggest that this tridecapeptide participates in the control of LH release and provide new data on the separate control of the release of the two gonadotropins.     

纳洛酮对大鼠烫伤休克的影响

36只烫伤大鼠,分为纳洛酮组和盐水对照组。两组动物侧脑室分别注射纳洛酮和生理盐水,观察纳洛酮对烫伤休克的影响。 结果表明:纳洛酮组大鼠的存活率高于盐水对照组。纳洛酮组动物烫伤后2小时存活率为83％,烫伤后4小时存活率为39％;盐水组动物烫伤后2小时存活率为44％,烫伤后4小时存活率为5.6％。纳洛酮组血压下降和心率减慢的进度也较慢,烫伤后180分钟血压才降低到63％,而盐水组在烫伤后90分钟血压已降低到62％。纳洛酮组动物的呼吸和体温变化也较慢。这些结果提示:纳洛酮具有一定的抗烫伤休克的作用。     

一次性力竭运动对大鼠PHB1表达及线粒体功能的影响

目的：观察一次性力竭运动后大鼠脑、心、骨骼肌组织和线粒体中PHB1含量的变化及对大鼠线粒体功能的影响,探寻PHB1与线粒体功能和能量代谢的关系。方法：健康雄性SD大鼠40只,随机分为2组（n=20）：对照组和一次性力竭运动组,大鼠进行一次性急性跑台运动建立力竭运动模型。收集各组大鼠的心、脑和骨骼肌组织样品并提取线粒体,检测其呼吸功能和ROS的变化。用Western blot方法检测组织和线粒体中PHB1蛋白表达水平;用分光光度计检测各器官中ATP含量以及线粒体中复合体V活性（ATP合酶活性）。结果：①一次性力竭运动后脑、心肌、骨骼肌中ATP含量显著性降低;②一次性力竭运动后脑、心肌、骨骼肌线粒体中复合体V活性、RCR、ROS显著性降低,ST4均显著性升高,ST3无显著性差异。③一次性力竭运动后心、脑、骨骼肌线粒体中PHB1的表达显著性减少。④通过相关性分析得出：一次性力竭运动后心、脑、骨骼肌中ATP含量与心、脑、骨骼肌中复合体V活性呈正相关;心、脑、骨骼肌中ATP含量和心、脑骨骼肌中PHB1的表达呈正相关。结论：一次性力竭运动后,降低线粒体氧化磷酸化功能,使大鼠脑、骨骼肌线粒体内ROS生成增加,PHB1的表达、ATP含量和复合体V活性均下降。一次性力竭运动使得大鼠线粒体内PHB1表达降低,线粒体功能减弱,机体能量代谢降低。