刺激大鼠穹窿下器官诱发饮水和脑内c—fos表达的胆碱能机制

实验以饮水行为脑内c-fos表达为指标,,观察刺激大鼠穹窿下器官（SFO）的效应,结果显示,刺激SFO能诱发明显的饮水行为,与此同时,前脑8个部位（终板血管器官,正中视前核,室旁核,视上核,下丘脑外侧区,穹窿周核背侧区,丘脑联合核和无名质）和后脑3个部位（最后区,孤束核和壁旁外侧核）的Fos蛋白表达明显增强,免疫组化双重染色结果显示,刺激SFO能诱导视上核和室旁核中部分神经元呈Fos蛋白和加压素共同表达。脑室注射阿托品能部分阻断刺激SFO诱发的饮水行为,脑内上述各部位所诱导的Fos蛋白表达也明显减弱,以上结果提示,M胆碱能机制参与 刺激SFO诱发的饮水行为和脑内Fos蛋白的表达。     

Depression-like changes in behavior and c-fos gene expression in dopaminergic brain structures in WAG/Rij rats

In WAG/Rij rats with genetic absence epilepsy, inborn changes in behavior were observed such as decreased level of locomotion, exploratory activity, and grooming reactions in the open-field test, increased immobility in the forced-swimming test, and decreased sucrose consumption (anhedonia) as compared to Wistar rats completely lacking in seizure pathology. These behavioral alterations in WAG/Rij rats resemble the symptoms of human depression (psychomotor retardation, depressed mood, and anhedonia). No significant behavioral changes were found in the light-dark choice, social interaction, and elevated plus-maze tests. This suggests the absence of increased anxiety in WAG/Rij rats. In contrast to Wistar, WAG/Rij rats were sensitive only to chronic treatment with antidepressant imipramine like depressive patients. Behavioral "despair" induced by forced swimming led to C-fos gene expression in three brain structures (frontal cortex, nucleus accumbens, and striatum), which are, respectively, terminal regions of three dopaminergic brain systems (mesocortical, mesolimbc, and nigrostriatal). c-fos gene expression in the brain of WAG/Rij rats was substantially different from that in the brain of Wistar rats in both intensity (in WAG/Rij the c-fos gene expression was higher than in Wistar rats in all involved brain structures) and its distribution between the structures. The results suggest that WAG/Rij strain is a new experimental (genetic) model of absence epilepsy-related depression unassociated with increased anxiety.     

The role of brain serotonin in the expression of genetically determined defensive behavior

The review summarizes the results of long-term studies on the role of the brain mediator serotonin and genetic predisposition to various types of defensive behavior. The involvement of the serotonergic brain system in the mechanisms of genetic control of both active and passive defensive responses has been established using silver foxes, Norway rats of S40 selection for low and high aggressiveness to humans, aggressive mice with genetic knockout of monoaminoxidase A, and S40 rats selected for predisposition to passive defensive response of freezing (catalepsy). The changes in the serotonergic 5-HT1A-brain receptors of rats genetically predisposed to different strategies of defensive behavior were similar. However, the activity of the key enzyme of serotonin biosynthesis and the brain structures, in which serotonin metabolism was altered, significantly differed with regard to the preferred strategy. The conclusion was drawn that the 5-HT1A-receptors and enzymes of serotonin metabolism in the brain are involved in implementing genetic control of defensive behavior. Expression of the 5-HT1A-brain receptors was suggested to determine the levels of fear and anxiety and, consequently, the predisposition to defensive behavior, whereas the preferred strategy of defensive response (active or passive defensive) depends on genetically determined features of serotonin metabolism in the brain structures.     

The expression of the c-fos gene in the brain of mice in the dynamic acquisition of defensive behavioral habits

Levels of c-fos mRNA expression in mouse cerebral cortex and hippocampus at different stages of footshock escape and avoidance learning were studied by Northern hydridization. In the first series of experiments a mouse was presented with 30 electric footshock daily in a chamber where it could escape from the floor by jumping on the safe platform attached to the wall. A large increase in c-fos mRNA level in the cerebral cortex and hippocampus was observed during the first day of training. Mice that were trained for 9 consecutive days and acquired a footshock escape reaction showed no elevation of c-fos expression in the brain as compared to the quiet control group. In the second series of experiments the levels of c-fos expression were compared in individual mice trained to avoid the footshock by jumping on the platform in response to an auditory conditioned stimulus. Mice which acquired avoidance behavior more rapidly had lower c-fos mRNA levels than slow learners. There was no such to difference between the corresponding yoked control groups which consisted of animals matched the rapid and slow learners by the number of footshocks received. It is concluded that achievement of adaptive results in the course of learning leads to a suppression of further c-fos induction by motivational excitation.     

Manifestation of active and passive defensive behavior in juvenile rats

The dynamics of freezing and flight reactions in juvenile rats was investigated. The rats were tested on the 20th, 25th, 35th, and 40th postnatal days. A sound of 6-sec duration (bell) was used as a threatening stimulus. The following parameters were recorded: number of rearing reactions and defecations within 5 min prior to stimulation, reactions to the bell, latent periods and durations of freezing reactions, freezing posture rigidity, and time of recovery of movements after freezing. It was shown that the intensity of freezing reduced in the period from the 20th to 35th postnatal day. The flight reactions were highest on the 25th and 40th days. Correlations between freezing indices and numbers of rearing and defecation reactions were different in rats of all age groups. The results suggest that the structure of defensive behavior changes with maturation of principal defensive reactions in rats within the first 40 postnatal days.     

化学刺激或电刺激大鼠穹窿下器官诱发的饮水行为和脑内c-fos表达

目的对化学刺激和电刺激穹窿下器官(subfornical organ, SFO)诱发的饮水量和脑内c-fos表达的结果是否不同进行比较. 方法向大鼠SFO内微量注射L-谷氨酸作为化学刺激,用恒流刺激SFO作为电刺激,记录诱发的1 h内饮水量,用免疫组化方法检测脑内Fos蛋白表达.结果电刺激和化学刺激SFO均能诱导相似的饮水行为,其诱饮率分别为75%和85.7%,1 h平均饮水量分别为(0.28±0.22) ml 和(0.31±0.15) ml ,明显高于各自的对照组(P<0.05),并均能使前脑的 11个脑区(终板血管器官, 正中视前核,室旁核,视上核,下丘脑外侧区,丘脑室旁核,联合核和中央内侧核,终纹床核,穹窿周背区和无名质)和后脑的4个脑区(最后区,孤束核,臂旁外侧核和中缝背核)相似的Fos蛋白表达.结论刺激SFO所诱导的饮水行为和脑内Fos蛋白表达是激活其神经元胞体的结果.     

c-fos Gene expression during emotional stress in rats: blocking by delta sleep-inducing peptide

An emotional stress induces an obvious immediate early gene c-fos expression in the brain limbic structures in the rats predisposed to emotional stress. Administration of the delta-sleep-inducing peptide (DSIP) was shown to inhibit the c-fos expression. It led to an obvious inhibition of the c-fos expression in paraventricular nuclei of the hypothalamus, medial and lateral parts of the septum of rats predisposed to emotional stress. This mechanism seems to play an important role in the DSIP anti-stress effects.     

Morphine activation of c-fos expression in rat brain

The post-receptor mechanism of opiate action has been studied by examining the activation by morphine of the proto-oncogene c-fos and its encoded nucleoprotein pp55c-fos (FOS) in rat caudate-putamen, which is rich in the mu-type opiate receptor. Following an acute morphine treatment, c-fos mRNA levels in rat caudate-putamen were increased to maximum (420% of control level) at 45 minutes and returned to control levels at 90 minutes. This induction was completely abolished by naloxone, a morphine antagonist. Fos protein, detected by immunocytochemistry, was also increased 3 hours after morphine injection, in the caudate-putamen, but not in the olfactory tubercle, which does not have the mu-type opiate receptor. Upon activation of opiate receptors by morphine, the c-fos gene is activated and Fos protein may act as a signal transducer uniquely involved in the mechanism of opiate addiction at the level of gene regulation.     

The action of korazol on the defensive behavior of rats]

The paper shows the dependence of behavioral changes provoked by corazol on individual characteristics of the animals. The rats with high activity in the ATS demonstrated the highest response to the drugs.     

A comparative analysis of learning and exploratory behavior in rats with different resistances to stress exposures and to the brain monoamine level]

Wistar rats stable (S) to sound stimulus differed from the unstable (NS) ones by a heightened investigatory activity in condition of moderate stress in the open field test, by heightened reactivity to sensory stimuli of various modalities (somatosensory, visual and olfactory), lowered level of investigatory behaviour in the test of burrow chamber. S-rats differed from NS-animals by a higher ability to learning of goal-directed reaction and a lower ability to discrimination of different emotional influences. The results of biochemical analysis of the content of biogenic amines in various brain structures revealed in stable rats an increase of noradrenaline level and in non-stable ones--a higher level of dopamine and serotonin.     

Effect of vibrissae removal on the defensive behavior of rats in early ontogeny

Influence of restricted sensory afferentation in rats forming of defensive reactions was studied by vibrissectomy from 9 to 20 day of postnatal ontogeny. Defensive withdrawal reaction in response to touch from 10 to 18 day, duration of freezing on 20 day, "open field" behavior on 25 day were measured. Intensity of withdrawal reactions, freezing duration, flight reaction and emotionality in "open field" were lower in vibrissectomized rats with comparison to control.     

Gene expression in rat brain

191 randomly selected cDNA clones prepared from rat brain cytoplasmic poly (A)+ RNA were screened by Northern blot hybridization to rat brain, liver and kidney RNA to determine the tissue distribution, abundance and size of the corresponding brain mRNA. 18% hybridized to mRNAs each present equally in the three tissues, 26% to mRNAs differentially expressed in the tissues, and 30% to mRNAs present only in the brain. An additional 26% of the clones failed to detect mRNA in the three tissues at an abundance level of about 0.01%, but did contain rat cDNA as demonstrated by Southern blotting; this class probably represents rare mRNAs expressed in only some brain cells. Therefore, most mRNA expressed in brain is either specific to brain or otherwise displays regulation. Rarer mRNA species tend to be larger than the more abundant species, and tend to be brain specific; the rarest, specific mRNAs average 5000 nucleotides in length. Ten percent of the clones hybridize to multiple mRNAs, some of which are expressed from small multigenic families. From these data we estimate that there are probably at most 30,000 distinct mRNA species expressed in the rat brain, the majority of which are uniquely expressed in the brain.     

Gene expression profile of the hippocampus of rats subjected to traumatic brain injury

Traumatic brain injury (TBI) is a serious public health problem as well as a leading cause of severe posttraumatic disability. Numerous studies indicate that the differentially expressed genes (DEGs) of neural signaling pathways are strongly correlated with brain injury. To further analyze the roles of the DGEs in the central nervous system, here we systematically investigated TBI on the hippocampus and its injury mechanism at the whole genome level. On the basis of Gene Ontology and Kyoto Encyclopedia of Genes and Genomes Analyses, we revealed that the DEGs were involved in many signaling pathways related to the nervous system, especially neuronal survival-related pathways. Finally, we verified the microarray results and detected the gene expression of neuronal survival-related genes in the hippocampus by using real-time quantitative polymerase chain reaction. With Western blot and axon growth assay, the expression of P2rx3 was upregulated in rats subjected to TBI, and overexpression of P2rx3 promoted neurite growth of NG108 cells. Our results suggested that the DEGs (especially P2rx3) and several signaling pathways might play a pivotal role in TBI. We also provided several targeted genes related to TBI for future investigation.     

学习记忆对脑内c-fos基因表达的影响

学习记忆是人和动物重要的脑功能，大量事实表明，学习记忆过程与脑内ｃ－ｆｏｓ基因的表达密切相关。由学习记忆所诱导的ｃ－ｆｏｓ基因表达在脑内广泛分布，以皮层、海马和边缘系统为多，依学习记忆训练模型的不同，其表达时程有所差异，但一般于训练后立即或３０分钟左右出现，１～２小时左右达峰值。被动和主动回避训练、光辨别训练及味觉厌恶性条件反射训练等多种学习记忆模型均可诱导脑内ｃ－ｆｏｓ基因的表达。其他影响学习记     

Novelty-induced increased expression of immediate-early genes c-fos and arg 3.1 in the mouse brain

The detection of novel stimuli is a memory-dependent process. The presented stimulus has to be compared with memory contents to judge its novelty. In addition, the novelty of stimuli activates attention-related processes that facilitate memory formation. To determine the involvement of limbic and neocortical brain structures in novelty detection, we exposed mice to a novel gustatory stimulus (0.5% saccharin) added to their drinking fluid. We then compared the novelty-induced expression of the two immediate-early genes (IEGs) c-fos and arg 3.1, with their expression in mice familiarized with the same stimulus or mice not exposed to that stimulus. Exposure to taste novelty increased expression of c-fos and arg 3.1 mRNA in the cingulate cortex and deep layers of the parietal cortex. In addition, c-fos mRNA expression was increased in the amygdala and arg 3.1 mRNA was increased in the dentate gyrus. Expression of c-fos and arg 3.1 was elevated 30 min after the exposure to novelty. For arg 3.1, a second peak of expression was found 4.5 h after presentation of the novel stimulus. Our results indicate that the amygdala, the dentate gyrus, and the cingulate and parietal cortices may be involved in novelty detection and associated cognitive events, and suggest that c-fos and arg 3.1 play distinct roles in these processes.     

Central angiotensin induction of fetal brain c-fos expression and swallowing activity

The present study examined physiological and cellular responses to central application of ANG II in ovine fetuses and determined the fetal central ANG-mediated dipsogenic sites in utero. Chronically prepared near-term ovine fetuses (130 +/- 2 days) received injection of ANG II (1.5 microg/kg icv). Fetuses were monitored for 3.5 h for swallowing activity, after which animals were killed and fetal brains were perfused for subsequent Fos staining. Intracerebroventricular ANG II significantly increased fetal swallowing in near-term ovine fetuses (1.1 +/- 0.2 to 4.5 +/- 1.0 swallows/min). The initiation of stimulated fetal swallowing activity was similar to the latency of thirst responses (drinking behavior) elicited by central ANG II in adult animals. ANG II evoked increased Fos staining in putative dipsogenic centers, including the subfornical organ, organum vasculosum of the lamina terminalis, and median preoptic nucleus. Intracerebroventricular injection of ANG II also caused c-fos expression in the fetal hindbrain. These results indicate that an ANG II-mediated central dipsogenic mechanism is intact before birth, acting at sites consistent with the dipsogenic neural network. Central ANG II mechanisms likely contribute to fetal body fluid and amniotic fluid regulation.     

Intranasal administration of testosterone increased immobile-sniffing, exploratory behavior, motor behavior and grooming behavior in rats

Currently, testosterone (T) replacement therapy is typically provided by oral medication, injectable T esters, surgically implanted T pellets, transdermal patches and gels. However, most of these methods of administration are still not ideal for targeting the central nervous system. Recently, therapeutic intranasal T administration (InT) has been considered as another option for delivering T to the brain. In the present study, the effects of 21-day InT treatment were assessed on open field behavior in gonadectomized (GDX) rats and intact rats. Subcutaneous injections of T at same dose were also tested in GDX rats. A total of 12 behavioral events were examined in GDX groups with or without T and in intact groups with or without InT. Significant decreases in open field activity were observed in rats after GDX without InT compared to sham-operated rats. The open field activity scores for most tests significantly increased with InT treatment in GDX rats and in intact rats compared with the corresponding GDX rats and intact rats. Intranasal administration of T improved the reduced behaviors resulted from T deficiency better than subcutaneous injection of T, demonstrating that T can be delivered to the brain by intranasal administration. Our results suggest that intranasal T delivery is an effective option for targeting the central nervous system.     

Intravenous angiotensin induces brain c-fos expression and vasopressin release in the near-term ovine fetus

The effect of intravenous angiotensin II (ANG II) on fetal brain c-fos expression and arginine vasopressin (AVP) release was studied in the near-term ovine fetus. Fetuses with chronically implanted catheters received an intravenous infusion of ANG II or saline. Fetal plasma AVP concentrations were significantly increased after the peripheral administration of ANG II, with peak levels (3-fold) at 30 min after the intravenous infusion. There was no change in fetal plasma osmolality, sodium, and hematocrit levels between the control and experimental groups or between the periods before and after the infusion of ANG II. Intravenous ANG II administration induced Fos immunoreactivity (Fos-IR) in the circumventricular organs and the median preoptic nucleus of the fetal brain. Fos-IR was also demonstrated in the fetal supraoptic nuclei (SON). Double labeling demonstrated that the AVP-containing neurons in the SON were expressing c-fos in response to intravenous ANG II. These results indicate that the peripheral ANG II in the fetus may play a significant role in stimulating the central hypothalamic-neurohypophysial system during late gestation. It supports the hypothesis that circulating ANG II may act at the fetal AVP neurons in the hypothalamus in body fluid balance via the circumventricular organs, which are situated outside the blood-brain barrier, and the central neural pathway between these two brain structures has been relatively established in utero, at least at near-term.