去甲肾上腺素参与吗啡神经适应性改变的中枢机制

That relapse still exists even after prolonged withdrawal is a difficult issue in the medical cure of drug addiction. Neuro-adaptation induced by prolonged exposure to addictive drugs is the neural mechanisms of both compulsive drug seeking and relapse.Neuro-adaptation caused by addictive drugs increases the individuals’ response to drugs and on the other hand, it reduces the response to natural reward in withdrawn individuals.There must be common neural mechanisms between the co-existing phenomena, and there must also be unique neural mechanisms in the drugs.To reveal the neuro-adaptation arising in the process from random, controllable drug-use to uncontrollable compulsive drug seeking is of great significance both theoretically and practically.Based on the above hypothesis, in order to reveal the function of alpha adrenergic receptor in compulsive drug-seeking motivation during the process of drug addiction, using sensitization of morphine-induced psychomotor activity as behavioral model, through the method of behavioral pharmacology, the neural mechanisms of alpha adrenergic receptor’s involvement in the process of addiction has been studied.The adjustment function caused by alpha receptors in medial prefrontal cortex and nucleus accumbens to morphine-induced psychomotor activity has been compared in the period of first use of drugs and in repetitive-use period. Furthermore, the effect on novelty seeking caused by alpha-receptors in relevant brain areas has also been compared. Major results are as follow: 1 After prolonged morphine exposure, rats’ response to morphine-induced psychomotor activity is strengthened and response to novel object induced reward weakened. 2 Injection of prazosin in medial prefrontal cortex will block morphine-induced psychomotor activity of naïve rats, however, it will not block that of morphine-withdrawn rats, but it will block the novelty seeking behavior of morphine-withdrawn rats. 3 Injection of clonidine in medial prefrontal cortex will block morphine-induced psychomotor effect of both naïve rats and morphine-withdrawn rats, and will block the novelty seeking behavior of morphine-withdrawn rats. 4 Injection of prazosin in nucleus accumbens will not affect the morphine-induced psychomotor effect of either naïve rats or morphine-withdrawn rats, nor will it affect the novelty seeking behavior of morphine-withdrawn rats. 5 Injection of clonidine in nucleus accumbens will block morphine-induced psychomotor effect of naïve rats, however, it will not block that of morphine-withdrawn rats, nor will it affect the novelty seeking behavior of morphine-withdrawn rats. These results show: 1 The weakening of the function of alpha1 receptors in medial prefrontal cortex and alpha2 receptors in nucleus accumbens caused by repetitive exposure to morphine is probably the cause of compulsive drug-seeking activity. 2 Blocking alpha1 receptors in medial prefrontal cortex accelerates the loss of interest in natural reward after morphine withdrawal. 3 Blocking alpha2 receptors in medial prefrontal cortex not only restrains drug-seeking motivation, but also blocks the individual’s seeking motivation for novelty stimulus, which suggests that, while selecting medicine for curing addiction, it should be considered to reduce the influence on natural reward as much as possible and to avoid major side-effect.

抑郁行为及不同抑郁亚型的多巴胺机制研究

The conceptualization of “depression” as a heterogenous disease has been widely accepted by most researchers. However, controlled experiments are rather sparse. To date, most studies demonstrated that animals with helplessness, a widely recognized behavioral index of “depression” also show varied comobidity expressions of other emotional behaviors, such as hightened or lightened anxiety level compared with controls. This means that distinct subtypes of “depression” may exist, in which different neural mechanisms may play roles. The present study aims to explore the possibility of behaviorally categorizing two depressive subtypes, referred as anxious helplessness and non-anxious helplessness, respectively. Then, by using RT-PCR, the dopamine D1, D2, D3 receptors mRNA expressions in medial prefrontal cortex (mPFC) and nucleus accubems (NAc) were quantified. The main findings are described as belows: 1. Uncontrollable shock could readily induce helpless behavior in shocked animals as a whole but with salient individual differences. Prior inescaoable shock induces subsuquent helplessness in approximately 40% shocked animals, while the other animals showed no sign of helpless expression, and were classified as non-helplessness. 2. Among helpless animals, the “subtype” of anxious helpless and non-anxious helpless could be identified according to the anxiety level evaluated by elevated plus maze. 3. D3 receptors mRNA expressions in the mPFC and NAc were increased in stressed animals after uncontrollable shock treatment. At the meanwhile, significant lower expressions of D2 receptors in the mPFC and NAc, and much lower expressions of D1 receptors in the mPFC were found in rats that did not become helpless after stress. In contrast, no significant difference between helpless and control animals was found in D1/D2 receptors mRNA expressions. 4. Based on above mentioned results, the up-regulation of D3 receptors in the mPFC and NAc may reflect a generalized effect of exposure to uncontrollalbe shock. While the down-regulation of D1\D2 receptors in the mPFC and decreased expression of D2 receptors in the NAc may be associated with adaptive or protective mechnisms which protecting animals from helplessness after uncontrollable shock treatment. 5. Futhermore, a significant negative relationship was found between anxiety level and D1 receptors expressions in the mPFC in helpless animals. Compared to the non-anxious helpless and control rats, the D1 receptors mRNA of anxious helpless rats were down-regulation in the mPFC. The present study indicated that the D1 dopamine receptor gene is associated with co-morbid depression and anxiety.

情绪应激对大鼠体液免疫功能的影响及其机制

This study was undertaken to investigate the effect of emotional stress on humoral immunoactivity and to examine whether the sympathetic nervous system was involved in the immunomodulation. In the present study, two types of emotional stressors were used. One was footshock apparatus used to cause the rats which were given footshock before, emotional stressed; the other was an empty water bottle used to cause the rats which were trained to drink water at two set times each day, emotional stressed. The effect of emotional stress on the primary immune function (anti-ovallum antibody level and spleen index), the endocrine response (corticosterone level, epinephrine and norepinephrine level), the behavioral changes (freezing, defecation, grooming and attacking behavior) were investigated. The main results were: 1. Two types of emotional stress significantly increased the level of plasma corticosterone, norepinephrine and epinephrine, as well as freezing, defecation and attacking behavior. 2. Two types of emotional stress significantly decreased the level of anti-ovallum antibody. A negative correlation between catecholamine level (epinephrine and norepinephrine) and antibody level or spleen index was found. 3. β-adrenergic receptor antagonist propranolol could reverse the immunomodulation induced by emotional stress. 4. After two types of emotional stress, c-fos expression was observed in the following brain areas or nucleus; arcuate nucleus, anterior commissure nucleus, diffuse part of dorsalmedial nucleus hypothalamus, lateral dorsal nucleus thalamus, medial nucleus amygdala, solitary nucleus, frontal cortex and cingulum. These brain areas and nucleus are involved in the central modulation of the autonomic nervous system. Taken together, these findings demonstrate that emotional stress can suppress humoral immunity and the activation of the sympathetic nervous system is involved in the humoral immunomodulation induced by emotional stress.