简讯

吗啡和海洛因在调节阿片类药物成瘾大鼠的海马区LTP中存在差异2007年初,中国科学院上海生物化学与细胞生物学研究所裴钢组在Neuropsychopharmacology上在线发表最新学术成果:吗啡和海洛因在调节阿片类药物成瘾大鼠的海马区LTP中存在差异。论文对于深入了解吗啡和海洛因的差异性、突触可塑性、学习记忆以及成瘾之间的密切关系具有一定的意义。药物成瘾被认为是神经元或神经回路的自适应性调节,其分子机制可以用神经元回路的突触可塑性改变来解释;之前和现在的研究结果为此提供了直接的实验证据。研究者们之前发现长期给与阿片类药物后所形…     

吗啡和海洛因在调节阿片类药物成瘾大鼠的海马区LTP中存在差异

2007年初,中国科学院上海生物化学与细胞生物学研究所裴钢组在Neuropsychopharmacology上在线发表最新学术成果：吗啡和海洛因在调节阿片类药物成瘾大鼠的海马区LTP中存在差异。论文对于深入了解吗啡和海洛因的差异性、突触可塑性、学习记忆以及成瘾之间的密切关系具有一定的意义。     

长期给予吗啡降低大鼠的听觉惊跳反射和惊跳反射弱刺激抑制

在药物成瘾过程中,多巴胺系统起着至关重要的作用,大多数成瘾性药物都是通过影响多巴胺系统使机体产生依赖性.而多巴胺系统也同样是感觉运动门控功能的主要神经基础.尤其是中脑边缘系统的多巴胺系统在这两种行为中都起很重要的作用.但是这两种行为是如何相互作用、相互影响的还不是很清楚.本实验室曾报道了吗啡如何影响海马区的感觉门控功能.本文研究了吗啡如何影响大鼠的感觉运动门控功能.在吗啡给予前,吗啡给予期间(10天)以及吗啡戒断期间,我们检测了大鼠的感觉运动门控功能.用到的指标为惊跳反射和惊跳前脉冲抑制,这两种指标也是研究精神分裂症的重要手段.其中惊跳反射的声音强度为115分贝,前脉冲声音强度测试了3个水平,分别为70,75,80分贝.研究发现,在吗啡给予期间,惊跳反射的强度降低,而戒断期间不受影响.前脉冲抑制功能在吗啡给予的后2天显著降低,而在吗啡戒断后恢复.     

罂粟中阿片依赖机制及药物治疗进展

阿片为罂粟中的主要成分 ,阿片依赖性机制可能涉及脑内奖赏中心、多巴胺 (DA)通路、阿片受体及内源性阿片肽及多种神经递质系统。阿片依赖性治疗主要包括脱毒治疗及防复吸治疗 ,防复吸是目前该领域的研究重点 ,探讨阿片类依赖性机制以开发新药是今后的研究方向。     

多巴胺D2受体拮抗剂、激动剂对SD大鼠条件化位置偏好的影响

通过慢性吗啡处理方式建立起SD大鼠吗啡依赖的条件化位置偏好(CPP)模型,用行为学手段研究多巴胺(DA)D2受体拮抗剂及激动剂对SD大鼠CPP的影响,探讨眶额叶DAD2受体在阿片精神依赖中的作用。通过腹腔注射吗啡同环境因素相结合,建立大鼠吗啡依赖的CPP模型;采用局部脑内微量注射法向额叶注射DAD2受体拮抗剂或激动剂或盐水(对照组),以得到SD大鼠在戒断期间的CPP的时间数据。CPP显示DAD2受体拮抗剂组与对照组相比,从戒断第2天起,前者表现出更明显的CPP增加现象,差异显著(P<0·05)。而DAD2受体激动剂组与对照组相比无显著差异(P>0·05)。采用腹腔小剂量注射吗啡,成功地建立了吗啡依赖SD大鼠的CPP模型;眶额叶微量注射DAD2受体拮抗剂增加了CPP时间,提示眶额叶多巴胺系统在吗啡依赖的过程中有着较为重要的作用;也提示了对于已经成瘾的动物,损伤其眶额叶,会使药物渴求增强。因而提示对于药物依赖患者进行手术干预治疗要极其慎重。     

慢性吗啡给予、戒断及再给药过程中大鼠海马感觉门控的动态变化

药物成瘾被认为是药物长期作用于脑而产生的一种慢性复吸性脑疾病,长期反复的药物（如吗啡）滥用会导致一系列严重后果,如药物依赖、药物耐受、强迫性药物寻求等。本实验利用条件化位置偏好（conditioned place preference,CPP）模型来检测大鼠对吗啡依赖和心理渴求等过程;采用双声刺激听觉诱发电位来研究大鼠在慢性吗啡给予、戒断以及再给药过程中海马感觉门控（N40）的动态变化。吗啡组大鼠注射吗啡（10mg／kg,i．p．）12d,经历第一次戒断12d,再次注射吗啡（2．5mg／kg,i．P．）1d,之后经历第二次戒断2d;对照组大鼠注射同体积生理盐水,其余实验条件与吗啡组相同。CPP实验表明,这种药物给予方法促使大鼠对吗啡产生药物依赖和心理渴求。双声刺激诱发电位实验表明,吗啡组大鼠在吗啡给予期间海马感觉门控受到损伤;第一次戒断期的第1～2天海马感觉门控能力减弱,第3天增强,第4～12天逐渐恢复到正常水平;再次给予吗啡后海马感觉门控能力与对照组相比显著降低,并且随后2d的戒断期内海马感觉门控能力也一直保持较低水平,表明再次给药使大鼠海马感觉门控对吗啡更加敏感化。结果提示,长期反复的吗啡给予及再给药干扰了海马的感觉门控能力,吗啡成瘾对大脑可能产生长期影响。     

阿片成瘾机制研究进展及治疗展望

关于阿片类药物成瘾机制的研究是药物成瘾研究中的一个热点,本文从参与阿片成瘾的神经递质系统及其相互作用、不同阿片受体在成瘾过程中的作用、学习记忆与阿片成瘾的关系、成瘾性药物的细胞内信号转导机制等几个方面介绍了近年来的研究进展,并对阿片类药物成瘾治疗和预防和新方法进行了展望。     

吗啡对于蟾蜍离体脊髓的兴奋作用

在蟾蜍离体脊髓标本上,吗啡10~(-5)—10~(-3)M 能增大背根-腹根反射(DR-VRR),此增大作用不被纳洛酮拮抗,但10~(-4)M 的纳洛酮可轻度增大 DR-VRR。含菲核结构的阿片生物碱蒂巴因、可待因的兴奋作用强于吗啡,这三种药物在更高浓度时则抑制、甚至取消 DR-VRR。不含菲核结构的合成镇痛药美沙酮、哌替啶及脑啡肽类似物 FK33-824对 DR-VRR只起抑制作用。虽然吗啡能阻滞脊髓突触前抑制,并以可被纳洛酮逆转的方式取消刺激腹根诱发的背根电位(VR-DDRP),吗啡增大 DR-VRR 并非由于它的去抑制作用。本文结果提示,吗啡的兴奋作用与阿片受体无关,并为含菲核结构的阿片生物碱所特有。     

在吗啡奖赏效应中多巴胺并非必需

多年来大量的实验证明,具有成瘾性的物质通过作用于脑内不同的靶点,最终都会引起伏核内多巴胺含量的上升;而损毁中脑边缘多巴胺系统能够抑制药物的奖赏作用。因此,在成瘾机制的研究中多巴胺处于重要地位。尽管如此,仍然有人质疑多巴胺在成瘾性药物的多种行为反应中的作用,从而提出了不依赖多巴胺的阿片奖赏机制。那么,多巴胺是否是阿片类药物诱导的各种行为反应所必需的呢？     

人参皂甙Rg1可改善吗啡依赖大鼠空间学习障碍

长时间应用阿片类制剂如吗啡、海洛因等会诱发脑的适应性改变,从而出现药物成瘾或依赖。以往研究显示,阿片成瘾在许多方面与学习记忆过程类似,相关学者认为是学习的一种异化形式,而这一异化行为的形成是脑内某一记忆系统非适应性回归介导的。另一方面,长时间应用阿片本身也会导致学习记忆能力受损。     

Neonatal Morphine Administration Leads to Changes in Hippocampal BDNF Levels and Antioxidant Enzyme Activity in the Adult Life of Rats

It is know that repeated exposure to opiates impairs spatial learning and memory and that the hippocampus has important neuromodulatory effects after drug exposure and withdrawal symptoms. Thus, the aim of this investigation was to assess hippocampal levels of BDNF, oxidative stress markers associated with cell viability, and TNF-α in the short, medium and long term after repeated morphine treatment in early life. Newborn male Wistar rats received subcutaneous injections of morphine (morphine group) or saline (control group), 5 μg in the mid-scapular area, starting on postnatal day 8 (P8), once daily for 7 days, and neurochemical parameters were assessed in the hippocampus on postnatal days 16 (P16), 30 (P30), and 60 (P60). For the first time, we observed that morphine treatment in early life modulates BDNF levels in the medium and long term and also modulates superoxide dismutase activity in the long term. In addition, it was observed effect of treatment and age in TNF-α levels, and no effects in lactate dehydrogenase levels, or cell viability. These findings show that repeated morphine treatment in the neonatal period can lead to long-lasting neurochemical changes in the hippocampus of male rats, and indicate the importance of cellular and intracellular adaptations in the hippocampus after early-life opioid exposure to tolerance, withdrawal and addiction.     

Morphine-element interactions – The influence of selected chemical elements on neural pathways associated with addiction

Addiction is a pressing social problem worldwide and opioid dependence can be considered the strongest and most difficult addiction to treat. Mesolimbic and mesocortical dopaminergic pathways play an important role in modulation of cognitive processes and decision making and, therefore, changes in dopamine metabolism are considered the central basis for the development of dependence. Disturbances caused by excesses or deficiency of certain elements have a significant impact on the functioning of the central nervous system (CNS) both in physiological conditions and in pathology and can affect the cerebral reward system and therefore, may modulate processes associated with the development of addiction. In this paper we review the mechanisms of interactions between morphine and zinc, manganese, chromium, cadmium, lead, fluoride, their impact on neural pathways associated with addiction, and on antinociception and morphine tolerance and dependence.     

Decreased mitochondrial DNA copy number in the hippocampus and peripheral blood during opiate addiction is mediated by autophagy and can be salvaged by melatonin

Drug addiction is a chronic brain disease that is a serious social problem and causes enormous financial burden. Because mitochondrial abnormalities have been associated with opiate addiction, we examined the effect of morphine on mtDNA levels in rat and mouse models of addiction and in cultured cells. We found that mtDNA copy number was significantly reduced in the hippocampus and peripheral blood of morphine-addicted rats and mice compared with control animals. Concordantly, decreased mtDNA copy number and elevated mtDNA damage were observed in the peripheral blood from opiate-addicted patients, indicating detrimental effects of drug abuse and stress. In cultured rat pheochromocytoma (PC12) cells and mouse neurons, morphine treatment caused many mitochondrial defects, including a reduction in mtDNA copy number that was mediated by autophagy. Knockdown of the Atg7 gene was able to counteract the loss of mtDNA copy number induced by morphine. The mitochondria-targeted antioxidant melatonin restored mtDNA content and neuronal outgrowth and prevented the increase in autophagy upon morphine treatment. In mice, coadministration of melatonin with morphine ameliorated morphine-induced behavioral sensitization, analgesic tolerance and mtDNA content reduction. During drug withdrawal in opiate-addicted patients and improvement of protracted abstinence syndrome, we observed an increase of serum melatonin level. Taken together, our study indicates that opioid addiction is associated with mtDNA copy number reduction and neurostructural remodeling. These effects appear to be mediated by autophagy and can be salvaged by melatonin.     

Effects of morphine administration and its withdrawal on rat brain aminopeptidase activities

The endogenous opioid neuropeptide system seems to be involved in the neural processes which underlie drug addiction. Several studies have reported that the administration of morphine induces changes in the levels and/or activity of endogenous opioid peptides (enkephalin, dynorphin) and their precursors in specific brain regions of the adult CNS. The aim of this work was to study the effects of chronic morphine exposure and its withdrawal on certain aminopeptidases capable of degrading opioid peptides in brain areas including the amygdala, hypothalamus, hippocampus, striatum and brain cortices. In animals treated with morphine, aminopeptidase N presented higher enzyme activity levels in the striatum, the hypothalamus and the amygdala compared to control animals, although statistically significant differences were observed only in the case of the striatum. In addition, the activity of soluble puromycin-sensitive aminopeptidase (PSA) was found to be higher in the frontal cortex of these rats. In contrast, rats experiencing withdrawal symptoms presented decreased levels of aminopeptidase activity in certain brain areas. Thus, the activity of aminopeptidase N in the hippocampus and soluble puromycin-sensitive aminopeptidase in the frontal cortex were found to be lower in rats experiencing naloxone precipitated withdrawal symptoms, compared to the corresponding controls. Finally, the activity of the three studied aminopeptidases in vitro was unaltered by incubation with morphine, suggesting that the observed effects are not due to a direct action of this opioid upon the aminopeptidases. The results of the present report indicate that aminopeptidases may play an important role in the processes of tolerance and withdrawal associated with morphine administration.     

Chronic morphine treatment decreases acoustic startle response and prepulse inhibition in rats

The reward-related effects of addictive drugs primarily act via the dopamine system, which also plays an important role in sensorimotor gating. The mesolimbic dopamine system is the common pathway of drug addiction and sensorimotor gating. However, the way in which addictive drugs affect sensorimotor gating is currently unclear. In previous studies, we examined the effects of morphine treatment on sensory gating in the hippocampus. The present study investigated the effects of morphine on sensorimotor gating in rats during chronic morphine treatment and withdrawal. Rats were examined during treatment with morphine for 10 successive days, followed by a withdrawal period. Acoustic startle responses to a single startle stimulus (115 dB SPL) and prepulse inhibition responses were recorded. The results showed that acoustic startle responses were attenuated during morphine treatment, but not during withdrawal. PPI was impaired in the last 2 morphine treatment days, but returned to a normal level during withdrawal.     

Chronic Morphine Reduces Surface Expression of δ-Opioid Receptors in Subregions of Rostral Striatum

The delta opioid receptor (DOPr), whilst not the primary target of clinically used opioids, is involved in development of opioid tolerance and addiction. There is growing evidence that DOPr trafficking is involved in drug addiction, e.g., a range of studies have shown increased plasma membrane DOPr insertion during chronic treatment with opioids. The present study used a transgenic mouse model in which the C-terminal of the DOPr is tagged with enhanced-green fluorescence protein to examine the effects of chronic morphine treatment on surface membrane expression in striatal cholinergic interneurons that are implicated in motivated learning following both chronic morphine and morphine sensitization treatment schedules in male mice. A sex difference was noted throughout the anterior striatum, which was most prominent in the nucleus accumbens core region. Incontrast with previous studies in other neurons, chronic exposure to a high dose of morphine for 6 days had no effect, or slightly decreased (anterior dorsolateral striatum) surface DOPr expression. A morphine sensitization schedule produced similar results with a significant decrease in surface DOPr expression in nucleus accumbens shell. These results suggest that chronic morphine and morphine sensitisation treatment may have effects on instrumental reward-seeking behaviours and learning processes related to drug addiction, via effects on striatal DOPr function.     

Single‐nucleotide polymorphism (A118G) in exon 1 of OPRM1 gene causes alteration in downstream signaling by mu‐opioid receptor and may contribute to the genetic risk for addiction

The opioid receptor mu1 (OPRM1) mediates the action of morphine. Although genetic background plays an important role in the susceptibility toward abuse of drugs as evident from familial, adoption and twin studies, association of specific single‐nucleotide polymorphisms of OPRM1 gene with narcotic addiction is to be established. Here, we demonstrate the involvement of A118G polymorphism of exon1 of human OPRM1 gene (hOPRM1), with heroin and alcohol addiction, in a population in eastern India. Statistical analysis exhibited a significant association of G allele with both heroin and alcohol addiction with a risk factor of P_trend < 0.05. The functional significance of G allele in A118G single‐nucleotide polymorphisms was evaluated by studying the regulation of protein kinase A (PKA), pCREB, and pERK1/2 by morphine in Neuro 2A cells, stably transfected with either wild type or A118G mutant hOPRM1. Unlike acute morphine treatment, both chronic morphine exposure and withdrawal precipitated by naloxone were differentially regulated by A118 and G118 receptor isoforms when both PKA and pERK1/2 activities were compared. Results suggest that the association of A118G polymorphism to heroin and alcohol addiction may be because of the altered regulation of PKA and pERK1/2 during opioid and alcohol exposures.     

SB-334867 (an Orexin-1 Receptor Antagonist) Effects on Morphine-Induced Sensitization in Mice—a View on Receptor Mechanisms

The present study focused upon the role of SB-334867, an orexin-1 receptor antagonist, in the acquisition of morphine-induced sensitization to locomotor activity in mice. Behavioral sensitization is an enhanced systemic reaction to the same dose of an addictive substance, which assumingly increases both the desire for the drug and the risk of relapse to addiction. Morphine-induced sensitization in mice was achieved by sporadic doses (five injections every 3 days) of morphine (10 mg/kg, i.p.), while a challenge dose of morphine (10 mg/kg) was injected 7 days later. In order to assess the impact of orexin system blockade on the acquisition of sensitization, SB-334867 was administered before each morphine injection, except the morphine challenge dose. The locomotor activity test was performed on each day of morphine administration. Brain structures (striatum, hippocampus, and prefrontal cortex) were collected after behavioral tests for molecular experiments in which mRNA expression of orexin, dopamine, and adenosine receptors was explored by the qRT-PCR technique. Additionally, the mRNA expression of markers, such as GFAP and Iba-1, was also analyzed by the same technique. SB-334867 inhibited the acquisition of morphine-induced sensitization to locomotor activity of mice. Significant alterations were observed in mRNA expression of orexin, dopamine, and adenosine receptors and in the expression of GFAP and Iba-1, showing a broad range of interactions in the mesolimbic system among orexin, dopamine, adenosine, and glial cells during behavioral sensitization. Summing up, the orexin system may be an effective measure to inhibit morphine-induced behavioral sensitization.     

Possible role of brain histamine in morphine addiction.

Several biogenic amines have been suggested to play a possible role in opiate addiction. While some reports indicated changes in brain norepinephrine and dopamine concentrations and/or synthesis (1,2,3), others have demonstrated the involvement of serotonin or acetylcholine (4,5,6,7). In view of recent reports suggesting a possible role for histamine in brain function as another putative neurotransmitter (8), we have investigated whether this biogenic amine might also participate in morphine addiction and withdrawal.