Dopamine signaling in food addiction: role of dopamine D2 receptors

Dopamine (DA) regulates emotional and motivational behavior through the mesolimbic dopaminergic pathway. Changes in DA signaling in mesolimbic neurotransmission are widely believed to modify reward-related behaviors and are therefore closely associated with drug addiction. Recent evidence now suggests that as with drug addiction, obesity with compulsive eating behaviors involves reward circuitry of the brain, particularly the circuitry involving dopaminergic neural substrates. Increasing amounts of data from human imaging studies, together with genetic analysis, have demonstrated that obese people and drug addicts tend to show altered expression of DA D2 receptors in specific brain areas, and that similar brain areas are activated by food-related and drug-related cues. This review focuses on the functions of the DA system, with specific focus on the physiological interpretation and the role of DA D2 receptor signaling in food addiction. [BMB Reports 2013; 46(11): 519-526]     

食欲素信号系统在成瘾中的作用

成瘾是对成瘾物质的强迫性、持续性需求并缺乏控制能力的行为,它会导致大脑中枢奖赏回路的改变。下丘脑是调控自然奖赏的重要脑区,它能特异性地表达一种被称为食欲素(orexins/hypocretins)的神经肽。食欲素通过作用于食欲素受体调控睡眠、觉醒状态,同时,食欲素受体在药物成瘾和奖赏相关的行为中也有重要作用,投射到不同脑区的食欲素对不同药物导致的成瘾调节作用也不同,调控食欲素信号系统,将可能成为治疗成瘾的重要方法。本文重点总结了食欲素信号系统在不同药物成瘾过程中的作用的最新研究进展。     

下丘脑食欲素在药物成瘾中的作用

下丘脑是调控自然奖赏的重要脑区,它能特异性地表达一种神经肽——食欲素(orexin),这种神经肽在药物奖赏中的作用受到广泛关注。在成瘾研究中,发现不同脑区中的食欲素神经元对奖赏和动机行为的调节作用是不相同的:围穹窿区(PFA)和背内侧下丘脑区(DMH)的食欲素神经元主要参与激活应激系统,而外侧下丘脑(LH)的食欲素神经元主要通过激活与奖赏学习相关的大脑环路参与奖赏行为的调控。提示食欲素系统可在延长戒断防止复吸发生中成为新的研究目标,食欲素受体可以作为治疗药物成瘾的一种新的治疗靶标。     

Review. Neurobiological mechanisms for opponent motivational processes in addiction

The conceptualization of drug addiction as a compulsive disorder with excessive drug intake and loss of control over intake requires motivational mechanisms. Opponent process as a motivational theory for the negative reinforcement of drug dependence has long required a neurobiological explanation. Key neurochemical elements involved in reward and stress within basal forebrain structures involving the ventral striatum and extended amygdala are hypothesized to be dysregulated in addiction to convey the opponent motivational processes that drive dependence. Specific neurochemical elements in these structures include not only decreases in reward neurotransmission such as dopamine and opioid peptides in the ventral striatum, but also recruitment of brain stress systems such as corticotropin-releasing factor (CRF), noradrenaline and dynorphin in the extended amygdala. Acute withdrawal from all major drugs of abuse produces increases in reward thresholds, anxiety-like responses and extracellular levels of CRF in the central nucleus of the amygdala. CRF receptor antagonists block excessive drug intake produced by dependence. A brain stress response system is hypothesized to be activated by acute excessive drug intake, to be sensitized during repeated withdrawal, to persist into protracted abstinence and to contribute to stress-induced relapse. The combination of loss of reward function and recruitment of brain stress systems provides a powerful neurochemical basis for the long hypothesized opponent motivational processes responsible for the negative reinforcement driving addiction.     

New perspectives on cocaine addiction: recent findings from animal research

Research with laboratory animals has provided several insights into the nature of cocaine abuse and addiction. First, the nature of drug addiction has been reevaluated and the emphasis has shifted from physical dependence to compulsive drug-taking behavior. Second, animal studies suggest that cocaine is at least as addictive as heroin and possibly even more addictive. Third, cocaine is potentially more dangerous than heroin as evidenced by the higher fatality rate seen in laboratory animals given unlimited access to these drugs. Fourth, the neural basis of cocaine reinforcement has been identified and involves an enhancement of dopaminergic neurotransmission in the ventral tegmental dopamine system. Other addictive drugs (e.g., opiates) may also derive at least part of their reinforcing impact by pharmacologically activating this reward system. Fifth, although the biological consequences of repeated cocaine self-administration on central nervous system functioning are poorly understood, preliminary findings suggest that intravenous cocaine self-administration may decrease neural functioning in this brain reward system. This has important clinical implications because diminished functioning of an important brain reward system may significantly contribute to relapse into cocaine addiction. These and other findings from experimentation with laboratory animals suggest new considerations for the etiology and treatment of drug addiction.     

Gene expression profiling of the rewarding effect caused by methamphetamine in the mesolimbic dopamine system

Methamphetamine, a commonly used addictive drug, is a powerful addictive stimulant that dramatically affects the CNS. Repeated METH administration leads to a rewarding effect in a state of addiction that includes sensitization, dependence, and other phenomena. It is well known that susceptibility to the development of addiction is influenced by sources of reinforcement, variable neuroadaptive mechanisms, and neurochemical changes that together lead to altered homeostasis of the brain reward system. These behavioral abnormalities reflect neuroadaptive changes in signal transduction function and cellular gene expression produced by repeated drug exposure. To provide a better understanding of addiction and the mechanism of the rewarding effect, it is important to identify related genes. In the present study, we performed gene expression profiling using microarray analysis in a reward effect animal model. We also investigated gene expression in four important regions of the brain, the nucleus accumbens, striatum, hippocampus, and cingulated cortex, and analyzed the data by two clustering methods. Genes related to signaling pathways including G-protein-coupled receptor-related pathways predominated among the identified genes. The genes identified in our study may contribute to the development of a gene modeling network for methamphetamine addiction.     

miRNAs与药物成瘾

药物成瘾是一种慢性复发性脑病,主要表现为不可控制的对药物持续渴求和戒断后的高复吸。目前观点认为,成瘾是中脑腹侧被盖（ventral tegmental area,VTA）到伏隔核（nucleus accumbens,NAc）脑区多巴胺能奖赏通路中神经可塑性发生改变而导致的一种神经精神疾病。基因表达变化在神经可塑性中发挥着重要作用,但成瘾药物导致相关脑区结构和功能改变的机制还不甚清楚。微小RNAs（microRNAs,miRNAs）是一类非编码RNA,主要通过结合靶基因mRNA 3′非翻译区（3′untranslated region,3′UTR）,在转录后水平阻断其翻译成蛋白质或触发其不稳定而降解。越来越多的研究证实,miRNAs参与调节成瘾相关神经可塑性的变化。本文较系统地阐述miRNAs在药物成瘾中的作用研究进展,将为深入阐明药物成瘾的机制以及药物成瘾临床有效干预和诊治提供新思路。     

Methamphetamine induces chronic corticostriatal depression: too much of a bad thing

Leading theories of drug addiction propose that repeated drug exposure produces a long-lasting homeostatic dysregulation in brain reward processing that is normalized by drug readministration. In this issue of Neuron, Bamford and colleagues describe a novel neurobiological substrate that may contribute to this effect.     

Reward mechanisms in obesity: new insights and future directions

Food is consumed in order to maintain energy balance at homeostatic levels. In addition, palatable food is also consumed for its hedonic properties independent of energy status. Such reward-related consumption can result in caloric intake exceeding requirements and is considered a major culprit in the rapidly increasing rates of obesity in developed countries. Compared with homeostatic mechanisms of feeding, much less is known about how hedonic systems in brain influence food intake. Intriguingly, excessive consumption of palatable food can trigger neuroadaptive responses in brain reward circuitries similar to drugs of abuse. Furthermore, similar genetic vulnerabilities in brain reward systems can increase predisposition to drug addiction and obesity. Here, recent advances in our understanding of the brain circuitries that regulate hedonic aspects of feeding behavior will be reviewed. Also, emerging evidence suggesting that obesity and drug addiction may share common hedonic mechanisms will also be considered.     

Synaptic plasticity and addiction

Addiction is caused, in part, by powerful and long-lasting memories of the drug experience. Relapse caused by exposure to cues associated with the drug experience is a major clinical problem that contributes to the persistence of addiction. Here we present the accumulated evidence that drugs of abuse can hijack synaptic plasticity mechanisms in key brain circuits, most importantly in the mesolimbic dopamine system, which is central to reward processing in the brain. Reversing or preventing these drug-induced synaptic modifications may prove beneficial in the treatment of one of society's most intractable health problems.     

Food reward, hyperphagia, and obesity

Given the unabated obesity problem, there is increasing appreciation of expressions like "my eyes are bigger than my stomach," and recent studies in rodents and humans suggest that dysregulated brain reward pathways may be contributing not only to drug addiction but also to increased intake of palatable foods and ultimately obesity. After describing recent progress in revealing the neural pathways and mechanisms underlying food reward and the attribution of incentive salience by internal state signals, we analyze the potentially circular relationship between palatable food intake, hyperphagia, and obesity. Are there preexisting individual differences in reward functions at an early age, and could they be responsible for development of obesity later in life? Does repeated exposure to palatable foods set off a cascade of sensitization as in drug and alcohol addiction? Are reward functions altered by secondary effects of the obese state, such as increased signaling through inflammatory, oxidative, and mitochondrial stress pathways? Answering these questions will significantly impact prevention and treatment of obesity and its ensuing comorbidities as well as eating disorders and drug and alcohol addiction.     

A role for brain stress systems in addiction

Drug addiction is a chronically relapsing disorder characterized by compulsion to seek and take drugs and has been linked to dysregulation of brain regions that mediate reward and stress. Activation of brain stress systems is hypothesized to be key to the negative emotional state produced by dependence that drives drug seeking through negative reinforcement mechanisms. This review explores the role of brain stress systems (corticotropin-releasing factor, norepinephrine, orexin [hypocretin], vasopressin, dynorphin) and brain antistress systems (neuropeptide Y, nociceptin [orphanin FQ]) in drug dependence, with emphasis on the neuropharmacological function of extrahypothalamic systems in the extended amygdala. The brain stress and antistress systems may play a key role in the transition to and maintenance of drug dependence once initiated. Understanding the role of brain stress and antistress systems in addiction provides novel targets for treatment and prevention of addiction and insights into the organization and function of basic brain emotional circuitry.     

网络成瘾者奖赏系统和认知控制系统的神经机制

网络成瘾作为一种行为成瘾,已成为严重影响人们心理健康的全球性问题.根据大脑发育的神经生物模型,揭示网络成瘾者奖赏和认知控制系统的神经机制是解决网络成瘾问题的关键,也是心理学研究的重大问题.行为研究探讨了网络成瘾具有高奖赏寻求和低认知控制特征;神经机制研究揭示了奖赏和认知控制系统的缺陷是网络成瘾行为的高风险因素;与药物成瘾的比较研究发现,网络成瘾有着独特的奖赏机制.这些研究深化了对网络成瘾心理和神经机制的理解,但仍存在网络成瘾筛查和入组标准不科学、分型笼统、因果研究匮乏、干预和治疗效果具有争议、研究范式存在漏洞等一些急需解决的问题.     

Functional microcircuitry in the accumbens underlying drug addiction: insights from real-time signaling during behavior

An understanding of the neurobiological basis of drug addiction requires examination of real-time (subsecond) cellular and chemical responses in the brain reward system during drug-seeking and drug-taking behavior. Electrophysiological and electrochemical studies in the rodent nucleus accumbens have examined changes in cell firing and rapid dopamine signaling during crucial periods of behavioral responding for drugs, and show the associative nature of those signals. These findings are considered with respect to the functional microcircuitry in the nucleus accumbens that underlies goal-directed behavior and the role of this circuit in drug addiction.     

Synaptic plasticity in drug reward circuitry

Drug addiction is a major public health issue worldwide. The persistence of drug craving coupled with the known recruitment of learning and memory centers in the brain has led investigators to hypothesize that the alterations in glutamatergic synaptic efficacy brought on by synaptic plasticity may play key roles in the addiction process. Here we review the present literature, examining the properties of synaptic plasticity within drug reward circuitry, and the effects that drugs of abuse have on these forms of plasticity. Interestingly, multiple forms of synaptic plasticity can be induced at glutamatergic synapses within the dorsal striatum, its ventral extension the nucleus accumbens, and the ventral tegmental area, and at least some of these forms of plasticity are regulated by behaviorally meaningful administration of cocaine and/or amphetamine. Thus, the present data suggest that regulation of synaptic plasticity in reward circuits is a tractable candidate mechanism underlying aspects of addiction.     

Addiction: Decreased reward sensitivity and increased expectation sensitivity conspire to overwhelm the brain's control circuit

Based on brain imaging findings, we present a model according to which addiction emerges as an imbalance in the information processing and integration among various brain circuits and functions. The dysfunctions reflect (a) decreased sensitivity of reward circuits, (b) enhanced sensitivity of memory circuits to conditioned expectations to drugs and drug cues, stress reactivity, and (c) negative mood, and a weakened control circuit. Although initial experimentation with a drug of abuse is largely a voluntary behavior, continued drug use can eventually impair neuronal circuits in the brain that are involved in free will, turning drug use into an automatic compulsive behavior. The ability of addictive drugs to co‐opt neurotransmitter signals between neurons (including dopamine, glutamate, and GABA) modifies the function of different neuronal circuits, which begin to falter at different stages of an addiction trajectory. Upon exposure to the drug, drug cues or stress this results in unrestrained hyperactivation of the motivation/drive circuit that results in the compulsive drug intake that characterizes addiction.     

Neurobiology of addictive behavior

Addictive behavior developes after repeated substance use and it typically include a strong desire to take the drug, difficulties in controlling its use, persisting in its use despite harmful consequences, a higher priority given to the drug use than to other activities. Relapse, the resumption of drug taking after periods of abstinence, remains the major problem for the treatment of addiction. The process of drug addiction shares striking commonalities with neural plasticity associated with natural reward learning and memory and is caused primarily by drug-induced sensitization in the brain mesocorticolimbic systems that attribute incentive salience to reward-associated stimuli. The switch from controlled to compulsive drug seeking represents a transition at the neural level from prefrontal cortical to striatal control. Current neurophysiologic evidence suggests that the development of addiction is to some extent due to neurochemical stimulation of the midbrain dopaminergic system that is traditionally considered as a 'common neural currency' for rewards of most kinds. Addictions are a result of the interplay of multiple genetic and environmental factors. They are characterized by phenotypic and genetic heterogeneity as well as polygenicity. Environmental factors are crucial in addiction vulnerability and resistese too.     

Multiple reward signals in the brain

The fundamental biological importance of rewards has created an increasing interest in the neuronal processing of reward information. The suggestion that the mechanisms underlying drug addiction might involve natural reward systems has also stimulated interest. This article focuses on recent neurophysiological studies in primates that have revealed that neurons in a limited number of brain structures carry specific signals about past and future rewards. This research provides the first step towards an understanding of how rewards influence behaviour before they are received and how the brain might use reward information to control learning and goal-directed behaviour.     

腹侧被盖区多巴胺能神经元对奖赏/厌恶刺激反应的异质性

中脑多巴胺奖赏系统,由腹侧被盖区及其投射靶区组成,参与药物依赖、精神疾病等病理过程的调控.奖赏和厌恶刺激是衡量上述病理过程的重要手段.一直以来,不同研究在该系统对奖赏和厌恶刺激的反应上存在分歧,越来越多的研究倾向于认为该系统,特别是腹侧被盖区多巴胺能神经元存在较大的异质性.本文从腹侧被盖区多巴胺能神经元判定标准、解剖定位和投射特异性等角度对其在奖赏和厌恶刺激中的功能异质性进行综述,并对未来研究方向进行展望.