Polymorphisms in dopamine system genes are associated with individual differences in attention in infancy

Knowledge about the functional status of the frontal cortex in infancy is limited. This study investigated the effects of polymorphisms in four dopamine system genes on performance in a task developed to assess such functioning, the Freeze-Frame task, at 9 months of age. Polymorphisms in the catechol-O-methyltransferase (COMT) and the dopamine D4 receptor (DRD4) genes are likely to impact directly on the functioning of the frontal cortex, whereas polymorphisms in the dopamine D2 receptor (DRD2) and dopamine transporter (DAT1) genes might influence frontal cortex functioning indirectly via strong frontostriatal connections. A significant effect of the COMT valine158methionine (Val158Met) polymorphism was found. Infants with the Met/Met genotype were significantly less distractible than infants with the Val/Val genotype in Freeze-Frame trials presenting an engaging central stimulus. In addition, there was an interaction with the DAT1 3′ variable number of tandem repeats polymorphism; the COMT effect was present only in infants who did not have two copies of the DAT1 10-repeat allele. These findings indicate that dopaminergic polymorphisms affect selective aspects of attention as early as infancy and further validate the Freeze-Frame task as a frontal cortex task.

A comprehensive analysis of sexual dimorphism in the midbrain dopamine system

Thesis (Ph.D.)--University of Washington, 2016-06

Exclusion of linkage between schizophrenia and the D2 dopamine receptor gene region of chromosome 11q in 112 Irish multiplex families

A leading theory hypothesizes that schizophrenia arises from dysregulation of the dopamine system in certain brain regions. As this dysregulation could arise from abnormal expression of D2 dopamine receptors, the D2 receptor gene (DRD2) on chromosome 11q is a candidate locus for schizophrenia. We tested whether allelic variation at DRD2 and five surrounding loci cosegregated with schizophrenia in 112 small- to moderate-size Irish families containing two or more members affected with schizophrenia or schizoaffective disorder, defined by DSM-III-R. Evidence of linkage was assessed using varying definitions of illness and modes of transmission. Assuming genetic homogeneity, linkage between schizophrenia and large regions of 11q around DRD2 could be strongly excluded. Assuming genetic heterogeneity, variation at the DRD2 locus could be rejected as a major risk factor for schizophrenia in more than 50% of these families for all models tested and in as few as 25% of the families for certain models. The DRD2 linkage in fewer than 25% of these families could not be excluded under any of the models tested. Our results suggest that the major component of genetic susceptibility to schizophrenia is not due to allelic variation at the DRD2 locus or other genes in the surrounding chromosomal region.

Interactions between the cholinergic and dopaminergic system during the production of ultrasonic vocalizations in rats

Rats produce ultrasonic vocalizations that can be categorized into two types of ultrasonic calls based on their sonographic structure. One group contains 22-kHz ultrasonic vocalization (USVs), characterized by relatively constant (flat) frequency with peak frequency ranging from 19 to 28-kHz, and a call duration ranging between 100 – 3000 ms. These vocalization can be induced by cholinomimetic agents injected into the ascending mesolimbic cholinergic system that terminates in the anterior hypothalamic-preoptic area (AH-MPO) and lateral septum (LS). The other group of USVs contains 50-kHz USVs, characterized by high peak frequency, ranging from 39 to 90-kHz, short duration ranging from 10-90 ms, and varying frequency and complex sonographic morphology. These vocalizations can be induced by dopaminergic agents injected into the nucleus accumbens, the target area for the mesolimbic dopaminergic system. 22-kHz USVs are emitted in situations that are highly aversive, such as proximity of a predator or anticipation of a foot shock, while 50 kHz USVs are emitted in rewarding and appetitive situations, such as juvenile play behaviour or anticipation of rewarding electrical brain stimulation. The activities of these two mesolimbic systems were postulated to be antagonistic to each other. The current thesis is focused on the interaction of these systems indexed by emission of relevant USVs. It was hypothesized that emission of 22 kHz USVs will be antagonized by prior activation of the dopaminergic system while emission of 50 kHz will be antagonized by prior activation of the cholinergic system. It was found that injection of apomorphine into the shell of the nucleus accumbens significantly decreased the number of carbachol-induced 22 kHz USVs from both AH-MPO and LS. Injection of carbachol into the LS significantly decreased the number of apomorphine-induced 50 kHz USVs from the shell of the nucleus accumbens. The results of the study supported the main hypotheses that the mesolimbic dopaminergic and cholinergic systems function in antagonism to each other.

Stress-induced cross-sensitization to amphetamine is related to changes in the dopaminergic system

Fundação de Amparo à Pesquisa do Estado de São Paulo (FAPESP)

Delay discounting task in pigs reveals response strategies related to dopamine metabolite.

We developed a novel delay discounting task to investigate outcome impulsivity in pigs. As impulsivity can affect aggression, and might also relate to proactive and reactive coping styles, eight proactive (HR) and eight reactive (LR) pigs identified in a manual restraint test ("Backtest", after Bolhuis et al., 2003) were weaned and mixed in four pens of four unfamiliar pigs, so that each pen had two HR and two LR pigs, and aggression was scored in the 9h after mixing. In the delay discounting task, each pig chose between two levers, one always delivering a small immediate reward, the other a large delayed reward with daily increasing delays, impulsive individuals being the ones discounting the value of the large reward quicker. Two novel strategies emerged: some pigs gradually switched their preference towards the small reward ('Switchers') as predicted, but others persistently preferred the large reward until they stopped making choices ('Omitters'). Outcome impulsivity itself was unrelated to these strategies, to urinary serotonin metabolite (5-HIAA) or dopamine metabolite (HVA) levels, aggression at weaning, or coping style. However, HVA was relatively higher in Omitters than Switchers, and positively correlated with behavioural measures of indecisiveness and frustration during choosing. The delay discounting task thus revealed two response strategies that seemed to be related to the activity of the dopamine system and might indicate a difference in execution, rather than outcome, impulsivity.

Dopamine receptor 4 promoter polymorphism modulates memory and neuronal responses to salience

Animal models and human functional imaging data implicate the dopamine system in mediating enhanced encoding of novel stimuli into human memory. A separate line of investigation suggests an association between a functional polymorphism in the promoter region for the human dopamine 4 receptor gene (DRD4) and sensitivity to novelty. We demonstrate, in two independent samples, that the -521Cmayor queT DRD4 promoter polymorphism determines the magnitude of human memory enhancement for contextually novel, perceptual oddball stimuli in an allele dose-dependent manner. The genotype-dependent memory enhancement conferred by the C allele is associated with increased neuronal responses during successful encoding of perceptual oddballs in the ventral striatum, an effect which is again allele dose-dependent. Furthermore, with repeated presentations of oddball stimuli, this memory advantage decreases, an effect mirrored by adaptation of activation in the hippocampus and substantia nigra/ventral tegmental area in C carriers only. Thus, a dynamic modulation of human memory enhancement for perceptually salient stimuli is associated with activation of a dopaminergic-hippocampal system, which is critically dependent on a functional polymorphism in the DRD4 promoter region.

Chronic morphine induces visible changes in the morphology of mesolimbic dopamine neurons.

The mesolimbic dopamine system, which arises in the ventral tegmental area (VTA), is an important neural substrate for opiate reinforcement and addiction. Chronic exposure to opiates is known to produce biochemical adaptations in this brain region. We now show that these adaptations are associated with structural changes in VTA dopamine neurons. Individual VTA neurons in paraformaldehyde-fixed brain sections from control or morphine-treated rats were injected with the fluorescent dye Lucifer yellow. The identity of the injected cells as dopaminergic or nondopaminergic was determined by immunohistochemical labeling of the sections for tyrosine hydroxylase. Chronic morphine treatment resulted in a mean approximately 25% reduction in the area and perimeter of VTA dopamine neurons. This reduction in cell size was prevented by concomitant treatment of rats with naltrexone, an opioid receptor antagonist, as well as by intra-VTA infusion of brain-derived neurotrophic factor. In contrast, chronic morphine treatment did not alter the size of nondopaminergic neurons in the VTA, nor did it affect the total number of dopaminergic neurons in this brain region. The results of these studies provide direct evidence for structural alterations in VTA dopamine neurons as a consequence of chronic opiate exposure, which could contribute to changes in mesolimbic dopamine function associated with addiction.

Increased dopamine turnover in the prefrontal cortex impairs spatial working memory performance in rats and monkeys.

The selective activation of the prefrontal cortical dopamine system by mild stress can be mimicked by anxiogenic beta-carbolines such as FG7142. To investigate the functional relevance of elevated levels of dopamine turnover in the prefrontal cortex, the current study examined the effects of FG7142 on the performance of spatial working memory tasks in the rat and monkey. FG7142 selectively increased prefrontal cortical dopamine turnover in rats and significantly impaired performance on spatial working memory tasks in both rats and monkeys. Spatial discrimination, a task with similar motor and motivational demands (rats), or delayed response performance following zero-second delays (monkeys) was unaffected by FG7142. Further, biochemical analysis in rats revealed a significant positive correlation between dopamine turnover in the prefrontal cortex and cognitive impairment on the delayed alternation task. The cognitive deficits in both rats and monkeys were prevented by pretreatment with the benzodiazepine receptor antagonist, RO15-1788, which blocked the increase in dopamine turnover and by the dopamine receptor antagonists, haloperidol, clozapine, and SCH23390. These findings indicate that excessive dopamine activity in the prefrontal cortex is detrimental to cognitive functions mediated by the prefrontal cortex.

Ghrelin receptor (GHS-R1A) antagonism suppresses both operant alcohol self-administration and high alcohol consumption in rats

The mechanisms involved in alcohol use disorders are complex. It has been shown that ghrelin is an important signal for the control of body weight homeostasis, preferably by interacting with hypothalamic circuits, as well as for drug reward by activating the mesolimbic dopamine system. The ghrelin receptor (GHS-R1A) has been shown to be required for alcohol-induced reward. Additionally, ghrelin increases and GHR-R1A antagonists reduce moderate alcohol consumption in mice, and a single nucleotide polymorphism in the GHS-R1A gene has been associated with high alcohol consumption in humans. However, the role of central ghrelin signaling in high alcohol consumption is not known. Therefore, the role of GHS-R1A in operant self-administration of alcohol in rats as well as for high alcohol consumption in Long-Evans rats and in alcohol preferring [Alko alcohol (AA)] rats was studied here. In the present study, the GHS-R1A antagonist, JMV2959, was found to reduce the operant self-administration of alcohol in rats and to decrease high alcohol intake in Long-Evans rats as well as in AA rats. These results suggest that the ghrelin receptor signaling system, specifically GHS-R1A, is required for operant self-administration of alcohol and for high alcohol intake in rats. Therefore, the GHS-R1A may be a therapeutic target for treatment of addictive behaviors, such as alcohol dependence.

Input from the amygdala to the rat nucleus accumbens : its relationship with tyrosine hydroxylase immunoreactivity and identified neurons.

Both tyrosine hydroxylase-positive fibres from the mesolimbic dopamine system and amygdala projection fibres from the basolateral nucleus are known to terminate heavily in the nucleus accumbens. Caudal amygdala fibres travelling dorsally via the stria terminalis project densely to the nucleus accumbens shell, especially in the dopamine rich septal hook. The amygdala has been associated with the recognition of emotionally relevant stimuli while the mesolimbic dopamine system is implicated with reward mechanisms. There is behavioural and electrophysiological evidence that the amygdala input to the nucleus accumbens is modulated by the mesolimbic dopamine input, but it is not known how these pathways interact anatomically within the nucleus accumbens. Using a variety of neuroanatomical techniques including anterograde and retrograde tracing, immunocytochemistry and intracellular filling, we have demonstrated convergence of these inputs on to medium-sized spiny neurons. The terminals of the basolateral amygdala projection make asymmetrical synapses predominantly on the heads of spines which also receive on their necks or adjacent dendrites, symmetrical synaptic input from the mesolimbic dopamine system. Some of these neurons have also been identified as projection neurons, possibly to the ventral pallidum. We have shown a synaptic level how dopamine is positioned to modulate excitatory limbic input in the nucleus accumbens.

Model-based influences on humans' choices and striatal prediction errors.

The mesostriatal dopamine system is prominently implicated in model-free reinforcement learning, with fMRI BOLD signals in ventral striatum notably covarying with model-free prediction errors. However, latent learning and devaluation studies show that behavior also shows hallmarks of model-based planning, and the interaction between model-based and model-free values, prediction errors, and preferences is underexplored. We designed a multistep decision task in which model-based and model-free influences on human choice behavior could be distinguished. By showing that choices reflected both influences we could then test the purity of the ventral striatal BOLD signal as a model-free report. Contrary to expectations, the signal reflected both model-free and model-based predictions in proportions matching those that best explained choice behavior. These results challenge the notion of a separate model-free learner and suggest a more integrated computational architecture for high-level human decision-making.

大麻受体CB1及CB2在慢性吗啡成瘾大鼠中枢神经系统与免疫系统的分布和表达

吗啡是临床常用的镇痛药物之一，通过模拟内源性抗痛物质脑啡肽的作用，激活中枢神经阿片受体而产生强大的镇痛作用。吗啡属于阿片类生物碱，为阿片受体激动剂，是目前我国主要的毒品成瘾类型之一，对人民生命健康危害极大。目前我国登记在册的吗啡成瘾者约有100万，每年导致的直接经济损失超过1000亿元。因此吗啡成瘾机制的研究以及治疗，是目前神经疾病的研究重点之一。 吗啡成瘾与其结合的受体有关。吗啡除结合阿片受体外，也可能结合大麻素受体，现发现体内有两种大麻素受体的存在：CB1受体和CB2受体。大麻CB1、CB2受体都是G蛋白耦联受体。其中CB1受体主要位于脑、脊髓与外周神经系统中，脑内CB1受体主要分布于基底神经节（黑质、苍白球、外侧纹状体）、海马CA锥体细胞层，小脑和大脑皮层。因此推测大麻CB1受体的功能可能与成瘾、记忆、认知、运动控制的调节有关。而大麻CB2受体主要分布于外周组织，如脾脏边缘区、扁桃体等，它的这种分布可能与免疫抑制作用有关。近来的研究发现大麻CB2受体在中枢神经系统也有分布，目前对其在此分布的功能不明确，推测可能与成瘾、抑郁症等神经类疾病有密切关系。 在药物成瘾导致的精神依赖作用中，奖赏效应是各种药物成瘾的药理学基础。中脑—边缘系统（(mesolimbic dopamine system,MLDS)是药物奖赏效应的神经解剖学基础。目前认为内源性大麻素所起的药理作用与多巴胺能和阿片能的神经传递有密切的关系。因此推断大麻素CB1受体与慢性吗啡成瘾有密切关系，至少是部分参与到慢性吗啡成瘾过程中。 相较于较多的关于大麻CB1受体的研究，有关大麻CB2受体的研究很少。尽管近来证实大麻CB2受体也分布于中枢神经系统，但在慢性吗啡成瘾时，大麻CB2受体表达的改变仍不清楚。在本项目中，我们将对慢性吗啡成瘾动物通过分子生物学、蛋白质化学、免疫组织化学的方法，探讨大麻CB2受体在中枢神经系统的分布和表达，以及大麻CB2受体在吗啡成瘾中可能的作用。 吗啡对免疫系统有抑制作用, 包括抑制淋巴细胞增殖, 减少细胞因子的分泌，减弱自然杀伤细胞（NKC）的细胞毒作用。现已证实激活周围神经系统的CB2受体可诱导IL-4的生成，从而影响阿片μ型受体的转录。此发现提供了内源性大麻系统-阿片系统-免疫系统之间存在相互作用的关系。然而，吗啡吸食是否通过CB2受体从而导致免疫功能的抑制，现在还没有直接证据，在本实验中我们将探讨CB2受体与吗啡成瘾导致免疫功能的改变有关。 实验结果显示（1）应用RT-PCR法，检测到大麻素受体CB1在慢性吗啡成瘾大鼠的皮质和海马处mRNA表达水平与对照组大鼠有明显不同。（2）应用western免疫印迹法，检测到大麻素受体CB1在慢性吗啡成瘾大鼠的皮质，海马和脑干处蛋白表达水平与对照组大鼠有明显不同。在脑干处，虽然mRNA表达水平无变化，但蛋白质的表达水平上升。（3）应用免疫组化检测到大麻素受体CB1在大鼠的皮质，海马，脑干，小脑处都广泛分布。（4）应用RT-PCR法，检测到大麻素受体CB2在慢性吗啡成瘾大鼠的皮质，海马，脑干处mRNA表达水平与对照组大鼠有明显不同。（5）应用western免疫印迹法，检测到大麻素受体CB2在慢性吗啡成瘾大鼠的皮质，海马，脑干蛋白表达水平与对照组大鼠有明显不同。且蛋白质的表达改变趋势与mRNA表达水平的改变相似。（6）应用免疫组化法检测到大麻素受体CB2在大鼠的皮质，海马，脑干，小脑处都广泛分布。但数量明显少于大麻CB1受体。（7）应用直接ELISA法，检测到慢性吗啡成瘾大鼠的血清与对照组大鼠的血清比较，IgM表达下降；IgG表达上升。 实验结果提示大麻受体CB1和CB2 很可能在慢性吗啡成瘾过程起着重要的作用，至少是部分参与到慢性吗啡成瘾的过程中。因为大麻素受体CB1和CB2都属于G 蛋白耦连受体，长期持续使用吗啡，其表达的变化可能会导致cAMP信号通路的上调；提高了腺苷酸环化酶(AC)和蛋白激酶A(PKA)的活性从而激活下游相关基因的表达最终导致成瘾。此外大麻素受体CB1和CB2表达的变化可能与慢性吗啡成瘾后免疫功能的改变有相关性。 通过以上的的实验结果，可以得到以下的结论：（1）我们验证了大麻素受体CB1在慢性吗啡成瘾大鼠的皮质，海马和脑干处mRNA和蛋白质表达水平与对照组大鼠有明显不同，且大麻CB1受体在大鼠中枢神经系统中广泛大量分布，表明大麻素受体CB1很可能在慢性吗啡成瘾过程中起着重要的作用，至少部分参与到慢性吗啡成瘾的过程中。（2）我们第一次证实了大麻素受体CB2在吗啡成瘾大鼠的皮质，海马和脑干处mRNA和蛋白质表达水平与对照组大鼠有明显不同，且大麻CB2受体在大鼠中枢神经系统中少量广泛分布。表明大麻素受体CB2很可能在慢性吗啡成瘾过程中起着重要的作用，至少部分参与到慢性吗啡成瘾的过程中。（3）同时我们发现大麻素受体CB1和CB2在大鼠脑组织中广泛表达，表明内源性大麻系统有可能广泛的参与各种神经疾病，很可能成为治疗的新靶点。（4）最后我们发现慢性吗啡成瘾大鼠血液中IgM表达下降；IgG表达上升，表明慢性吗啡成瘾对机体的免疫功能有广泛的调节作用。慢性吗啡成瘾大鼠血清CB2受体mRNA表达上升。我们证实了大麻受体CB2可能正是把神经系统和免疫系统相联系的一个靶点。

阿片药物依赖的神经机制---内侧前额叶与药物的心理依赖

Mental dependence, characterized by craving and impulsive seeking behavior, is the matter of intensive study in the field of drug addiction. The mesolimbic dopamine system has been suggested to play an important role in rewarding of drugs and relapse. Although chronic drug use can induce neuroadaptations of the mesolimbic system and changes of drug reinforcement, these mechanisms cannot fully account for the craving and the compulsive drug-using behavior of addicts. Acknowledging the reinforcement effects of drugs, most previous studies have studied the impact of environmental cues and conditioned learning on addiction behavior, often using established classical or operant conditioning model. These studies, however, paid little attention to the role of cognitive control and emotion in addiction. These mental factors that are believed to have an important influence on conditioned learning. The medial prefrontal cortex (mPFC) has close anatomic and functional connections with the mesolimbic dopamine system. A number of the cognitive neurological studies demonstrate that mPFC is involved in motivation, emotional regulation, monitoring of responses and other executive functions. Thus we speculated that the function of abnormality in mPFC following chronic drug use would cause related to the abnormal behavior in addicts including impulse and emotional changes. In the present study of a series of experiments, we used functional magnetic resonance imaging to examine the hemodynamic response of the mPFC and related circuits to various cognitive and emotional stimuli in heroin addicts and to explore the underlying dopamine neuromechnism by microinjection of tool drugs into the mPFC in laboratory animals. In the first experiment, we found that heroin patients, relative to the normal controls, took a much shorter time and committed more errors in completing the more demanding of cognitive regulation in the reverse condition of the task, while the neural activity in anterior cingulate cortex (ACC) was attenuated. In the second experiment, the scores of the heroin patients in self-rating depression scale (SDS) and Self-rating anxiety scale (SAS) were significantly higher than the normal controls and they rated the negative pictures more aversive than the normal controls. Being congruent with the behavioral results, hemodynamic response to negative pictures showed significant difference between the two groups in bilateral ventral mPFC (VMPFC), amygdala, and right thalamus. The VMPFC of patients showed increased activation than normal controls, whereas activation in the amygdala of patients was weaker than that in normal subjects. Our third experiment showed that microinjection of D1 receptor agonist SKF38393 into the mPFC of rats decreased hyperactivity, which was induced by morphine injection, in contrast, D1 receptor antagonist SCH23390 increased the hyperactivity, These findings suggest: (1) The behavior and neural activity in ACC of addicts changed in chronic drug users. Their impulsive behavior might result from the abnormal neural activity in the mPFC especially the ACC. (2) Heroine patients were more depress and anxiety than normal controls. The dysfunction of the mPFC---amygdala circuit of heroine addicts might be related to the abnormal emotion response. (3) Dopamine in the mPFC has an inhibitory effect on morphine induced behavior. The hyperactivity induced by chronic morphine was reduced by dopamine increase with D1 receptor agonist, confirm the first experiment that the neuroadaption of mPFC system induced by chronic morphine administration appears to be the substrate the impulse behavior of drug users.