New roles for dopamine D2 and D3 receptors in pancreatic beta cell insulin secretion.

Although long-studied in the central nervous system, there is increasing evidence that dopamine (DA) has important roles in the periphery including in metabolic regulation. Insulin-secreting pancreatic ß-cells express the machinery for DA synthesis and catabolism, as well as all five DA receptors. In these cells, DA functions as a negative regulator of glucose-stimulated insulin secretion (GSIS), which is mediated by DA D2-like receptors including D2 (D2R) and D3 (D3R) receptors. However, the fundamental mechanisms of DA synthesis, storage, release, and signaling in pancreatic ß-cells and their functional relevance in vivo remain poorly understood. Here, we assessed the roles of the DA precursor L-DOPA in ß-cell DA synthesis and release in conjunction with the signaling mechanisms underlying DA's inhibition of GSIS. Our results show that the uptake of L-DOPA is essential for establishing intracellular DA stores in ß-cells. Glucose stimulation significantly enhances L-DOPA uptake, leading to increased DA release and GSIS reduction in an autocrine/paracrine manner. Furthermore, D2R and D3R act in combination to mediate dopaminergic inhibition of GSIS. Transgenic knockout mice in which ß-cell D2R or D3R expression is eliminated exhibit diminished DA secretion during glucose stimulation, suggesting a new mechanism where D2-like receptors modify DA release to modulate GSIS. Lastly, ß-cell-selective D2R knockout mice exhibit marked postprandial hyperinsulinemia in vivo. These results reveal that peripheral D2R and D3R receptors play important roles in metabolism through their inhibitory effects on GSIS. This opens the possibility that blockade of peripheral D2-like receptors by drugs including antipsychotic medications may significantly contribute to the metabolic disturbances observed clinically.

The roles of class I histone deacetylases (HDACs) in memory, learning, and executive cognitive functions: A review.

Coordinated changes in gene expression are critical for synaptic plasticity supporting learning, memory, and optimal cognitive task performance. These gene expression changes are not only mediated by signaling pathways that activate transcription factors, but also by chromatin modifications that influence the accessibility of the transcriptional machinery to specific genomic regions. During the past decade, evidence accumulated that alterations in chromatin-based epigenetic regulation of gene expression are linked to cognitive dysfunctions in the ageing or neurodegenerating brain as well as to cognitive dysfunctions resulting from chronic stress exposure. This review summarizes the results of studies that unraveled a role of histone modifying enzymes and histone modifications in normal and impaired learning and memory, and in the disruption of executive cognitive task performance. It emphasizes the different roles of specific class I histone deacetylases (HDACs) in cognitive processes governed by the hippocampus and prefrontal cortex and discusses the potential therapeutic implications of targeting them to hold the progression of disease-related cognitive dysfunctions.

Cognitive deficits triggered by early life stress: The role of histone deacetylase 1.

Studies showed that histone deacetylase (HDAC) inhibitors can reverse cognitive deficits found in neurodegenerative disorders and age-related memory decline. However, the role of HDACs in stress-induced cognitive deficits has not been investigated. In the stress-susceptible mouse strain Balb/c, early life stress triggers a persistent decrease in HDAC expression in the forebrain neocortex, including reduced expression of class I HDACs. The same mice show pronounced cognitive deficits in adulthood, namely deficits in working memory and attention set-shifting. Here we show that these mice also exhibit reduced association of HDAC1 with promotor III of the brain-derived neurotrophic factor (Bdnf) gene, and that cognitive testing leads to abnormally increased Bdnf mRNA expression. A pharmacological reduction of Bdnf-tropomyosine kinase B receptor signaling effectively reverses the cognitive deficits, indicating that enhanced transcriptional activation of the Bdnf gene contributes to their emergence. In contrast to Balb/c mice, C57Bl/6 mice only develop attention set-shifting deficits when raised by Balb/c foster mothers during the time the pups are exposed to early life stress. HDAC1 levels at Bdnf promotor III are unaltered in such C57Bl/6 mice, although they exhibit decreased levels of HDAC1 at the promotor of the early-growth response gene 2 (Egr2) and abnormally increased Egr2 mRNA expression after cognitive testing. Hence, contrary to the beneficial effects of HDAC inhibition in neurodegenerative diseases, the reduced HDAC1 levels at promotors of distinct plasticity-associated genes predispose animals exposed to early life stress to enhanced expression of these genes upon cognitive challenge, an effect that negatively influences cognitive task performance.

Trans-generational effects of early life stress: the role of maternal behavior.

Using a rodent paradigm of early life stress, infant maternal separation (IMS), we examined whether IMS-triggered behavioral and epigenetic phenotypes of the stress-susceptible mouse strain Balb/c are propagated across generations. These phenotypes include impaired emotional behavior and deficits in executive cognitive functions in adulthood, and they are associated with increased acetylation of histone H4K12 protein (acH4K12) in the forebrain neocortex. These behavioral and epigenetic phenotypes are transmitted to the first progeny of IMS Balb/c mothers, but not fathers, and cross-fostering experiments revealed that this transmission is triggered by maternal behavior and modulated by the genetic background of the pups. In the continued absence of the original stressor, this transmission fades in later progenies. An adolescent treatment that lowers the levels of acH4K12 in IMS Balb/c mice augments their emotional abnormality but abolishes their cognitive deficits. Conversely, a treatment that further elevates the levels of acH4K12 improved the emotional phenotype but had no effects on the cognitive deficits. Moreover, treatments that prevent the emergence of either emotional or cognitive deficits in the mother also prevent the establishment of such deficits in her offspring, indicating that trans-generational effects of early life stress can be prevented.

Cariprazine, a dopamine D(3)-receptor-preferring partial agonist, blocks phencyclidine-induced impairments of working memory, attention set-shifting, and recognition memory in the mouse.

RATIONALE: A major challenge in the pharmacological treatment of psychotic disorders is the effective management of the associated cognitive dysfunctions. Novel concepts emphasize a potential benefit of partial agonists acting upon dopamine D(2)-like receptors in ameliorating these cognitive deficits, and pre-clinical studies suggest that D(3)-receptor-preferring compounds can exert pro-cognitive effects. OBJECTIVE: The objective of the study was to use acute phencyclidine (PCP) treatment to model the cognitive deficits of schizophrenia in mice, and to test the efficacy of the novel, dopamine D(3)-receptor-preferring drug cariprazine in ameliorating the severity of PCP-triggered cognitive deficits. METHODS: One group of wild-type or D(3)-receptor knockout mice was acutely treated with either saline or phencyclidine (PCP, 1 mg/kg). A separate group of mice was treated with cariprazine prior to PCP administration. Both groups were then tested in three cognitive tasks: social interaction/recognition and recognition memory, spatial working memory, and attention-set-shifting. RESULTS: PCP effectively disrupted social recognition and social recognition memory, spatial working memory, and extradimensional attention set-shifting. Cariprazine pretreatment significantly attenuated the emergence of these cognitive deficits in PCP-treated wild-type mice, but not in PCP-treated D(3)-receptor knockout mice. CONCLUSIONS: In an animal model of PCP-induced cognitive impairment, cariprazine pretreatment significantly diminished PCP-triggered cognitive deficits, and studies on knockout mice show that dopamine D(3) receptors contribute to this effect.

Early life stress triggers sustained changes in histone deacetylase expression and histone H4 modifications that alter responsiveness to adolescent antidepressant treatment.

Early life stress can elicit long-lasting changes in gene expression and behavior. Recent studies on rodents suggest that these lasting effects depend on the genetic background. Whether epigenetic factors also play a role remains to be investigated. Here we exposed the stress-susceptible mouse strain Balb/c and the more resilient strain C57Bl/6 to a powerful early life stress paradigm, infant maternal separation. In Balb/c mice, infant maternal separation led to decreased expression of mRNA encoding the histone deacetylases (HDACs) 1, 3, 7, 8, and 10 in the forebrain neocortex in adulthood, an effect accompanied by increased expression of acetylated histone H4 proteins, especially acetylated H4K12 protein. These changes in HDAC expression and histone modifications were not detected in C57Bl/6 mice exposed to early life stress. Moreover, a reversal of the H4K12 hyperacetylation detected in infant maternally separated Balb/c mice (achieved with chronic adolescent treatment with a low dose of theophylline that only activates HDACs) worsened the abnormal emotional phenotype resulting from this early life stress exposure. In contrast, fluoxetine, a drug with potent antidepressant efficacy in infant maternally separated Balb/c mice, potentiated all histone modifications triggered by early life stress. Moreover, in non-stressed Balb/c mice, co-administration of an HDAC inhibitor and fluoxetine, but not fluoxetine alone, elicited antidepressant effects and also triggered changes in histone H4 expression that were similar to those provoked by fluoxetine treatment of mice exposed to early life stress. These results suggest that Balb/c mice develop epigenetic modifications after early life stress exposure that, in terms of the emotive phenotype, are of adaptive nature, and that enhance the efficacy of antidepressant drugs.

Detection of antigen interactions ex vivo by proximity ligation assay: endogenous dopamine D2-adenosine A2A receptor complexes in the striatum.

The existence of G protein-coupled receptor (GPCR) dimers and/or oligomers has been demonstrated in heterologous systems using a variety of biochemical and biophysical assays. While these interactions are the subject of intense research because of their potential role in modulating signaling and altering pharmacology, evidence for the existence of receptor interactions in vivo is still elusive because of a lack of appropriate methods to detect them. Here, we adapted and optimized a proximity ligation assay (PLA) for the detection in brain slices of molecular proximity of two antigens located on either the same or two different GPCRs. Using this approach, we were able to confirm the existence of dopamine D2 and adenosine A2A receptor complexes in the striatum of mice ex vivo.

Strain-specific cognitive deficits in adult mice exposed to early life stress.

Early life stress is a prominent risk factor for the development of adult psychopathology. Numerous studies have shown that early life stress leads to persistent changes in behavioral and endocrine responses to stress. However, despite recent findings of gene expression changes and structural abnormalities in neurons of the forebrain neocortex, little is known about specific cognitive deficits that can result from early life stress. Here we examined five cognitive functions in two inbred strains of mice, the stress-resilient strain C57Bl/6 and the stress-susceptible strain Balb/c, which were exposed to an infant maternal separation paradigm and raised to adulthood. Between postnatal ages P60 to P90, mice underwent a series of tests examining five cognitive functions: Recognition memory, spatial working memory, associative learning, shifts of attentional sets, and reversal learning. None of these functions were impaired in IMS C57Bl/6 mice. In contrast, IMS Balb/c mice exhibited deficits in spatial working memory and extradimensional shifts of attention, that is, functions governed primarily by the medial prefrontal cortex. Thus, like recently discovered changes in frontocortical gene expression, the emergence of specific cognitive deficits associated with the medial prefrontal cortex is also strain-specific. These findings illustrate that early life stress can indeed affect specific cognitive functions in adulthood, and they support the hypothesis that the genetic background and environmental factors are critical determinants in the development of adult cognitive deficits in subjects with a history of early life stress.

The roles of phospholipase C activation and alternative ADAR1 and ADAR2 pre-mRNA splicing in modulating serotonin 2C-receptor editing in vivo.

The serotonin 2C receptor (5-HT2CR), a Gq-protein-coupled neurotransmitter receptor, exists in multiple isoforms that result from RNA editing of five exonic adenosines that are converted to inosines. In the adult brain, editing of 5-HT2C pre-mRNA exhibits remarkable plasticity in response to environmental and neurochemical stimuli. Here, we investigated two potential mechanisms underlying these plastic changes in adult 5-HT2CR editing phenotypes in vivo: activation of phospholipase C (PLC) and alternative splicing of pre-mRNA encoding the editing enzymes ADAR1 and ADAR2. Studies on two inbred strains of mice (C57Bl/6 and Balb/c) revealed that sustained stimulation of PLC--a downstream effector of activated G alpha q protein--increased editing of forebrain neocortical 5-HT2C pre-mRNA at two sites known to be targeted by ADAR2. Moreover, changes in relative expression of the alternatively spliced "a" and "b" mRNA isoforms of ADAR1 and ADAR2 also correlate with changes in 5-HT2CR editing. The site-specific changes in 5-HT2CR editing detected in mice with different "a" over "b" ADAR mRNA isoform ratios only partially overlap with those evoked by sustained PLC activation and are best explained by the increased editing efficiency of ADAR1. Thus, activation of PLC and alternative splicing of ADAR pre-mRNA have both overlapping and specific roles in modulating 5-HT2CR editing phenotypes.

Expression of glucocorticoid receptor and early growth response gene 1 during postnatal development of two inbred strains of mice exposed to early life stress.

Early life stress can elicit profound changes in adult gene expression and behavior. One consequence of early life stress is a decreased expression of glucocorticoid receptors (GRs) in the frontal cortex and hippocampus. However, neither the time of onset nor the mechanism(s) leading to decreased GR expression during postnatal development are known. The present study used two inbred strains of mice that differ in their behavioral responsiveness to stress (Balb/c and C57Bl/6), exposed them to an established paradigm of early life stress (infant maternal separation), and measured their expression of frontal cortical and hippocampal GRs and the putative transcriptional activator of the GR gene, early growth response gene (egr)-1, at defined stages of postnatal development. In both strains, real-time RT-PCR experiments revealed that decreased expression of GR in adolescence and adulthood is, in fact, preceded by increased GR expression during early life stress exposure. Thus, the early life stress-induced disruption of the normal stress-hyporesponsive period during infancy is accompanied by increased GR expression. Moreover, chronic treatment with the antidepressant drug fluoxetine during adolescence or adulthood reversed the effect of early life stress on adult GR mRNA expression. In contrast to the strain-independent effect of early life stress on GR expression, however, changes in egr-1 expression occurred only in Balb/c mice, and unlike the biphasic developmental changes in GR mRNA expression, egr-1 mRNA was decreased throughout postnatal development. Moreover, there was no consistent overlap of anatomic regions affected by decreased GR and egr-1 protein expression. Thus, in Balb/c mice, changes in GR and egr-1 expression can independently contribute to the phenotypes resulting from early life stress exposure. These findings illustrate that the impact of early life stress on gene expression changes is modulated by the genetic background and that the persistent changes in GR and egr-1 expression that arise early during postnatal developmental are reversible by chronic fluoxetine treatment during adolescence and adulthood.

Antidepressant drug-induced stimulation of mouse hippocampal neurogenesis is age-dependent and altered by early life stress.

The continuous generation of new neurons in the adult hippocampus exhibits remarkable plasticity. Decreased neurogenesis is thought to underlie depression-like behaviors, and increased neurogenesis is thought to occur following antidepressant drug treatment. Studies on different strains of mice, however, yielded contrasting results with regard to the link between behavioral modifications induced by antidepressant drugs or environmental enrichment and changes in adult hippocampal neurogenesis. Therefore, we conducted a comparative study on the inbred strains Balb/c and C57Bl/6 that differ substantially in emotionality, stress reactivity, and behavioral responses to chronic antidepressant drugs. Quantitative assessments of progenitor cell proliferation and immature neuronal differentiation in the dentate gyrus revealed that, despite significantly different basal proliferation rates between both strains, neither strain exhibited changes in adult neurogenesis after exposure to early life stress or adult chronic fluoxetine treatment. A stimulatory effect of fluoxetine on adult hippocampal neurogenesis was only detected when treatment was initiated during adolescence, and this effect was abolished in mice exposed to early life stress, a prominent risk factor for developing adult-onset depression-like behaviors. Thus, in both strains of mice neither adult fluoxetine treatment nor adolescent fluoxetine treatment following early life stress exposure increased the proliferation and early differentiation of adult neural progenitor cells.

Early life stress alters adult serotonin 2C receptor pre-mRNA editing and expression of the alpha subunit of the heterotrimeric G-protein G q.

Infant maternal separation, a paradigm of early life stress in rodents, elicits long-lasting changes in gene expression that persist into adulthood. In BALB/c mice, an inbred strain with spontaneously elevated anxiety and stress reactivity, infant maternal separation led to increased depression-like behavioral responses to adult stress and robustly increased editing of serotonin 2C receptor pre-mRNA. Chronic fluoxetine treatment of adult BALB/c mice exposed to early life stress affected neither their behavioral responses to stress nor their basal 5-HT2C pre-mRNA editing phenotype. However, when fluoxetine was administered during adolescence, depression-like behavioral responses to stress were significantly diminished in these mice, and their basal and stress-induced 5-HT2C pre-mRNA editing phenotypes were significantly lower. Moreover, when BALB/c mice exposed to early life stress were raised in an enriched postweaning environment, their depression-like behavioral responses to adult stress were also significantly diminished. However, their 5-HT2C pre-mRNA editing phenotype remained unaltered. Hence, the similar behavioral effects of enrichment and fluoxetine treatment during adolescence were not accompanied by similar changes in 5-HT2C pre-mRNA editing. Enriched and nonenriched BALB/c mice exposed to early life stress also exhibited significantly increased expression of mRNA and protein encoding the G alpha q subunit of G-protein that couples to 5-HT2A/2C receptors. In contrast, G alpha q expression levels were significantly lower in fluoxetine-treated mice. These findings suggest that compensatory changes in G alpha q expression occur in mice with persistently altered 5-HT2C pre-mRNA editing and provide an explanation for the dissociation between 5-HT2C receptor editing phenotypes and behavioral stress responses.

Distinct roles of presynaptic dopamine receptors in the differential modulation of the intrinsic synapses of medium-spiny neurons in the nucleus accumbens.

BACKGROUND: In both schizophrenia and addiction, pathological changes in dopamine release appear to induce alterations in the circuitry of the nucleus accumbens that affect coordinated thought and motivation. Dopamine acts principally on medium-spiny GABA neurons, which comprise 95% of accumbens neurons and give rise to the majority of inhibitory synapses in the nucleus. To examine dopamine action at single medium-spiny neuron synapses, we imaged Ca2+ levels in their presynaptic varicosities in the acute brain slice using two-photon microscopy. RESULTS: Presynaptic Ca2+ rises were differentially modulated by dopamine. The D1/D5 selective agonist SKF81297 was exclusively facilitatory. The D2/D3 selective agonist quinpirole was predominantly inhibitory, but in some instances it was facilitatory. Studies using D2 and D3 receptor knockout mice revealed that quinpirole inhibition was either D2 or D3 receptor-mediated, while facilitation was mainly D3 receptor-mediated. Subsets of varicosities responded to both D1 and D2 agonists, showing that there was significant co-expression of these receptor families in single medium-spiny neurons. Neighboring presynaptic varicosities showed strikingly heterogeneous responses to DA agonists, suggesting that DA receptors may be differentially trafficked to individual varicosities on the same medium-spiny neuron axon. CONCLUSION: Dopamine receptors are present on the presynaptic varicosities of medium-spiny neurons, where they potently control GABAergic synaptic transmission. While there is significant coexpression of D1 and D2 family dopamine receptors in individual neurons, at the subcellular level, these receptors appear to be heterogeneously distributed, potentially explaining the considerable controversy regarding dopamine action in the striatum, and in particular the degree of dopamine receptor segregation on these neurons. Assuming that post-receptor signaling is restricted to the microdomains of medium-spiny neuron varicosities, the heterogeneous distribution of dopamine receptors on individual varicosities is likely to encode patterns in striatal information processing.

Physiological modulation of intestinal motility by enteric dopaminergic neurons and the D2 receptor: analysis of dopamine receptor expression, location, development, and function in wild-type and knock-out mice.

Dopaminergic neurons are present in both plexuses of the murine bowel and are upregulated after extrinsic denervation but play unknown roles in enteric nervous system (ENS) physiology. Transcripts encoding dopamine (DA) receptors D1-D5 were analyzed by reverse transcription-PCR in stomach approximately duodenum approximately ileum approximately proximal > > distal colon. Dissected muscle and myenteric plexus contained transcripts encoding D1-D3 and D5, whereas mucosa contained D1 and D3-D5. D1-D5 expression began in fetal gut [embryonic day 10 (E10)], before the appearance of neurons (E12), and was sustained without developmental regulation through postnatal day 1. In situ hybridization revealed that subsets of submucosal and myenteric neurons contained mRNA encoding D2 or D3. Immunoblots confirmed that D1, D2, and D5 receptor proteins were present from stomach through distal colon. Subsets of submucosal and myenteric neurons were also D1, D2, or D3 immunoreactive. When double labeled by in situ hybridization, these neurons contained mRNA encoding the respective receptors. Total gastrointestinal transit time (TGTT) and colonic transit time (CTT) were measured in mice lacking D2, D3, or D2 plus D3. Both TGTT and CTT were decreased significantly (motility increased) in D2 and D2 plus D3, but not D3, knock-out animals. Mice lacking D2 and D2 plus D3 but not D3 were smaller than wild-type littermates, yet ate significantly more and had greater stool frequency, water content, and mass. Because motility is abnormal when D2 is absent, the net inhibitory DA effect on motility is physiologically significant. The early expression of DA receptors is also consistent with the possibility that DA affects ENS development.

How stress and fluoxetine modulate serotonin 2C receptor pre-mRNA editing.

In two inbred strains of mice, C57BL/6 and 129Sv, the majority of forebrain neocortical pre-mRNA encoding the serotonin 2C (5-HT2C) receptor is altered by adenosine-to-inosine editing. As a result, >60% of all mRNAs encode receptors with reduced constitutive and agonist-stimulated activity. However, in the BALB/c strain, a genetically distinct inbred strain with lower forebrain serotonin levels, spontaneously elevated anxiety, and increased stress reactivity, the majority of 5-HT2C mRNA is nonedited and encodes receptors with the highest constitutive activity and the highest agonist affinity and potency. Neither acute stress (the forced swim test) nor chronic treatment with the serotonin-selective reuptake inhibitor fluoxetine elicit significant changes in 5-HT2C pre-mRNA editing in C57BL/6 mice. In contrast, exposure of BALB/c mice to acute stress and chronic treatment of nonstressed BALB/c mice with fluoxetine elicit significant, site-specific increases in 5-HT2C pre-mRNA editing that increase the pool of mRNA encoding receptors with reduced function. These changes in 5-HT2C pre-mRNA editing resemble those detected previously in the prefrontal cortex of subjects with major depression. However, when chronic fluoxetine treatment is combined with stress exposure of BALB/c mice, these changes in 5-HT2C pre-mRNA editing are no longer detected. These findings illustrate that 5-HT2C pre-mRNA editing responses to stress and chronic fluoxetine are modulated by the genetic background, as well as the behavioral state of the animal. They suggest further that the changes in 5-HT2C pre-mRNA editing found in major depression reflect a previously unrecognized molecular response to stress that can be prevented by chronic antidepressant treatment.

Mice lacking dopamine D2 and D3 receptors exhibit differential activation of prefrontal cortical neurons during tasks requiring attention.

Mice lacking dopamine D2 and D3 receptors and wildtype littermates were tested in a two-choice perceptual discrimination test that is dependent upon optimal functioning of the prefrontal cortex. Both mutants showed no deficits in attending to the perceptual stimuli or in shifting attention between stimulus dimensions. However, the performance of both mutants differed from the wildtype in different test phases. D2 mutants exhibited significant impairment in the first compound discrimination, indicating deficits in the initial acquisition of the task-governing rules. In contrast, D3 mutants performed significantly better in a set-shifting phase that required reversal learning. The higher response accuracy of D3 mutants was also accompanied by significantly increased response latency. A stereological assessment of test-induced expression of the c-fos gene in neurons of the anterior cingulate and prelimbic/infralimbic cortices revealed highest activation in D3 mutants, intermediate activation in wildtype and lowest activation in D2 mutants, indicating that response accuracy in the cognitive test correlates with the magnitude of prefrontal cortical activation regardless of which test phases revealed different performances. The study illustrates that dopamine differentially modulates prefrontal cortical activity during tasks requiring attention depending upon the type of D2-like receptor that is activated.

Effect of methamphetamine on cognition and repetitive motor behavior of mice deficient for dopamine D2 and D3 receptors.

Mice deficient for dopamine D2 and D3 receptors exhibit blunted D(1)-receptor responses to agonist stimulation. This blunted D1-receptor activity is prominent in the medial prefrontal cortex (mPFC) and results in a significantly impaired performance of the mutants in a test for spatial working memory. A single dose of methamphetamine (METH; 5 mg/kg i.p.), however, elicits a long-lasting increase in agonist-stimulated D1 receptor activity in the mPFC. In D2 mutants, this increase reaches wild-type levels, and the working memory of METH-treated mutants is completely rescued. In D3 mutants, however, the METH-induced increase in D1-receptor activity remains below wild-type levels and does not result in improved working memory performance. D2 and D3 mutants also differ in their locomotor responses to METH. Repeated administration of this drug (5 mg/kg administered three times at 2-h intervals) leads to a transition from horizontal hyperlocomotion to excessive orofacial stereotypy (taffy pulling) only in wild type and D3 mutants. In both genotypes, this transition is accompanied by a change in the relative ratios of striatal neuronal activation in two neurochemically distinct compartments, with striosomal neuronal activation exceeding that of the striatal matrix during stereotypy. Both the stereotypic response to METH and the associated predominant activation of neurons located in striosomes require D2-receptor expression. These studies indicate a differential requirement for D1- and D2-like receptor activation in mediating the effects of METH on cognitive and motor function.

Regulation of dopamine D-receptor activation in vivo by protein phosphatase 2B (calcineurin).

Mice lacking dopamine D2 receptors exhibit a significantly decreased agonist-promoted forebrain neocortical D1 receptor activation that occurs without changes in D1 receptor expression levels. This raises the possibility that, in brains of D2 mutants, a substantial portion of D1 receptors are uncoupled from their G protein, a phenomenon known as receptor desensitization. To test this, we examined D1-agonist-stimulated [35S]GTPgammaS binding (in the presence and absence of protein phosphatase inhibitors) and cAMP production (in the presence and absence of pertussis toxin) in forebrain neocortical tissues of wild-type mice and D2-receptor mutants. These studies revealed a decreased agonist-stimulated G-protein activation in D2 mutants. Moreover, whereas protein phosphatase 1/2A (PP1/2A) and 2B (PP2B) inhibitors decrease [35S]GTPgammaS binding in a concentration-dependent manner in wild type, they have either no (PP2B) or only partial (PP1/2A) effects in D2 mutants. Furthermore, for D2 mutants, immunoprecipitation experiments revealed increased basal and D1-agonist-stimulated phosphorylation of D1-receptor proteins at serine residues. Finally, D1 immunoprecipitates of both wild type and D2 mutants also contain protein kinase A (PKA) and PP2B immunoreactivities. In D2 mutants, however, the catalytic activity of the immunoprecipitated PP2B is abolished. These data indicate that neocortical D1 receptors are physically linked to PKA and PP2B and that the increased phosphorylation of D1 receptors in brains of D2 mutants is due to defective dephosphorylation of the receptor rather than increased kinase-mediated phosphorylation.

Heterosynaptic dopamine neurotransmission selects sets of corticostriatal terminals.

Dopamine input to the striatum is required for voluntary motor movement, behavioral reinforcement, and responses to drugs of abuse. It is speculated that these functions are dependent on either excitatory or inhibitory modulation of corticostriatal synapses onto medium spiny neurons (MSNs). While dopamine modulates MSN excitability, a direct presynaptic effect on the corticostriatal input has not been clearly demonstrated. We combined optical monitoring of synaptic vesicle exocytosis from motor area corticostriatal afferents and electrochemical recordings of striatal dopamine release to directly measure effects of dopamine at the level of individual presynaptic terminals. Dopamine released by either electrical stimulation or amphetamine acted via D2 receptors to inhibit the activity of subsets of corticostriatal terminals. Optical and electrophysiological data suggest that heterosynaptic inhibition was enhanced by higher frequency stimulation and was selective for the least active terminals. Thus, dopamine, by filtering less active inputs, appears to reinforce specific sets of corticostriatal synaptic connections.