Dopamine Transporter Mice Research Articles

Development of hyperactivity and anxiety responses in dopamine transporter-deficient mice

Dopamine (DA) is a catecholamine neurotransmitter that regulates many aspects of motivated behavior in animals. Extracellular DA is highly regulated by the presynaptic high-affinity dopamine transporter (DAT), and drug- or genetically induced deficiencies in DAT function result in loss of DA reuptake. Mice in which DAT expression has been ablated have been previously proposed to be a relevant model of attention deficit hyperactivity disorder and have led to mechanistic insights regarding psychostimulant drug actions. However, very little previous work has emphasized the biobehavioral development of DAT-deficient mice. We therefore examined motoric, emotional and cognitive phenotypes in preadolescent (P22-26) DAT mutant mice. Consistent with previous reports in adult DAT(-/-) mice, we observed a hyperlocomotive phenotype in preadolescent mice across multiple assays. Somewhat surprisingly, spatial working memory in a Y-maze appeared intact, suggesting that cognitive phenotypes may emerge relatively late in development following hyperdopaminergia. Anxiety levels appeared to be reduced in DAT(-/-) mice, as defined by elevated plus maze and light-dark preference assays. No significant differences were observed between wild-type and heterozygous mice, suggesting a minimal impact of DAT haploinsufficiency on neurobehavioral status. Taken together, these data for the first time establish behavioral phenotypes of DAT mutant mice during development and suggest complex developmental stage-dependent effects of DA signaling on cognitive and emotional behaviors.

Sex differences in striatal dopaminergic function within heterozygous mutant dopamine transporter knock-out mice

The issue of whether a deletion of the dopamine transporter (DAT) allele (+/- DAT) would differentially alter striatal dopamine (DA) and dihydroxyphenylacetic acid (DOPAC) concentrations and DA release upon potassium and methamphetamine (MA) stimulation between male and female mice was examined. Striatal DA and DOPAC concentrations of female +/- DAT mice were significantly decreased as compared with wild type (+/+) controls and male +/- DAT mice. No such changes were obtained from the olfactory tubercle suggesting that these effects might be specific for the striatum. Potassium-stimulated DA was increased in male and female +/- DAT mice and maximally stimulated DA was obtained from +/- DAT females, although these mice showed the lowest DA concentrations. MA-evoked DA was increased in male and female +/- mice. While MA-evoked DA was significantly increased in +/+ males versus +/+ females, the +/- females showed the highest DA responses, thereby showing a reversal in the results seen in wild-type conditions. These findings indicate: (1) that a deficiency in the DAT interacts with the sex of the subject, (2)+/- DAT females show more extreme changes in dopaminergic responses, and (3) the importance for considering such variables such as sex when examining differences among knock-out conditions.

MDMA "ecstasy" alters hyperactive and perseverative behaviors in dopamine transporter knockout mice.

Mice lacking the gene for the dopamine transporter (DAT) show a unique behavioral phenotype characterized by locomotor hyperactivity and repetitive circling in a novel environment. The hyperactivity of DAT (-/-) mice can be attenuated by psychostimulants and by serotonin uptake inhibitors, suggesting an important role for serotonin in the attenuation of locomotor hyperactivity in these mice. These studies characterized the effects of 3,4-methylenedioxy-N-methylamphetamine (MDMA), a serotonin releaser, on the amount and patterns of locomotor activity in DAT (+/+) and (-/-) mice. We compared the locomotor patterns produced by MDMA to those observed in DAT (-/-) mice, and examined whether MDMA altered the hyperactivity and perseverative locomotor patterns in DAT (-/-) mice. The effects of MDMA (10, 30 mg/kg) on locomotor activity in DAT (+/+) mice were measured for 90 min in a video tracker system to determine the optimal dose for subsequent studies in DAT (+/+) and (-/-) mice. The effects of 20 mg/kg MDMA on patterns of locomotor activity in DAT (+/+) and (-/-) mice were measured for 90 min. In DAT (+/+) mice, MDMA increased locomotor activity and induced repetitive straight movement patterns. In DAT (-/-) mice, however, MDMA (20 mg/kg) attenuated the characteristic locomotor hyperactivity seen in these mice. In contrast, MDMA potentiated the thigmotaxis and decreased entropy observed in the DAT (-/-) mice. The effects of MDMA observed here demonstrate that the different aspects of the abnormal locomotor behavior exhibited by DAT (-/-) mice can be independently manipulated by pharmacological treatments.

Prepulse Inhibition Deficits and Perseverative Motor Patterns in Dopamine Transporter Knock-Out Mice: Differential Effects of D1 and D2 Receptor Antagonists

Dopamine is known to regulate several behavioral phenomena, including sensorimotor gating and aspects of motor activity. The roles of dopamine D1 and D2 receptors in these behaviors have been documented in the rat literature, but few reports exist on their role in mice. We used dopamine transporter (DAT) (-/-) mice to examine the behavioral consequences of a chronically hyperdopaminergic state, challenging them with the preferential dopamine D2 receptor antagonist raclopride and D1 receptor antagonist SCH23390. At baseline, DAT (-/-) mice exhibited deficient sensorimotor gating as measured by prepulse inhibition (PPI) of the startle response, exhibited nonfocal preservative patterns of locomotion, and were hyperactive in a novel environment. Pretreatment with raclopride significantly increased PPI in the DAT (-/-) mice, whereas SCH23390 had no significant effect. Blockade of D2 receptors did not affect the predominantly straight patterns of motor behavior produced by the DAT (-/-) mice, but antagonism of D1 receptors significantly attenuated the preservative patterns, producing more of a meandering behavior seen in the DAT (+/+) control mice. Both D1 and D2 receptor antagonists decreased the hyperactivity seen in the DAT (-/-) mice. These findings support the role of the D2, but not the D1, receptor in the modulation of PPI in mice. Furthermore, D1 receptor activation appears to be the critical substrate for the expression of preservative patterns of motor behavior, whereas both D1 and D2 receptors appear to regulate the amount of motor activity.