Abstract
Dopamine transporter knockout (DATk) mice are known to demonstrate profound hyperactivity concurrent with elevated (5-fold) extracellular dopamine in the basal ganglia. At the same time, heterozygous DAT mice (DATh) demonstrate a 2-fold increase in dopamine levels yet only a marginal elevation in locomotor activity level. Another model of dopaminergic hyperactivity is the D3 dopamine receptor knockout (D3k) mice, which present only a modest hyperactivity phenotype, predominately manifested as stereotypical behaviors. In the D3k mice, the hyperactivity is also correlated with elevated extracellular dopamine levels (2-fold) in the basal ganglia. Cross-breeding was used to evaluate the functional consequences of the deletion of both genes. In the heterozygous DAT mice, inactivation of the D3R gene (DATh/D3k) resulted in significant hyperactivity and further elevation of striatal extracellular dopamine above levels observed in respective single mutant mice. The decreased weight of DATk mice was evident regardless of the D3 dopamine receptor genotype. In contrast, measures of thermoregulation revealed that the marked hypothermia of DATk mice (−2 °C) was reversed in double knockout mice. Thus, the extracellular dopamine levels elevated by prolonging uptake could be elevated even further by eliminating the D3 receptor. These data also suggest that the hypothermia observed in DATk mice may be mediated through D3 receptors.
Highlights
The dopamine system is involved in the regulation of many vital physiological functions, including locomotor activity, hormonal status, and thermoregulation [1]
Double knockout mice (DATk/D3 knockout (D3k)) demonstrated excessive grooming and self-injuries, but the lesions were less severe and they were available to analyze weight and temperature parameters but due to excessive skin lesions, they were not used in locomotor and microdialysis studies
In total, 122 animals (15 litters) of both sexes with the following genotypes—wild type (WT) (n = 22), DATh (n = 8), dopamine transporter (DAT) knockout (DATk) (n = 26), D3h (n = 20), D3k (n = 8), DATh/D3h (n = 11), DATk/D3h (n = 19), and DATk/D3k (n = 8)—were used in this study
Summary
The dopamine system is involved in the regulation of many vital physiological functions, including locomotor activity, hormonal status, and thermoregulation [1]. Extracellular dopamine levels in the basal ganglia can be regulated by several mechanisms. Lack of DAT in knockout animals results in remarkable changes in behavior, physiology, and neurochemistry [2,3]. DAT knockout (DATk) mice and rats have a 5–7 fold elevated level of striatal extracellular dopamine, with about 15–20-fold decreased level of total tissue content of dopamine [2,3,4]. DATk mice show dramatically increased locomotor activity in a novel environment that can be attenuated by the administration of amphetamine [5]. DATk mice show decreased bodyweight that manifested in adult animals [2,6]. It was shown that DATk animals have a lower body temperature during the daytime [7]
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