D2 dopamine receptor internalization prolongs the decrease of radioligand binding after amphetamine: A PET study in a receptor internalization-deficient mouse model

Dopamine released by amphetamine decreases the in vivo binding of PET radioligands to the dopamine D2 receptor. Although concentrations of extracellular dopamine largely return to baseline within 1 to 2 h after amphetamine treatment, radioligand binding remains decreased for several hours. The purpo...

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Bibliographic Details
Published in:NeuroImage (Orlando, Fla.) Fla.), 2010-05, Vol.50 (4), p.1402-1407
Main Authors: Skinbjerg, Mette, Liow, Jeih-San, Seneca, Nicholas, Hong, Jinsoo, Lu, Shuiyu, Thorsell, Annika, Heilig, Markus, Pike, Victor W., Halldin, Christer, Sibley, David R., Innis, Robert B.
Format: Article
Language:English
Subjects:
[11C]MNPA
[18F]fallypride
Amphetamine - pharmacology
Animals
Arrestin3
Arrestins - deficiency
Arrestins - genetics
Arrestins - metabolism
Brain - diagnostic imaging
Brain - drug effects
Brain - metabolism
Carbon Radioisotopes - metabolism
Cell Membrane - diagnostic imaging
Cell Membrane - drug effects
Cell Membrane - metabolism
Cerebellum - diagnostic imaging
Cerebellum - drug effects
Cerebellum - metabolism
Corpus Striatum - diagnostic imaging
Corpus Striatum - drug effects
Corpus Striatum - metabolism
D2 receptor
Dopamine
Dopamine Agents - pharmacology
Female
Fluorine Radioisotopes - metabolism
Internalization
Male
Medicin och hälsovetenskap
Mice
Mice, Knockout
Naproxen - pharmacokinetics
PET
Positron-Emission Tomography
Radiopharmaceuticals - metabolism
Receptors, Dopamine D2 - metabolism
Time Factors
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Summary:Dopamine released by amphetamine decreases the in vivo binding of PET radioligands to the dopamine D2 receptor. Although concentrations of extracellular dopamine largely return to baseline within 1 to 2 h after amphetamine treatment, radioligand binding remains decreased for several hours. The purpose of this study was to determine whether the prolonged decrease of radioligand binding after amphetamine administration is caused by receptor internalization. To distinguish dopamine displacement from receptor internalization, we used wild-type and arrestin3 (arr3) knockout mice, which are incapable of internalizing D2 receptors. In addition, we used both the D2 selective agonist [11C]MNPA (which is thought to bind to the high affinity state of the receptor) and the D2 selective antagonist [18F]fallypride (which does not differentiate between high and low affinity state). After an initial baseline scan, animals were divided in three groups for a second scan: either 30 min or 4 h after amphetamine administration (3 mg/kg, i.p.) or as retest. At 30 min, [11C]MNPA showed greater displacement than [18F]fallypride, but each radioligand gave similar displacement in knockout and wild-type mice. At 4 h, the binding of both radioligands returned to baseline in arr3 knockout mice, but remained decreased in wild-type mice. Radioligand binding was unaltered on retest scanning. Our results suggest that the prolonged decrease of radioligand binding after amphetamine is mainly due to internalization of the D2 receptor rather than dopamine displacement. In addition, this study demonstrates the utility of small animal PET to study receptor trafficking in vivo in genetically modified mice.
ISSN:1053-8119
1095-9572
1095-9572
DOI:10.1016/j.neuroimage.2010.01.055