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Abstract

Background: Animal data indicate that chronic exposure to dopaminergic drugs can alter levels of the dopamine transporter (DAT), which is critically involved in regulation of synaptic dopamine levels. DAT changes could influence the response to therapy in PD. Methods: A randomized, assessor-blinded, placebo-controlled clinical trial was performed in subjects with early PD to determine whether l-dopa or pramipexole might regulate striatal DAT binding as measured by PET with [11C]RTI-32. Thirty clinically asymmetrical patients were randomly assigned to receive 6 weeks of l-dopa (300/75 mg/d), pramipexole (1.5 mg/d), or placebo; PET studies were performed before and after treatment. Results: Mean interval change in DAT binding was significantly reduced by 16% to 22% in all striatal regions (caudate, anterior and posterior putamen) of the l-dopa–treated patients, whereas significant changes in the pramipexole-treated patients were limited to the contralateral caudate (−15%), ipsilateral anterior putamen (−14%), and posterior putamen (−20%). In the placebo group there were significant changes in contralateral caudate (−11%) and ipsilateral anterior putamen (−12%). l-dopa and pramipexole produced similar clinical benefit. Conclusions: Short-term therapy with l-dopa and, to a lesser extent, pramipexole can modestly down-regulate striatal DAT in patients with early PD. Decreased striatal DAT could increase dopaminergic neurotransmission with potential benefit, but might also play a role in the development of dopamine-related response fluctuations in patients with advanced disease. Our data also suggest caution in interpretation of longitudinal imaging studies employing DAT to assess disease progression and the efficacy of neuroprotective agents.

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References

1.
Giros B, Jaber M, Jones SR, et al. Hyperlocomotion and indifference to cocaine and amphetamine in mice lacking the dopamine transporter. Nature . 1996; 379: 606–612.
2.
Wilson JM, Nobrega JM, Carroll M, et al. Heterogeneous subregional binding patterns of 3H-WIN 35,428 and 3H-GBR 12,935 are differentially regulated by chronic cocaine self-administration. J Neurosci . 1994; 14: 2966–2979.
3.
Moody CA, Granneman JG, Bannon MJ. Dopamine transporter binding in rat striatum and nucleus accumbens is unaltered following chronic changes in dopamine levels. Neurosci Lett . 1996; 217: 55–57.
4.
Gordon I, Weizman R, Rehavi M. Modulatory effect of agents active in the presynaptic dopaminergic system on the striatal dopamine transporter. Eur J Pharmacol . 1996; 298: 27–30.
5.
Vander Borght TM, Kilbourn MR, Desmond T, et al. The vesicular monoamine transporter is not regulated by dopaminergic drug treatments. Eur J Pharmacol . 1995; 294: 577–583.
6.
Murer MG, Dziewczapolski G, Menalled LB, et al. Chronic levodopa is not toxic for remaining dopamine neurons, but instead promotes their recovery, in rats with moderate nigrostriatal lesions. Ann Neurol . 1998; 43: 561–575.
7.
Ikawa K, Watanabe A, Kaneno S, et al. Modulation of [3H]mazindol binding sites in rat striatum by dopaminergic agents. Eur J Pharmacol . 1993; 250: 261–266.
8.
Gnanalingham KK, Robertson RG. The effects of chronic continuous versus intermittent levodopa treatments on striatal and extrastriatal D1 and D2 dopamine receptors and dopamine uptake sites in the 6-hydroxydopamine lesioned rat—an autoradiographic study. Brain Res . 1994; 640: 185–194.
9.
Innis RB, Marek KL, Sheff K, et al. Effect of treatment with L-DOPA/carbidopa or L-selegiline on striatal dopamine transporter SPECT imaging with [123I]β-CIT. Mov Disord . 1999; 14: 436–442.
10.
Ahlskog JE, Uitti RJ, O’Connor MK, et al. The effect of dopamine agonist therapy on dopamine transporter imaging in Parkinson’s Disease. Mov Disord . 1999; 14: 940–946.
11.
Nurmi E, Bergman J, Eskola O, et al. Reproducibility and effect of levodopa on dopamine transporter function measurements: a [18-F]CFT PET study. J Cereb Blood Flow Metab . 2000; 20: 1604–1609.
12.
Wilson A, DaSilva J, Houle S. Facile radiolabelling and purification of 2B-[O-[11]CH3]-carbomethoxy-2B-aryltropanes: radiotracers for the dopamine transporter. J Labelled Comp Radiopharm . 1994; 34: 759–765.
13.
Wilson A, DaSilva J, Houle S. In vivo evaluation of [11C] and [18F]-labelled cocaine analogues as potential dopamine transporter ligands for positron emission tomography. Nucl Med Biol . 1996; 23: 141–146.
14.
Guttman M, Burkholder J, Kish SJ, et al. PET studies of the dopamine transporter in early dopa-naive Parkinson’s disease: implications for the symptomatic threshold. Neurology . 1997; 48: 1578–1582.
15.
Mierau J, Schneider FJ, Ensinger HA, et al. Pramipexole binding and activation of cloned and expressed dopamine D2, D3 and D4 receptors. Eur J Pharmacol . 1995; 290: 29–36.
16.
Perlmutter JS, Raichle ME. Regional blood flow in hemiparkinsonism. Neurology . 1985; 35: 1127–1134.
17.
Wolfson LI, Leenders KL, Brown LL, et al. Alterations of regional cerebral blood flow and oxygen metabolism in Parkinson’s disease. Neurology . 1985; 35: 1399–1405.
18.
Leenders KL, Wolfson LI, Gibbs JM, et al. The effects of L-dopa on regional cerebral blood flow and oxygen metabolism in patients with Parkinson’s disease. Brain . 1985; 108: 171–191.
19.
Jorga KM. Pharmacokinetics, pharmacodynamics, and tolerability of tolcapone: a review of early studies in volunteers. Neurology . 1998; 50 (suppl 1): S31–S38.
20.
Carroll FI, Gao Y, Rahman MA, et al. Synthesis, ligand binding, QSAR and CoMFA study of 3B-(p-substituted phenol) tropane-2B-carboxylic acid methyl esters. J Med Chem . 1991; 34: 2719–2725.
21.
Pristupa ZB, McConkey F, Liu F, et al. Protein kinase-mediated bidirectional trafficking and functional regulation of the human dopamine transporter. Synapse . 1998; 30: 79–87.
22.
Laruelle M, Baldwin RM, Malison RT, et al. SPECT imaging of dopamine and serotonin transporters with [123I]β-CIT: pharmacological characterization of brain uptake in nonhuman primates. Synapse . 1993; 13: 295–309.
23.
Alexander GM, Schwartzman RJ, Brainard L, et al. Changes in brain catecholamines and dopamine uptake sites at different stages of MPTP parkinsonism in monkeys. Brain Res . 1992; 588: 261–269.
24.
Rioux L, Frohna PA, Joyce JN, et al. The effects of chronic levodopa treatment on pre- and postsynaptic markers of dopaminergic function in striatum of parkinsonian monkeys. Mov Disord . 1997; 12: 148–158.
25.
Little KY, Gorebig J, Carroll FI, et al. Lack of dopamine receptor agonists effect on striatal dopamine transporter binding sites. Brain Res . 1996; 742: 313–316.
26.
Wilson JM, Levey AI, Rajput SK, et al. Differential changes in neurochemical markers of striatal dopamine nerve terminals in idiopathic Parkinson’s disease. Neurology . 1996; 47: 718–726.
27.
Lee CS, Samii A, Sossi V, et al. In vivo positron emission tomographic evidence for compensatory changes in presynaptic dopaminergic nerve terminals in Parkinson’s disease. Ann Neurol . 2000; 47: 493–503.
28.
Frey KA, Koeppe RA, Kilbourn MR, et al. Presynaptic monoaminergic vesicles in Parkinson’s disease and normal aging. Ann Neurol . 1996; 40: 873–884.
29.
Engber TM, Susel Z, Kuo S, et al. Levodopa replacement therapy alters enzyme activities in striatum and neuropeptide content in striatal output regions of 6-hydroxydopamine lesioned rats. Brain Res . 1991; 552: 113–118.
30.
Vingerhoets FJG, Snow BJ, Lee CS, et al. Longitudinal fluorodopa positron emission tomographic studies of the evolution of idiopathic parkinsonism. Ann Neurol . 1994; 36: 759–764.
31.
Morrish PK, Sawle GV, Brooks DJ. An [18F]dopa-PET and clinical study of the rate of progression in Parkinson’s disease. Brain . 1996; 119: 101–107.

Information & Authors

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Published In

Neurology®
Volume 56Number 11June 12, 2001
Pages: 1559-1564
PubMed: 11402115

Publication History

Received: October 13, 2000
Accepted: January 25, 2001
Published online: June 12, 2001
Published in print: June 12, 2001

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Authors

Affiliations & Disclosures

M. Guttman, MD, FRPCP
From the Centre for Addiction and Mental Health (Drs. Guttman, Stewart, Wilson, Houle, and Kish, and D. Hussey), Division of Neurology (Dr. Guttman), and Department of Psychiatry (Drs. Guttman, Wilson, Houle, and Kish), University of Toronto, Ontario, Canada.
D. Stewart, PhD, FRCPC, MD
From the Centre for Addiction and Mental Health (Drs. Guttman, Stewart, Wilson, Houle, and Kish, and D. Hussey), Division of Neurology (Dr. Guttman), and Department of Psychiatry (Drs. Guttman, Wilson, Houle, and Kish), University of Toronto, Ontario, Canada.
D. Hussey, BSc
From the Centre for Addiction and Mental Health (Drs. Guttman, Stewart, Wilson, Houle, and Kish, and D. Hussey), Division of Neurology (Dr. Guttman), and Department of Psychiatry (Drs. Guttman, Wilson, Houle, and Kish), University of Toronto, Ontario, Canada.
A. Wilson, PhD
From the Centre for Addiction and Mental Health (Drs. Guttman, Stewart, Wilson, Houle, and Kish, and D. Hussey), Division of Neurology (Dr. Guttman), and Department of Psychiatry (Drs. Guttman, Wilson, Houle, and Kish), University of Toronto, Ontario, Canada.
S. Houle, MD, PhD, FRCPC
From the Centre for Addiction and Mental Health (Drs. Guttman, Stewart, Wilson, Houle, and Kish, and D. Hussey), Division of Neurology (Dr. Guttman), and Department of Psychiatry (Drs. Guttman, Wilson, Houle, and Kish), University of Toronto, Ontario, Canada.
S. Kish, PhD
From the Centre for Addiction and Mental Health (Drs. Guttman, Stewart, Wilson, Houle, and Kish, and D. Hussey), Division of Neurology (Dr. Guttman), and Department of Psychiatry (Drs. Guttman, Wilson, Houle, and Kish), University of Toronto, Ontario, Canada.

Notes

Address correspondence and reprint requests to Dr. Mark Guttman, 377 Church St. #407, Markham, ON, Canada, L6B 1A1; e-mail: [email protected]

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