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FUNCTIONAL ALTERATIONS IN THE DOPAMINE TRANSPORTER OF RODENTS FOLLOWING SELF-ADMINISTRATION OF COCAINE, HEROIN AND SPEEDBALL BY LINDSEY P. PATTISON A Dissertation Submitted to the Graduate Faculty of WAKE FOREST UNIVERSITY GRADUATE SCHOOL OF ARTS AND SCIENCES in Partial Fulfillment of the Requirements for the Degree of DOCTOR OF PHILOSOPHY Neuroscience MAY 2013 Winston-Salem, North Carolina Approved By Scott E. Hemby, Ph.D., Advisor Ashok N. Hegde, Ph.D., Chair Sara R. Jones, Ph.D. Brian A. McCool, Ph.D. Michael A. Nader, Ph.D. Loren H. Parsons, Ph.D. ACKNOWLEDGEMENTS I would like to acknowledge my labmates Scot McIntosh and Amanda Grigg for their continued assistance, but most of all their friendship. I would also like to thank my “step-advisors,” Dr. Evgeny (Zhenya) Budygin and Dr. Steve Childers. They welcomed me into their labs and worked extensively with me through understanding concepts and resolving technical difficulties to ensure that I received the best training possible. And of course, I would like to thank my advisor, Dr. Scott Hemby, for his unrelenting professional and personal support system throughout my entire graduate career. It was indeed a pleasure to work with an advisor who is so passionate about science and I will greatly miss the inspiring conversations we’ve had over the years. I would like to dedicate this dissertation to my father, Chuck Pattison, who has been my role model as a life-long learner and has always supported my scholastic endeavors, particularly throughout graduate school. This research was funded by DA012498, DA021634 and DA006634 from the National Institute on Drug Abuse. ii TABLE OF CONTENTS PAGE LIST OF ABBREVIATIONS iv LIST OF TABLES AND FIGURES ix ABSTRACT xii CHAPTER I THE DOPAMINERGIC CORRELATES OF CHRONIC COCAINE, HEROIN AND SPEEDBALL ADMINISTRATION 1 II SPEEDBALL-INDUCED CHANGES IN ELECTRICALLY STIMULATED DOPAMINE OVERFLOW IN RAT NUCLEUS ACCUMBENS 61 Published in Neuropharmacology September 14, 2010 III DIFFERENTIAL REGULATION OF ACCUMBAL DOPAMINE TRANSMISSION IN RATS FOLLOWING COCAINE, HEROIN AND SPEEDBALL SELF-ADMINISTRATION 87 Published in Journal of Neurochemistry March 19, 2012 IV EFFECTS OF COCAINE, HEROIN AND SPEEDBALL SELF- ADMINISTRATION ON DOPAMINE TRANSPORTER BINDING SITES 118 V COMPARING IN VIVO AND IN VITRO ALTERATIONS IN DAT KINETICS AND BINDING TO ELUCIDATE FUNCTIONAL ADAPTATIONS TO CHRONIC SPEEDBALL SELF-ADMINISTRATION 169 APPENDIX 219 SCHOLASTIC VITAE 231 iii LIST OF ABBREVIATIONS [125I]RTI-55 iodinated 3β-(4-iodophenyl)tropan-2β-carboxylic acid methyl ester [3H] tritium [3H]CFT tritiated 3β-(4-fluorophenyl)tropan-2β-carboxylic acid methyl ester [3H]DA tritiated dopamine [Ca2+] intracellular calcium concentration I [DA] dopamine concentration [DA] extracellular dopamine concentration e [DA] concentration of dopamine release per stimulation pulse p [Na+] extracellular sodium concentration e [Na+] intracellular sodium concentration i 3-MT 3-methoxytyramine 5-HT serotonin 6-MAM 6-monoacetylmorphine AC adenylyl cyclase ANOVA analysis of variance B binding density max B 1 high-affinity binding density max B 2 low-affinity binding density max B total high- and low-binding densities combined max Ca2+ calcium ion CaMKII calcium/calmodulin-dependent protein kinase cAMP 3’,5’-cyclic monophosphate Cdk 5 cyclin-dependent kinase 5 CFT 3β-(4-fluorophenyl)tropan-2β-carboxylic acid methyl ester (WIN 35,428) Cl- chloride ion CNS central nervous system iv COMT catechol-O-methyl transferase CPE carboxypeptidase CPu caudate putamen D1R dopamine D1 receptor subtype D2L dopamine D2 receptor long isoform D2R dopamine D2 receptor subtype D2S dopamine D2 receptor short isoform D3R dopamine D3 receptor subtype D4R dopamine D4 receptor subtype D5R dopamine D5 receptor subtype DA dopamine DA-RT dopamine reverse transport DAT dopamine transporter DBH dopamine-beta-hydroxylase DOPAC 3,4-dihydroxyphenylacetic acid DOPAL 3,4-dihydroxyphenylacetaldehyde DOPET 3,4-dihydroxyphenylethanol DYN dynorphin EGFP enhanced green fluorescent protein ENK enkephalin EPI epinephrine ERK1/2 extracellular signal-regulated kinases FR fixed-ratio FSCV fast-scan cyclic voltammetry GABA gamma-aminobutyric acid GABAergic gamma-aminobutyric acid-expressing cells GABAT gamma-aminobutyric acid transporter v Gα inhibitory G protein alpha subunit i/o Gα stimulatory G protein alpha subunit s/olf glu glutamate GP globus pallidus GPCR G protein-coupled receptor GP globus pallidus external e GP globus pallidus internal i hDAT human dopamine transporter HPLC high-pressure liquid chromatography HVA homovanillic acid i.p. intraperitoneal i.v. intravenous JNK c-Jun N-terminal kinase K+ potassium ion K dissociation constant d K 1 high-affinity dissociation constant d K 2 low-affinity dissociation constant d K Michaelis-Menten constant, representing apparent affinity m L-DOPA L-3,4-dihydroxyphenylalanine LeuT leucine transporter purified from Aquifex aeolicus Aa MAO monoamine oxidase MAPK mitogen-activated protein kinase MAT monoamine transporter MKP3 mitogen-activated protein kinase phosphatase 3 MOPET 3-methoxy-4-hydroxyphenylethanol MOR mu opioid receptor mPFC medial prefrontal cortex vi MSN medium spiny neuron Na+ sodium ion NAc nucleus accumbens NE norepinephrine NET norepinephrine transporter NO nitric oxide NPY neuropeptide Y NT neurotensin OCT organic cation transporter OT olfactory tubercle PET positron emission tomography PFC prefrontal cortex PI3K phosphoinositide 3-kinase PKA protein kinase A PKB protein kinase B PKC protein kinase C PP1/PP2Ac protein phosphatases 1 and 2Ac PR progressive-ratio PTM post-translational modification PV parvalbumin rDAT rat dopamine transporter RTI-55 3β-(4-iodophenyl)tropan-2β-carboxylic acid methyl ester s.c. subcutaneous S1 primary binding site S2 secondary binding site SA self-administration SERT serotonin transporter vii SN substantia nigra SNc substantia nigra pars compacta SP substance P TH tyrosine hydroxylase TM transmembrane VMAT1 vesicular monoamine transporter 1 VMAT2 vesicular monoamine transporter 2 V maximal reuptake rate max VP ventral pallidum VTA ventral tegmental area WF-23 2β-propanoyl-3β-(2-naphthyl) tropane viii LIST OF TABLES AND FIGURES PAGE CHAPTER I Table 1. Effects of cocaine on the mesolimbic DA system 23 Table 2. Compounds used to elucidate mechanisms of cocaine/heroin combinations 40 CHAPTER II Figure 1. Representative traces of evoked DA signals detected by FSCV in rat NAc before and 1 min after cocaine (1.0 mg/kg, i.v.), heroin (0.03 mg/kg, i.v.) and speedball (1.0 mg/kg cocaine + 0.03 mg/kg heroin, i.v.) injection in drug-naïve animals (upper panel) and topographical color plots of voltammetric data before drug administration, with time on the x-axis, applied scan potential on the y-axis and background-subtracted faradaic current shown on the z-axis in pseudo-color (lower panel) 71 Figure 2. Electrically evoked DA efflux in the NAc of anesthetized drug-naïve rats following a single i.v. injection of cocaine (1.0 mg/kg), heroin (0.03 mg/kg) and speedball (1.0 mg/kg cocaine + 0.03 mg/kg heroin) 72 Figure 3. DAT apparent affinity (K , or Michaelis-Menten rate constant) in the NAc m of anesthetized drug-naïve rats following a single i.v. injection of cocaine (1.0 mg/kg), heroin (0.03 mg/kg) and speedball (1.0 mg/kg cocaine + 0.03 mg/kg heroin) 74 Figure 4. DAT-mediated maximal reuptake rate (V ) in the NAc of anesthetized max drug-naïve rats following a single i.v. injection of cocaine (1.0 mg/kg), heroin (0.03 mg/kg) and speedball (1.0 mg/kg cocaine + 0.03 mg/kg heroin) 76 ix CHAPTER III Figure 1. (A) Acquisition of self-administration during the first 14 days of training rats to self-administer cocaine (250 µg/infusion), heroin (4.95 µg/infusion) or speedball (250/4.95 µg/infusion cocaine/heroin) 98 (B) Mean interinfusion intervals for each group (n = 5) throughout the 25 day period of self-administration under an FR2 99 Figure 2. DA changes detected by FSCV in the NAc of anesthetized rats following i.v. cocaine, speedball and heroin infusion 101 Figure 3. Electrically evoked DA efflux in the NAc of anesthetized rats approximately 24 hours after the last chronic self-administration session, following a single i.v. injection of cocaine (1.0 mg/kg), heroin (0.03 mg/kg) and speedball (1.0 mg/kg cocaine + 0.03 mg/kg heroin) 102 Figure 4. DAT apparent affinity (K ) in the NAc of anesthetized rats (n = 5/group) m approximately 24 hours after the last chronic self-administration session, following a single i.v. injection of cocaine (1.0 mg/kg), heroin (0.03 mg/kg) and speedball (1.0 mg/kg cocaine + 0.03 mg/kg heroin) 105 Figure 5. (A) DAT-mediated maximal reuptake rate (V ) in the NAc of max anesthetized rats (n = 5/group) approximately 24 hours after the last chronic self-administration session, following a single i.v. injection of cocaine (1.0 mg/kg), heroin (0.03 mg/kg) and speedball (1.0 mg/kg cocaine + 0.03 mg/kg heroin) 106 (B) Baseline, or pre-drug, V calculated at three time points prior to max bolus drug infusions as compared to the baseline V values of drug- max naïve rats 107 Figure 6. Comparison of electrically evoked DA efflux in NAc of drug-naïve rats and chronically self-administering rats following a single challenge i.v. infusion of (A) cocaine (1.0 mg/kg), (B) speedball (1.0/0.03 mg/kg cocaine/heroin), and (C) heroin (0.03 mg/kg), and effects on the inhibition of DA uptake, or apparent K , in NAc following i.v. challenge infusions m of (D) cocaine (1.0 mg/kg), (E) speedball (1.0/0.03 mg/kg cocaine/heroin) and (F) heroin (0.03 mg/kg) in chronic self-administering rats and in drug- naïve animals (n = 5/group) [Data from drug-naïve rats is reprinted with permission from Pattison et al., 2011] 109-110 x

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voltammetric data before drug administration, with time on the x-axis, . fast-scan cyclic voltammetry (FSCV) was used to compare evoked DA release
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