Multi-facetted impulsivity following nigral degeneration and dopamine replacement therapy.

Impulse control disorders (ICDs) are debilitating side effects of dopamine replacement therapy (DRT) in Parkinson's disease (PD) that severely affect the quality of life of patients. While DRT, the pattern and extent of neurodegeneration, and prodromic factors of vulnerability (e.g. impulsivity) have all been hypothesized to play a role in the development of ICDs, their respective, and potentially interacting, contributions remain to be established. High impulsive (HI), Intermediate (Int) or low impulsive (LI) rats were identified based on their performance in both a differential reinforcement of low rate of responding (DRL) and a fixed consecutive number (FCN) schedules, that operationalize two independent facets of impulsivity, waiting and action inhibition (motor impulsivity). We investigated whether high impulsivity trait influenced the progressive development of a parkinsonian state induced by viral-mediated overexpression of α-synuclein, and whether impulsivity trait and nigrostriatal neurodegeneration independently or jointly influenced the effects of DRT on impulse control. α-synuclein-induced nigrostriatal neurodegeneration increased both waiting and motor impulsivity. The D2/D3 dopamine receptor agonist pramipexole exacerbated motor impulsivity more than waiting. However, the pramipexole-induced increase in waiting impulsivity observed in both sham and lesioned rats, was more pronounced in HI lesioned rats, which displayed a restricted α-synuclein-induced dopaminergic neurodegeneration. Thus, a PD-like nigrostriatal lesion increases both motor and waiting impulsivity, but its interaction with a pre-existing impulsivity trait, which, at the cellular level, confers resilience to dopaminergic neurodegeneration, worsens the detrimental effects of D2/D3 dopamine receptor agonists on inhibitory control.This is the final published version. It first appeared at http://www.sciencedirect.com/science/article/pii/S0028390816302118

Alterations of dopaminergic responsiveness in Parkinson’s disease : from dyskinesia to impulse control disorders

Mon projet de thèse porte sur les altérations de la réponse dopaminergique dans la maladie de Parkinson (MP). Les troubles moteur de la MP sont améliorés par la L-Dopa (précurseur de la dopamine) et/ou les agonistes dopaminergiques. Cependant, ces traitements engendrent des effets secondaires moteurs (les dyskinésies) et non-moteurs. Ainsi, environ 15% des patients atteints de la MP sous agoniste dopaminergique vont présenter des addictions comportementales avec un syndrome de sevrage, et 3 à 4% des patients traités à la L-Dopa ou à l’apomorphine développent une prise compulsive de médicament. Ces complications motrices et non-motrices des thérapies dopaminergiques, font intervenir une dysfonction du réseau des ganglions de la base. Ce travail a exploré le lien entre l’accumulation de la protéine ΔFosB et les modifications des propriétés électriques des neurones impliqués dans l’expression des dyskinésies, en utilisant une technique d’inactivation sélective des neurones exprimant ΔFosB dans le striatum de rat et de singe. Mes travaux ont également évalué chez le singe, comment la L-Dopa modifiait les taux de monoamines pour engendrer les dyskinésies. Ceci m’a permis de montrer que les structures cognitives et limbiques sont elles aussi affectées et qu’elles pourraient être directement impliqués dans les dyskinésies. Sur cette base, j’ai étudié la physiopathologie des troubles du traitement de la récompense et démontré que la L-Dopa, le traitement de référence de la MP, peut acquérir des propriétés récompensantes proches de celles de la cocaïne dans un modèle rat de la MP par surexpression de gène codant pour l’α-synucléine mutée. J’ai également utilisé des procédures d’auto-administration intraveineuse chez le rat pour montrer que le Pramipexole, un agoniste dopaminergique couramment utilisé dans le traitement de la MP, possédait des propriétés renforçantes. Ceci m’a permis de souligner que des susceptibilités individuelles sous-tendraient le développement de ces addictions comportementales. Ces découvertes ont ensuite été complétées par des expériences montrant que les altérations liées à la MP modifiaient le trait d’impulsivité des rats et que les traitements dopaminergiques pouvaient empirer ces changements.My PhD focused on the alterations of the dopaminergic response in Parkinson’s disease (PD). Motor impairments in PD are reduced by the dopamine precursor L-Dopa and/or dopamine agonists. However, these medications elicit motor (dyskinesia) and non-motor side-effects. Up to 15% of PD patients under dopamine agonists experience behavioral addictions and withdrawal syndrome, and 3-4% of patients treated with L-Dopa or apomorphine exhibit compulsive medication intake. Both motor and non-motor complications of dopaminergic therapies involve dysfunctions in the basal ganglia network. I explored the link between deltaFosB protein accumulation and the cellular electrical properties that trigger dyskinesia by using a cell-type specific inactivation of FosB expressing neurons of the striatum in rats and monkeys. I have also investigated in monkeys how L-Dopa modifies monoaminergic functions to mediate dyskinesia and demonstrated that limbic/cognitive structures are identically affected providing a basis for a non-motor component involved in motor side effects in PD. From this, I studied the pathophysiology of addiction-like disorders by revealing that L-Dopa, the most widely-used treatment for PD, can acquire rewarding properties similar to cocaine in a viral-mediated rat model of PD. I also used self-administration procedures in rats to demonstrate the rewarding properties of Pramipexole, a dopamine agonist commonly use in the treatment of PD, and identified individual susceptibilities in the development of addiction-like disorders. These findings were followed by additional work showing that PD alterations modify the impulsivity trait of rats and that medication might worsen these changes

Alterations of dopaminergic responsiveness in Parkinson’s disease : from dyskinesia to impulse control disorders

Mon projet de thèse porte sur les altérations de la réponse dopaminergique dans la maladie de Parkinson (MP). Les troubles moteur de la MP sont améliorés par la L-Dopa (précurseur de la dopamine) et/ou les agonistes dopaminergiques. Cependant, ces traitements engendrent des effets secondaires moteurs (les dyskinésies) et non-moteurs. Ainsi, environ 15% des patients atteints de la MP sous agoniste dopaminergique vont présenter des addictions comportementales avec un syndrome de sevrage, et 3 à 4% des patients traités à la L-Dopa ou à l’apomorphine développent une prise compulsive de médicament. Ces complications motrices et non-motrices des thérapies dopaminergiques, font intervenir une dysfonction du réseau des ganglions de la base. Ce travail a exploré le lien entre l’accumulation de la protéine ΔFosB et les modifications des propriétés électriques des neurones impliqués dans l’expression des dyskinésies, en utilisant une technique d’inactivation sélective des neurones exprimant ΔFosB dans le striatum de rat et de singe. Mes travaux ont également évalué chez le singe, comment la L-Dopa modifiait les taux de monoamines pour engendrer les dyskinésies. Ceci m’a permis de montrer que les structures cognitives et limbiques sont elles aussi affectées et qu’elles pourraient être directement impliqués dans les dyskinésies. Sur cette base, j’ai étudié la physiopathologie des troubles du traitement de la récompense et démontré que la L-Dopa, le traitement de référence de la MP, peut acquérir des propriétés récompensantes proches de celles de la cocaïne dans un modèle rat de la MP par surexpression de gène codant pour l’α-synucléine mutée. J’ai également utilisé des procédures d’auto-administration intraveineuse chez le rat pour montrer que le Pramipexole, un agoniste dopaminergique couramment utilisé dans le traitement de la MP, possédait des propriétés renforçantes. Ceci m’a permis de souligner que des susceptibilités individuelles sous-tendraient le développement de ces addictions comportementales. Ces découvertes ont ensuite été complétées par des expériences montrant que les altérations liées à la MP modifiaient le trait d’impulsivité des rats et que les traitements dopaminergiques pouvaient empirer ces changements.My PhD focused on the alterations of the dopaminergic response in Parkinson’s disease (PD). Motor impairments in PD are reduced by the dopamine precursor L-Dopa and/or dopamine agonists. However, these medications elicit motor (dyskinesia) and non-motor side-effects. Up to 15% of PD patients under dopamine agonists experience behavioral addictions and withdrawal syndrome, and 3-4% of patients treated with L-Dopa or apomorphine exhibit compulsive medication intake. Both motor and non-motor complications of dopaminergic therapies involve dysfunctions in the basal ganglia network. I explored the link between deltaFosB protein accumulation and the cellular electrical properties that trigger dyskinesia by using a cell-type specific inactivation of FosB expressing neurons of the striatum in rats and monkeys. I have also investigated in monkeys how L-Dopa modifies monoaminergic functions to mediate dyskinesia and demonstrated that limbic/cognitive structures are identically affected providing a basis for a non-motor component involved in motor side effects in PD. From this, I studied the pathophysiology of addiction-like disorders by revealing that L-Dopa, the most widely-used treatment for PD, can acquire rewarding properties similar to cocaine in a viral-mediated rat model of PD. I also used self-administration procedures in rats to demonstrate the rewarding properties of Pramipexole, a dopamine agonist commonly use in the treatment of PD, and identified individual susceptibilities in the development of addiction-like disorders. These findings were followed by additional work showing that PD alterations modify the impulsivity trait of rats and that medication might worsen these changes

A Role for Peroxisome Proliferator-Activated Receptor Gamma Coactivator-1α in Nucleus Accumbens Neuron Subtypes in Cocaine Action.

BACKGROUND: Molecules critically involved in cocaine behavioral plasticity are known to regulate and interact with peroxisome proliferator-activated receptor gamma coactivator-1alpha, PGC-1α. Additionally, the PGC-1α promoter has binding sites for early growth response 3 (Egr3), which plays a dynamic role in cocaine action in nucleus accumbens (NAc) medium spiny neurons (MSN) subtypes, those enriched in dopamine receptor D1 vs. D2. However, the role of PGC-1α in NAc in cocaine action is unknown. METHODS: PGC-1α mRNA and protein were examined in NAc after repeated cocaine exposure. Binding of Egr3 to and histone methylation at the PGC-1α promoter was examined in NAc, using chromatin immunoprecipitation (ChIP), after repeated cocaine. PGC-1α ribosome-associated mRNA in MSN subtypes was assessed after repeated cocaine using D1-Cre-RiboTag and D2-Cre-RiboTag lines. Finally, PGC-1α was expressed in NAc D1-MSNs vs. D2-MSNs using a Cre-inducible AAV and Cre lines during cocaine conditioned place preference and cocaine-induced locomotion. RESULTS: Repeated cocaine increased PGC-1α levels, and increased Egr3 binding and H3K4me3 at the PGC-1α promoter in NAc. Increased PGC-1α occurred in D1-MSNs, while D2-MSNs showed reduced levels. Viral mediated expression of PGC-1α in D1-MSNs enhanced behavioral responses to cocaine, while expression in D2-MSNs blunted these behaviors. CONCLUSIONS: We demonstrate a novel role for PGC-1α in NAc in cocaine action. PGC-1α is enhanced in NAc D1-MSNs specifically after cocaine exposure. These data are consistent with increased active methylation and Egr3 binding at the PGC-1α promoter. Finally, we demonstrate a bidirectional role for PGC-1α in mediating behavioral plasticity to cocaine through D1-MSNs vs. D2-MSNs

L-dopa gains psychostimulant-like properties after nigral dopaminergic loss

Dopamine Dysregulation Syndrome shares some core behavioral features of psychostimulant addiction, suggesting that dopamine replacement therapy can acquire psychostimulant-like properties in some patients with Parkinson's disease (PD). We here report strong experimental evidence supporting this hypothesis in an alpha-synuclein rat model of PD. Though L-Dopa had no effect in controls, it acquired two prominent psychostimulant-like properties in Parkinsonian rats: i) it produced intense reward on its own and in parallel ii) decreased interest in other nondrug reward. These two effects may combine to explain the addictive use of L-Dopa after loss of midbrain dopamine neurons in some PD patients. ANN NEUROL 2010.status: publishe

Context-dependent modulation of hippocampal and cortical recruitment during remote spatial memory retrieval.

International audienceAccording to systems consolidation, as hippocampal-dependent memories mature over time, they become additionally (or exclusively) dependent on extra-hippocampal structures. We assessed the recruitment of hippocampal and cortical structures on remote memory retrieval in a performance-degradation resistant (PDR; no performance degradation with time) versus performance-degradation prone (PDP; performance degraded with time) context. Using a water-maze task in two contexts with a hidden platform and three control conditions (home cage, visible platform with or without access to distal cues), we compared neuronal activation (c-Fos imaging) patterns in the dorsal hippocampus and the medial prefrontal cortex (mPFC) after the retrieval of recent (5 days) versus remote (25 days) spatial memory. In the PDR context, the hippocampus exhibited greater c-Fos protein expression on remote than recent memory retrieval, be it in the visible or hidden platform group. In the PDP context, hippocampal activation increased at the remote time point and only in the hidden platform group. In the anterior cingulate cortex, c-Fos expression was greater for remote than for recent memory retrieval and only in the PDR context. The necessity of the mPFC for remote memory retrieval in the PDR context was confirmed using region-specific lidocaine inactivation, which had no impact on recent memory. Conversely, inactivation of the dorsal hippocampus impaired both recent and remote memory in the PDR context, and only recent memory in the PDP context, in which remote memory performance was degraded. While confirming that neuronal circuits supporting spatial memory consolidation are reorganized in a time-dependent manner, our findings further indicate that mPFC and hippocampus recruitment (i) depends on the content and perhaps the strength of the memory and (ii) may be influenced by the environmental conditions (e.g., cue saliency, complexity) in which memories are initially formed and subsequently recalled

Seeking mechanisms of plasma/catalyst interaction with surface in situ diagnostics

International audienc

Selective Inactivation of Striatal FosB/ΔFosB-Expressing Neurons Alleviates L-DOPA-Induced Dyskinesia

International audienceBACKGROUND:ΔFosB is a surrogate marker of L-DOPA-induced dyskinesia (LID), the unavoidable disabling consequence of Parkinson's disease L-DOPA long-term treatment. However, the relationship between the electrical activity of FosB/ΔFosB-expressing neurons and LID manifestation is unknown.METHODS:We used the Daun02 prodrug-inactivation method associated with lentiviral expression of β-galactosidase under the control of the FosB promoter to investigate a causal link between the activity of FosB/ΔFosB-expressing neurons and dyskinesia severity in both rat and monkey models of Parkinson's disease and LID. Whole-cell recordings of medium spiny neurons (MSNs) were performed to assess the effects of Daun02 and daunorubicin on neuronal excitability.RESULTS:We first show that daunorubicin, the active product of Daun02 metabolism by β-galactosidase, decreases the activity of MSNs in rat brain slices and that Daun02 strongly decreases the excitability of rat MSN primary cultures expressing β-galactosidase upon D1 dopamine receptor stimulation. We then demonstrate that the selective, and reversible, inhibition of FosB/ΔFosB-expressing striatal neurons with Daun02 decreases the severity of LID while improving the beneficial effect of L-DOPA.CONCLUSIONS:These results establish that FosB/ΔFosB accumulation ultimately results in altered neuronal electrical properties sustaining maladaptive circuits leading not only to LID but also to a blunted response to L-DOPA. These findings further reveal that targeting dyskinesia can be achieved without reducing the antiparkinsonian properties of L-DOPA when specifically inhibiting FosB/ΔFosB-accumulating neuro

Lack of additive role of ageing in nigrostriatal neurodegeneration triggered by α-synuclein overexpression

International audienceINTRODUCTION:Parkinson's disease (PD) is a progressive neurodegenerative disorder characterized by the loss of dopaminergic neurons as well as the presence of proteinaceous inclusions named Lewy bodies. α-synuclein (α-syn) is a major constituent of Lewy bodies, and the first disease-causing protein characterized in PD. Several α-syn-based animal models of PD have been developed to investigate the pathophysiology of PD, but none of them recapitulate the full picture of the disease. Ageing is the most compelling and major risk factor for developing PD but its impact on α-syn toxicity remains however unexplored. In this study, we developed and exploited a recombinant adeno-associated viral (AAV) vector of serotype 9 overexpressing mutated α-syn to elucidate the influence of ageing on the dynamics of PD-related neurodegeneration associated with α-syn pathology in different mammalian species.RESULTS:Identical AAV pseudotype 2/9 vectors carrying the DNA for human mutant p.A53T α-syn were injected into the substantia nigra to induce neurodegeneration and synucleinopathy in mice, rats and monkeys. Rats were used first to validate the ability of this serotype to replicate α-syn pathology and second to investigate the relationship between the kinetics of α-syn-induced nigrostriatal degeneration and the progressive onset of motor dysfunctions, strikingly reminiscent of the impairments observed in PD patients. In mice, AAV2/9-hα-syn injection into the substantia nigra was associated with accumulation of α-syn and phosphorylated hα-syn, regardless of mouse strain. However, phenotypic mutants with either accelerated senescence or resistance to senescence did not display differential susceptibility to hα-syn overexpression. Of note, p-α-syn levels correlated with nigrostriatal degeneration in mice. In monkeys, hα-syn-induced degeneration of the nigrostriatal pathway was not affected by the age of the animals. Unlike mice, monkeys did not exhibit correlations between levels of phosphorylated α-syn and neurodegeneration.CONCLUSIONS:In conclusion, AAV2/9-mediated hα-syn induces robust nigrostriatal neurodegeneration in mice, rats and monkeys, allowing translational comparisons among species. Ageing, however, neither exacerbated nigrostriatal neurodegeneration nor α-syn pathology per se. Our unprecedented multi-species investigation thus favours the multiple-hit hypothesis for PD wherein ageing would merely be an aggravating, additive, factor superimposed upon an independent disease process