NOVEL DOPAMINERGIC SIGNALING MODULATING HIPPOCAMPAL SYNAPTIC TRANSMISSION

Rizvi, Nisha

01 August 2015

Dopaminergic systems regulate many brain functions and dysfunction of dopaminergic neurotransmission is thought to underlie numerous disorders, including schizophrenia, attention deficit hyperactivity disorder (ADHD), depression and Alzheimer’s disease. In the hippocampus, a dopaminergic projection from the ventral tegmental area (VTA) is proposed to be essential for controlling entry of sensory information into long-term memory through novelty and salience detection. However, the effects of the VTA-dopamine system on hippocampal synaptic transmission are largely under-explored and the underlying mechanisms are unclear. The goal of this project was to investigate mechanisms involved in dopaminergic modulation of hippocampal neurophysiology. Specifically, I (1) examined if dopamine modulates hippocampal synaptic transmission in a region- and input-specific manner, and (2) studied the signaling mechanisms underlying such modulation. In the first aim for the study, I tested whether SKF38393, a dopamine D1-like receptor agonist, differentially affects excitatory synaptic transmission in perforant path synapses onto dentate gyrus granule cells and whether such effects differ from those at area CA1 synapses. I found that SKF38393 produced a concentration-dependent increase in field excitatory postsynaptic potential (fEPSP) in both subregions, but that higher concentrations were needed in the dentate gyrus to produce comparable effects. This synaptic enhancement was long-lasting and largely irreversible which suggests it may be a form of long term enhancement (LTP). Also, the increase in synaptic transmission at medial perforant path synapses was larger than in the lateral perforant path. Importantly, effects in the dentate gyrus, unlike those in CA1, differed substantially along the dorsoventral axis, with effects being significantly larger at the dorsal compared to the ventral pole. In the second aim, various combinations of D1 and D2-like receptor agonists and antagonists as well as inhibitors of second messenger systems, demonstrated that differential mechanisms were required for initiation and maintenance of SKF38393-mediated early and late-phase enhancement and that a novel non-canonical phospholipase-C (PLC) dependent signaling pathway may be involved. Based on recent discoveries in other brain regions, we hypothesized that multiple subcellular signaling pathways may contribute to PLC activation which may include but are not limited to D1(5)-D2 heteromers and Gβγ complex. In conclusion, this work uncovers novel dopaminergic signaling pathways regulating hippocampal physiology, which will lead to development of better (functionally selective) therapeutic agents.

D1-D2 heteromers

Dopamine

Hippocampus

Phospholipase C

Synaptic transmission

Dynamique et fonction des interactions entre récepteurs du glutamate et de la dopamine / Dynamics and function of glutamate and dopamine receptors interactions

Goyet, Elise

27 June 2017

Dans certaines aires cérébrales, l’action synergique du glutamate et de la dopamine est nécessaire pour induire et maintenir la plasticité synaptique. Un dialogue fonctionnel entre le récepteur métabotropique du glutamate mGlu5 et le récepteur de la dopamine D1 a été mise en évidence. Par ailleurs, de nombreuses études ont démontré que les récepteurs couplés aux protéines G ont la capacité de former des hétéromères créant ainsi de nouvelles entités fonctionnelles. En s’appuyant sur l’hypothèse d’une hétéromérisation des récepteurs, l’objectif de ce projet de thèse était d’étudier les mécanismes moléculaires qui sous-tendent une synergie fonctionnelle entre les récepteurs mGlu5 et D1. Dans la première partie de ce travail, j’ai caractérisé les bénéfices de la Nanoluciférase, une luciférase très lumineuse, pour améliorer la technique de BRET en imagerie (Bioluminescence Resonance Energy Transfer imaging) qui permet d’étudier la dynamique des interactions entre protéines dans les cellules vivantes. Les bénéfices mis en évidence en termes de résolution spatio-temporelle, de stabilité et de sensibilité du signal ont été exploités pour la suite de ce projet. Dans la seconde partie de ce travail, les améliorations techniques mentionnées ci-dessus ont permis de mettre en évidence pour la première fois des hétéromères mGlu5/D1 dans des neurones en culture. En outre, nous avons montré que la co-expression des récepteurs mGlu5 et D1 en système hétérologue favorise la signalisation calcique, d’une part en augmentant l'activité constitutive de mGlu5 et, d’autre part, en créant une voie de libération du calcium intracellulaire atypique induite par l'agoniste D1.Ces résultats apportent de nouveaux éléments de compréhension des bases moléculaires du dialogue fonctionnel glutamate/dopamine dans le contrôle de la communication neuronale en conditions physiologiques et ouvrent la voie à de nouvelles stratégies thérapeutiques capables de moduler sélectivement la fonction des hétéromères. / In some specific brain areas, synergism between glutamate and dopamine transmission is required to induce synaptic plasticity. Metabotropic glutamate receptor mGlu5 and dopamine receptor D1 are both known to control synaptic plasticity. Moreover, multiple lines of evidence converge toward the ability of G-protein coupled receptors to form dynamic heteromers thereby creating new entities with unique properties. Focusing on the hypothesis of receptor heteromerization, my PhD project aimed at investigating the molecular mechanisms underlying a functional interplay between mGlu5 and D1 receptors.To address this issue, a first part of this work consisted in improving single-cell Bioluminescent Resonance Energy Transfer (BRET) imaging, a technology enabling to study real time protein-protein interaction dynamics in living cells. Using the Nanoluciferase, an extremely bright luciferase, we characterized a faster and higher resolution single-cell BRET imaging technique with unprecedented performance in terms of temporal and spatial resolution, duration of signal stability and signal sensitivity. In the second part of this project, we showed that mGlu5 and D1 can form heteromers in heterologous expression system. The above-mentioned improvements of single-cell BRET imaging technique allowed to evidence the occurrence and the dynamics of mGlu5/D1 heteromers in cultured primary neurons. Furthermore, our results showed that the co-expression of mGlu5 and D1 receptors modifies single receptor properties to favor calcium signaling by increasing mGlu5 constitutive activity and creating a D1 agonist-induced activation of Ca2+ release from intracellular stores.These findings advance our knowledge about the molecular basis of the glutamate/dopamine functional dialogue to control neuronal communication in physiological conditions. Further investigation will help the dissection of the mGlu5/D1 heteromer specific signaling pathway with the hope of defining new therapeutics that may selectively modulate heteromer function and thus bypass undesirable side effects.

Dopamine

Glutamate

Hétéromères

Imagerie BRET

Récepteur D1

Récepteur mGlu5

Dopamine

Glutamate

Heteromers

BRET imaging

D1 receptor

MGlu5 receptor

Structural and Evolutionary Studies on Bio-Molecular Complexes

Sudha, G

January 2014

No description available.

Bio-Molecular Complexes

Protein Complexes

Protein-Protein Interactions

Human Casein Kinase

Hepatitis C Virus (HCV) Proteins

Adeno Associated Virus (AAV) Proteins

Protein Structural Bioinformatics

Homomeric Proteins

Heteromers

Paralogous Proteins

Biomolecular Structure

Computational Structural Biology

AAV2 Capsid

NS3 protease

HCV IRES

Molecular Biophysics