Global ETD Search

21	Synthesis of β-turn and pyridine based peptidomimetics Blomberg, David January 2007 (has links) Despite the unfavorable pharmacokinetic properties associated with peptides, they are still of great interest in drug development due to a multitude of interesting biological functions. The development of peptidomimetics strives to maintain or improve the biological activity of a peptide concurrently with removing the unwanted properties. This thesis describes two synthetic approaches to peptidomimetics with particular emphasis on secondary structure mimetics. First the design, synthesis and evaluation of two beta-turn mimetics incorporated in the endorphin Leu-enkephalin is presented. The beta-turn mimetics were stabilized by replacement of the intramolecular hydrogen bond with an ethylene bridge, and the amide bond between Tyr and Gly was replaced with an ether linkage. Linear analogues of the two mimetics were also synthesized. The peptidomimetics and their linear analogues were evaluated in a competitive binding assay at two opiate receptors, my and delta. One of the cyclized beta-turn mimetics was found to be a delta receptor antagonist with an IC50 value of 160 nM. Second a synthetic strategy to a beta-strand mimetic using 2-fluoro-4-iodopyridine as scaffold is described. The synthesis involved a Grignard exchange reaction on the pyridine scaffold using an amino acid derivative as electrophile followed by an SNAr reaction using an amine as nucleophile. The synthesis of a tripeptidomimetic of Leu-Gly-Gly and attempts to introduce chiral building blocks at the C-terminal, as well as studies towards elongated mimetics are presented. Two additional studies deal with the synthesis of two classes of potential thrombin inhibitors based on the pyridine scaffold. The first class contain pyridine as central fragment (P2 residue) substituted with a para-amidinobenzylamine group as P1 residue and various benzoyl groups as P3 residues. Three potential thrombin inhibitors were synthesized and found to be microM inhibitors in an enzymatic assay. In the second class, the pyridine ring serves as P3 residue. This class also lacks a strongly basic group in the P1 position. A small library of eight compounds were synthesized and evaluated in the enzymatic assay. Unfortunately, these compounds lacked inhibitory activity. Peptidomimetics beta-turn beta-strand pyridine scaffold Grignard exchange reaction SNAr reaction thrombin inhibitor Leu-enkephalin. Organic synthesis Organisk syntes
22	La modulation transcriptionnelle du neuropeptide enképhaline par les récepteurs nucléaires Nur77 et RXRγ Voyer, David 12 1900 (has links) Certains neuropeptides (enképhaline et neurotensine) sont des modulateurs du système dopaminergique. Chez les rongeurs, le traitement avec l’antipsychotique typique halopéridol (antagoniste des récepteurs D2), augmente fortement leurs niveaux d’ARNm dans le striatum, une structure centrale du système dopaminergique qui contrôle l’activité locomotrice. Comme l’halopéridol est associé avec de nombreux effets secondaires moteurs, on peut penser que la modulation des neuropeptides est possiblement un mécanisme d’adaptation visant à rétablir l’homéostasie du système dopaminergique après le blocage des récepteurs D2. Cependant, le mécanisme moléculaire de cette régulation transcriptionnelle n’est pas bien compris. Nur77 est un facteur de transcription de la famille des récepteurs nucléaires orphelins qui agit en tant que gène d’induction précoce. Le niveau de son ARNm est aussi fortement augmenté dans le striatum suivant un traitement avec halopéridol. Plusieurs évidences nous suggèrent que Nur77 est impliqué dans la modulation transcriptionnelle des neuropeptides. Nur77 peut former des hétérodimères fonctionnels avec le récepteur rétinoïde X (RXR). En accord avec une activité transcriptionnelle d’un complexe Nur77/RXR, l’agoniste RXR (DHA) réduit tandis que l’antagoniste RXR (HX531) augmente les troubles moteurs induits par un traitement chronique à l’halopéridol chez les souris sauvages tandis que ces ligands pour RXR n’ont aucun effet chez les souris Nur77 nulles. Nos travaux ont révélé que l’antagoniste RXR (HX531) réduit l’augmentation des niveaux d’enképhaline suivant un traitement chronique avec l’halopéridol. Nous avons ensuite démontré la liaison in vitro de Nur77 sur un élément de réponse présent dans le promoteur proximal de la proenképhaline, le peptide précurseur de l’enképhaline. Ces résultats supportent l’hypothèse que Nur77, en combinaison avec RXR, pourrait participer à la régulation transcriptionnelle des neuropeptides dans le striatum et donc contribuer à la neuroadaptation du système dopaminergique suivant un traitement aux antipsychotiques typiques. / Neuropeptides (enkephalin and neurotensin) are modulators of dopaminergic system. In the rodent’s striatum, antipsychotic drugs strongly modulate their mRNA levels. For exemple, haloperidol (D2 receptor antagonist) increases their mRNA levels in the striatum, a central structure of dopaminergic system that control locomotor activity. Since haloperidol is associated with many motor side effects, it is likely that neuropeptides modulation is a compensatory mechanism to restore the dopaminergic system homeostasis after D2 receptor blockade. However, molecular mechanism of this transcriptional regulation is not well understood. Nur77 is a transcription factor of the orphan nuclear receptor family that acts as an immediate early gene. In the striatum, its mRNA level is strongly increased following haloperidol treatment. Several evidences suggest that Nur77 is involved in neuropeptides transcriptional modulation. Nur77 can form functional heterodimers with retinoid X receptor (RXR). In agreement with a transcriptional activity of Nur77/RXR complex, RXR agonist (DHA) decreases while the RXR antagonist (HX531) exacerbates acute and chronic motor side effects of haloperidol treatment in wild type mice but remain without effect in Nur77 knockout mice. Our work shows that RXR antagonist (HX531) significantly reduced the increased levels of enkephalin following chronic treatment with haloperidol. We have set up the EMSA (electro-mobility shift assay) to demonstrate the in vitro binding of Nur77 on a responsive element from proenkephalin’s proximal promotor. These results support the hypothesis that Nur77 could be involve in transcriptional modulation of neuropeptides in the striatum and thus, contribute to neuroadaptation of dopaminergic system after treatment with typical antipsychotic drugs. Enképhaline dyskinésie tardive striatum Nur77 RXRγ halopéridol Enkephalin tardive dyskinesia
23	Maternal Separation in the Rat : The Short- and Long-term effects of Early-life Experience on Neuropeptides, Monoamines and Voluntary Ethanol Consumption Oreland, Sadia January 2009 (has links) Early-life experience has profound effects on the individual’s neurobiology and behaviour later in life. The rodent animal experimental model maternal separation (MS) was used to study this more in detail. The MS model involves short and prolonged postnatal separations simulating an emotionally safe and stressful environment, respectively. The aims of the thesis were to examine the impact of individual MS on ethanol consumption and on brain dopamine and serotonin systems in adult male rats. Furthermore, the influence of separation conditions on the short- and long-term consequences of MS on several neurotransmitter systems was examined. Rat pups were assigned to either litter-wise MS for 15 or 360 minutes (MS15l or MS360l) or individual MS for 15 or 360 minutes (MS15i or MS360i). Control rats were subjected to conventional animal facility rearing (AFR). Ethanol intake was assessed in a two-bottle free-choice paradigm. Neuropeptides were analyzed with radioimmunoassay, monoamines and metabolites with electrochemical detection and gene expression with qPCR. Using the MSi paradigm, minor effects on voluntary ethanol consumption were observed. However, the monoaminergic responses elicited by ethanol were dependent on the early-life environment. Furthermore, short- and long-term consequences of MS on serotonin, opioid, oxytocin and vasopressin systems were studied. Multiple neurobiological measurements in one and the same rat offered a unique possibility to examine the effects of duration (MS15 versus MS360) and condition (l versus i) of MS. Time-, region-, sex- and transmitter-specific effects were observed. More pronounced differences were seen in serotonin measures and oxytocin in young rats. In adults these differences in basal levels were normalized. Opioid peptides differed in stress-related brain areas in young rats and in limbic areas in adults. Rats subjected to the MS15l environment that relates to natural conditions generally exhibited a different neurobiological profile than other groups. AFR rats, i.e. conventional control rats, were more similar to the putative most stressful condition MS360. Taken together, the networks examined in the present thesis are important for the establishment of normal social behaviour and derangements in these systems may result in neurobiological changes leading to the susceptibility for psychopathological conditions later in life. Early-life stress Handling Serotonin Dopamine Oxytocin Vasopressin Enkephalin Dynorphin Two-bottle free choice Maternal deprivation Pharmaceutical pharmacology Farmaceutisk farmakologi
24	Développement de nanomédicaments innovants pour vaincre la douleur : une alternative à la morphine / A new painkiller nanomedicine to by-pass the blood-brain-barrier and the use of morphine Feng, Jiao 14 December 2018 (has links) Les neuropeptides endogènes chez l’homme, tels que les enképhalines et endomorphines, ont un potentiel thérapeutique considérable dans le traitement de la douleur. Ils agissent en activant les récepteurs opioïdes qui sont très largement distribués dans le système nerveux central ainsi que dans plusieurs tissus périphériques. Ces neuropeptides présentent, cependant, un certain nombre d’inconvénients qui limitent de manière importante leur efficacité thérapeutique. Tout d’abord, en raison de leur hydrophilie, ils ne passent pas la barrière sang/système nerveux, ce qui limite leur accès aux récepteurs opioïdes. De plus, ils présentent un temps de demi-vie plasmatique relativement court du fait d’une métabolisation rapide. Enfin, pour être efficaces, ces neuropeptides devraient résister à la protéolyse dans le système circulatoire et être suffisamment hydrophobes pour traverser ces barrières hémato-nerveuses.Le but de la thèse a consisté à créer de nouveaux nanomédicaments à base d’endorphines pour vectoriser et combattre la douleur de manière efficace.. Dans ce but, a été établi une liaison chimique covalente, enzymatiquement clivable (ester ou amide), entre le squalène (SQ, un lipide naturel et biocompatible) et le neuropeptide. Ce couplage donne lieu à des prodrogues qui ont la capacité de s'auto-assembler en nanoparticules (NPs) dans l'eau sans l’aide d'un agent tensio-actif. D’une manière générale, cette technologie présente de nombreux avantages tels qu’un taux de charge élevé en principe actif, une protection efficace de celui-ci vis-à-vis de la métabolisation et l’absence de phénomène de « burst release ».Durant ce travail de thèse, nous avons pu montrer pour la première fois que les Leu-enképhalines (LENK) pouvaient devenir efficaces pharmacologiquement une fois couplées au squalène, via une liaison amide (Am), ou via un bras espaceur, tel que le dioxycarbonyl (Diox), ou le diglycolate (Dig). Les prodrogues résultant de ce couplage ont toutes montré des propriétés d’auto-assemblage en milieu aqueux. Cette nanoformulation à base de squalène a permis, d’une part de protéger la LENK de la métabolisation rapide dans le plasma et d’autre part, de lui conférer un effet anti-hyperalgésique significatif dans un modèle de douleur inflammatoire induite chez le rat par la carragénine (test de Hargreaves). Il est important de souligner que cet effet anti-hyperalgésique a duré 3 fois plus longtemps qu’avec la morphine. Un prétraitement avec un antagoniste des récepteurs opioїdes imperméable à la BHE, comme la méthylnaloxone a complètement antagonisé l’effet anti-hyperalgésique des nanoparticules de LENK-SQ, démontrant ainsi que celles-ci agissent via les récepteurs opioïdes périphériques. De plus, l’étude de biodistribution de NPs LENK-SQ fluorescentes a montré une forte accumulation des celles-ci au niveau de la patte œdémateuse, mais aussi dans le foie, la rate et les poumons alors qu’aucun signal n’a pu être détecté au niveau cérébral, ce qui confirme bien l’effet périphérique de ces nanoparticules. Enfin, des études toxicologiques ont montré que malgré l’accumulation des NPs dans le foie, les taux d’aspartate transaminase (AST) et alanine transaminase (ALT) n’ont pas augmenté garantissant ainsi l’innocuité des NPs LENK-SQ après leur injection i.v. Cette étude représente une approche innovante et prometteuse permettant une distribution ciblée du neuropeptide endogène LENK dans les tissus œdémateux pour soulager efficacement la douleur inflammatoire. / Enkephalin is an endogenous pentapeptide producing potent analgesia by activating opioid receptors located on central and peripheral neuronal cell membranes. However, its clinical use has historically been limited due to pharmacokinetic issues, including restricted plasma stability and blood brain barrier impermeability. The aim of this project is to create a new enkephalin-based nanomedicine targeting pain, using biocompatible and biodegradable materials for drug delivery and targeting purposes, such as squalene (squalenoylation nanotechnology). This nanotechnology presents a new concept with numerous advantages in comparison with the conventional nanocarriers, such as high drug loading and absence of “burst release”. Here, we show for the first time, that the rapidly metabolized Leu-enkephalin (LENK) neuropeptide may become pharmacologically efficient owing to its simple conjugation with the squalene (SQ) using three different chemical linkers, i.e., dioxycarbonyl (Diox), diglycolate (Dig), or amide bond (Am). The resulting prodrugs were able to self-assemble in nanoparticles in aqueous media. This new squalene-based nanoformulation prevented rapid plasma degradation of LENK and conferred to the released neuropeptide a significant anti-hyperalgesic effect in a carrageenan-induced paw edema model in rats (Hargreaves test). It should be stressed that this effect lasted 3 times longer than morphine. Pretreatment with brain impermeant opioid receptor antagonist naloxone methiodide (Nal-M) reversed the nanoparticles induced anti-hyperalgesia, indicating that LENK-SQ NPs acted through peripherally located opioid receptors. Moreover, the biodistribution of DiD-fluorescently labeled LENK-SQ NPs showed a strong accumulation of the fluorescence within the inflamed paw as well as in the liver, spleen, and lung, while no signal could be detected in the brain, confirming the peripheral effect of LENK-SQ NPs. Toxicological studies showed that despite nanoparticles accumulation in the liver, the levels of aspartate transaminase (AST) and alanine transaminase (ALT) were not increased after i.v. injection of LENK-SQ NPs, highlighting thus their safety. This study represents a novel drug targeting approach, allowing the specific delivery of LENK neuropeptide into inflamed tissues for pain alleviation. Nanomédecine Leu-Enképhaline Squalène Hyperalgésie Douleur inflammatoire Récepteurs opioïdes périphériques Nanomedicine Leu-Enkephalin Squalene Hyperalgesia Inflammatory pain Peripheral opioid receptors
25	NMR as a tool in drug research : Structure elucidation of peptidomimetics and pilicide-chaperone complexes Hedenström, Mattias January 2004 (has links) In the last decades NMR spectroscopy has become an invaluable tool both in academic research and in the pharmaceutical industry. This thesis describes applications of NMR spectroscopy in biomedicinal research for structure elucidation of biologically active peptides and peptidomimetics as well as in studies of ligand-protein interactions. The first part of this thesis describes the theory and methodology of structure calculations of peptides using experimental restraints derived from NMR spectroscopy. This methodology has been applied to novel mimetics of the peptide hormones desmopressin and Leu-enkephalin. The results of these studies highlight the complicating issue of conformational exchange often encountered in structural determination of peptides and how careful analysis of experimental data as well as optimization of experimental conditions can enable structure determinations in such instances. Although the mimetics of both desmopressin and Leu-enkephalin were found to adopt the wanted conformations, they exhibited no or very poor biological activity. These results demonstrate the difficulties in designing peptidomimetics without detailed structural information of the receptors. A stereoselective synthetic route towards XxxΨ[CH2O]Ala pseudodipeptides is also presented. Such pseudodipeptides can be used as isosteric amide bond replacements in peptides in order to increase their resistance towards proteolytic degradation. The second part of this thesis describes the study of the interaction between compounds that inhibit pilius assembly, pilicides, and periplasmic chaperones from uropathogenic Escherichia coli. Periplasmic chaperones are key components in assembly of pili, i.e. hair-like protein complexes located on the surface of Escherichia coli that cause urinary tract infections. Detailed knowledge about this interaction is important in understanding how pilicides can inhibit pilus assembly by binding to chaperones. Relaxation-edited NMR experiments were used to confirm the affinity of the pilicides for the chaperones and chemical shift mapping was used to study the pilicide-chaperone interaction surface. These studies show that at least two interaction sites are present on the chaperone surface and consequently that two different mechanisms resulting in inhibition of pilus assembly may exist. Organic chemistry NMR structure calculations peptidomimetics desmopressin Leu-enkephalin chemical shift mapping pilicides chaperones urinary tract infections. Organisk kemi Organic chemistry Organisk kemi
26	A Single Neonatal Injury Induces Life-Long Adaptations In Stress And Pain Responsiveness Victoria, Nicole C 27 August 2013 (has links) Approximately 1 in 6 infants are born prematurely each year. Typically, these infants spend 25 days in the Neonatal Intensive Care Unit (NICU) where they experience 10-18 painful and inflammatory procedures each day. Remarkably, pre-emptive analgesics and/or anesthesia are administered less than 30% of the time. Unalleviated pain during the perinatal period is associated with permanent decreases in pain sensitivity, blunted cortisol responses and high rates of neuropsychiatric disorders. To date, the mechanism(s) by which these long-term changes in stress and pain behavior occur, and whether such alterations can be prevented by appropriate analgesia at the time of injury, remains unclear. We have previously reported in rats that inflammation experienced on the day of birth permanently upregulates central opioid tone, resulting in a significant reduction in adult pain sensitivity. However, the impact on early life pain on anxiety- and stress-related behavior and HPA axis regulation is not known. Therefore the goal of this dissertation was to determine the long-term impact of a single neonatal inflammatory pain experience on adult anxiety- and stress-related responses. Neuroanatomical changes in stress-associated neurocircuits were also examined. As the endogenous pain control system and HPA axis are in a state of exaggerated developmental plasticity early in postnatal life, and these systems work in concert to respond to noxious or aversive stimuli, this dissertation research aimed to answer the following questions: (1) Does neonatal injury produce deficits in adult stress-related behavior and alter stress-related neuroanatomy through an opioid-dependent mechanism? (2) Does neonatal injury alter receptor systems regulating the activation and termination of the stress response in adulthood? (3) Are stress- and pain-related neurotransmitters altered within the first week following early life pain? (4) Is early activation of the pain system necessary for the long-term changes in anxiety- and stress-related behavior? Together these studies demonstrate the degree, severity and preventability of the long-term deficits in stress responding associated with a single painful experience early in life. The goal of this research is to promote change in the treatment of infant pain in the NICU to reduce long-term sensory and mental health complications associated with prematurity. Hypothalamic pituitary adrenal axis Amygdala Lateral septum Periaqueductal gray Corticosterone Glucocorticoid receptor Endogenous opioids Enkephalin Endorphin Morphine
27	A Single Neonatal Injury Induces Life-Long Adaptations In Stress And Pain Responsiveness Victoria, Nicole C 27 August 2013 (has links) Approximately 1 in 6 infants are born prematurely each year. Typically, these infants spend 25 days in the Neonatal Intensive Care Unit (NICU) where they experience 10-18 painful and inflammatory procedures each day. Remarkably, pre-emptive analgesics and/or anesthesia are administered less than 30% of the time. Unalleviated pain during the perinatal period is associated with permanent decreases in pain sensitivity, blunted cortisol responses and high rates of neuropsychiatric disorders. To date, the mechanism(s) by which these long-term changes in stress and pain behavior occur, and whether such alterations can be prevented by appropriate analgesia at the time of injury, remains unclear. We have previously reported in rats that inflammation experienced on the day of birth permanently upregulates central opioid tone, resulting in a significant reduction in adult pain sensitivity. However, the impact on early life pain on anxiety- and stress-related behavior and HPA axis regulation is not known. Therefore the goal of this dissertation was to determine the long-term impact of a single neonatal inflammatory pain experience on adult anxiety- and stress-related responses. Neuroanatomical changes in stress-associated neurocircuits were also examined. As the endogenous pain control system and HPA axis are in a state of exaggerated developmental plasticity early in postnatal life, and these systems work in concert to respond to noxious or aversive stimuli, this dissertation research aimed to answer the following questions: (1) Does neonatal injury produce deficits in adult stress-related behavior and alter stress-related neuroanatomy through an opioid-dependent mechanism? (2) Does neonatal injury alter receptor systems regulating the activation and termination of the stress response in adulthood? (3) Are stress- and pain-related neurotransmitters altered within the first week following early life pain? (4) Is early activation of the pain system necessary for the long-term changes in anxiety- and stress-related behavior? Together these studies demonstrate the degree, severity and preventability of the long-term deficits in stress responding associated with a single painful experience early in life. The goal of this research is to promote change in the treatment of infant pain in the NICU to reduce long-term sensory and mental health complications associated with prematurity. Hypothalamic pituitary adrenal axis Amygdala Lateral septum Periaqueductal gray Corticosterone Glucocorticoid receptor Endogenous opioids Enkephalin Endorphin Morphine
28	The laryngeal mucosa and the superior laryngeal nerve of the rat : an immunohistochemical and electron microscopic study Domeij, Siw January 1990 (has links) Neuropeptides are present in nerve fibers of the upper and lower airways. Local release of these substances may be of importance for the pathophysiology of airway disorders and may play a role in responses to different stimuli. However, little is known about the distribution of neuropeptides in the larynx. The superior laryngeal nerve is one of the vagal branches supplying the larynx. The aim of the present study was to investigate the fiber composition of this nerve and to analyse the distribution of different neuropeptides and mast cells in the larynx. The internal and the external branches of the superior laryngeal nerve had a similar number and size of the nerve fibers. Numerous unmyelinated fibers were evenly distributed in the branches. A large majority of the fibers were sensory myelinated and unmyelinated fibers; only a few of the myelinated fibers of the external branch ( 2-10 %) were motor. About a quarter of the unmyelinated fibers of the internal and the external branches had their cell bodies in the brainstem, and single myelinated and unmyelinated fibers emanated from the superior cervical ganglion. In every superior laryngeal nerve examined one to three spherical paraganglia were observed. These paraganglia contained cells which were similar to the type I and type II cells found in the carotid body and the paraganglia of the recurrent laryngeal nerve. Thin-walled sinusoidal blood vessels which were sometimes fenestrated were also present The laryngeal mucosa was supplied with nerve fibers exhibiting substance P- and calcitonin gene-related peptide-like immunoreactivity with regional differences in the distribution. The laryngeal side of the epiglottis and the ventral recess were richly supplied, and the vocal cords showed no evidence of immunoreactive nerve fibers. The distribution of connective tissue mast cells and mucosal mast cells/globular leucocytes was similar to that of nerve fibers displaying substance P- and calcitonin gene-related peptide-like immunoreactivity. These cells were found in close approximation to nerve fibers. Acetylcholinesterase-positive ganglionic cells in the larynx showed vasoactive intestinal polypeptide-, neuropeptide Y-and enkephalin-like immunoreactivity. Neuropeptide Y-like immunoreactivity was co-localized with tyrosine-hydroxylase/dopamine beta-hydroxylase-like immunoreactivity in nerve fibers in some blood vessel walls. Enkephalin-like immunoreactivity was rarely found in this location and co-localization with tyrosine- hydroxylase-like immunoreactivity was not detected. In glands and some blood vessel walls neuropeptide Y- and enkephalin-like immunoreactivity were localized in nerve fibers showing a positive acetylcholinesterase reaction and vasoactive intestinal polypeptide-like immunoreactivity. Thus, this indicates that neuropeptide Y is present in both the sympathetic and parasympathetic nervous systems, while enkephalin and vasoactive intestinal polypeptide are confined to the parasympathetic nervous system in the rat larynx. The present study shows that the superior laryngeal nerve is mainly sensory, and the study also provides a morphological basis for neuropeptide effects in laryngeal physiology/pathophysiology. / <p>S. 1-27: sammanfattning, s. 29-97: 6 uppsatser</p> / digitalisering@umu Superior laryngeal nerve paraganglia substance P calcitonin gene-related peptide neuropeptide Y vasoactive intestinal polypeptide enkephalin mast cells electron microscopy immunohistochemistry
29	Regulation of G-protein gated inwardly rectifying potassium channels by tyrosine phosphorylation / Ippolito, Danielle Lorraine. January 2005 (has links) Thesis (Ph. D.)--University of Washington, 2005. / Vita. Includes bibliographical references (leaves 137-167).
30	Validation of a transgenic mouse line with knockdown of mGluR5 selectively in dopamine D1receptor expressing neurons Nasr Esfahani, Ali January 2010 (has links) One of the main difficulties of addiction treatment is the high risk of relapse even after a longabstinence and fully detoxification. Therefore, discovering the underlying molecular principlesof relapse is essential. The metabotropic glutamate receptor, mGluR5, is considered to beinvolved in this aspect. One of the brain structures expressing mGluR5 is the striatum, an areawith well-established role in addiction which is largely composed of medium-sized spinyneurons (MSNs). These neurons are basically divided into two major subpopulationscharacterized based on their projections and protein properties. It is known that the mGluR5receptor is expressed on both subpopulations of MSNs. Consequently, it can be used to establishthe proportional contribution of each of MSNs subpopulations in relapse to addiction. In ourconstellation, we have generated a mouse line designed to have a selective mGluR5 knock-downin one of these subpopulations – the dopamine D1 receptor (D1R) expressing neurons. It hashowever been unclear if the expression of the transgene is indeed limited to only D1R-expressingneurons. By immunofluorescence technique, I here show that the construct is expressed only inMSNs and is restricted to the D1R-expressing cell population in the striatum. Thus the transgenicmouse line is a good tool for the study of mGluR5 selectively in D1R expressing neurons. Cocaine DARPP-32 Enkephalin GFP MSNs mGluR5 Relapse Striatum Biochemistry and Molecular Biology Biokemi och molekylärbiologi Cell Biology Cellbiologi Biochemistry and Molecular Biology Biokemi och molekylärbiologi Neurosciences Neurovetenskaper

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