970 resultados para G protein-coupled receptor kinase
Resumo:
RAMPs (receptor activity-modifying proteins) are single-pass transmembrane proteins that associate with certain family-B GPCRs (G-protein-coupled receptors). Specifically for the CT (calcitonin) receptor-like receptor and the CT receptor, this results in profound changes in ligand binding and receptor pharmacology, allowing the generation of six distinct receptors with preferences for CGRP (CT gene-related peptide) adrenomedullin, amylin and CT. There are three RAMPs: RAMP1-RAMP3. The N-terminus appears to be the main determinant of receptor pharmacology whereas the transmembrane domain contributes to association of the RAMP with the GPCR. The N-terminus of all members of the RAMP family probably contains two disulphide bonds; a potential third disulphide is found in RAMP1 and RAMP3. The N-terminus appears to be in close proximity to the ligand and plays a key role in its binding, either directly or indirectly. BIBN4096BS, a CGRP antagonist, targets RAMP1 and this gives the compound very high selectivity for the human CGRP(1) receptor.
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The increasing prevalence, variable pathogenesis, progressive natural history, and complications of type 2 diabetes emphasise the urgent need for new treatment strategies. Longacting (eg, once weekly) agonists of the glucagon-like-peptide-1 receptor are advanced in development, and they improve prandial insulin secretion, reduce excess glucagon production, and promote satiety. Trials of inhibitors of dipeptidyl peptidase 4, which enhance the effect of endogenous incretin hormones, are also nearing completion. Novel approaches to glycaemic regulation include use of inhibitors of the sodium-glucose cotransporter 2, which increase renal glucose elimination, and inhibitors of 11ß-hydroxysteroid dehydrogenase 1, which reduce the glucocorticoid effects in liver and fat. Insulin-releasing glucokinase activators and pancreatic-G-protein-coupled fatty-acid-receptor agonists, glucagon-receptor antagonists, and metabolic inhibitors of hepatic glucose output are being assessed. Early proof of principle has been shown for compounds that enhance and partly mimic insulin action and replicate some effects of bariatric surgery.
Resumo:
G protein coupled receptors (GPCRs) are highly flexible and dynamic proteins, which are able to interact with diverse ligands, effectors, and regulatory proteins. Site-directed mutagenesis (SDM) is a powerful tool for providing insight into how these proteins actually work, both in its own right and when used in conjunction with information provided by other techniques such as crystallography or molecular modelling. Mutagenesis has been used to identify and characterise a myriad of functionally important residues, motifs and domains within the GPCR architecture, and to identify aspects of similarity and differences between the major families of GPCRs. This chapter presents the necessary information for undertaking informative SDM of these proteins. Whilst this is relevant to protein structure/function studies in -general, specific pitfalls and protocols suited to investigating GPCRs in particular will be highlighted.
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Full text: The idea of producing proteins from recombinant DNA hatched almost half a century ago. In his PhD thesis, Peter Lobban foresaw the prospect of inserting foreign DNA (from any source, including mammalian cells) into the genome of a λ phage in order to detect and recover protein products from Escherichia coli [ 1 and 2]. Only a few years later, in 1977, Herbert Boyer and his colleagues succeeded in the first ever expression of a peptide-coding gene in E. coli — they produced recombinant somatostatin [ 3] followed shortly after by human insulin. The field has advanced enormously since those early days and today recombinant proteins have become indispensable in advancing research and development in all fields of the life sciences. Structural biology, in particular, has benefitted tremendously from recombinant protein biotechnology, and an overwhelming proportion of the entries in the Protein Data Bank (PDB) are based on heterologously expressed proteins. Nonetheless, synthesizing, purifying and stabilizing recombinant proteins can still be thoroughly challenging. For example, the soluble proteome is organized to a large part into multicomponent complexes (in humans often comprising ten or more subunits), posing critical challenges for recombinant production. A third of all proteins in cells are located in the membrane, and pose special challenges that require a more bespoke approach. Recent advances may now mean that even these most recalcitrant of proteins could become tenable structural biology targets on a more routine basis. In this special issue, we examine progress in key areas that suggests this is indeed the case. Our first contribution examines the importance of understanding quality control in the host cell during recombinant protein production, and pays particular attention to the synthesis of recombinant membrane proteins. A major challenge faced by any host cell factory is the balance it must strike between its own requirements for growth and the fact that its cellular machinery has essentially been hijacked by an expression construct. In this context, Bill and von der Haar examine emerging insights into the role of the dependent pathways of translation and protein folding in defining high-yielding recombinant membrane protein production experiments for the common prokaryotic and eukaryotic expression hosts. Rather than acting as isolated entities, many membrane proteins form complexes to carry out their functions. To understand their biological mechanisms, it is essential to study the molecular structure of the intact membrane protein assemblies. Recombinant production of membrane protein complexes is still a formidable, at times insurmountable, challenge. In these cases, extraction from natural sources is the only option to prepare samples for structural and functional studies. Zorman and co-workers, in our second contribution, provide an overview of recent advances in the production of multi-subunit membrane protein complexes and highlight recent achievements in membrane protein structural research brought about by state-of-the-art near-atomic resolution cryo-electron microscopy techniques. E. coli has been the dominant host cell for recombinant protein production. Nonetheless, eukaryotic expression systems, including yeasts, insect cells and mammalian cells, are increasingly gaining prominence in the field. The yeast species Pichia pastoris, is a well-established recombinant expression system for a number of applications, including the production of a range of different membrane proteins. Byrne reviews high-resolution structures that have been determined using this methylotroph as an expression host. Although it is not yet clear why P. pastoris is suited to producing such a wide range of membrane proteins, its ease of use and the availability of diverse tools that can be readily implemented in standard bioscience laboratories mean that it is likely to become an increasingly popular option in structural biology pipelines. The contribution by Columbus concludes the membrane protein section of this volume. In her overview of post-expression strategies, Columbus surveys the four most common biochemical approaches for the structural investigation of membrane proteins. Limited proteolysis has successfully aided structure determination of membrane proteins in many cases. Deglycosylation of membrane proteins following production and purification analysis has also facilitated membrane protein structure analysis. Moreover, chemical modifications, such as lysine methylation and cysteine alkylation, have proven their worth to facilitate crystallization of membrane proteins, as well as NMR investigations of membrane protein conformational sampling. Together these approaches have greatly facilitated the structure determination of more than 40 membrane proteins to date. It may be an advantage to produce a target protein in mammalian cells, especially if authentic post-translational modifications such as glycosylation are required for proper activity. Chinese Hamster Ovary (CHO) cells and Human Embryonic Kidney (HEK) 293 cell lines have emerged as excellent hosts for heterologous production. The generation of stable cell-lines is often an aspiration for synthesizing proteins expressed in mammalian cells, in particular if high volumetric yields are to be achieved. In his report, Buessow surveys recent structures of proteins produced using stable mammalian cells and summarizes both well-established and novel approaches to facilitate stable cell-line generation for structural biology applications. The ambition of many biologists is to observe a protein's structure in the native environment of the cell itself. Until recently, this seemed to be more of a dream than a reality. Advances in nuclear magnetic resonance (NMR) spectroscopy techniques, however, have now made possible the observation of mechanistic events at the molecular level of protein structure. Smith and colleagues, in an exciting contribution, review emerging ‘in-cell NMR’ techniques that demonstrate the potential to monitor biological activities by NMR in real time in native physiological environments. A current drawback of NMR as a structure determination tool derives from size limitations of the molecule under investigation and the structures of large proteins and their complexes are therefore typically intractable by NMR. A solution to this challenge is the use of selective isotope labeling of the target protein, which results in a marked reduction of the complexity of NMR spectra and allows dynamic processes even in very large proteins and even ribosomes to be investigated. Kerfah and co-workers introduce methyl-specific isotopic labeling as a molecular tool-box, and review its applications to the solution NMR analysis of large proteins. Tyagi and Lemke next examine single-molecule FRET and crosslinking following the co-translational incorporation of non-canonical amino acids (ncAAs); the goal here is to move beyond static snap-shots of proteins and their complexes and to observe them as dynamic entities. The encoding of ncAAs through codon-suppression technology allows biomolecules to be investigated with diverse structural biology methods. In their article, Tyagi and Lemke discuss these approaches and speculate on the design of improved host organisms for ‘integrative structural biology research’. Our volume concludes with two contributions that resolve particular bottlenecks in the protein structure determination pipeline. The contribution by Crepin and co-workers introduces the concept of polyproteins in contemporary structural biology. Polyproteins are widespread in nature. They represent long polypeptide chains in which individual smaller proteins with different biological function are covalently linked together. Highly specific proteases then tailor the polyprotein into its constituent proteins. Many viruses use polyproteins as a means of organizing their proteome. The concept of polyproteins has now been exploited successfully to produce hitherto inaccessible recombinant protein complexes. For instance, by means of a self-processing synthetic polyprotein, the influenza polymerase, a high-value drug target that had remained elusive for decades, has been produced, and its high-resolution structure determined. In the contribution by Desmyter and co-workers, a further, often imposing, bottleneck in high-resolution protein structure determination is addressed: The requirement to form stable three-dimensional crystal lattices that diffract incident X-ray radiation to high resolution. Nanobodies have proven to be uniquely useful as crystallization chaperones, to coax challenging targets into suitable crystal lattices. Desmyter and co-workers review the generation of nanobodies by immunization, and highlight the application of this powerful technology to the crystallography of important protein specimens including G protein-coupled receptors (GPCRs). Recombinant protein production has come a long way since Peter Lobban's hypothesis in the late 1960s, with recombinant proteins now a dominant force in structural biology. The contributions in this volume showcase an impressive array of inventive approaches that are being developed and implemented, ever increasing the scope of recombinant technology to facilitate the determination of elusive protein structures. Powerful new methods from synthetic biology are further accelerating progress. Structure determination is now reaching into the living cell with the ultimate goal of observing functional molecular architectures in action in their native physiological environment. We anticipate that even the most challenging protein assemblies will be tackled by recombinant technology in the near future.
Resumo:
G-protein-coupled receptors (GPCRs) form the largest class of membrane proteins and are an important target for therapeutic drugs. These receptors are highly dynamic proteins sampling a range of conformational states in order to fulfil their complex signalling roles. In order to fully understand GPCR signalling mechanisms it is necessary to extract the receptor protein out of the plasma membrane. Historically this has universally required detergents which inadvertently strip away the annulus of lipid in close association with the receptor and disrupt lateral pressure exerted by the bilayer. Detergent-solubilized GPCRs are very unstable which presents a serious hurdle to characterization by biophysical methods. A range of strategies have been developed to ameliorate the detrimental effect of removing the receptor from the membrane including amphipols and reconstitution into nanodics stabilized by membrane scaffolding proteins (MSPs) but they all require exposure to detergent. Poly(styrene-co-maleic acid) (SMA) incorporates into membranes and spontaneously forms nanoscale poly(styrene-co-maleic acid) lipid particles (SMALPs), effectively acting like a 'molecular pastry cutter' to 'solubilize' GPCRs in the complete absence of detergent at any stage and with preservation of the native annular lipid throughout the process. GPCR-SMALPs have similar pharmacological properties to membrane-bound receptor, exhibit enhanced stability compared with detergent-solubilized receptors and being non-proteinaceous in nature, are fully compatible with downstream biophysical analysis of the encapsulated GPCR.
Resumo:
During the last decades, it has been established that there is a relationship between major depression and activation of immune system. Nociceptin/orphanin FQ (N/OFQ) is the natural ligand of a Gi-protein coupled receptor named NOP, both compose the peptidergic system wich is involved in the regulation of mood states and inflammatory responses. Considering these actions, the present thesis aimed to investigate the consequences of blocking NOP signaling in lipopolysaccharide (LPS)-induced sickness and depressive-like behaviors in mice. Systemic administration of LPS doses, that do not cause sepsis in mice, induce changes in their behaviors related with activity of pro-inflammatory cytokines tumor necrosis factor-α (TNF-α) and interleukins 6 (IL-6) and 1β (IL-1 β). At the time points of 2 to 6 h and 24 h after intraperitoneal injection, mice treated with LPS displayed, respectively, sickness and depressive-like behaviors. In the present work the administration of LPS 0.8 mg/kg (ip) significantly induced sickness signs in Swiss and CD-1 mice, such as weight loss, transient reduction in rectal temperature and decrease of food and water intake. Moreover at 24 h after LPS injection these same mice strains displayed significantly increased immobility time on the tail suspension test (TST) when compared with control mice, this alteration was not related with possible locomotion impairments as verified on the open field test. Treatment with Nortriptyline 30 mg/kg (ip, 60 min prior the TST) reduced the immobility time of control and LPS-treated mice and was used as standard antidepressant. The NOP receptor antagonist SB-612111 (10 mg/kg, ip), 30 min prior LPS, did not modify LPS-induced sickness signs and depressive-like behavior. However, when injected 24 h after LPS treatment, SB-612111 (ip, 30 min prior the TST) as well as the peptidergic NOP receptor antagonist UFP-101 (10 nmol/2μL, icv, 5 min prior the TST) significantly reversed the toxin effects. The protocol of LPS-induced depressive-like states was also tested in NOP receptor knockout mice (NOP(-/-)) and their respective wild types (NOP(+/+)). LPS evoked transient rectal temperature reduction in NOP(-/-) mice and loss of body weight, food and water intake reduction in both NOP(+/+) and NOP(-/-) mice. The consumption of water was significantly different due to the genotype. LPS injection induced transient changes in pro-inflammatory cytokines. At 6 h after LPS injection, serum levels of TNF-α were significantly increased in NOP(+/+) and NOP(-/-) mice, as the IL-6 levels were significantly increased just in NOP(+/+) serum. At 24 h after LPS treatment the pro-inflammatory cytokines had returned to the baseline levels in both genotypes. LPS treatment elicited depressive-like effects in NOP(+/+) but not in NOP(-/-) mice. The data obtained during the execution of this doctoral thesis reveal that pharmacological and genetic blockade of NOP signaling does not affect LPS evoked sickness signs while reversing depressive-like behavior. In conclusion, these results highlight the involvement of the peptidergic system N/OFQ - NOP receptor in the modulation of behaviors related to mood and activation of the immune system.
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Lors de l’attribution du prix Nobel de chimie aux docteurs Robert Leftkowitz et Brian Kobika pour leurs travaux essentiels sur les récepteurs couplés à des protéines G (RCPGs), Sven Lindin, membre du comité Nobel, a affirmé que « jusqu'à la moitié » des médicaments « reposent sur une action ciblant les RCPG ». En raison de leurs rôles importants, leurs mécanismes d'activation et l’action de leurs ligands, les RCPG demeurent les cibles potentielles de la majorité des recherches pour le développement de nouveaux médicaments et de leurs applications cliniques. Dans cette optique, nous avons concentré nos recherches à travers cette thèse pour élucider les rôles, les mécanismes d’action et les effets des ligands de trois RCPG : GPR55; GPR91 et GPR99 au cours du développement des axones des cellules ganglionnaires de la rétine (CGRs). Les résultats de nos études confirment l’expression des récepteurs lors du développement embryonnaire, postnatal et adulte des CGRs ainsi qu’au cours de l’établissement de la voie rétinothalamique. In vitro, la modulation pharmacologique et génétique de l’activité de ces RCPGs réorganise la morphologie du cône de croissance des CGRs, celle des neurones corticaux et elle modifie la croissance axonale globale. De plus, les effets de la stimulation avec des ligands des ces trois RCPGs sur le guidage axonal varient d’aucun effet (GPR91 et GPR99) à la répulsion ou l’attraction (GPR55). La voie de signalisation MAPK-ERK1/2 joue un rôle essentiel dans la médiation des effets des ligands de ces récepteurs avec une implication de la voie de RhoA à hautes concentrations pour l’agoniste endogène de GPR55. In vivo, cette recherche démontre également l’implication de GPR55 dans les processus de sélection des cibles thalamiques et de raffinement au cours du développement du système nerveux visuel.
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One aspect of the function of the beta-arrestins is to serve as scaffold or adapter molecules coupling G-protein coupled receptors (GPCRs) to signal transduction pathways distinct from traditional second messenger pathways. Here we report the identification of Dishevelled 1 and Dishevelled 2 (Dvl1 and Dvl2) as beta-arrestin1 (betaarr1) interacting proteins. Dvl proteins participate as key intermediates in signal transmission from the seven membrane-spanning Frizzled receptors leading to inhibition of glycogen synthase kinase-3beta (GSK-3beta), stabilization of beta-catenin, and activation of the lymphoid enhancer factor (LEF) transcription factor. We find that phosphorylation of Dvl strongly enhances its interaction with betaarr1, suggesting that regulation of Dvl phosphorylation and subsequent interaction with betaarr1 may play a key role in the activation of the LEF transcription pathway. Because coexpression of the Dvl kinases, CK1epsilon and PAR-1, with Dvl synergistically activates LEF reporter gene activity, we reasoned that coexpression of betaarr1 with Dvl might also affect LEF-dependent gene activation. Interestingly, whereas betaarr1 or Dvl alone leads to low-level stimulation of LEF (2- to 5-fold), coexpression of betaarr1 with either Dvl1 or Dvl2 leads to a synergistic activation of LEF (up to 16-fold). Additional experiments with LiCl as an inhibitor of GSK-3beta kinase activity indicate that the step affected by betaarr1 is upstream of GSK-3beta and most likely at the level of Dvl. These results identify betaarr1 as a regulator of Dvl-dependent LEF transcription and suggest that betaarr1 might serve as an adapter molecule that can couple Frizzled receptors and perhaps other GPCRs to these important transcription pathways.
Resumo:
Lors de l’attribution du prix Nobel de chimie aux docteurs Robert Leftkowitz et Brian Kobika pour leurs travaux essentiels sur les récepteurs couplés à des protéines G (RCPGs), Sven Lindin, membre du comité Nobel, a affirmé que « jusqu'à la moitié » des médicaments « reposent sur une action ciblant les RCPG ». En raison de leurs rôles importants, leurs mécanismes d'activation et l’action de leurs ligands, les RCPG demeurent les cibles potentielles de la majorité des recherches pour le développement de nouveaux médicaments et de leurs applications cliniques. Dans cette optique, nous avons concentré nos recherches à travers cette thèse pour élucider les rôles, les mécanismes d’action et les effets des ligands de trois RCPG : GPR55; GPR91 et GPR99 au cours du développement des axones des cellules ganglionnaires de la rétine (CGRs). Les résultats de nos études confirment l’expression des récepteurs lors du développement embryonnaire, postnatal et adulte des CGRs ainsi qu’au cours de l’établissement de la voie rétinothalamique. In vitro, la modulation pharmacologique et génétique de l’activité de ces RCPGs réorganise la morphologie du cône de croissance des CGRs, celle des neurones corticaux et elle modifie la croissance axonale globale. De plus, les effets de la stimulation avec des ligands des ces trois RCPGs sur le guidage axonal varient d’aucun effet (GPR91 et GPR99) à la répulsion ou l’attraction (GPR55). La voie de signalisation MAPK-ERK1/2 joue un rôle essentiel dans la médiation des effets des ligands de ces récepteurs avec une implication de la voie de RhoA à hautes concentrations pour l’agoniste endogène de GPR55. In vivo, cette recherche démontre également l’implication de GPR55 dans les processus de sélection des cibles thalamiques et de raffinement au cours du développement du système nerveux visuel.
Resumo:
Five G protein-coupled receptors (GPCRs) have been identified to be activated by free fatty acids (FFA). Among them, FFA1 (GPR40) and FFA4 (GPR120) bind long-chain fatty acids, FFA2 (GPR43) and FFA3 (GPR41) bind short-chain fatty acids and GPR84 binds medium-chain fatty acids. Free fatty acid receptors have now emerged as potential targets for the treatment of diabetes, obesity and immune diseases. The recent progress in crystallography of GPCRs has now enabled the elucidation of the structure of FFA1 and provided reliable templates for homology modelling of other FFA receptors. Analysis of the crystal structure and improved homology models, along with mutagenesis data and structure activity, highlighted an unusual arginine charge pairing interaction in FFA1-3 for receptor modulation, distinct structural features for ligand binding to FFA1 and FFA4 and an arginine of the second extracellular loop as a possible anchoring point for FFA at GPR84. Structural data will be helpful for searching novel small molecule modulators at the FFA receptors.
Resumo:
Ethanol, classified as a drug, affects the central nervous system, and its consumption has been linked to the development of several behaviours including tolerance and dependence. Alcohol tolerance is defined as the need for higher doses of alcohol to induce the same changes observed in the initial exposure or where repetitive exposures of the same alcohol dose induce a lower response. Ethanol has been shown to interact with numerous targets and ultimately influence both short and long term adaptation at the cellular and molecular level in brain [1]. These adaptation processes are likely to involve signalling molecules: our work has focussed on G proteins gene expression. Using both wild type and several mutant fruit fly (Drosophila melanogaster) as a model for behaviour and molecular studies, we observed significant increases in sedation time (ST50) in response to alcohol (P<0.001) Fig.A. We also observed a consistent and significant decrease of Gq protein mRNA expression in Drosophila dUNC and DopR2 mutants chronically exposed to alcohol (*P<0.05). Fig B. Method: Six male flies were observed in drosophila polystyrene 25 x 95mm transparent vial in between cotton plugs. To the top plug, 500uL of 100% ethanol was added. Time till 50% of the flies were sedated was recorded on each day following the schedule. Fig. C (n=4-6). Using RT-PCR, we also quantified G protein mRNA expression levels one hour post initial 30 minutes of ethanol expression on day 1 and day 3 relative to expression in naïve flies.(n=2) [A] Increase in sedation time indicative of tolerance in different mutant lines and wild type flies. Six male flies were used in each experiment and (n= 4-6. ***P<0.001 unpaired t tests). [B] RT-PCR results showing significant reduction in Gq mRNA in flies chronically exposed to alcohol. (n=2. *P<0.05) [C] Alcohol exposure schedule. (1) Kaun K.R., R. Azanchi, Z. Maung, J. Hirsh, U. Heberlein. (2011). A Drosophila model for alcohol reward. Nature Neuroscience. 14 (5), 612–619.
Resumo:
Les récepteurs couplés aux protéines G (RCPG) démontrent de plus en plus de capacités à activer des mécanismes jusqu’alors associés à des facteurs de transcription ou des molécules d’adhésion. En effet, de nouvelles preuves rapportent qu’ils pourraient également participer au guidage axonal qui est le mécanisme permettant aux axones de cellules nerveuses de rejoindre leur cible anatomique. Le guidage axonal se fait par l’interaction entre les molécules de guidage et une structure particulière présente à l’extrémité de l’axone, le cône de croissance. Par exemple, les RCPGs participent au guidage des cellules ganglionnaires de la rétine (CGR), dont les axones s’étendent de la rétine jusqu’au noyaux cérébraux associés à la vision. Cet effet est observé avec des RCPGs tels que les récepteurs aux cannabinoïdes (CB1 et CB2) et celui du lysophosphatidylinositol, le GPR55. Les RCPGs GPR91 et GPRG99, respectivement récepteurs au succinate et à l’α-cétoglutarate, se trouvent à la surface de ces CGRs, ce qui en font des candidats potentiels pouvant participer au guidage axonal. Dans ce mémoire, l’effet des ligands de ces récepteurs sur la croissance et la navigation des axones des CGRs fut analysé. L’impact produit par ces récepteurs ainsi que leurs ligands sur la morphologie des cônes de croissance fut déterminé en mesurant leur taille et le nombre de filopodes présents sur ces cônes. Pour évaluer le rôle du succinate et de l’a-cétoglutarate sur la croissance globale des axones de CGRs, la longueur totale des projections axonales d’explants rétiniens a été mesurée. L’effet de ces ligands des récepteurs GPR91 et GPR99 sur le guidage axonal a également été évalué en temps réel à l’aide d’un gradient créé par un micro injecteur placé à 45° et à 100µm du cône de croissance. La distribution in vivo des récepteurs GPR91 et GPR99 sur la rétine a été étudié à l’aide d’expériences d’immunohistochimie. Les résultats obtenus indiquent que l’ajout de 100µM de succinate produit une augmentation de la taille des cônes de croissance et du nombre de filopodes présents à leur surface. Il augmente également la croissance des axones. Ce type de réponse fut également observé lorsque les cellules furent soumises à 200µM d’α-cétoglutarate. Fait à noter, les deux récepteurs n’ont pas d’impact sur le guidage axonal. Ces résultats indiquent donc que les agonistes des récepteurs GPR91 et GPR99 augmentent la croissance des cellules ganglionnaires lorsqu’ils sont présents lors du développement. Par contre, ils n’ont pas d’influence sur la direction prise par les cônes de croissance. Ces nouvelles données sont un pas de plus dans la compréhension des mécanismes qui gèrent et participent au développement et la croissance des CGRs, ce qui pourrait donner de nouvelles cibles thérapeutique pouvant mener à la régénération de nerfs optiques endommagés.
Resumo:
Les récepteurs couplés aux protéines G (RCPG) démontrent de plus en plus de capacités à activer des mécanismes jusqu’alors associés à des facteurs de transcription ou des molécules d’adhésion. En effet, de nouvelles preuves rapportent qu’ils pourraient également participer au guidage axonal qui est le mécanisme permettant aux axones de cellules nerveuses de rejoindre leur cible anatomique. Le guidage axonal se fait par l’interaction entre les molécules de guidage et une structure particulière présente à l’extrémité de l’axone, le cône de croissance. Par exemple, les RCPGs participent au guidage des cellules ganglionnaires de la rétine (CGR), dont les axones s’étendent de la rétine jusqu’au noyaux cérébraux associés à la vision. Cet effet est observé avec des RCPGs tels que les récepteurs aux cannabinoïdes (CB1 et CB2) et celui du lysophosphatidylinositol, le GPR55. Les RCPGs GPR91 et GPRG99, respectivement récepteurs au succinate et à l’α-cétoglutarate, se trouvent à la surface de ces CGRs, ce qui en font des candidats potentiels pouvant participer au guidage axonal. Dans ce mémoire, l’effet des ligands de ces récepteurs sur la croissance et la navigation des axones des CGRs fut analysé. L’impact produit par ces récepteurs ainsi que leurs ligands sur la morphologie des cônes de croissance fut déterminé en mesurant leur taille et le nombre de filopodes présents sur ces cônes. Pour évaluer le rôle du succinate et de l’a-cétoglutarate sur la croissance globale des axones de CGRs, la longueur totale des projections axonales d’explants rétiniens a été mesurée. L’effet de ces ligands des récepteurs GPR91 et GPR99 sur le guidage axonal a également été évalué en temps réel à l’aide d’un gradient créé par un micro injecteur placé à 45° et à 100µm du cône de croissance. La distribution in vivo des récepteurs GPR91 et GPR99 sur la rétine a été étudié à l’aide d’expériences d’immunohistochimie. Les résultats obtenus indiquent que l’ajout de 100µM de succinate produit une augmentation de la taille des cônes de croissance et du nombre de filopodes présents à leur surface. Il augmente également la croissance des axones. Ce type de réponse fut également observé lorsque les cellules furent soumises à 200µM d’α-cétoglutarate. Fait à noter, les deux récepteurs n’ont pas d’impact sur le guidage axonal. Ces résultats indiquent donc que les agonistes des récepteurs GPR91 et GPR99 augmentent la croissance des cellules ganglionnaires lorsqu’ils sont présents lors du développement. Par contre, ils n’ont pas d’influence sur la direction prise par les cônes de croissance. Ces nouvelles données sont un pas de plus dans la compréhension des mécanismes qui gèrent et participent au développement et la croissance des CGRs, ce qui pourrait donner de nouvelles cibles thérapeutique pouvant mener à la régénération de nerfs optiques endommagés.
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Background: Melanoma progression occurs through three major stages: radial growth phase (RGP), confined to the epidermis; vertical growth phase (VGP), when the tumor has invaded into the dermis; and metastasis. In this work, we used suppression subtractive hybridization (SSH) to investigate the molecular signature of melanoma progression, by comparing a group of metastatic cell lines with an RGP-like cell line showing characteristics of early neoplastic lesions including expression of the metastasis suppressor KISS1, lack of alpha v beta 3-integrin and low levels of RHOC. Methods: Two subtracted cDNA collections were obtained, one (RGP library) by subtracting the RGP cell line (WM1552C) cDNA from a cDNA pool from four metastatic cell lines (WM9, WM852, 1205Lu and WM1617), and the other (Met library) by the reverse subtraction. Clones were sequenced and annotated, and expression validation was done by Northern blot and RT-PCR. Gene Ontology annotation and searches in large-scale melanoma expression studies were done for the genes identified. Results: We identified 367 clones from the RGP library and 386 from the Met library, of which 351 and 368, respectively, match human mRNA sequences, representing 288 and 217 annotated genes. We confirmed the differential expression of all genes selected for validation. In the Met library, we found an enrichment of genes in the growth factors/receptor, adhesion and motility categories whereas in the RGP library, enriched categories were nucleotide biosynthesis, DNA packing/repair, and macromolecular/vesicular trafficking. Interestingly, 19% of the genes from the RGP library map to chromosome 1 against 4% of the ones from Met library. Conclusion: This study identifies two populations of genes differentially expressed between melanoma cell lines from two tumor stages and suggests that these sets of genes represent profiles of less aggressive versus metastatic melanomas. A search for expression profiles of melanoma in available expression study databases allowed us to point to a great potential of involvement in tumor progression for several of the genes identified here. A few sequences obtained here may also contribute to extend annotated mRNAs or to the identification of novel transcripts.
Resumo:
We analyzed the mouse Representative Transcript and Protein Set for molecules involved in brain function. We found full-length cDNAs of many known brain genes and discovered new members of known brain gene families, including Family 3 G-protein coupled receptors, voltage-gated channels, and connexins. We also identified previously unknown candidates for secreted neuroactive molecules. The existence of a large number of unique brain ESTs suggests an additional molecular complexity that remains to be explored. A list of genes containing CAG stretches in the coding region represents a first step in the potential identification of candidates for hereditary neurological disorders.
