Insights Into Cytostatic Mechanisms Regulated By Receptor Guanylyl Cyclase C

Basu, Nirmalya

07 1900

All cells are equipped to sense changes in their environment and make adaptive responses according to the stimuli. Signal recognition usually occurs at the cell membrane (with the exception of steroid signalling) where the ligand, which can be a small molecule, a peptide or a protein, binds its cognate receptor. This results in a change in the conformation of the receptor which in turn can regulate the production of second messengers. Second messengers can now modulate specific pathways which control gene expression and modify various aspects of cell behaviour. The signalling cascade is terminated by the removal of second messenger and/or by desensitisation of the receptor to the extracellular signal. Cyclic guanosine monophosphate (cGMP) was first identified in the rat urine and since then has emerged as an important second messenger regulating diverse cell processes. Subsequent to its discovery in mammalian cells, enzymes responsible for its synthesis (guanylyl cyclases), hydrolysis (phosphodiesterases) and its most common effectors (cGMP-dependent protein kinases) were identified. Guanylyl cyclases exist in two forms, cytosolic and membrane bound. Both have a conserved guanylyl cyclase domain, but differ in their choice of ligands, overall structure and tissue localization. It is now known that cytosolic and the membrane-bound forms are involved in eliciting distinct cellular responses. Receptor guanylyl cyclase C (GC-C) was identified as the target for a family of heat-stable enterotoxin toxins (ST) produced by enterotoxigenic E.coli. Stable toxin-mediated diarrhoeas are observed frequently in infants and contribute significantly to the incidence of Travellers’ Diarrhea. Early studies demonstrated that the effects of ST were mediated by an increase in intracellular cGMP levels in intestinal cells, and the receptor for ST was almost exclusively expressed in the apical microvilli of the intestinal brush-border epithelia. Effectors of cGMP in intestinal cells include protein kinase G (PKG), cyclic nucleotide gated ion channel 3 (CNG), and the cystic fibrosis transmembrane conductance regulator (CFTR). ST is an exogenous ligand which serves as a hyperagonist for GC-C, in comparison with the endogenous ligands guanylin and uroguanylin, which maintain fluid-ion homeostasis in the intestinal epithelia. The GC-C/cGMP signal transduction pathway also modulates intestinal cell proliferation along the crypt-villus axis by exerting a cytostatic effect on the epithelial cells, thereby regulating their turnover and neoplastic transformation. The current study describes in molecular detail two signalling pathways, one impinging on and one emerging from GC-C, which regulate colonic cell proliferation. The first part identifies the cross-talk and cross-regulation of GC-C and c-src. The second part delves into the molecular basis of GC-C/cGMP-mediated cytostasis and its effect on colonic tumorigenesis. Cross-talk between signalling pathways is believed to play a key role in regulating cell physiology. Phosphorylation of signalling molecules by protein kinases is frequently used as a means of achieving this cross-regulation. Aberrant hyperactivation of the c-src tyrosine kinase is an early event in the progression of colorectal cancer, and activated c-src specifically phosphorylates a number of proteins in the cell. It was found that c-src can phosphorylate GC-C in T84 colorectal carcinoma cells, as well as in the rat intestinal epithelia. Tyrosine phosphorylation of GC-C resulted in attenuation of ligand-mediated cGMP production; an effect which was reversed by chemical or transcriptional knockdown of c-src. These effects were found to be cell line-independent and relied only on the extent of c-src expression and activation in the cell. Mutational analysis revealed GC-C to be phosphorylated on a conserved tyrosine residue (Y820) in the guanylyl cyclase domain. The sequence of GC-C around Y820 allowed for efficient phosphorylation by c-src, and indeed, kinase assays indicated that the affinity of c-src for the GC-C Y820 peptide was one of the highest reported till date. A phospho-mimetic mutation at this site, which mimics a constitutively phosphorylated receptor, resulted in a sharp reduction of guanylyl cyclase activity of the receptor, reiterating the inhibitory role of Y820 phosphorylation on GC-C activity. Phosphorylation of GC-C at Y820 generated a docking site for the SH2 domain of c-src which could interact and thereby co-localize with GC-C on the cell membrane. Intriguingly, this interaction resulted in activation of c-src, setting-up a feed-forward loop of inhibitory GC-C phosphorylation and c-src activation. Treatment of colorectal carcinoma cells with ligands for GC-C reduces cell proliferation and inhibits tumorigenesis. It was observed that this cytostatic effect can be modulated by the status of c-src activation, and consequently, the fraction of tyrosine phosphorylated GC-C in these cells. Since activation of c-src is a frequent event in intestinal neoplasia, phosphorylation of GC-C by active c-src may be one of the means by which the cytostatic effects of GC-C agonists (guanylin and uroguanylin) in the intestine are bypassed, thereby leading to cancer progression. Colonisation of the gut with enteropathogenic microorganisms induces secretion of IFNγ from the host mucosal immune system, which subsequently activates c-src in intestinal epithelial cells. Ligand-stimulated activity of GC-C was found to be reduced in IFNγ treated cells. This could be one of the host defence mechanisms initiated in response to enterotoxigenic E. coli infection. These results provide the first evidence of cross-talk between a receptor guanylyl cyclase and a tyrosine kinase that results in heterologous desensitisation of the receptor. Populations with a higher incidence of enterotoxigenic E.coli infections appear to be protected from intestinal neoplasia. It was found that mice lacking GC-C, and therefore unable to respond to ST, displayed an increased cell proliferation in colonic crypts and enhanced carcinogen-induced aberrant crypt foci formation, which is a surrogate marker for colorectal carcinogenesis. However, pharmacological elevation of cGMP was able to efficiently induce cytostasis even in GC-C knockout mice, indicating a key role for cGMP in regulating colonic cell proliferation. Through microarray analyses, genes regulated by ST-induced GC-C activation in T84 colorectal carcinoma cells were identified. Genes involved in a number of cellular pathways were differentially expressed, including those involved in signal transduction, protein and solute secretion, transcriptional regulation and extracellular matrix formation. One of the genes found to be significantly up-regulated was the cell-cycle inhibitor, p21. The increase in p21 expression was validated at both the transcript and protein level. This p53-independent up-regulation of p21 was coupled to the activation of the cGMP-responsive kinase, PKGII, since knockdown of PKGII using specific siRNAs abolished ST-induced p21 induction. Activation of PKGII led to phosphorylation and activation of the stress responsive p38 MAPK. Similar to what was seen following knockdown of PKGII, inhibition of p38 MAPK activity attenuated the up-regulation of p21 in response to cGMP, indicating that PKGII and p38 MAPK could be a part of a pathway regulating p21 expression. It was found that active p38 MAPK phosphorylated the ubiquitous transcription factor SP1, enhancing its occupancy at the proximal p21 promoter. Therefore, SP1 could be one of the factors linking cGMP to transcription of the p21 mRNA. Chronic activation of GC-C led to nuclear accumulation of p21 in colonic cells, which entered a quiescent state. These cells arrested in the G1 phase of the cell cycle, consequent to p21-dependent inhibition of the G1 cyclin-CDK complexes. A fraction of these quiescent cells stochastically initiated a cGMP-dependent senescence programme and displayed all the hallmarks of senescent cells, including flattened cell morphology, expression of SA- galactosidase and formation of senescence-associated heterochromatic foci. Activation of senescence and loss of tumorigenicity in these cells was crucially dependent on the up-regulation of p21. This irreversible exit from the cell cycle due to cGMP-mediated activation of the PKGII/p38/p21 axis was well correlated with reduced colonic polyp formation in mice exposed to ST. In summary, these observations may provide a possible explanation for the low incidence of colorectal carcinoma seen in countries with a high incidence of ST-mediated diarrhoea. Interestingly, c-src mediated tyrosine phosphorylation of GC-C prevented p21 accumulation following ligand application. The findings described in this thesis may have important implications in understanding the molecular mechanisms involved in the progression and treatment of colorectal cancer.

Protein Receptors

Guanylyl Cyclase C (GC-C)

Colorectal Carcinoma Cells

Cyclic GMP-Mediated Regulation

Colonic Cell Proliferation

Colorectal Carcinoma

Colorectal Cancer

Intestinal Epithelia

Guanylyl Cyclases

Molecular Biology

Plateforme Nano Bio Intelligente : membrane biomimétique pour la reconstitution d'une cascade calmoduline dépendante / Intelligent Nano Bio Platform : Biomimetic membrane for the reconstitution of a Calmodulin dependent cascade

Veneziano, Rémi

25 November 2013

L'objectif principal de ces travaux de thèse est de développer des modèles membranaires biomimétiques pour la reconstitution et l'étude d'interactions protéine/membrane. Dans ce but, deux approches sont adoptées : l'une mettant en œuvre une plateforme basée sur des nanoparticules de silice/Au recouvertes de lipides et l'autre comprenant la formation de bicouches lipidiques découplées d'un support solide d'or. Dans la première approche, nous avons synthétisé des particules de silice de taille nanométrique contenant des grains d'or inclus dans la matrice silicique. Ces nanoparticules sont ensuite recouvertes par différents phospholipides. Les propriétés plasmoniques acquises grâce aux grains d'or sont caractérisées puis utilisées pour suivre l'interaction avec les lipides et/ou les protéines. Le suivi de ces interactions est également visualisé par analyse de la mobilité électrophorétique des particules. La deuxième stratégie développée, consiste à assembler un système membranaire sur une surface solide d'or. Dans un premier temps, une couche de calmoduline est liée à la surface de manière stable. Dans un deuxième temps, une bicouche est formée au-dessus de la couche de calmoduline par deux méthodes. La première méthode consiste à ancrer la bicouche directement sur la couche de protéine par un mécanisme faisant intervenir des lipides chélateurs. Alors que dans la deuxième méthode les lipides sont liés à la surface et découplés grâce à l'utilisation d'une surface d'or modifiée par de la cystéamine et à des lipides fonctionnalisés. L'ancrage est assuré par des groupements succinimidyl et le découplage par des polymères de polyéthylène glycol porté sur un même lipide. Dans les deux stratégies, un réservoir sub-membranaire est créé entre la bicouche étanche et le support. Le suivi des constructions moléculaires est réalisé par résonance plasmonique de surface et analyse du retour de fluorescence. De plus le système est implémenté par des électrodes afin d'étudier l'effet d'application de potentiel sur la bicouche. Après caractérisation, le modèle membranaire est validé par la reconstitution de la translocation de la toxine CyaA de Bordetella pertussis. Cette protéine dispose en effet d'un mécanisme d'internalisation singulier qui permet d'explorer tout le potentiel de notre modèle membranaire. / The main objective of this work is to develop biomimetic membrane models for the reconstitution and study of protein/membrane interaction. Two devices were designed: one operate a nanometric platform composed of phospholipids coated lipid silica/Au nanoparticles, while the other including tethered lipid bilayer reconstitution on a gold surface. The first approach needs the synthesis of nanometer sized gold/silica particles and that are subsequently coated with different phospholipids. The plasmonic properties provided by gold seeds are characterized and they are of utility to follow the interaction between lipids and/or proteins at the surface. Following of these interactions was also realized with electrophoretic mobility analysis. The second biomimetic device involves a membrane assembly on a gold surface. In a first time, a calmodulin layer is bound on the surface. In a second time, a lipid bilayer is assembled above the calmodulin layer by two approaches. In the first approach the lipid bilayer is anchored on the protein layer with chelators lipid and His-Tag bearing by the proteins. While, in the second approach, lipids are bound on the surface and tethered with the use of a cysteamin modified gold surface and functionalized lipids. The anchorage is realized by succinimidyl group and the tethering by polyethylene glycol group wearing by one kind of lipid. A sub-membrane reservoir is created under the lipid bilayer. The biomimetic model formation was followed by plasmonic resonance and fluorescence recovery after photobleaching. After their characterization the tethered model is validated by reconstitution of a particular mechanism: the CyaA toxin from Bordetella pertussis translocation.

Membrane Biomimétique

Cascade calmoduline dépendante

Resonance plasmonique de surface

Toxine CyaA

Nanoparticules de silice

Adénylate cyclase

Biomimetic Membrane

Calmodulin dependent cascade

Surface plasmon resonance

CyaA Toxin

Silica nanoparticles

Adenylate cyclase

Caractérisation fonctionnelle de nouvelles isoformes d'adénylyl cyclase 8 identifiées dans les cellules musculaires lisses vasculaires trans-différenciées / Functional characterization of new adenylyl cyclase 8 isoforms identified in trans-differentiated vascular smooth muscle cells

Vallin, Benjamin

29 June 2017

La trans-différenciation des cellules musculaires lisses vasculaires (CMLV) vers un phénotype migratoire, prolifératif et sécrétoire joue un rôle clé dans la progression des lésions athéromateuses et l’hyperplasie intimale qui sous-tend la resténose post-angioplastie. Nos travaux suggèrent que la transition phénotypique des CMLV implique, chez le rat, la souris et l’Homme, l’expression de novo de l’Adénylyl Cyclase 8 (AC8), une enzyme catalysant la synthèse de l’AMP cyclique (AMPc) (Clément et al., 2006; Gueguen et al., 2010; Keuylian et al., 2012; résultats non publiés). Ce travail de thèse avait pour objectif d’appréhender le rôle de l’AC8 dans la trans-différenciation des CMLV en évaluant son impact sur la signalisation AMPc. L’étude des dynamiques de production du second messager avec le biosenseur T-Epac-VV montre que l’AC8 inhibe les hausses d’AMPc dans les CMLV trans-différenciées à l’Interleukine-1β. Cette fonction non canonique est assurée par de nouvelles isoformes d’AC8 que nous avons identifiées et clonées, les AC8E1 à 4, qui partagent une délétion des cinq premiers domaines transmembranaires. Des dosages de l’accumulation d’AMPc couplés à des expériences de co-immunoprécipitation et d’immunocytochimie révèlent que les AC8E exprimées de façon hétérologue dans des cellules HEK s’hétéro-dimérisent avec les AC en transit dans le réticulum, suppriment leur activité enzymatique et préviennent leur adressage à la membrane plasmique. L’induction des AC8E dans les CMLV trans-différenciées pourrait prévenir les effets vasculoprotecteurs de l’AMPc (Douglas et al., 2005; Katakami et al., 2010), favorisant ainsi l’acquisition et/ou le maintien du phénotype synthétique. / The phenotypic switch of vascular smooth muscle cells (VSMC) towards a migratory, proliferative and secretory state plays a key role in atherosclerotic plaque expansion and intimal hyperplasia leading to post-angioplasty restenosis. Our previous results suggest that the trans-differentiation of rat, mouse and human VSMC involves the de novo expression of the Adenylyl Cyclase 8 (AC8), an enzyme that catalyzes the synthesis of cyclic AMP (cAMP) (Clement et al., 2006; Gueguen et al., 2010; Keuylian et al., 2012; unpublished results). The main goal of my PhD was to decipher the impact of AC8 expression on cAMP signaling in trans-differentiated VSMC. Using the FRET-based biosensor T-Epac-VV, we showed that the de novo expression of AC8 limits increases in cellular cAMP. This non-canonical function relies on a new family of AC8 isoforms that we have identified and cloned: the AC8E1 to 4. They share a common deletion of the first five transmembrane domains. The biochemical characterization of AC8E over-expressed in HEK cells allowed us to elucidate their functioning. cAMP accumulation assays, co-immunoprecipitation experiments and immunocytochemistry revealed that AC8E hetero-dimerize with functional AC during their maturation in the reticulum, suppress their enzymatic activity and prevent their traffic to the plasma membrane. Numerous studies have shown that increases in cAMP concentration within trans-differentiated VSMC antagonize pathological vascular remodeling (Douglas et al., 2005; Katakami et al., 2010). Thus, the induction of AC8E in trans-differentiated VSMC could prevent the vasculoprotective effects of cAMP and promote the acquisition of a synthetic phenotype.

Cellule musculaire lisse vasculaire

Trans-différenciation

AMP cyclique

Adénylyl cyclase 8

Hétéro-dimérisation

Dominant-négatif

Vascular smooth muscle cell

Adenylyl cyclase 8

Cyclic AMP

612.74

THE POLYKETIDE ORIGINS OF CANNABINOIDS IN CANNABIS SATIVA

2013 October 1900

Phytocannabinoids are the active substances responsible for the medicinal and psychotropic effects of Cannabis sativa. Although the bioactivity of cannabis and its preparations have been known for millennia, several steps in the biosynthetic pathway leading to phytocannabinoids remain unclear. Phytocannabinoids are prenylated resorcylic acids which are formed in specialized plant organs called glandular trichomes. Following the analysis of a pre-generated cannabis trichome cDNA library, a type III polyketide synthase (tetraketide synthase; TKS) was identified and assayed, yielding three major compounds, hexanoyl triacetic acid lactone (HTAL), pentyl diacetic acid lactone (PDAL), and olivetol, yet no resorcylic acid was detected. This lack of resorcylic acid in enzyme assays has instigated the characterization of TKS and a search for putative cyclases in the cannabis trichome cDNA library, and involved protein pulldown, co-immunoprecipitation, and co-assay experiments. These experiments led to the discovery of a novel polyketide cyclase protein named olivetolic acid cyclase (OAC) responsible for the proper cyclization of a polyketide intermediate produced by TKS. This thesis shows that TKS assays conducted with OAC produce olivetolic acid (OA), an intermediate required during the biosynthesis of cannabinoids. The TKS/OAC spatial relationship was also investigated following the creation of fluorescent fusion proteins which show that the enzymes co-localized in vivo when viewed with confocal microscopy. Furthermore, yeast two-hybrid assays using TKS and OAC were performed to establish whether the enzymes physically interact. Finally, an attempt to determine the responsible amino acids involved in OAC’s mechanism was conducted by comparing the activity of single point OAC mutants with the wild-type OAC. Based on the available data, mechanisms for the production of HTAL, PDAL, olivetol, and OA are proposed.

polyketide

cyclase

polyketide synthase

cyclization

cannabinoid

cannabis

marijuana

hemp

THC

tetrahydrocannabinol

olivetolic acid

olivetol

olivetolic acid cyclase

tetraketide synthase

dimeric α + β barrel

stress response

trichome

Σχεδιασμός-διερεύνηση της σύνθεσης νέων υποψήφιων ενεργοποιητών της διαλυτής γουανυλικής κυκλάσης & νέων ινδολοαζεπινονικών παραγώγων ως πιθανοί αναστολείς του ενζύμου κυκλινο-εξαρτώμενη κινάση 1 (CDK1)

Ρουμανά, Αγγελική

20 February 2014

Πολλές παθήσεις του καρδιαγγειακού συστήματος σχετίζονται με την λειτουργία του ενζύμου της διαλυτής γουανυλικής κυκλάσης (soluble guanylate cyclase, sGC). Η sGC εμπλέκεται στο μονοπάτι ΝΟ-sGC-cGMP το οποίο ενεργοποιείται από το βιολογικά διαθέσιμο μονοξείδιο του αζώτου (nitric oxide, ΝΟ). Πολλές παθολογικές καταστάσεις αντιμετωπίστηκαν για πάνω από 140 χρόνια με τη χρήση φαρμάκων που παρέχουν NO (ΝΟ-φάρμακα), χωρίς ωστόσο να είναι γνωστός ο μηχανισμός δράσης τους. Αν και τα φάρμακα αυτά συνεισέφεραν στη βελτίωση των παθολογικών καταστάσεων, ωστόσο παρουσίαζαν σημαντικά μειονεκτήματα. Για την αντιμετώπιση αυτών, το ενδιαφέρον στράφηκε στον σχεδιασμό και την σύνθεση ενώσεων των οποίων η δράση θα ήταν ανεξάρτητη από το ΝΟ. Μεταξύ αυτών, τα παράγωγα BAY 58-2667 και η HMR 1766 αποδείχθηκαν ενεργοποιητές της sGC. Στα πλαίσια της παρούσας μελέτης, σχεδιάσθηκαν και συντέθηκαν έξι νέα βενζοφουρανικά ανάλογα του HMR-1766, σε μία προσπάθεια ανακάλυψης νέων ενώσεων, ενεργοποιητών της sGC με ενισχυμένη δραστικότητα και εκλεκτικότητα δράσης. Η προσέγγιση που ακολουθήθηκε για την σύνθεση των τελικών προϊόντων περιελάμβανε την ανοικοδόμηση του βενζοφουρανικού δακτυλίου από υποκατεστημένα παράγωγα σαλικυλικού οξέος και την μετέπειτα σύζευξη αυτού με κατάλληλους δομικούς λίθους για τον σχηματισμό μίας σουλφοναμιδικής και μίας αμιδικής πλευρικής αλυσίδας. Στα πλαίσια της μελέτης, διερευνήθηκαν και βελτιστοποιήθηκαν όλα τα συνθετικά στάδια για την παραλαβή των ενδιάμεσων και των τελικών προϊόντων. Η μελλοντική αποτίμηση της βιολογικής δράσης των νέων ενώσεων αναμένεται να διευκρινίσει αν οι ενώσεις αυτές είναι ικανές να δράσουν ως ενεργοποιητές της sGC, αλλά και αν μπορούν να αποτελέσουν χρήσιμα χημικά εργαλεία για την διευκρίνιση δομικών πληροφοριών του ενζύμου. Το δεύτερο τμήμα της παρούσας εργασίας, αφορά στον σχεδιασμό και την σύνθεση νέων αναλόγων του φυσικού προιόντος Hymenialdesine (HMD). Η HMD είναι ένα φυσικό προϊόν το οποίο έχει αποδειχθεί αναστολέας πολλών πρωτεϊνικών κινασών, όπως των κυκλινο-εξαρτώμενων κινασών (CDKs), η υπερλειτουργία των CDKs ενέχεται στην εμφάνιση παθολογικών καταστάσεων (καρκίνος, νευροεκφυλιστικές παθήσεις, διαβήτης). Στόχος της μελέτης ήταν ο σχεδιασμός και η διερεύνηση της σύνθεσης νέων σπειρανικών ινδολοαζεπινικών αναλόγων της HMD, με ενισχυμένη ανασταλτική και εκλεκτική δράση έναντι των CDKs. Για το σκοπό αυτό, μελετήθηκε η μετατροπή της 5-κετονομάδας της αζεπινο[3,4-b]ινδολο-1,5-διόνης σε ένα αμινο-υποκατεστημένο στερεογονικό κέντρο μέσω νουκλεόφιλης προσβολής της πρόδρομης χειρόμορφης t-βουτυλοσουλφινυλ-ιμίνης. Διερευνήθηκαν ποικίλες πειραματικές συνθήκες για τη βελτιστοποίηση σχηματισμού τόσο της ενδιάμεσης σουλφινυλ-ιμίνης, όσο και της υποκατάστασης αυτής. Τα συνθετικά αυτά στάδια θεωρούνται κρίσιμα και η βελτιστοποίηση τους απαραίτητη για την ομαλή εξέλιξη του συνθετικού σχήματος. Τα αποτελέσματα που καταγράφηκαν στα πλαίσια της μελέτης αναμένεται να συμβάλλουν ουσιαστικά στην επιτυχή ολοκλήρωση της σύνθεσης των νέων σπειρανικών αναλόγων της HMD. / Many cardiovascular diseases are connected with the activity of soluble guanylate cyclase (sGC). sGC is part of the NO-sGC-cGMP pathway, which is activated by the biologically available nitric oxide (NO). Many drugs that release NO (NO-drugs) have been used for more than 140 years. Although these drugs have contributed to the treatment of these diseases, they have presented some disadvantages. Thus, new compounds have been discovered whose activity is independent of NO. Compounds BAY 58-2667 and HMR-1766 belong to this new class of compounds and are characterized as sGC activators. In the first part of this study, six new benzofuran derivatives of HMR-1766 were designed and synthesized, aiming at the discovery of new compounds, activators of sGC with enhanced activity and selectivity against sGC. The synthetic approach involves the initial formation of benzofuran ring from substituted derivatives of salicylic acid and its coupling with selected building blocks. The optimazation of all synthetic steps for the synthesis of the intermediate and final products was also part of this study. The biological evaluation of the new compounds is expected to reveal their biological activity as sGC activators and/or their role as chemical tools for the structural elucidation of the enzyme. The second part of this study, concerns the design and synthesis of new derivatives of Hymenialdesine (HMD). HMD is a natural product with inhibitory activity against many protein kinases, such as cyclin-dependent kinases (CDKs). Hypeactivation of CDKs is implicated in pathological disorders such as cancer, neurodegenerative diseases and diabetes. The aim of the study was the synthesis of new spiro-indolazepino derivatives of HMD with potential enhanced inhibitory activity and selectivity against CDKs. The transformation of the 5-ketogroup of the azepino[3,4-b]indol-1,5-dione to a new amino-substituted stereogenic center by nucleophilic attack of the intermediate chiral tert-sulfinylimine was the key-step of the synthetic approach. The results of this study are expected to contribute substantially to the synthesis of new spiro HMD derivatives.

Soluble guanylate cyclase

Soluble guanylate cyclase activators

Cyclin dependent kinase 1

Protein kinase inhibitors

INJURY ESTABLISHES CONSTITUTIVE µ-OPIOID RECEPTOR ACTIVITY LEADING TO LASTING ENDOGENOUS ANALGESIA AND DEPENDENCE

Corder, Gregory F

01 January 2013

Injury causes increased pain sensation in humans and animals but the mechanisms underlying the emergence of persistent pathological pain states, which arise in the absence of on-going physical damage, are unclear. Therefore, elucidating the physiological regulation of such intractable pain is of exceptional biomedical importance. It is well known that endogenous activation of µ-opioid receptors (MORs) provides relief from acute pain but the consequences of prolonged endogenous opioidergic signaling have not been considered. Here we test the hypothesis that the intrinsic mechanisms of MOR signaling promote pathological sensitization of pain circuits in the spinal cord. We found that tissue inflammation produces agonist-independent MOR signaling in the dorsal horn of the spinal cord, which tonically represses hyperalgesia for months, even after complete recovery from injury and re-established normal pain thresholds. Disruption of this constitutive activity with MOR inverse agonists reinstated pain and precipitated cellular, somatic and aversive signs of physical withdrawal. This phenomenon required N-methyl-D-aspartate receptor activation of calcium-sensitive adenylyl cyclase type 1. Thus, we present a novel mechanism of long-lasting opioid analgesia that regulates the transition from acute to chronic pain while, in parallel, generates physical dependence. In conclusion we propose that the prevalence of chronic pain syndromes may result from a failure in constitutive signaling of spinal MORs and a loss of endogenous analgesic control.

pain

NMDA receptor

adenylyl cyclase

allostasis

inflammation

Behavioral Neurobiology

Molecular and Cellular Neuroscience

Nitric Oxide Signaling through Soluble Guanylate Cyclase

Hu, Xiaohui

January 2008

Soluble guanylyl/guanylate cyclase (sGC), the primary receptor for nitric oxide (NO), is a heme containing heterodimeric enzyme involved in numerous physiological events in animals. The small molecule YC-1 stimulates sGC, but the mechanism behind and the location of binding are unknown. I have developed a prokaryotic expression system for insect ( <italic>Manduca sexta</italic>) sGC. The recombinant holoenzyme, like its mammalian counterpart, is responsive to NO, CO and YC-1, displaying a 175-fold increase in activity on binding. Truncated constructs containing the N-terminal two-thirds of both subunits (msGC-NT) were designed to facilitate expression. With the highly pure material, we investigated NO and CO binding, reaction kinetics and regulation. Binding of NO to msGC-NT heme forms a six-coordinate intermediate followed by release of the proximal histidine to yield a five-coordinate nitrosyl complex. The conversion rate is insensitive to nucleotides, YC-1 and changes in NO concentration up to ~30 micromolar. In contrast, NO release from msGC-NT is biphasic in the absence of YC-1, while binding of YC-1 eliminates the fast phase but has little effect on the slower phase. CO binding to msGC-NT is also regulated by YC-1. The CO release rate is reduced by YC-1 while the on rate remains unchanged, which leads to an ~50-fold increase in binding affinity. YC-1 binding leads to a substantial geminate recombination of CO to msGC-NT upon photolysis. Our data are consistent with a model for allosteric activation in which (1) YC-1 binds away from the catalytic site and (2) sGC undergoes a conformational switch between two states of an open and a closed heme pocket. The final catalysis results from the integration of the influence of numerous allosteric effectors on the equilibrium between these two states.<italic>S </italic>-nitrosoglutathione (GSNO) exists <italic>in vivo </italic> and plays important roles in NO signaling. We have developed a model cell line, in which inducible NO synthase and human sGC genes were included. GSNO stimulation of sGC has been investigated using recombinant insect and human enzymes. GSNO can activate sGC as efficiently as gaseous NO, but apparently with a distinct mechanism. GSNO or endogenous NO could <italic>S </italic>-nitrosylate sGC, which might regulate the enzyme function.

cGMP

kinetics

ligand-recptor interaction

nitric oxide

signaling

soluble guanylate cyclase

Pathogenesis of 'Cronobacter' Species: Enterotoxin Production, Adhesion and Invasion of the Blood Brain Barrier

Abdesselam, Kahina

21 August 2012

Cronobacter species cause serious infections such as meningitis and enteritis in newborns and neonates, with the major vehicle being contaminated powdered infant formula. The main objectives of this study were i) to identify potential virulence factors, such as enterotoxin production; ii) characterize the gene(s) involved in adhesion and invasion of the human brain microvascular endothelial cells (HBMEC); and iii) determine whether strains from clinical, food, and environmental sources differ in their ability to produce surface-attached bacterial aggregates, known as biofilms. Random transposon mutagenesis was used on strains demonstrating the best adherence and invasion to blood- brain barrier cell lines (BBB). Isogenic mutants were then screened for increased or decreased adherence and invasion. Screening of the transposon library identified one isogenic mutant of a clinical strain which lost the ability to adhere to BBB cells. The transposon rescue revealed the insertion site to be within a diguanylate cyclase (DGC) gene. The major function of DGC in many Gram-negative bacteria is to synthesize cyclic diguanylate (c-di-GMP), a secondary bacterial metabolite known for regulating biofilm formation, motility, and virulence or aspects of microbial pathogenicity. Based on the findings of this study, DGC appears to play an important role in Cronobacter species’ ability to produce biofilms and may also have a role of the pathogenicity in the microorganism.

Cronobacter spp.

Enterotoxin production

Biofilms

Diguanylate cyclase

Threonine Synthase

La pluridimensionalité de l'efficacité des ligands des récepteurs couplés aux protéines G : les récepteurs B[bêta]₁- et B[bêta]₂-adrénergiques en tant que modèles d'étude

Galandrin, Ségolène

January 2007

Thèse numérisée par la Direction des bibliothèques de l'Université de Montréal.

RCPG

Efficacité

Sélectivité

Conformation des récepteurs

Adénylate cyclase

MAPK

Récepteur B[bêta]₁-

Récepteur B[bêta]₂-adrénergique

Characterization of cyclic-di-GMP signaling with the Lyme spirochete, Borrelia burgdorferi

Kostick, Jessica

23 September 2011

Lyme disease is a tick-borne infection caused by Borrelia burgdorferi, B. garinii, and B. afzelii. These spirochetes experience environmental fluctuations as they are passed between mammalian and Ixodes tick hosts throughout their enzootic cycle. Recent studies have suggested cyclic diguanylate (c-di-GMP), a ubiquitous secondary messenger, is a key modulator of B. burgdorferi adaptive responses and may play a significant role in cycle progression. In this study, we examined the impact of the sole diguanylate cyclase (Rrp1), c-di-GMP binding proteins (PlzA and PlzB), and HD-GYP-containing phosphodiesterase (PdeB) in disease establishment of both murine and Ixodes tick systems. Strains harboring targeted gene deletions or plasmid-based constitutive gene expression constructs were generated. Rrp1 was required for tick colonization, yet overexpression abolished murine disease, thus implicating the requirement of finely regulated c-di-GMP levels for enzootic cycle progression. Deletion of rrp1 disrupted translational motion and swarming patterns by causing extended cell runs, eliminating stops/flexes, and reducing swarming capabilities. This was attributed to a defect in N-acetyl-D-glucosamine (NAG) metabolism and chemotaxis. NAG is a major source of nutrition for B. burgdorferi within the tick environment; therefore this defect would impede spirochete migration towards feeding ticks, as well as pathogen uptake and survival within the Ixodes vector. In contrast, the downstream c-di-GMP effector, PlzA, was critical for murine disease but nonessential for survival within ticks nor functionally complemented by PlzB. Deletion of plzA altered strain motility and swarming similarly to the rrp1 deletion mutant, yet had a distinct phenotype with significantly slower translational motion and no affect on NAG chemotaxis and metabolism. This indicates B. burgdorferi could possess alternate c-di-GMP effectors or Rrp1 could be directly influencing these cellular processes. Uniquely, PdeB did not abolish murine infection via needle inoculation, but wasrequired for natural transmission from ticks. This defect was linked to the decreased tick colonization efficiency upon pdeB deletion. Together, these analyses indicate that c-di-GMP signaling is an important virulence mechanism of Borrelia burgdorferi and demonstrate the complexity of this signaling pathway in an arthropod-borne pathogen. The data presented here additionally provide significant new insight into the gene regulatory mechanisms of the Lyme disease spirochetes.

Borrelia

cyclic-di-GMP

enzootic cycle

diguanylate cyclase

phosphodiesterase

Rrp1

PlzA

PlzB

PdeB

Medicine and Health Sciences