Cellular mechanisms underlying the regulation of calcium signaling in brain pericytes

Phillips, Braxton

06 1900

Les cellules murales du cerveau sont un groupe de cellules neurovasculaires qui présentent une hétérogénéité moléculaire, morphologique et fonctionnelle exceptionnelle. Celles en contact avec les plus petis vaisseaux du cerveau, les péricytes du lit capillaire moyen sont connues pour être essentielles à l'homéostasie cérébrale, bien que leur capacité contractile ait longtemps été débattue. Cependant, nombre de leurs propriétés physiologiques, telles que leurs mécanismes de signalisation calcique, n'ont pas encore été élucidées. Cette thèse vise donc à identifier les mécanismes cellulaires de la signalisation calcique des péricytes des capillaires cérébraux. Dans le chapitre 2, nous utilisons la pharmacologie et l'imagerie des péricytes cérébraux exprimant l'indicateur de calcium GCaMP6f (provenant de souris transgéniques PDGFRβ-Cre::GCaMP6f) pour découvrir ces mécanismes. Contrairement aux péricytes engainants dont la signalisation du calcique dépend des canaux calcique voltage-dépendants, nous constatons que les signaux calcique des péricytes capillaire moyen sont indépendants des canaux calcique voltage-dépendants. Au contraire, nous constatons que les signaux calciques transitoires des pericytes du lit capillaire moyen sont inhibés par l'élimination du Ca2+ extracellulaire, l'inhibition des canaux Orai opérés par les réserves, le blocage du remplissage des réserves du réticulum endoplasmique, ainsi que l'inhibition des récepteurs de la ryanodine (RyRs) et des récepteurs de l'inositol trisphosphate (IP3Rs). Nous constatons également que l'entrée de Ca2+ opérée par les réserves peut être induite par la déplétion des réserves du réticulum endoplasmique et inhibée par les bloqueurs d'Orai dans les pericytes du lit capillaire moyen, et que l'influx basal de Ca2+ est largement dépendant de la déplétion des réserves. Enfin, nous montrons que l'entrée de Ca2+ opérée par les réserves d'Orai amplifie les élévations de Ca2+ cytosolique en réponse au vasoconstricteur endothéline-1. Nous concluons que la signalisation calcique dans les pericytes du lit capillaire moyen, qu'elle soit spontanée ou induite de façon agoniste, est régulée par le couplage entre la libération des réserves du réticulum endoplasmique et les voies d'influx opérées par les réserves. / Brain mural cells are a grouping of neurovascular cells that display exceptional molecular, morphological, and functional heterogeneity. Mid-capillary pericytes, the mural cells which contact the smallest vessels of the brain, are known to be critical to brain homeostasis, and their contractile ability has long been debated. However, many of their physiological properties, such as their Ca2+ signaling mechanisms, have not been elucidated. This thesis aims to uncover the cellular mechanisms of brain mid-capillary pericyte Ca2+ signaling. In chapter 2, we harness pharmacology and imaging of brain pericytes expressing the calcium indicator GCaMP6f (from transgenic PDGFRβ-Cre::GCaMP6f mice) to uncover these mechanisms. In contrast to ensheathing pericytes whose Ca2+ signaling is dependent on voltage-gated Ca2+ channels (VGCCs), we find that mid-capillary pericyte Ca2+ signals are independent of VGCCs. Instead, we find that mid-capillary pericyte Ca2+ transients are inhibited by removal of extracellular Ca2+, inhibition of store-operated Orai channels, blockade of endoplasmic reticulum store filling, as well as inhibition of ryanodine receptors (RyRs) and inositol triphosphate receptors (IP3Rs). We further find that store-operated Ca2+ entry can be induced by endoplasmic reticulum store depletion and inhibited by Orai blockers in mid-capillary pericytes, and that basal Ca2+ influx is largely dependent on store depletion. Finally, we show that Orai store-operated Ca2+ entry amplifies cytosolic Ca2+ elevations in response to the vasoconstrictor endothelin-1. We conclude that both spontaneous and Gq-coupled protein receptor agonist-induced Ca2+ signaling in mid-capillary pericytes is regulated by coupling between endoplasmic reticulum store release and store-operated influx pathways.

Pericytes

calcium

capillaries

orai

ryanodine receptor

IP3 receptor

live cell imaging

confocal microscopy

péricytes

récepteur de la ryanodine

récepteur IP3

imagerie cellulaire en direct

microscopie confocale

The Role of CaMK-II in Skeletal Muscle Function and Swimming Behavior in Zebrafish

Nguyen, Minh

26 April 2013

Previous research showed mutations in muscle sarcoplasmic reticulum-bound calcium handler proteins cause swimming defects in embryonic zebrafish. CaMK-II is a highly conserved Ca2+/calmodulin-dependent protein kinase expressed in all vertebrates has been defined to activate and inactivate multiple Ca2+ handler proteins involved in excitation- contraction coupling and relaxation of cardiac and skeletal muscle. In this study, evidence is provided through pharmacological and genetic intervention that CaMK-II inhibition and overexpression causes swimming defects, particularly response to stimuli and swimming ability, reinforced by immunolocalization of skeletal muscle. Transient CaMK-II inactivation does not have any long-term defects to swimming behavior. Overexpression of wild-type, constitutively active, and dominant-negative CaMK-II-GFP in embryos tended to co-localize in fast muscle which led to defects in swimming behavior. This study concludes that inhibition or overexpression of CaMK-II in skeletal muscle diminishes normal swimming behavior specifically in response to mechanical stimulation and swimming ability.

skeletal muscle

CaMK-II

zebrafish development

ryanodine receptor

phospholamban

developmental biology

zebrafish swimming

Biology

Life Sciences

Antioxidant Anthocyanidins and Calcium Transport Modulation of the Ryanodine Receptor of Skeletal Muscle (RyR1)

Dornan, Thomas J.

01 January 2011

Cardiovascular disease (CVD) claims more lives than any other disease in the world. Although numerous biological pathways share the blame, ventricular tachyarrhythmia (VT) is estimated to account for ~25% of all CVD deaths. A complete understanding of the molecular mechanisms underlying VT is unknown but recent studies have linked VT to improper calcium handling in the heart (canine). The principle calcium regulator in the muscle cell is the calcium ion release channel (aka RyR). Numerous endogenous and exogenous compounds can affect the way the RyR regulates calcium. In particular, abnormal levels of oxidants (reactive oxygen species) can oxidize critical thiol groups on the RyR and modulate its activity. Interestingly, high levels of oxidants are also associated with numerous bodily disease states including cancers, muscle fatigue/failure, and CVD. In this thesis, two important dietary antioxidant compounds, the anthocyanidins pelargonidin and delphinidin, are evaluated for their effects on regulating the transport of calcium through the calcium release channel (RyR1) of the sarcoplasmic reticulum of skeletal muscle. Pelargonidin and delphinidin are structurally similar with delphinidin only differing from pelargonidin by the addition of two hydroxyl groups. Both compounds undergo time dependent structural changes in aqueous solutions at physiological pH and a mixture of more than four structures of each compound can be present in solution simultaneously. Pelargonidin and delphinidin show distinct differences in their calcium flux regulating effect on the RyR1. Delphinidin stimulates calcium flux and RyR1 activity where as pelargonidin can cause both inhibition and stimulation of the RyR1. The strength of stimulation and inhibition of calcium transport through the RyR by delphinidin and pelargonidin may be attributed to the structural and chemical changes in those compounds that occur in solutions near physiological pH and the subsequent chemical characteristics of the diverse set of structures that are simultaneously present in solution.

Delphinidin

Pelargonidin

Cardiovascular system -- Diseases

Ventricular tachycardia

Ryanodine -- Receptors

Calcium channels

Antioxidants

Anthocyanidins

Identification of Ryanodine Receptor 1 (RyR1) Interacting Protein Partners Using Liquid Chromatography and Mass Spectrometry

Ryan, Timothy

13 January 2011

Ryanodine receptor 1 (RyR1) is a homotetrameric calcium channel located in the sarcoplasmic reticulum (SR) of skeletal muscle. We employed metal affinity chromatography followed by liquid chromatography mass spectrometry from HEK-293 cells to purify affinity tagged cytosolic RyR1, with interacting proteins. In total, we identified 703 proteins with high confidence (>99%). Of the putative RyR1 interacting proteins, five candidates [calcium homeostasis endoplasmic reticulum protein (CHERP), ER-golgi intermediate compartment 53kDa protein (LMAN1), T-complex protein (TCP), phosphorylase b kinase (PHBK) and four and half LIM domains protein 1 (FHL1)], were selected for interaction studies. Immunofluorescence analysis showed that CHERP co-localizes with RyR1 in the SR of rat soleus muscle. Calcium transient assays in HEK293 cells over-expressing RyR1 with siRNA suppressed CHERP or FHL1, showed reduced calcium release via RyR1. In conclusion, we have identified RyR1 interacting proteins in CHERP and FHL1 which may represent novel regulatory mechanisms involved in excitation-contraction coupling.

Ryanodine Receptor 1

Metal affinity chromatography

Mass Spectrometry

Protein-protein interactions

0719

Identification of Ryanodine Receptor 1 (RyR1) Interacting Protein Partners Using Liquid Chromatography and Mass Spectrometry

Ryan, Timothy

13 January 2011

Ryanodine receptor 1 (RyR1) is a homotetrameric calcium channel located in the sarcoplasmic reticulum (SR) of skeletal muscle. We employed metal affinity chromatography followed by liquid chromatography mass spectrometry from HEK-293 cells to purify affinity tagged cytosolic RyR1, with interacting proteins. In total, we identified 703 proteins with high confidence (>99%). Of the putative RyR1 interacting proteins, five candidates [calcium homeostasis endoplasmic reticulum protein (CHERP), ER-golgi intermediate compartment 53kDa protein (LMAN1), T-complex protein (TCP), phosphorylase b kinase (PHBK) and four and half LIM domains protein 1 (FHL1)], were selected for interaction studies. Immunofluorescence analysis showed that CHERP co-localizes with RyR1 in the SR of rat soleus muscle. Calcium transient assays in HEK293 cells over-expressing RyR1 with siRNA suppressed CHERP or FHL1, showed reduced calcium release via RyR1. In conclusion, we have identified RyR1 interacting proteins in CHERP and FHL1 which may represent novel regulatory mechanisms involved in excitation-contraction coupling.

Ryanodine Receptor 1

Metal affinity chromatography

Mass Spectrometry

Protein-protein interactions

0719

Plasticité de l'expression de protéines clés du couplage excitation-contraction du muscle squelettique dans un modèle d'atrophie fonctionnelle

Bastide, Bruno, Mounier, Yvonne,

January 2003

Habilitation à diriger des recherches : Sciences naturelles : Lille 1 : 2003. / Synthèse de travaux en français et articles publiés en anglais reproduits dans le texte. N° d'ordre (Lille 1) : 396. Résumé. Curriculum vitae. Pagination multiple pour les articles reproduits. Bibliogr. p. 150-188 et à la suite des articles. Liste des publications.

Structural Insights into the Regulatory Mechanism of the Ryanodine Receptor and its Disease-associated Mutants

Amador, Fernando

08 January 2014

Calcium is a ubiquitous second messenger in cells that plays a vital role in the control of cellular and physiological processes as diverse as cell division, memory and learning, fertilization and muscle contraction. Opening of the sarcoplasmic reticulum (SR) Ca2+-release channel, the ryanodine receptor (RyR), in response to mechanical or chemical stimuli via the dihydropyridine receptor (DHPR) is a crucial step in the process of muscle excitation-contraction coupling. I have determined the first high-resolution structure of a folded domain of RyR1 (RyR1A). The structure adopts a β-trefoil fold that is similar to the homologous suppressor domain of the inositol 1,4,5-trisphosphate receptor (IP3R). I identified a loop region in RyR1A concentrated with malignant hyperthermia (MH)- and central core disease (CCD)-associated mutations that have been implicated in perturbing inter-domain interactions with downstream regions of RyR. More recently I have used nuclear magnetic resonance (NMR) spectroscopy to study the structure and dynamics of the cardiac isoform (RyR2) A domain and its mutants. I detected a dynamic α-helix that undergoes an α-helix to β-strand switch in the catecholaminergic polymorphic ventricular tachycardia (CPVT)-associated mutant, RyR2A Δ exon 3. This dynamic helix is localized at an interface with electron dense columns in the cryo-EM map of the tetrameric receptor that connect with the pore region, suggesting that this dynamic helix may also interact with downstream regions of RyR to gate the channel. My high-resolution structural studies in collaboration with others have shed light on the structural underpinnings of RyR function and dysfunction in human disease.

Structural Biology

Ryanodine receptor

NMR

X-ray crystallography

0487

0719

0307

Structural Insights into the Regulatory Mechanism of the Ryanodine Receptor and its Disease-associated Mutants

Amador, Fernando

08 January 2014

Calcium is a ubiquitous second messenger in cells that plays a vital role in the control of cellular and physiological processes as diverse as cell division, memory and learning, fertilization and muscle contraction. Opening of the sarcoplasmic reticulum (SR) Ca2+-release channel, the ryanodine receptor (RyR), in response to mechanical or chemical stimuli via the dihydropyridine receptor (DHPR) is a crucial step in the process of muscle excitation-contraction coupling. I have determined the first high-resolution structure of a folded domain of RyR1 (RyR1A). The structure adopts a β-trefoil fold that is similar to the homologous suppressor domain of the inositol 1,4,5-trisphosphate receptor (IP3R). I identified a loop region in RyR1A concentrated with malignant hyperthermia (MH)- and central core disease (CCD)-associated mutations that have been implicated in perturbing inter-domain interactions with downstream regions of RyR. More recently I have used nuclear magnetic resonance (NMR) spectroscopy to study the structure and dynamics of the cardiac isoform (RyR2) A domain and its mutants. I detected a dynamic α-helix that undergoes an α-helix to β-strand switch in the catecholaminergic polymorphic ventricular tachycardia (CPVT)-associated mutant, RyR2A Δ exon 3. This dynamic helix is localized at an interface with electron dense columns in the cryo-EM map of the tetrameric receptor that connect with the pore region, suggesting that this dynamic helix may also interact with downstream regions of RyR to gate the channel. My high-resolution structural studies in collaboration with others have shed light on the structural underpinnings of RyR function and dysfunction in human disease.

Structural Biology

Ryanodine receptor

NMR

X-ray crystallography

0487

0719

0307

A functional analysis of RYR1 mutations causing malignant hyperthermia : a thesis presented to Massey University in partial fulfillment of the requirements for the degree of Doctor of Philosophy in Biochemistry

Sato, Keisaku

January 2009

Malignant hyperthermia (MH) is a rare pharmacogenetic disorder in humans induced by volatile anaesthetics and depolarising muscle relaxants. An MH reaction shows abnormal calcium homeostasis in skeletal muscle leading to a hypermetabolic state and increased muscle contracture. A mutation within the skeletal muscle calcium release channel ryanodine receptor gene (RYR1) is associated with MH and is thought to cause functional defects in the RYR1 channel leading to abnormal calcium release to the sarcoplasm and consequent MH reactions. Mutations within RYR1 are also associated with a rare congenital myopathy, central core disease (CCD). CCD is characterised by muscle weakness and is thought to be caused by insufficient calcium release from the RYR1 channel during excitation-contraction (EC) coupling. To investigate functional effects of RYR1 mutations, the entire coding region of human RYR1 was assembled and cloned into an expression vector. Mutant clones containing RYR1 mutations linked to MH or CCD were also constructed. Wild-type (WT) and mutant RYR1 clones were used for transient transfection of HEK-293 cells. Western blotting was performed after harvesting and expressed WT and mutant RYR1 proteins were successfully detected. Immunofluorescence showed co-localisation of RYR1 proteins and the endoplasmic reticulum in HEK-293 cells. [3H]ryanodine binding assays showed that RYR1 mutants linked to MH were more sensitive to the agonist 4-chloro-m-cresol (4-CmC) and less sensitive to the antagonist Mg2+ compared with WT. Two C-terminal RYR1 mutants T4826I and H4833Y were very significantly hypersensitive to 4-CmC and they may also result in a leaky channel. This hypersensitivity of mutants linked to MH may result in abnormal calcium release through the RYR1 channel induced by triggering agents leading to MH reactions. RYR1 mutants linked to CCD showed no response to 4-CmC showing their hyposensitive characteristics to agonists. This study showed that the human RYR1 proteins could be expressed in HEK-293 cells. Moreover, using the recombinant human RYR1 clone, a single mutation within RYR1 resulted in a functional defect in expressed RYR1 proteins and functions of mutant RYR1 proteins varied from hypersensitive to hyposensitive depending on the mutation and whether it was linked to MH or CCD.

malignant hyperthermia genetic aspects

ryanodine receptors

Inhibition of the calcium plateau following in vitro status epilepticus prevents the development of spontaneous recurrent epileptiform discharges

Nagarkatti, Nisha.

January 1900

Thesis (Ph.D.)--Virginia Commonwealth University, 2009. / Prepared for: Dept. of Pharmacology and Toxicology. Title from resource description page. Includes bibliographical references.