Integration of Extracellular and Intracellular Calcium Signals: Roles of Calcium-Sensing Receptor (CASR), Calmodulin and Stromal Interaction Molecule 1 (STIM1)

Huang, Yun

20 November 2008

Ca2+, both as a first and a second messenger, is closely involved in the modulation and regulation of numerous important cellular events, such as cell proliferation, differentiation and cell death. Fine-tuned Ca2+ signaling is achieved by its reversible or irreversible binding to a repertoire of Ca2+ signaling molecules. Among them, the extracellular calcium sensing receptor (CaSR) senses Ca2+ concentration ([Ca2+]o) in the milieu outside of cells where Ca2+ serves as a first messenger. An array of naturally-occurring mutations in CaSR has been found in patients with inherited disorders of Ca2+ homeostasis, leading to abnormal intracellular responses toward [Ca2+]o. In the present study, we have computationally predicted and experimentally characterized the metal-binding properties of five Ca2+-binding sites within CaSR and the accompanying metal--induced conformational changes by using two complementary methods-the grafting approach and the subdomain approach. Based on our results, a model has been proposed to explain the distinct CaSR-mediated responses toward abnormally ¡°high¡± or ¡°low¡± extracellular Ca2+ levels. In addition, we predicted and verified the interaction between CaSR with the most ubiquitously expressed four EF-hand-containing intracellular Ca2+ sensor protein, calmodulin (CaM). Our results demonstrate that the C-terminal CaM-binding domain of the CaSR is essential for proper intracellular Ca2+ response to external signals. Furthermore, we have applied the grafting approach to study the metal-binding properties and oligomeric state of the single EF-hand containing protein, STIM1. Our studies confirmed that the single EF-hand motif in STIM1, which resides in an equilibratium between its monomeric and dimeric forms, was capable of binding Ca2+ with a dissociation constant comparable to the ER Ca2+ concentration, suggesting it could function as a ER Ca2+ sensor responsible for sensing the Ca2+ filling state of ER.

Signaling

Ca2+

Fluorescence

Sensor

STIM1

Protein engineering

CD2

Prediction

Calmodulin

EF-hand

Calcium sensing receptor

Chemistry

Régulation négative de l'activité des canaux calciques : identification de deux nouveaux frins biologiques

Nguyen, Nathalie

January 2013

Le Ca[indice supérieur 2+] joue un rôle primordial dans plusieurs processus physiologiques comme la contraction, la sécrétion, la croissance et la prolifération cellulaire et même l’apoptose. Ainsi, une régulation adéquate des niveaux de Ca[indice supérieur 2+] dans la cellule est essentielle à son bon fonctionnement. Plusieurs protéines-clés sont impliquées dans cette homéostasie calcique. Cette étude a permis d’identifier deux mécanismes distincts responsables de friner la signalisation calcique dans un modèle de cellules non-excitables et dans un modèle de cellules excitables, en mettant l’emphase sur la régulation des canaux calciques par leur interaction avec des protéines clés. Le premier mécanisme implique la régulation du récepteur à l’inositol 1,4,5-trisphosphate (IP[indice inférieur 3]R) par la protéine chaperonne Hsp90 dans les cellules HEK293T. J’ai montré que Hsp90 interagit avec l'IP[indice inférieur 3]R dans le but de diminuer son activité. De plus, cette interaction dépend de la voie de signalisation de l’insuline, plus particulièrement des protéines kinases mTOR et Src, qui sont impliquées dans cette interaction. Ainsi, l’interaction entre Hsp90 et l'IP[indice inférieur 3]R fait partie d’un mécanisme de rétroaction négative de la voie de signalisation de l’insuline. Le second mécanisme implique la régulation des canaux calciques dépendants du voltage de type T (T-VDCC) par la protéine STIM1 dans les cardiomyocytes HL-1. J'ai montré que STIM1, qui est le principal senseur de Ca[indice supérieur 2+] du réticulum sarco/endoplasmique, interagit avec les T-VDCC afin de diminuer leur expression à la membrane cellulaire et ainsi atténuer leur activité. Cette interaction permet de prévenir une entrée excessive de Ca[indice supérieur 2+] dans la cellule menant à une surcharge de Ca[indice supérieur 2+] dans le réticulum sarcoplasmique et, par le fait même, à des événements arythmiques associés à la surcharge. Bien que ces deux études aient été effectuées dans des environnements différents, soit un modèle de cellules non-excitables et un modèle de cellules excitables, elles mettent en évidence deux mécanismes pouvant friner la signalisation calcique dans le but d’assurer une fonction normale à la cellule.

T-VDCC

STIM1

IP[indice inférieur 3]R

Hsp90

Signalisation calcique

Ca[indice supérieur 2+]

GPR40 activation initiates store-operated Ca²⁺ entry and potentiates insulin secretion via the IP3R1/STIM1/Orai1 pathway in pancreatic β-cells / 膵β細胞におけるGPR40活性化はIP3R1/STIM1/Orai1経路を介してストア作動性カルシウム流入を誘導し、インスリン分泌を増強する

Usui, Ryota

23 March 2020

京都大学 / 0048 / 新制・課程博士 / 博士(医学) / 甲第22360号 / 医博第4601号 / 新制||医||1043(附属図書館) / 京都大学大学院医学研究科医学専攻 / (主査)教授 長船 健二, 教授 岩田 想, 教授 松原 和夫 / 学位規則第4条第1項該当 / Doctor of Medical Science / Kyoto University / DFAM

インスリン分泌

ストア作動性カルシウム流入

GPR40

STIM1

490

Gemcitabine Resistance Elicits a Calcium Dependent Epigenetic Reprogramming in Pancreatic Cancer

Kutschat, Ana Patricia

26 February 2021

No description available.

570

Pancreatic cancer

Gemcitabine

Chemotherapy resistance

Epigenetics

Calcium

STIM1

Store operated calcium entry (SOCE)

Biologie (PPN619462639)

Vliv aktivace žírných buněk na organizaci mikrotubulů / The effect of the mast cell activation on the microtubule organisation

Hájková, Zuzana

January 2011

The activation of bone marrow-derived mast cells (BMMCs) induces a number of cell processes such as degranulation, proliferation and cytoskeleton rearrangements. Although microtubules are important in these processes, molecular mechanisms that control changes in microtubule organisation during cell activation are unknown. Activation of BMMCs can be achieved in several ways. Under physiological conditions, the aggregation of IgE receptors (FcRI) on the surface of BMMCs leads to the initiation of specific signaling pathways. Cells can be also activated nonspecifically by a tyrosine phosphatase inhibitor pervanadate, or by thapsigargin that inhibits Ca2+ ATPase pumps located on the endoplasmic reticulum. In this diploma thesis it was found out that rapid morphological changes can be monitored when BMMC are immobilised on the fibronectin before their activation. It was proved that specific and nonspecific activation events lead to microtubule reorganization, as well as to generation of a large number of microtubule-dependent protrusions. In the course of FcRI aggregation, generation of microtubule protrusions depends on the activity of Src family protein tyrosine kinases and on the intracellular Ca2+ concentration. STIM1, an endoplasmic reticulum Ca2+ sensor, which participates in the activation of...

Lysophosphatidic Acid Promotes Cell Migration through STIM1- and Orai1-Mediated Ca2+i Mobilization and NFAT2 Activation

Jans, R., Mottram, L., Johnson, D.L., Brown, A.M., Sikkink, Stephen, Ross, K., Reynolds, N.J.

January 2013

no / Lysophosphatidic acid (LPA) enhances cell migration and promotes wound healing in vivo, but the intracellular signaling pathways regulating these processes remain incompletely understood. Here we investigated the involvement of agonist-induced Ca2+ entry and STIM1 and Orai1 proteins in regulating nuclear factor of activated T cell (NFAT) signaling and LPA-induced keratinocyte cell motility. As monitored by Fluo-4 imaging, stimulation with 10 μM LPA in 60 μM Ca2+o evoked Ca2+i transients owing to store release, whereas addition of LPA in physiological 1.2 mM Ca2+o triggered store release coupled to extracellular Ca2+ entry. Store-operated Ca2+ entry (SOCE) was blocked by the SOCE inhibitor diethylstilbestrol (DES), STIM1 silencing using RNA interference (RNAi), and expression of dominant/negative Orai1R91W. LPA induced significant NFAT activation as monitored by nuclear translocation of green fluorescent protein-tagged NFAT2 and a luciferase reporter assay, which was impaired by DES, expression of Orai1R91W, and inhibition of calcineurin using cyclosporin A (CsA). By using chemotactic migration assays, LPA-induced cell motility was significantly impaired by STIM1, CsA, and NFAT2 knockdown using RNAi. These data indicate that in conditions relevant to epidermal wound healing, LPA induces SOCE and NFAT activation through Orai1 channels and promotes cell migration through a calcineurin/NFAT2-dependent pathway.

Development of Protein-based Tools to Image and Modulate Ca2+ Signaling

Pham, Elizabeth

11 January 2012

Optogenetics has emerged as a branch of biotechnology that combines genetic engineering with optics to observe intracellular changes as well as control cellular function. Despite recent progress, there still remains the need for an optogenetic tool that can specifically control Ca2+. Such a tool would greatly facilitate the study of highly Ca2+-dependent cellular processes that are regulated both spatially and temporally. Ca2+ signaling regulates many cellular processes in both healthy and diseased cells. The ability to modulate the shape, duration, and amplitude of Ca2+ signaling is important for elucidating mechanisms by which endogenous Ca2+ concentrations are maintained. In this thesis, we used optogenetic approaches to explore a number of strategies to control Ca2+ influx through store-operated Ca2+ entry (SOCE) mediated by Stim1 and Orai1. To better study Ca2+ signaling in live cells, protein-based biosensors can be developed to monitor intracellular Ca2+ changes. To aid in this, we developed a computational modeling tool called FPMOD to improve both new and existing biosensor designs. Although FPMOD was initially intended for evaluating biosensor designs, other research groups have since used it to construct models of other proteins to answer questions related to protein conformation. We next studied the modulation of SOCE by using drug-inducible fusion proteins to study the regulation of Stim1 puncta formation. Interestingly, recruiting a Ca2+-buffering protein to Stim1 led to puncta formation, a previously unknown means of inducing puncta. These results suggest Stim1 may additionally be regulated by cytoplasmic Ca2+ levels. Finally, we developed LOVS1K, an optogenetic tool to directly activate Orai1 channels and specifically control Ca2+ influx. Photo-sensitive LOVS1K was used to generate both local Ca2+ influx at the membrane and global cytoplasmic Ca2+ signals. As proof of concept, LOVS1K was further used to modulate engineered Ca2+-dependent proteins. Ca2+ is a remarkably versatile intracellular messenger. The combination of high spatiotemporal control of irradiation and the ability of LOVS1K to generate both local and global Ca2+ changes provides a promising platform to study cellular processes that are highly dependent on different Ca2+ signals. Together, biosensors and engineered Ca2+-modulating tools can be used to study the many different aspects of Ca2+ signaling and controllably manipulate endogenous Ca2+ signaling pathways.

Calcium Signaling

FRET Biosensors

Store Operated Calcium Entry

Stim1

Orai1

Optogenetics

Photo-activated

LOVS1K

Fusion Proteins

Protein Engineering

0541

Development of Protein-based Tools to Image and Modulate Ca2+ Signaling

Pham, Elizabeth

11 January 2012

Optogenetics has emerged as a branch of biotechnology that combines genetic engineering with optics to observe intracellular changes as well as control cellular function. Despite recent progress, there still remains the need for an optogenetic tool that can specifically control Ca2+. Such a tool would greatly facilitate the study of highly Ca2+-dependent cellular processes that are regulated both spatially and temporally. Ca2+ signaling regulates many cellular processes in both healthy and diseased cells. The ability to modulate the shape, duration, and amplitude of Ca2+ signaling is important for elucidating mechanisms by which endogenous Ca2+ concentrations are maintained. In this thesis, we used optogenetic approaches to explore a number of strategies to control Ca2+ influx through store-operated Ca2+ entry (SOCE) mediated by Stim1 and Orai1. To better study Ca2+ signaling in live cells, protein-based biosensors can be developed to monitor intracellular Ca2+ changes. To aid in this, we developed a computational modeling tool called FPMOD to improve both new and existing biosensor designs. Although FPMOD was initially intended for evaluating biosensor designs, other research groups have since used it to construct models of other proteins to answer questions related to protein conformation. We next studied the modulation of SOCE by using drug-inducible fusion proteins to study the regulation of Stim1 puncta formation. Interestingly, recruiting a Ca2+-buffering protein to Stim1 led to puncta formation, a previously unknown means of inducing puncta. These results suggest Stim1 may additionally be regulated by cytoplasmic Ca2+ levels. Finally, we developed LOVS1K, an optogenetic tool to directly activate Orai1 channels and specifically control Ca2+ influx. Photo-sensitive LOVS1K was used to generate both local Ca2+ influx at the membrane and global cytoplasmic Ca2+ signals. As proof of concept, LOVS1K was further used to modulate engineered Ca2+-dependent proteins. Ca2+ is a remarkably versatile intracellular messenger. The combination of high spatiotemporal control of irradiation and the ability of LOVS1K to generate both local and global Ca2+ changes provides a promising platform to study cellular processes that are highly dependent on different Ca2+ signals. Together, biosensors and engineered Ca2+-modulating tools can be used to study the many different aspects of Ca2+ signaling and controllably manipulate endogenous Ca2+ signaling pathways.

Calcium Signaling

FRET Biosensors

Store Operated Calcium Entry

Stim1

Orai1

Optogenetics

Photo-activated

LOVS1K

Fusion Proteins

Protein Engineering

0541

Etude de la signalisation calcique dans les cellules gustatives lipidiques chez la souris

Dramane, Gado, Dramane, Gado

08 October 2012

Les personnes en surcharge pondérale semblent préférer une alimentation riche en graisse. Face à l'épidémie d'obésité qui touche nos Sociétés tant urbaines que rurales, élucider les mécanismes de la détection des lipides alimentaires devient un enjeu majeur. Il avait précédemment été admis que la glycoprotéine CD36 exprimée dans les papilles caliciformes de souris, est impliquée dans la perception oro-gustative des lipides alimentaires. Dans ce travail, nous avons montré que l'acide linoléique (LA), en activant les phospholipases A2, sPLA2, cPLA2 et iPLA2 via CD36, produit de l'acide arachidonique (AA) et la lyso-phosphatidylcholine (lyso-PC). LA déclenche un influx calcique dans les cellules CD36-positives et induit la production du facteur CIF (Calcium Influx Factor). CIF, AA et lyso-PC exercent différentes actions sur l'ouverture des canaux SOC (Stored Operated Calcium Channel) constitués de protéines Orai et contrôlés par STIM1. Stim1 est un senseur calcique situé sur la membrane du réticulum endoplasmique activé par la déplétion du calcium intracellulaire. Nous avons utilisé la technologie siRNA et des modèles de souris transgéniques pour montrer que CIF et lyso-PC activent des canaux calciques homodimériques composés de protéines Orai1 tandis qu'AA active des canaux hétéro-pentamériques composés d'Orai1 et Orai3. Nous avons également montré que STIM1 régule la production de CIF dans les cellules stimulées par la thapsigargine et l'acide linoléique ainsi que l'ouverture de deux types de canaux calciques. Par ailleurs les souris au phénotype Stim1-/- perdent la préférence spontanée pour les lipides observé chez les animaux de type sauvage. D'un autre côté les cellules CD36-positive de souris Stim1-/- sont incapables de libérer la sérotonine dans l'environnement extracellulaire. Nos résultats suggèrent que des acides gras à longue chaine (AGLC) induisent la signalisation calcique régie par STIM1 via CD36. La perception oro-gustative des lipides alimentaires détermine la préférence spontanée pour les lipides observée chez les mammifères

Acide linoléique

CD36

PLA2

Stim1

Orai1/3

Préférence gustative lipidique

Etude de la dérégulation des entrées calciques du lymphocyte B de leucémie lymphoïde chronique : mise en évidence d'une nouvelle piste thérapeutique / Study of calcium entries deregulation in chronic lymphocytic leukemia B-cells : evidence for a new therapeutic target

Debant, Marjolaine

19 December 2017

La leucémie lymphoïde chronique (LLC) constitue l'hémopathie maligne la plus fréquente dans les pays occidentaux et résulte d’une accumulation de lymphocytes B (LB) monoclonaux matures porteurs de la glycoprotéine CD5. Les LB de LLC sont également caractérisées par une altération de l'homéostasie du calcium avec, d'une part, la mise en évidence de facteurs de survie contrôlés par le calcium tels que phospho-ERK, NFAT-2 et IL-10, et d'autre part par une progression de la maladie qui est associée à la réponse au calcium. Tout d'abord, afin de mieux comprendre l'impact de la molécule CD5 sur les dérégulations du calcium, il a été montré que l'introduction d'un plasmide d'expression pour CD5 dans les lignées de cellules B humaines s'accompagnait d'une entrée calcique à l’état basale. Ensuite, cette entrée, appelée entrée constitutive, a été recherchée dans les LB de LLC pour montrer qu'elle caractérisait les patients non traités en phase d'évolution. Comme pour les lignées de cellules B CD5, cette nouvelle voie d'entrée du calcium est autonome et indépendante de la voie classique de signalisation du LB de LLC : BCR-IP3R. L'étude des protéines responsables de cet influx a permis de mettre en évidence, premièrement trois partenaires STIM1, Orai1 et TRPC1, et deuxièmement l'importance de la fraction membranaire de STIM1 (STIMPM) puisque l'utilisation d'un anticorps monoclonal anti-STIM1 (Acm) est capable d’inhiber l'entrée constitutive du calcium qui à son tour agit sur la survie des LB, pour les patients STIMPM positifs, lorsque l'Acm anti-STIM1 est utilisé en association avec le rituximab, un Acm thérapeutique anti-CD20. Enfin, la modélisation de la partie Cterminale de STIM1 permet d'envisager plusieurs cibles potentielles pour le développement de nouveaux Acm anti-STIM1. En conclusion, la mise en place, par le clone malin de LLC, d'une entrée constitutive du calcium favorise son agressivité et constitue donc une nouvelle voie thérapeutique contrôlable par l'utilisation d’Acm anti-STIM1 ce qui ouvre de nouvelles perspectives comme outils diagnostiques et thérapeutiques. / Chronic lymphocytic leukemia (CLL) is the most common hematological malignancy in Western countries and is a result of the accumulation of mature monoclonal B lymphocytes (B-CLL) carrying the CD5 glycoprotein. The B-CLL are also characterized by an alteration of calcium homeostasis with, on the one hand, the demonstration of calcium-controlled survival factors such as phospho-ERK, NFAT- 2 and IL-10, and on the other hand by a progression of the disease which is associated with the response to calcium. Initially, in order to better understand the impact of the CD5 molecule on calcium deregulations, it has been shown that the introduction of an expression plasmid for CD5 into human B cell lines was accompanied by a calcium entry in the basal state. Then, this entry, called constitutive entry, was sought in the B-CLL to show that it characterized untreated patients in the evolution phase.As with CD5 B cell lines, this new calcium entry pathway is autonomous and independent of the classical B-CLL signaling pathway: BCR-IP3R. The study of the proteins responsible for this influx made it possible to highlight, firstly three partners (STIM1, Orai1 and TRPC1), and secondly the importance of the membrane fraction of STIM1 (STIMPM) since the use of a human monoclonal antibody (mAb) anti-STIM1 is able to inhibit the constitutive entry of calcium which in turn acts on the survival of B-CLL, for STIMPM positive patients, when the anti-STIM1 mAb was used in combination with rituximab, a therapeutic anti-CD20 mAb. Finally, the modeling of the C-terminal part of STIM1 makes it possible to envisage several potential targets for the development of new anti-STIM1 mAbs. In conclusion, the introduction by the CLL malignant clone of a constitutive entry of calcium favors its aggressiveness and thus constitutes a new therapeutic pathway controllable by the use of anti-STIM1 mAb, which opens new perspectives like diagnostic and therapeutic tools.

Signalisation calcique

Leucémie lymphoïde chronique

Lymphocyte B

STIM

Thérapie

Calcium signaling

Chronic lymphocytic leukemia

B lymphocyte

STIM1

Therapy

571.967

616.15