CANDLES, an assay for monitoring GPCR induced cAMP generation in cell cultures

G protein-coupled receptors (GPCRs) represent a physiologically and pharmacologically important family of receptors that upon coupling to GαS stimulate cAMP production catalyzed by adenylyl cyclase. Thus, developing assays to monitor cAMP production is crucial to screen for ligands in studies of GPC...

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Veröffentlicht in:	Cell communication and signaling 2014-11, Vol.12 (1), p.70-70, Article 70
Hauptverfasser:	Trehan, Ashutosh, Rotgers, Emmi, Coffey, Eleanor T, Huhtaniemi, Ilpo, Rivero-Müller, Adolfo
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Sprache:	eng
Schlagworte:	Analysis Animals Biological Assay Cell Communication Cell Line Cells, Cultured Cerebral Cortex - cytology Coculture Techniques Colleges & universities Competition Cyclic adenylic acid Cyclic AMP - metabolism Experiments Female Gap Junctions - metabolism Glycoproteins Granulosa Cells - metabolism HEK293 Cells Humans Kinases Ligands Medical screening Methodology Methods Mice, Inbred C57BL Mutation Neurons - metabolism Physiological aspects Proteins Rats, Sprague-Dawley Receptors, G-Protein-Coupled - metabolism Sensors
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creator	Trehan, Ashutosh Rotgers, Emmi Coffey, Eleanor T Huhtaniemi, Ilpo Rivero-Müller, Adolfo
description	G protein-coupled receptors (GPCRs) represent a physiologically and pharmacologically important family of receptors that upon coupling to GαS stimulate cAMP production catalyzed by adenylyl cyclase. Thus, developing assays to monitor cAMP production is crucial to screen for ligands in studies of GPCR signaling. Primary cell cultures represent a more robust model than cell lines to study GPCR signaling since they physiologically resemble the parent tissue. Current cAMP assays have two fundamental limitations: 1) absence of cAMP kinetics as competition-based assays require cell lysis and measure only a single time-point, and 2) high variation with separate samples needed to measure consecutive time points. The utility of real-time cAMP biosensors is also limited in primary cell cultures due to their poor transfection efficiency, variable expression levels and inability to select stable clones. We therefore, decided to develop an assay that can measure cAMP not only at a single time-point but the entire cAMP kinetics after GPCR activation in untransfected primary cells. CANDLES (Cyclic AMP iNdirect Detection by Light Emission from Sensor cells) assay for monitoring cAMP kinetics in cell cultures, particularly in primary cultures was developed. The assay requires co-culturing of primary cells with sensor cells that stably express a luminescent cAMP sensor. Upon GPCR activation in primary cells, cAMP is transferred to sensor cells via gap junction channels, thereby evoking a luminescent read-out. GPCR activation using primary cultures of rat cortical neurons and mouse granulosa cells was measured. Kinetic responses of different agonists to adrenergic receptors were also compared using rat cortical neurons. The assay optimization was done by varying sensor-test cell ratio, using phosphodiesterase inhibitors and testing cell-cell contact requirement. Here we present CANDLES assay based on co-culturing test cells with cAMP-detecting sensor cells. This co-culture setup allows kinetic measurements, eliminates primary cell transfections and reduces variability. A variety of cell types (rat cortical neurons, mouse granulosa cells and established cell lines) and receptors (adrenergic, follicle stimulating hormone and luteinizing hormone/chorionic gonadotropin receptors) were tested for use with CANDLES. The assay is best applied while comparing cAMP generation curves upon different drug treatments to untransfected primary cells.
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CANDLES (Cyclic AMP iNdirect Detection by Light Emission from Sensor cells) assay for monitoring cAMP kinetics in cell cultures, particularly in primary cultures was developed. The assay requires co-culturing of primary cells with sensor cells that stably express a luminescent cAMP sensor. Upon GPCR activation in primary cells, cAMP is transferred to sensor cells via gap junction channels, thereby evoking a luminescent read-out. GPCR activation using primary cultures of rat cortical neurons and mouse granulosa cells was measured. Kinetic responses of different agonists to adrenergic receptors were also compared using rat cortical neurons. The assay optimization was done by varying sensor-test cell ratio, using phosphodiesterase inhibitors and testing cell-cell contact requirement. Here we present CANDLES assay based on co-culturing test cells with cAMP-detecting sensor cells. This co-culture setup allows kinetic measurements, eliminates primary cell transfections and reduces variability. A variety of cell types (rat cortical neurons, mouse granulosa cells and established cell lines) and receptors (adrenergic, follicle stimulating hormone and luteinizing hormone/chorionic gonadotropin receptors) were tested for use with CANDLES. 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CANDLES (Cyclic AMP iNdirect Detection by Light Emission from Sensor cells) assay for monitoring cAMP kinetics in cell cultures, particularly in primary cultures was developed. The assay requires co-culturing of primary cells with sensor cells that stably express a luminescent cAMP sensor. Upon GPCR activation in primary cells, cAMP is transferred to sensor cells via gap junction channels, thereby evoking a luminescent read-out. GPCR activation using primary cultures of rat cortical neurons and mouse granulosa cells was measured. Kinetic responses of different agonists to adrenergic receptors were also compared using rat cortical neurons. The assay optimization was done by varying sensor-test cell ratio, using phosphodiesterase inhibitors and testing cell-cell contact requirement. Here we present CANDLES assay based on co-culturing test cells with cAMP-detecting sensor cells. This co-culture setup allows kinetic measurements, eliminates primary cell transfections and reduces variability. A variety of cell types (rat cortical neurons, mouse granulosa cells and established cell lines) and receptors (adrenergic, follicle stimulating hormone and luteinizing hormone/chorionic gonadotropin receptors) were tested for use with CANDLES. 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Academic</collection><collection>PubMed Central (Full Participant titles)</collection><jtitle>Cell communication and signaling</jtitle></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext</fulltext></delivery><addata><au>Trehan, Ashutosh</au><au>Rotgers, Emmi</au><au>Coffey, Eleanor T</au><au>Huhtaniemi, Ilpo</au><au>Rivero-Müller, Adolfo</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>CANDLES, an assay for monitoring GPCR induced cAMP generation in cell cultures</atitle><jtitle>Cell communication and signaling</jtitle><addtitle>Cell Commun Signal</addtitle><date>2014-11-04</date><risdate>2014</risdate><volume>12</volume><issue>1</issue><spage>70</spage><epage>70</epage><pages>70-70</pages><artnum>70</artnum><issn>1478-811X</issn><eissn>1478-811X</eissn><abstract>G protein-coupled receptors (GPCRs) represent a physiologically and pharmacologically important family of receptors that upon coupling to GαS stimulate cAMP production catalyzed by adenylyl cyclase. Thus, developing assays to monitor cAMP production is crucial to screen for ligands in studies of GPCR signaling. Primary cell cultures represent a more robust model than cell lines to study GPCR signaling since they physiologically resemble the parent tissue. Current cAMP assays have two fundamental limitations: 1) absence of cAMP kinetics as competition-based assays require cell lysis and measure only a single time-point, and 2) high variation with separate samples needed to measure consecutive time points. The utility of real-time cAMP biosensors is also limited in primary cell cultures due to their poor transfection efficiency, variable expression levels and inability to select stable clones. We therefore, decided to develop an assay that can measure cAMP not only at a single time-point but the entire cAMP kinetics after GPCR activation in untransfected primary cells. CANDLES (Cyclic AMP iNdirect Detection by Light Emission from Sensor cells) assay for monitoring cAMP kinetics in cell cultures, particularly in primary cultures was developed. The assay requires co-culturing of primary cells with sensor cells that stably express a luminescent cAMP sensor. Upon GPCR activation in primary cells, cAMP is transferred to sensor cells via gap junction channels, thereby evoking a luminescent read-out. GPCR activation using primary cultures of rat cortical neurons and mouse granulosa cells was measured. Kinetic responses of different agonists to adrenergic receptors were also compared using rat cortical neurons. The assay optimization was done by varying sensor-test cell ratio, using phosphodiesterase inhibitors and testing cell-cell contact requirement. Here we present CANDLES assay based on co-culturing test cells with cAMP-detecting sensor cells. This co-culture setup allows kinetic measurements, eliminates primary cell transfections and reduces variability. A variety of cell types (rat cortical neurons, mouse granulosa cells and established cell lines) and receptors (adrenergic, follicle stimulating hormone and luteinizing hormone/chorionic gonadotropin receptors) were tested for use with CANDLES. The assay is best applied while comparing cAMP generation curves upon different drug treatments to untransfected primary cells.</abstract><cop>England</cop><pub>BioMed Central Ltd</pub><pmid>25366423</pmid><doi>10.1186/s12964-014-0070-x</doi><tpages>1</tpages><oa>free_for_read</oa></addata></record>
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subjects	Analysis Animals Biological Assay Cell Communication Cell Line Cells, Cultured Cerebral Cortex - cytology Coculture Techniques Colleges & universities Competition Cyclic adenylic acid Cyclic AMP - metabolism Experiments Female Gap Junctions - metabolism Glycoproteins Granulosa Cells - metabolism HEK293 Cells Humans Kinases Ligands Medical screening Methodology Methods Mice, Inbred C57BL Mutation Neurons - metabolism Physiological aspects Proteins Rats, Sprague-Dawley Receptors, G-Protein-Coupled - metabolism Sensors
title	CANDLES, an assay for monitoring GPCR induced cAMP generation in cell cultures
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