cAMP Gs dynamic kit HTRF®

Name: cAMP Gs dynamic kit
Brand: Cisbio
SKU: 40361
Availability: InStock

Produits associés

This HTRF kit detects changes of cAMP accumulation in response to Gs coupled GPCR activation or inhibition

Voir plus d’informations

Ease-of-use
High sensitivity
Accurate pharmacology

Télécharger les protocoles

This HTRF kit detects changes of cAMP accumulation in response to Gs coupled GPCR activation or inhibition

Taille

Référence sélectionnée: :

Quantité

Overview

Based on HTRF technology, the kit contains all the reagents needed to quantify cAMP, ensuring that you benefit from a complete tool for your needs.

Cisbio's cAMP kits are best suited for measuring cAMP modulations in response to Gs-activation, leveraging an optimized combination of robustness and sensitivity

Benefits

SCREENING OF GS COUPLED GPCR
LEAD OPTIMIZATION OF GS COMPOUNDS
STUDY OF GS GPCR RESPONSES

Assay principle

cAMP kits are based on a competitive format involving a specific antibody labeled with cryptate (donor) and cAMP coupled to d2 (acceptor). This enables the direct characterization of all types of compounds acting on Gs-coupled receptors in either adherent or suspension cells. Native cAMP produced by cells competes with d2-labeled cAMP for binding to monoclonal anti-cAMP Eu3+ cryptate.

Assay protocol

The protocol is simple and straightforward, with just two incubation steps: - Cell stimulation by the target compounds - cAMP detection using HTRF reagents

cAMP Gs dynamic product specifications

Use this optimized kit to study your most challenging and precious cellular models.

Designed to produce results with minimal cell consumption, this kit features the lowest nanomolar IC50.

Left-shifted IC50 enables you to quantify lower cAMP concentrations, significantly reducing the number of cells required.

cAMP Gs dynamic standard curve characteristics

	S/B	IC20 nM	IC50 nM	IC80 nM
cAMP - Gs dynamic	>14	0.91	4.07	18.1
cAMP - Gs HiRange	>28	4.27	22.8	121

Validation on agonist dose response

HEK293 cells expressing the endogenous ß2 adrenergic receptor were treated with the isoproterenol agonist for 45min.

Isoproterenol was well characterized, displaying the right potency in good correlation with the literature.

Isoproterenol agonist does response on the B2 adrenergic receptor

Validation on antagonist dose response

HEK293 cells at 7,500 cells/well (optimal cellular concentration situated in the dynamic range of the kit) were treated with a serial concentration of isoproterenol, a beta 2 adrenergic receptor full-agonist.

The EC80-EC90 was determined to choose the optimal agonist concentration to use for the antagonist mode experiment.

Fitting the serial dilution of the antagonist allowed IC50 calculation for the compounds (potency) which was in perfect correlation with the literature.

Propanolol antagonist does response on the B2 adrenergic receptor

Can HTRF technology answer to different scientific questions? An academic with industrial standards point of view

In collaboration with CNRS - Présentations scientifiaues

Structure, function and pharmacology of G protein-coupled receptors: State-of-the-art and future challenges

In collaboration with the Faculty of health and medical sciences Denmark - Présentations scientifiaues

HTRF assays of IP1, cAMP and pERK pathways employed to study biased signaling of the calcium-sensing receptor

In collaboration with the Faculty of health and medical sciences Denmark - Présentations scientifiaues

Identification and characterization of allosteric modulators of GPCRs: The utility of HTRF and incorporation into generalised screening strategies

In collaboration with MRC technology - Présentations scientifiaues

HTRF a versatil approach for 7TM drug discovery

In collaboration with MRC - Présentations scientifiaues

Novel Functional Assay Approaches for GPCR Ligand Discovery. Comparison of three different technologies to assess slow acting agonist activity. FLIPR, CellKey and IP-One HTRF

In collaboration with Novartis - Présentations scientifiaues

cAMP Fresh and Frozen Cell Usage

In collaboration with Bristol Myers Squibb - Présentations scientifiaues

IP-One & cAMP HTRF Functional Cell-based Screening

In collaboration with Schering AG - Présentations scientifiaues

Biomarker and Cell Signaling Assays for Fibrosis and NASH

HTRF solutions for NASH - Flyers

GPCR research from A to Z

HTRF products and supporting scientific content to investifgate GPCRs - Flyers

Application of Bioassay Performance Monitoring Process with Statistical Tools

In collaboration with Amylin Pharmaceuticals Inc., Biocon Limited - Posters

High Throughput Tag-Lite® Cell-based Functional and Surface Binding Assays on the SpectraMax®Paradigm Plate Reader Platform

In collaboration with Molecular Devices - Posters

Nanobodies and HTRF® technology to address an orphan class B GPCR: The GPR97 receptor

In collaboration with Sanofi - Posters

Characterisation of Inositol Phosphate & cAMP Signalling from GPCRs using HTRF

In collaboration with College of Science, King Saud University, University of Western Australia - Posters

HTRF® technology on the SpectraMax® i3 Multi-Mode Platform

In collaboration with Mollecular Devices - Posters

Structure-activity characterization of glucagon receptor, an example of using HTRF®cAMP assay

In collaboration with Chinese Academy of Sciences - Posters

HTRF cell-based assays to establish relationships between G protein activation and downstream pathways

Multidimentional GPCR investigations - Posters

Identification of human endogenous calcitonin receptor in 293H cell lines: characterization by cyclic AMP and calcium mobilization

In collaboration with CEREP - Posters

Differentiation of partial and full GPR40 agonists for the treatment of type 2diabetes

In collaboration with Jansen research & development - Posters

Webinar: Advancing GPCR drug discovery through Allosteric Modulation

Featuring a panel of experts - Vidéos

Ultimate guides to master Gs and Gi GPCR assays

Optimizing cAMP assays has never been easier - Guides

Webinar: High-Throughput Screening of GPCRs for Drug Discovery Applications

Featuring a panel of experts - Vidéos

HTRF and Tag-lite technologies in multidimensional cell-based assays for GPCR investigations

4 GPCR challenges, 1 solution - Posters

Understanding GPCRs is the key to improved DD

In collaboration with GEN - Guides

Guidelines and recommendations for analyzing GPCR 2nd messenger data

Written by a panel of experts - Guides

How to run a cAMP HTRF assay

What to expect at the bench - Vidéos

Product Insert cAMP Gs dyn / 62AM4PEB-62AM4PEC-62AM4PEJ

62AM4PEB-62AM4PEC-62AM4PEJ - Protocoles

Quantitate cAMP and TNF Utilizing the Synergy 2 Multi-Detection Microplate Reader and HTRF assays

BioTek - Notes d'application

Cisbio Product Catalog 2019

All your HTRF assays in one document! - Catalogue

A guide to Homogeneous Time Resolved Fluorescence

General principles of HTRF - Guides

How HTRF compares to Western Blot and ELISA

Get the brochure about technology comparison. - Brochures

GPCR signaling in cardiovascular research addressed with HTRF 2nd messenger assays

See how peer researchers monitor GPCR signaling with HTRF - Notes d'application

Molecular basis of neuroinflammation and neurodegeneration diseases

The essential guide for extending your knowledge on the molecular mechanisms of neurodegenerative diseases - Guides

Neurodegeneration and its main related diseases

Discover this infographic design on neurodegenerative diseases - Infographies

GPCRs Pharmacology

A comprehensive overview of pharmacology's main ligands - Guides

Three drug discovery approaches for Multiple Sclerosis

Power up your multiple sclerosis research projects with this technical note - Notes d'application

GPCR compounds identification and pharmacological characterization with GTP Gi binding assay

Characterization of candidate molecules through GTP binding assays - Notes d'application

Upstream/Downstream GPCR Readout Monitoring with GTP Gi Binding and cAMP Gi HTRF Assays

Read this note featuring two case studies that demonstrate the relevance of combining upstream (GTP) and downstream (cAMP) readouts for characterizing pharmacological compounds - Notes d'application

GPCRs: the pathway to Discovery

Complete solutions for GPCR Drug Discovery - Brochures

Cyclic-AMP: A Functional Second Messenger for Assaying GPCR Target Activation

Selection of kits to detect of a broad range of cAMP - Notes d'application

Safety Data Sheet cAMP Gs dyn / 62AM4PEB

62AM4PEB - Fiches de sécurité

Safety Data Sheet (DEU) cAMP Gs dyn / 62AM4PEB

62AM4PEB - Fiches de sécurité

Safety Data Sheet (ELL) cAMP Gs dyn / 62AM4PEB

62AM4PEB - Fiches de sécurité

Safety Data Sheet (FRA-FR) cAMP Gs dyn / 62AM4PEB

62AM4PEB - Fiches de sécurité

Safety Data Sheet (ITA) cAMP Gs dyn / 62AM4PEB

62AM4PEB - Fiches de sécurité

Safety Data Sheet (SPA) cAMP Gs dyn / 62AM4PEB

62AM4PEB - Fiches de sécurité

Safety Data Sheet (ENG-GB) cAMP Gs dyn / 62AM4PEB

62AM4PEB - Fiches de sécurité

Safety Data Sheet (ENG-US) cAMP Gs dyn / 62AM4PEB

62AM4PEB - Fiches de sécurité

Safety Data Sheet cAMP Gs dyn / 62AM4PEC

62AM4PEC - Fiches de sécurité

Safety Data Sheet (DEU) cAMP Gs dyn / 62AM4PEC

62AM4PEC - Fiches de sécurité

Safety Data Sheet (ELL) cAMP Gs dyn / 62AM4PEC

62AM4PEC - Fiches de sécurité

Safety Data Sheet (FRA-FR) cAMP Gs dyn / 62AM4PEC

62AM4PEC - Fiches de sécurité

Safety Data Sheet (ITA) cAMP Gs dyn / 62AM4PEC

62AM4PEC - Fiches de sécurité

Safety Data Sheet (SPA) cAMP Gs dyn / 62AM4PEC

62AM4PEC - Fiches de sécurité

Safety Data Sheet (ENG-GB) cAMP Gs dyn / 62AM4PEC

62AM4PEC - Fiches de sécurité

Safety Data Sheet (ENG-US) cAMP Gs dyn / 62AM4PEC

62AM4PEC - Fiches de sécurité

Plate Reader Requirement

Choosing the right microplate reader ensures you’ll get an optimal readout. Discover our high performance reader, or verify if your lab equipment is going to be compatible with this detection technology.

Let's find your reader