camizestrant [Ligand Id: 12716] activity data from GtoPdb and ChEMBL
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| ChEMBL ligand: CHEMBL4650365 (AZ-14066724, AZ14066724, Azd9833, AZD-9833, AZD9833, Camizestrant) |
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| DB | Assay description | Assay Type | Standard value | Standard parameter | Original value | Original units | Original parameter | Reference |
|---|---|---|---|---|---|---|---|---|
| Estrogen receptor-α/Estrogen receptor in Human (target type: SINGLE PROTEIN) [ChEMBL: CHEMBL206] [GtoPdb: 620] [UniProtKB: P03372] | ||||||||
| ChEMBL | Binding Assay: ER: The ability of compounds to bind to isolated Estrogen Receptor Alpha Ligand binding domain (ER alpha-LBD (GST)) was assessed in competition assays using a LanthaScreen Time-Resolved Fluorescence Resonance Energy Transfer (TR-FRET) detection end-point. For the LanthaScreen TR-FRET endpoint, a suitable fluorophore (Fluormone ES2, ThermoFisher, Product code P2645) and recombinant human Estrogen Receptor alpha ligand binding domain, residues 307-554 (expressed and purified in-house) were used to measure compound binding. The assay principle is that ER alpha-LBD (GST) is added to a fluorescent ligand to form a receptor/fluorophore complex. A terbium-labelled anti-GST antibody (Product code PV3551) is used to indirectly label the receptor by binding to its GST tag, and competitive binding is detected by a test compound's ability to displace the fluorescent ligand, resulting in a loss of TR-FRET signal between the Tb-anti-GST antibody and the tracer. The assay was performed as follows with all reagent additions carried out using the Beckman Coulter BioRAPTR FRD microfluidic workstation: 1. Acoustic dispense 120 nL of the test compound into a black low volume 384 well assay plates. 2. Prepare 1×ER alpha-LBD/Tb-antiGST Ab in ES2 screening buffer and incubate for 15 minutes. 3. Dispense 6 μL of the 1×AR-LBD/Tb-anti-GST Ab reagent into each well of the assay plate followed by 6 μL of Fluorophore reagent into each well of the assay plate 4. Cover the assay plate to protect the reagents from light and evaporation, and incubate at room temperature for 4 hours. 5. Excite at 337 nm and measure the fluorescent emission signal of each well at 490 nm and 520 nm using the BMG PheraSTAR.Compounds were dosed directly from a compound source microplate containing serially diluted compound (4 wells containing 10 mM, 0.1 mM, 1 mM and 10 nM final compound respectively) to an assay microplate using the Labcyte Echo 550. The Echo 550 is a liquid handler that uses acoustic technology to perform direct microplate-to-microplate transfers of DMSO compound solutions and the system can be programmed to transfer multiple small nL volumes of compound from the different source plate wells to give the desired serial dilution of compound in the assay which is then back-filled to normalise the DMSO concentration across the dilution range. | B | 4.66 | pIC50 | 22000 | nM | IC50 | US-10590130-B2. Chemical compounds (2020) |
| ChEMBL | Binding Assay: ER: The ability of compounds to bind to isolated Estrogen Receptor Alpha Ligand binding domain (ER alpha-LBD (GST)) was assessed in competition assays using a LanthaScreen Time-Resolved Fluorescence Resonance Energy Transfer (TR-FRET) detection end-point. For the LanthaScreen TR-FRET endpoint, a suitable fluorophore (Fluormone ES2, ThermoFisher, Product code P2645) and recombinant human Estrogen Receptor alpha ligand binding domain, residues 307-554 (expressed and purified in-house) were used to measure compound binding. The assay principle is that ER alpha-LBD (GST) is added to a fluorescent ligand to form a receptor/fluorophore complex. A terbium-labelled anti-GST antibody (Product code PV3551) is used to indirectly label the receptor by binding to its GST tag, and competitive binding is detected by a test compound's ability to displace the fluorescent ligand, resulting in a loss of TR-FRET signal between the Tb-anti-GST antibody and the tracer. The assay was performed as follows with all reagent additions carried out using the Beckman Coulter BioRAPTR FRD microfluidic workstation: 1. Acoustic dispense 120 nL of the test compound into a black low volume 384 well assay plates. 2. Prepare 1×ER alpha-LBD/Tb-antiGST Ab in ES2 screening buffer and incubate for 15 minutes. 3. Dispense 6 μL of the 1×AR-LBD/Tb-anti-GST Ab reagent into each well of the assay plate followed by 6 μL of Fluorophore reagent into each well of the assay plate 4. Cover the assay plate to protect the reagents from light and evaporation, and incubate at room temperature for 4 hours. 5. Excite at 337 nm and measure the fluorescent emission signal of each well at 490 nm and 520 nm using the BMG PheraSTAR.Compounds were dosed directly from a compound source microplate containing serially diluted compound (4 wells containing 10 mM, 0.1 mM, 1 mM and 10 nM final compound respectively) to an assay microplate using the Labcyte Echo 550. The Echo 550 is a liquid handler that uses acoustic technology to perform direct microplate-to-microplate transfers of DMSO compound solutions and the system can be programmed to transfer multiple small nL volumes of compound from the different source plate wells to give the desired serial dilution of compound in the assay which is then back-filled to normalise the DMSO concentration across the dilution range. | B | 4.85 | pIC50 | 14000 | nM | IC50 | US-10590130-B2. Chemical compounds (2020) |
| ChEMBL | Agonist activity at ERalpha in human MCF7 cells assessed as increase in progesterone receptor expression level by western blot analysis | B | 6.5 | pIC50 | >316.23 | nM | IC50 | J Med Chem (2020) 63: 14530-14559 [PMID:32910656] |
| ChEMBL | Induction of ERalpha degradation in human MCF7 cells assessed as decrease in ERalpha expression in presence of tamoxifen by Western blot analysis | B | 8.2 | pIC50 | 6.31 | nM | IC50 | J Med Chem (2020) 63: 14530-14559 [PMID:32910656] |
| ChEMBL | Displacement of fluorescent labelled fluormone ES2 from human recombinant GST tagged ER alpha LBD ( 282 to 595 residues) expressed in baculovirus infected insect cells incubate for 20 mins measured after 1 hr by TR-FRET Lanthascreen assay | B | 8.6 | pIC50 | 2.51 | nM | IC50 | ACS Med Chem Lett (2020) 11: 2519-2525 [PMID:33335676] |
| ChEMBL | Displacement of fluormone ES2 green reagent from human GST-tagged ERalpha LBD (282 to 595 residues) expressed in baculovirus infected insect cells incubated for 1 hrs by TR-FRET Lanthascreen assay | B | 8.6 | pIC50 | 2.51 | nM | IC50 | J Med Chem (2020) 63: 14530-14559 [PMID:32910656] |
| ChEMBL | Binding Assay: The assay was performed as follows with all reagent additions carried out using the Beckman Coulter BioRAPTR FRD microfluidic workstation:1. Acoustic dispense 120 nL of the test compound into a black low volume 384 well assay plates.2. Prepare 1×ER alpha-LBD/Tb-antiGST Ab in ES2 screening buffer and incubate for 15 minutes.3. Dispense 6 μL of the 1×AR-LBD/Tb-anti-GST Ab reagent into each well of the assay plate followed by 6 μL of Fluorophore reagent into each well of the assay plate4. Cover the assay plate to protect the reagents from light and evaporation, and incubate at room temperature for 4 hours.5. Excite at 337 nm and measure the fluorescent emission signal of each well at 490 nm and 520 nm using the BMG PheraSTAR. | B | 8.62 | pIC50 | 2.4 | nM | IC50 | US-10961241-B2. Chemical compounds (2021) |
| ChEMBL | Binding Assay: The assay was performed as follows with all reagent additions carried out using the Beckman Coulter BioRAPTR FRD microfluidic workstation:1. Acoustic dispense 120 nL of the test compound into a black low volume 384 well assay plates.2. Prepare 1×ER alpha-LBD/Tb-antiGST Ab in ES2 screening buffer and incubate for 15 minutes.3. Dispense 6 μL of the 1×AR-LBD/Tb-anti-GST Ab reagent into each well of the assay plate followed by 6 μL of Fluorophore reagent into each well of the assay plate4. Cover the assay plate to protect the reagents from light and evaporation, and incubate at room temperature for 4 hours.5. Excite at 337 nm and measure the fluorescent emission signal of each well at 490 nm and 520 nm using the BMG PheraSTAR. | B | 8.74 | pIC50 | 1.8 | nM | IC50 | US-10961241-B2. Chemical compounds (2021) |
| ChEMBL | ERalpha Binding Assay: The assay principle is that ER alpha-LBD (GST) is added to a fluorescent ligand to form a receptor/fluorophore complex. A terbium-labelled anti-GST antibody (Product code PV3551) is used to indirectly label the receptor by binding to its GST tag, and competitive binding is detected by a test compound's ability to displace the fluorescent ligand, resulting in a loss of TR-FRET signal between the Tb-anti-GST antibody and the tracer. The assay was performed as follows with all reagent additions carried out using the Beckman Coulter BioRAPTR FRD microfluidic workstation:1. Acoustic dispense 120 nL of the test compound into a black low volume 384 well assay plates.2. Prepare 1×ER alpha-LBD/Tb-antiGST Ab in ES2 screening buffer and incubate for 15 minutes.3. Dispense 6 μL of the 1×AR-LBD/Tb-anti-GST Ab reagent into each well of the assay plate followed by 6 μL of Fluorophore reagent into each well of the assay plate4. Cover the assay plate to protect the reagents from light and evaporation, and incubate at room temperature for 4 hours.5. Excite at 337 nm and measure the fluorescent emission signal of each well at 490 nm and 520 nm using the BMG PheraSTAR.Compounds were dosed directly from a compound source microplate containing serially diluted compound (4 wells containing 10 mM, 0.1 mM, 1 mM and 10 nM final compound respectively) to an assay microplate using the Labcyte Echo 550. The Echo 550 is a liquid handler that uses acoustic technology to perform direct microplate-to-microplate transfers of DMSO compound solutions and the system can be programmed to transfer multiple small nL volumes of compound from the different source plate wells to give the desired serial dilution of compound in the assay which is then back-filled to normalise the DMSO concentration across the dilution range.In total 120 nL of compound plus DMSO were added to each well and compounds were tested in a 12-point concentration response format over a final compound concentration range of 10, 2.917, 1.042, 0.2083, 0.1, 0.0292, 0.0104, 0.002083, 0.001, 0.0002917, 0.0001042, and 0.00001 μM respectively. TR-FRET dose response data obtained with each compound was exported into a suitable software package (such as Origin or Genedata) to perform curve fitting analysis. Competitive ER alpha binding was expressed as an IC50 value. | B | 8.74 | pIC50 | 1.8 | nM | IC50 | US-10131663-B2. Chemical compounds (2018) |
| ChEMBL | Binding Assay: The assay was performed as follows with all reagent additions carried out using the Beckman Coulter BioRAPTR FRD microfluidic workstation:1. Acoustic dispense 120 nL of the test compound into a black low volume 384 well assay plates.2. Prepare 1×ER alpha-LBD/Tb-antiGST Ab in ES2 screening buffer and incubate for 15 minutes.3. Dispense 6 μL of the 1×AR-LBD/Tb-anti-GST Ab reagent into each well of the assay plate followed by 6 μL of Fluorophore reagent into each well of the assay plate4. Cover the assay plate to protect the reagents from light and evaporation, and incubate at room temperature for 4 hours.5. Excite at 337 nm and measure the fluorescent emission signal of each well at 490 nm and 520 nm using the BMG PheraSTAR. | B | 8.82 | pIC50 | 1.5 | nM | IC50 | US-10961241-B2. Chemical compounds (2021) |
| ChEMBL | ERalpha Binding Assay: The assay principle is that ER alpha-LBD (GST) is added to a fluorescent ligand to form a receptor/fluorophore complex. A terbium-labelled anti-GST antibody (Product code PV3551) is used to indirectly label the receptor by binding to its GST tag, and competitive binding is detected by a test compound's ability to displace the fluorescent ligand, resulting in a loss of TR-FRET signal between the Tb-anti-GST antibody and the tracer. The assay was performed as follows with all reagent additions carried out using the Beckman Coulter BioRAPTR FRD microfluidic workstation:1. Acoustic dispense 120 nL of the test compound into a black low volume 384 well assay plates.2. Prepare 1×ER alpha-LBD/Tb-antiGST Ab in ES2 screening buffer and incubate for 15 minutes.3. Dispense 6 μL of the 1×AR-LBD/Tb-anti-GST Ab reagent into each well of the assay plate followed by 6 μL of Fluorophore reagent into each well of the assay plate4. Cover the assay plate to protect the reagents from light and evaporation, and incubate at room temperature for 4 hours.5. Excite at 337 nm and measure the fluorescent emission signal of each well at 490 nm and 520 nm using the BMG PheraSTAR.Compounds were dosed directly from a compound source microplate containing serially diluted compound (4 wells containing 10 mM, 0.1 mM, 1 mM and 10 nM final compound respectively) to an assay microplate using the Labcyte Echo 550. The Echo 550 is a liquid handler that uses acoustic technology to perform direct microplate-to-microplate transfers of DMSO compound solutions and the system can be programmed to transfer multiple small nL volumes of compound from the different source plate wells to give the desired serial dilution of compound in the assay which is then back-filled to normalise the DMSO concentration across the dilution range.In total 120 nL of compound plus DMSO were added to each well and compounds were tested in a 12-point concentration response format over a final compound concentration range of 10, 2.917, 1.042, 0.2083, 0.1, 0.0292, 0.0104, 0.002083, 0.001, 0.0002917, 0.0001042, and 0.00001 μM respectively. TR-FRET dose response data obtained with each compound was exported into a suitable software package (such as Origin or Genedata) to perform curve fitting analysis. Competitive ER alpha binding was expressed as an IC50 value. | B | 8.82 | pIC50 | 1.5 | nM | IC50 | US-10131663-B2. Chemical compounds (2018) |
| ChEMBL | MCF-7 ER Down-Regulation Assay: The ability of compounds to down-regulate Estrogen Receptor (ER) numbers was assessed in a cell based immuno-fluorescence assay using the MCF-7 human ductal carcinoma breast cell line. MCF-7 cells were revived directly from a cryovial (approx 5×106 cells) in Assay Medium (phenol red free Dulbecco's Modified Eagle's medium (DMEM); Sigma D5921) containing 2 mM L-Glutamine and 5% (v/v) Charcoal/Dextran treated foetal calf serum. Cells were syringed once using a sterile 18G×1.5 inch (1.2×40 mm) broad gauge needle and cell density was measured using a Coulter Counter (Beckman). Cells were further diluted in Assay Medium to a density of 3.75×104 cells per mL and 40 μL per well added to transparent bottomed, black, tissue culture-treated 384 well plates (Costar, No. 3712) using a Thermo Scientific Matrix WellMate or Thermo Multidrop. Following cell seeding, plates were incubated overnight at 37° C., 5% CO2 (Liconic carousel incubator). Test data was generated using the LabCyte Echo model 555 compound reformatter which is part of an automated workcell (Integrated Echo 2 workcell). Compound stock solutions (10 mM) of the test compounds were used to generate a 384 well compound dosing plate (Labcyte P-05525-CV1). 40 μL of each of the 10 mM compound stock solutions was dispensed into the first quadrant well and then 1:100 step-wise serial dilutions in DMSO were performed using a Hydra II (MATRIX UK) liquid handling unit to give 40 μL of diluted compound into quadrant wells 2 (0.1 mM), 3 (1 μM) and 4 (0.01 μM), respectively. 40 μL of DMSO added to wells in row P on the source plate allowed for DMSO normalisation across the dose range. To dose the control wells 40 μL of DMSO was added to row O1 and 40 μL of 100 μM fulvestrant in DMSO was added to row O3 on the compound source plate. | B | 9.77 | pIC50 | 0.17 | nM | IC50 | US-10131663-B2. Chemical compounds (2018) |
| ChEMBL | Induction of ERalpha degradation in human MCF7 cells incubated for 18 to 22 hrs by immuno-fluorescence assay | B | 9.8 | pIC50 | 0.16 | nM | IC50 | ACS Med Chem Lett (2020) 11: 2519-2525 [PMID:33335676] |
| ChEMBL | Induction of ERalpha degradation in human MCF7 cells assessed as decrease in ER-alpha level incubated for 18 to 24 hrs by Alexa fluor 488/Hoechst staining based immunofluorescence imaging analysis | B | 9.8 | pIC50 | 0.16 | nM | IC50 | J Med Chem (2020) 63: 14530-14559 [PMID:32910656] |
| ChEMBL | Induction of ERalpha degradation in human MCF7 cells assessed as decrease in ERalpha expression by Western blot analysis | B | 9.8 | pIC50 | 0.16 | nM | IC50 | J Med Chem (2020) 63: 14530-14559 [PMID:32910656] |
| GtoPdb | - | - | 9.8 | pIC50 | 0.16 | nM | IC50 | J Med Chem (2020) 63: 14530-14559 [PMID:32910656] |
| ChEMBL | Induction of ERalpha degradation in human MCF7 cells assessed as decrease in ERalpha expression in presence of cycloheximide by Western blot analysis | B | 9.9 | pIC50 | 0.13 | nM | IC50 | J Med Chem (2020) 63: 14530-14559 [PMID:32910656] |
| ChEMBL | MCF-7 ER Down-Regulation Assay: The ability of compounds to down-regulate Estrogen Receptor (ER) numbers was assessed in a cell based immuno-fluorescence assay using the MCF-7 human ductal carcinoma breast cell line. MCF-7 cells were revived directly from a cryovial (approx 5×106 cells) in Assay Medium (phenol red free Dulbecco's Modified Eagle's medium (DMEM); Sigma D5921) containing 2 mM L-Glutamine and 5% (v/v) Charcoal/Dextran treated foetal calf serum. Cells were syringed once using a sterile 18G×1.5 inch (1.2×40 mm) broad gauge needle and cell density was measured using a Coulter Counter (Beckman). Cells were further diluted in Assay Medium to a density of 3.75×104 cells per mL and 40 μL per well added to transparent bottomed, black, tissue culture-treated 384 well plates (Costar, No. 3712) using a Thermo Scientific Matrix WellMate or Thermo Multidrop. Following cell seeding, plates were incubated overnight at 37° C., 5% CO2 (Liconic carousel incubator). Test data was generated using the LabCyte Echo model 555 compound reformatter which is part of an automated workcell (Integrated Echo 2 workcell). Compound stock solutions (10 mM) of the test compounds were used to generate a 384 well compound dosing plate (Labcyte P-05525-CV1). 40 μL of each of the 10 mM compound stock solutions was dispensed into the first quadrant well and then 1:100 step-wise serial dilutions in DMSO were performed using a Hydra II (MATRIX UK) liquid handling unit to give 40 μL of diluted compound into quadrant wells 2 (0.1 mM), 3 (1 μM) and 4 (0.01 μM), respectively. 40 μL of DMSO added to wells in row P on the source plate allowed for DMSO normalisation across the dose range. To dose the control wells 40 μL of DMSO was added to row O1 and 40 μL of 100 μM fulvestrant in DMSO was added to row O3 on the compound source plate. | B | 9.92 | pIC50 | 0.12 | nM | IC50 | US-10131663-B2. Chemical compounds (2018) |
| ChEMBL | Induction of ERalpha degradation in human MCF7 | B | 9 | pEC50 | <1 | nM | EC50 | J Med Chem (2023) 66: 8339-8381 [PMID:37377342] |
| H3 receptor/Histamine H3 receptor in Human (target type: SINGLE PROTEIN) [ChEMBL: CHEMBL264] [GtoPdb: 264] [UniProtKB: Q9Y5N1] | ||||||||
| ChEMBL | Antagonist activity at human histamine H3 receptor expressed in CHO-K1 cells after 10 mins by HTRF assay | B | 6.48 | pIC50 | 330 | nM | IC50 | J Med Chem (2020) 63: 14530-14559 [PMID:32910656] |
| Kv11.1/Voltage-gated inwardly rectifying potassium channel KCNH2 in Human (target type: SINGLE PROTEIN) [ChEMBL: CHEMBL240] [GtoPdb: 572] [UniProtKB: Q12809] | ||||||||
| ChEMBL | Inhibition of human ERG by plate-based planar patch clamp technique | B | 4.66 | pIC50 | 22000 | nM | IC50 | J Med Chem (2020) 63: 14530-14559 [PMID:32910656] |
| ChEMBL | Binding Assay : hERG (human ether go go-related gene) potassium channels are essential for normal electrical activity in the heart. Arrhythmia can be induced by a blockage of hERG channels by a diverse group of drugs. This side effect is a common reason for drug failure in preclinical safety trials and therefore minimisation of hERG channel blocking activity may be a desirable property for drug candidates.The purpose of the hERG binding assay is to evaluate the effects of test compounds on the voltage-dependent potassium channel encoded by the human ether go go-related gene (hERG) using a constitutively expressing CHO cell line on the Nanion Syncropatch 384PE automated patch clamp system.The assay was conducted as follows with all reagents used at room temperature unless otherwise stated.Reagent Preparations Include:1. Internal IC700 solution used to perfuse the underside of chip (in mM), KF 130, KCl 20, MgCl2 1, EGTA 10 and HEPES 10, (all Sigma-Aldrich; pH 7.2-7.3 using 10 M KOH, 320 mOsm) and supplemented with 25 □M escin.2. External and cell buffer (in mM), NaCl 137, KCl 4, HEPES 10, D-glucose 10, CaCl2 2, MgCl2 1 (pH7.4, NaOH)3. NMDG reference buffer used to establish a stable baseline prior to the addition of test compounds, NaCl 80, KCl 4, CaCl2 2, MgCl2 1, NMDG Cl 60, D-Glucose monohydrate 5, HEPES 10 (pH7.4 NaOH 298 mOsm)4. Seal enhancer used to improve seal quality of cells, NaCl 80, KCl 3, CaCl2 10, HEPES 10, MgCl2 1 (pH7.4 NaOH) | B | 8.62 | pIC50 | 2.4 | nM | IC50 | US-10590130-B2. Chemical compounds (2020) |
| ChEMBL | Binding Assay : hERG (human ether go go-related gene) potassium channels are essential for normal electrical activity in the heart. Arrhythmia can be induced by a blockage of hERG channels by a diverse group of drugs. This side effect is a common reason for drug failure in preclinical safety trials and therefore minimisation of hERG channel blocking activity may be a desirable property for drug candidates.The purpose of the hERG binding assay is to evaluate the effects of test compounds on the voltage-dependent potassium channel encoded by the human ether go go-related gene (hERG) using a constitutively expressing CHO cell line on the Nanion Syncropatch 384PE automated patch clamp system.The assay was conducted as follows with all reagents used at room temperature unless otherwise stated.Reagent Preparations Include:1. Internal IC700 solution used to perfuse the underside of chip (in mM), KF 130, KCl 20, MgCl2 1, EGTA 10 and HEPES 10, (all Sigma-Aldrich; pH 7.2-7.3 using 10 M KOH, 320 mOsm) and supplemented with 25 □M escin.2. External and cell buffer (in mM), NaCl 137, KCl 4, HEPES 10, D-glucose 10, CaCl2 2, MgCl2 1 (pH7.4, NaOH)3. NMDG reference buffer used to establish a stable baseline prior to the addition of test compounds, NaCl 80, KCl 4, CaCl2 2, MgCl2 1, NMDG Cl 60, D-Glucose monohydrate 5, HEPES 10 (pH7.4 NaOH 298 mOsm)4. Seal enhancer used to improve seal quality of cells, NaCl 80, KCl 3, CaCl2 10, HEPES 10, MgCl2 1 (pH7.4 NaOH) | B | 8.68 | pIC50 | 2.1 | nM | IC50 | US-10590130-B2. Chemical compounds (2020) |
| ChEMBL | Binding Assay : hERG (human ether go go-related gene) potassium channels are essential for normal electrical activity in the heart. Arrhythmia can be induced by a blockage of hERG channels by a diverse group of drugs. This side effect is a common reason for drug failure in preclinical safety trials and therefore minimisation of hERG channel blocking activity may be a desirable property for drug candidates.The purpose of the hERG binding assay is to evaluate the effects of test compounds on the voltage-dependent potassium channel encoded by the human ether go go-related gene (hERG) using a constitutively expressing CHO cell line on the Nanion Syncropatch 384PE automated patch clamp system.The assay was conducted as follows with all reagents used at room temperature unless otherwise stated.Reagent Preparations Include:1. Internal IC700 solution used to perfuse the underside of chip (in mM), KF 130, KCl 20, MgCl2 1, EGTA 10 and HEPES 10, (all Sigma-Aldrich; pH 7.2-7.3 using 10 M KOH, 320 mOsm) and supplemented with 25 □M escin.2. External and cell buffer (in mM), NaCl 137, KCl 4, HEPES 10, D-glucose 10, CaCl2 2, MgCl2 1 (pH7.4, NaOH)3. NMDG reference buffer used to establish a stable baseline prior to the addition of test compounds, NaCl 80, KCl 4, CaCl2 2, MgCl2 1, NMDG Cl 60, D-Glucose monohydrate 5, HEPES 10 (pH7.4 NaOH 298 mOsm)4. Seal enhancer used to improve seal quality of cells, NaCl 80, KCl 3, CaCl2 10, HEPES 10, MgCl2 1 (pH7.4 NaOH) | B | 8.74 | pIC50 | 1.8 | nM | IC50 | US-10590130-B2. Chemical compounds (2020) |
| ChEMBL | Binding Assay : hERG (human ether go go-related gene) potassium channels are essential for normal electrical activity in the heart. Arrhythmia can be induced by a blockage of hERG channels by a diverse group of drugs. This side effect is a common reason for drug failure in preclinical safety trials and therefore minimisation of hERG channel blocking activity may be a desirable property for drug candidates.The purpose of the hERG binding assay is to evaluate the effects of test compounds on the voltage-dependent potassium channel encoded by the human ether go go-related gene (hERG) using a constitutively expressing CHO cell line on the Nanion Syncropatch 384PE automated patch clamp system.The assay was conducted as follows with all reagents used at room temperature unless otherwise stated.Reagent Preparations Include:1. Internal IC700 solution used to perfuse the underside of chip (in mM), KF 130, KCl 20, MgCl2 1, EGTA 10 and HEPES 10, (all Sigma-Aldrich; pH 7.2-7.3 using 10 M KOH, 320 mOsm) and supplemented with 25 □M escin.2. External and cell buffer (in mM), NaCl 137, KCl 4, HEPES 10, D-glucose 10, CaCl2 2, MgCl2 1 (pH7.4, NaOH)3. NMDG reference buffer used to establish a stable baseline prior to the addition of test compounds, NaCl 80, KCl 4, CaCl2 2, MgCl2 1, NMDG Cl 60, D-Glucose monohydrate 5, HEPES 10 (pH7.4 NaOH 298 mOsm)4. Seal enhancer used to improve seal quality of cells, NaCl 80, KCl 3, CaCl2 10, HEPES 10, MgCl2 1 (pH7.4 NaOH) | B | 8.82 | pIC50 | 1.5 | nM | IC50 | US-10590130-B2. Chemical compounds (2020) |
ChEMBL data shown on this page come from version 36:
Zdrazil B, Felix E, Hunter F, Manners EJ, Blackshaw J, Corbett S, de Veij M, Ioannidis H, Lopez DM, Mosquera JF, Magarinos MP, Bosc N, Arcila R, Kizilören T, Gaulton A, Bento AP, Adasme MF, Monecke P, Landrum GA, Leach AR. (2024). The ChEMBL Database in 2023: a drug discovery platform spanning multiple bioactivity data types and time periods. Nucleic Acids Res., 52(D1). DOI: 10.1093/nar/gkad1004. [EPMCID:10767899] [PMID:37933841]
Davies M, Nowotka M, Papadatos G, Dedman N, Gaulton A, Atkinson F, Bellis L, Overington JP. (2015) 'ChEMBL web services: streamlining access to drug discovery data and utilities.' Nucleic Acids Res., 43(W1). DOI: 10.1093/nar/gkv352. [EPMCID:25883136]
