PhosphoWorks™ Luminometric ATP Assay Kit Maximized Luminescence

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Telephone	1-800-990-8053
Fax	1-800-609-2943
Email	sales@aatbio.com
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H-phrase	H303, H313, H333
Hazard symbol	XN
Intended use	Research Use Only (RUO)
R-phrase	R20, R21, R22
UNSPSC	12352200

Alternative formats

PhosphoWorks™ Luminometric ATP Assay Kit *Extended Luminescence*

PhosphoWorks™ Luminometric ATP Assay Kit *DTT-Free*

Overview SDS Protocol

Adenosine triphosphate (ATP) plays a fundamental role in cellular energenics, metabolic regulation and cellular signaling. The PhosphoWorks™ ATP Assay Kit provides a fast, simple and homogeneous luminescence assay for the determination of cell proliferation and cytotoxicity in mammalian cells. The assay can be performed in a convenient 96-well and 384-well microtiter-plate format. The high sensitivity of this assay permits the detection of ATP in many biological systems, environmental samples and foods. This PhosphoWorks ATP Assay Kit can detect as low as 10 cells/well. It has stable luminescence with no mixing or separations required, and formulated to have minimal hands-on time.

Platform

Luminescence microplate reader

Recommended plate

Solid white

Components

Example protocol

AT A GLANCE

Protocol summary

Prepare cells (samples) with test compounds (100 µL/96-well plate or 25 µL/384-well plate)
Add equal volume of ATP working solution (100 µL/96-well plate or 25 µL/384-well plate)
Incubate at room temperature for 10 - 20 minutes
Monitor the luminescence intensity

Important notes
To achieve the best results, it’s strongly recommended to use the white plates. Thaw all the kits components at room temperature before starting the experiment.

PREPARATION OF WORKING SOLUTION

1. Transfer the whole content of Reaction Buffer (Component C, 10 mL) into ATP Sensor (Component B) and mix well.

2. Add 20 µL of ATP Monitoring Enzyme (Component A) into the bottle of Component B+C and mix well to make ATP working solution. Note: Avoid potential ATP contamination from exogenous biological sources.

For guidelines on cell sample preparation, please visit
https://www.aatbio.com/resources/guides/cell-sample-preparation.html

SAMPLE EXPERIMENTAL PROTOCOL

Run ATP assay:

Treat cells (or samples) with test compounds by adding 10 µL of 10X compounds for a 96-well plate or 5 µL of 5X compounds for a 384-well plate in desired compound buffer. For blank wells (medium without the cells), add the corresponding amount of compound buffer.
Incubate the cell plate in a 37°C, 5% CO₂ incubator for a desired period of time, such as 24, 48 or 96 hours.
Add 100 µL (96-well plate) or 25 µL (384-well plate) of ATP working solution into each well.
Incubate at room temperature for 10 - 20 minutes.
Monitor luminescence intensity with a standard luminometer.

Generate a standard ATP calibration curve:

An ATP standard curve should be generated together with the above assay if the absolute amount of ATP in samples needs to be calculated.

Make a series of dilutions of ATP in PBS buffer with 0.1% BSA by including a sample without ATP (as a control) for measuring background luminescence. Note: Typically ATP concentrations from 1 nM to 10 µM are appropriate.
Add the same amount of the diluted ATP solution into an empty plate (100 µL for a 96-well plate or 25 µL for a 384-well plate).
Add 100 µL/well (96-well plate) or 25 µL/well (384-well plate) of ATP working solution.
Incubate the reaction mixture at room temperature for 10 to 20 minutes.
Monitor the luminescence intensity with a standard luminometer.
Generate the ATP standard curve.

Images

Figure 1. CHO-K1 cell number was measured with PhosphoWorks™ Luminescence ATP Assay Kit on a 96-well white plate using a NOVOstar plate reader (BMG Labtech). The integration time was 1 sec.

Figure 2. Impact of host-cell metabolism inhibition on ATP levels and τ2-NAD(P)H. Cellular ATP levels under glucose starvation and inhibition of oxidative phosphorylation by antimycin A. *ATP was measured using a luminometric ATP assay kit (ABD Bioquest, Sunnyvale, CA) and a microplate reader (Tecan Infinite 200 PRO, Maenedorf, Switzerland). HEp-2 cells were grown in 96-well plates (2000 cells/ well) and treated with the metabolic inhibitors as described above. ATP assays were performed according to the manufacturer's instructions. Source: Graph from Fluorescence Lifetime Imaging Unravels C. trachomatis Metabolism and Its Crosstalk with the Host Cell by Márta Szaszák, et al., PLOS ONE, July 2011.

Figure 3. Optimization of the indirect glycolate cytotoxicity. (A) A collection of eight CHO cell lines were cultured in 384-well plates and assayed for the glycolate toxicity. (B–D) Optimization of assay parameters was carried out in three aspects: seeding CHO cells at different density (B), adding glycolate at a range of concentrations (C), and varying the incubation period (D). Signal-to-basal ratio was evaluated for each parameter. (E) Partial reduction of the indirect glycolate cytotoxicity in the cell-based assay by 2-hydroxy-3-butynoic acid (2H3BA) c, a known GO inhibitor. ATP content cell viability assay using an assay kit (21610, AAT Bioquest). Source: High throughput cell-based assay for identification of glycolate oxidase inhibitors as a potential treatment for Primary Hyperoxaluria Type 1 by Wang M, Xu M, Long Y, Fargue S, Southall N, Hu X, McKew JC, Danpure CJ, Zheng W. High. Sci Rep., Sep. 2016.

Citations

View all 12 citations: Citation Explorer

Knocking out Fkbp51 decreases CCl4-induced liver injury through enhancement of mitochondrial function and Parkin activity
Authors: Qiu, Bin and Zhong, Zhaohui and Dou, Longyu and Xu, Yuxue and Zou, Yi and Weldon, Korri and Wang, Jun and Zhang, Lingling and Liu, Ming and Williams, Kent E and others,
Journal: Cell \& Bioscience (2024): 1

Hepatitis B Surface Antigen Activates Unfolded Protein Response in Forming Ground Glass Hepatocytes of Chronic Hepatitis B
Authors: Li, Yao and Xia, Yuchen and Cheng, Xiaoming and Kleiner, David E and Hewitt, Stephen M and Sproch, Julia and Li, Tong and Zhuang, Hui and Liang, T Jake
Journal: Viruses (2019): 386

High throughput cell-based assay for identification of glycolate oxidase inhibitors as a potential treatment for Primary Hyperoxaluria Type 1
Authors: Wang, Mengqiao and Xu, Miao and Long, Yan and Fargue, Sonia and Southall, Noel and Hu, Xin and McKew, John C and Danpure, Christopher J and Zheng, Wei
Journal: Scientific Reports (2016)

NT1014, a novel biguanide, inhibits ovarian cancer growth in vitro and in vivo
Authors: Zhang, Lu and Han, Jianjun and Jackson, Am and a L , undefined and Clark, Leslie N and Kilgore, Joshua and Guo, Hui and Livingston, Nick and Batchelor, Kenneth and Yin, Yajie and Gilliam, Timothy P and others, undefined
Journal: Journal of Hematology & Oncology (2016): 91

The Different Effects of Atorvastatin and Pravastatin on Cell Death and PARP Activity in Pancreatic NIT-1 Cells
Authors: Chen, Ya-Hui and Chen, Yi-Chun and Liu, Chin-San and Hsieh, Ming-Chia
Journal: Journal of Diabetes Research (2016)

Glutamine promotes ovarian cancer cell proliferation through the mTOR/S6 pathway
Authors: Yuan, Lingqin and Sheng, Xiugui and Willson, Adam K and Roque, Dario R and Stine, Jessica E and Guo, Hui and Jones, Hannah M and Zhou, Chunxiao and Bae-Jump, Victoria L
Journal: Endocrine-related cancer (2015): 577--591

BPA-induced DNA hypermethylation of the master mitochondrial gene PGC-1α contributes to cardiomyopathy in male rats
Authors: Jiang, Ying and Xia, Wei and Yang, Jie and Zhu, Yingshuang and Chang, Huailong and Liu, Juan and Huo, Wenqian and Xu, Bing and Chen, Xi and Li, Yuanyuan and others, undefined
Journal: Toxicology (2015): 21--31

Loss of histone deacetylase Hdac1 disrupts metabolic processes in intestinal epithelial cells
Authors: Gonneaud, Alexis and Turgeon, Naomie and Boisvert, Fran&ccaron;ois-Michel and Boudreau, Fran&ccaron;ois and Asselin, Claude
Journal: FEBS letters (2015): 2776--2783

JQ1 suppresses tumor growth through downregulating LDHA in ovarian cancer
Authors: Qiu, Haifeng and Jackson, Am and a L , undefined and Kilgore, Joshua E and Zhong, Yan and Chan, Leo Li-Ying and Gehrig, Paola A and Zhou, Chunxiao and Bae-Jump, Victoria L
Journal: Oncotarget (2015): 6915

A neutrophil intrinsic impairment affecting Rab27a and degranulation in cystic fibrosis is corrected by CFTR potentiator therapy
Authors: Pohl, Kerstin and Hayes, Elaine and Keenan, Joanne and Henry, Michael and Meleady, Paula and Molloy, Kevin and Jundi, Bakr and Bergin, David A and McCarthy, Cormac and McElvaney, Oliver J and others, undefined
Journal: Blood (2014): 999--1009