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MitoROS Brite™ 670 *Optimized for Detecting Reactive Oxygen Species (ROS) in Mitochondria*
Ordering information
| Price | |
| Catalog Number | |
| Unit Size | |
| Quantity |
Additional ordering information
| Telephone | 1-800-990-8053 |
| Fax | 1-800-609-2943 |
| sales@aatbio.com | |
| International | See distributors |
| Bulk request | Inquire |
| Custom size | Inquire |
| Shipping | Standard overnight for United States, inquire for international |
Physical properties
| Molecular weight | 758.87 |
| Solvent | DMSO |
Spectral properties
| Excitation (nm) | 651 |
| Emission (nm) | 670 |
Storage, safety and handling
| H-phrase | H303, H313, H333 |
| Hazard symbol | XN |
| Intended use | Research Use Only (RUO) |
| R-phrase | R20, R21, R22 |
| Storage | Freeze (< -15 °C); Minimize light exposure |
| Overview |  SDSProtocol |
Molecular weight 758.87 | Excitation (nm) 651 | Emission (nm) 670 |
Mitochondrial ROS (mtROS or mROS) are reactive oxygen species (ROS) produced in mitochondria. Selective detection of mtROS is a critical task to investigate the cellular functions of mitochondria. The cell-permeant MitoROS Brite™ 670 reagent is cell-permeable and selectively located in mitochondria. It is nonfluorescent and produces bright red fluorescence upon ROS oxidation in mitochondria. The resulting fluorescence can be measured using fluorescence imaging, high-content imaging, microplate fluorometry, or flow cytometry. mtROS was considered to be the by-products of cellular metabolism. However, they are now recognized as important signaling molecules. mtROS is primarily formed during oxidative phosphorylation at the electron transport chain (ETC) on the inner mitochondrial membrane. Electrons leak from complexes I and III, partially reducing oxygen to form superoxide. Superoxide is rapidly converted to hydrogen peroxide by two dismutases: SOD2 in the mitochondrial matrix and SOD1 in intermembrane space. At low levels, mtROS are essential for metabolic adaptation (e.g., in hypoxia). They regulate inflammatory responses triggered by danger signals. High mtROS levels activate apoptosis and autophagy pathways, potentially inducing cell death. Mitochondrial dysfunction leads to increased ROS levels, contributing to aging. mtROS induces cellular senescence, a stress response. Recently it has been reported that monocytes/macrophages in the lungs produce mtROS in COVID-19 patients, affecting disease pathogenicity, thus targeting mtROS could be a therapeutic strategy for novel drugs against coronavirus.
Platform
Fluorescence microscope
| Excitation | Cy5 Filter Set |
| Emission | Cy5 Filter Set |
| Recommended plate | Black wall/clear bottom |
Example protocol
AT A GLANCE
Important Note
Before use, thaw MitoROS Brite™ 670 at room temperature. Once thawed, briefly centrifuge to collect the dried pellet.
Subsection title
Prepare the cells in a growth medium.
Stain the cells using the MitoROS Brite™ 670 working solution.
Treat the cells with your desired test compounds.
Monitor fluorescence intensity with a Cy5 filter set or Ex/Em = 650/670 nm.
PREPARATION OF STOCK SOLUTIONS
Unless otherwise noted, all unused stock solutions should be divided into single-use aliquots and stored at -20 °C after preparation. Avoid repeated freeze-thaw cycles
MitoROS Brite™ 670 Stock Solution
Prepare a 5 to 10 mM MitoROS Brite™ 670 stock solution in DMSO.
Note: Prepare single-use aliquots of the MitoROS Brite™ 670 stock solution and store at ≤ -20°C, protected from light. Avoid freeze-thaw cycles.
PREPARATION OF WORKING SOLUTION
MitoROS Brite™ 670 Working Solution
Prepare a 5 to 10 μM MitoROS Brite™ 670 working solution by diluting the MitoROS Brite™ 670 stock solution into Hanks solution with 20 mM Hepes buffer (HHBS).
Note: For optimal results, use this solution within a few hours of preparation.
Note: Protect the working solution from light by covering it with foil or storing it in a dark place.
SAMPLE EXPERIMENTAL PROTOCOL
Plate the cells as desired in a 96-well black wall-clear bottom plate.
Add 100 µL of the MitoROS Brite™ 670 working solution to the cells.
Incubate the cells at 37°C for 30 to 60 minutes, protected from light.
Note: The optimal concentration and incubation time for MitoROS Brite™ 670 may vary between different cell lines. You may need to test different concentrations to determine the best conditions.
Remove the dye working solution and wash the cells twice with HHBS buffer.
Treat cells as desired.
Remove the treatment and wash cells twice with HHBS buffer.
Add HHBS buffer and examine the cells using a fluorescence microscope with a Cy5 filter set.
Calculators
Common stock solution preparation
Table 1. Volume of DMSO needed to reconstitute specific mass of MitoROS Brite™ 670 *Optimized for Detecting Reactive Oxygen Species (ROS) in Mitochondria* to given concentration. Note that volume is only for preparing stock solution. Refer to sample experimental protocol for appropriate experimental/physiological buffers.
| 0.1 mg | 0.5 mg | 1 mg | 5 mg | 10 mg | |
| 1 mM | 131.775 µL | 658.874 µL | 1.318 mL | 6.589 mL | 13.177 mL |
| 5 mM | 26.355 µL | 131.775 µL | 263.55 µL | 1.318 mL | 2.635 mL |
| 10 mM | 13.177 µL | 65.887 µL | 131.775 µL | 658.874 µL | 1.318 mL |
Molarity calculator
Enter any two values (mass, volume, concentration) to calculate the third.
| Mass (Calculate) | Molecular weight | Volume (Calculate) | Concentration (Calculate) | Moles | ||||
| / | = | x | = |
Product Family
| Name | Excitation (nm) | Emission (nm) |
| MitoROS Brite™ 570 *Optimized for Detecting Reactive Oxygen Species (ROS) in Mitochondria* | 555 | 568 |
| ROS Brite™ 670 *Optimized for Detecting Reactive Oxygen Species (ROS)* | 651 | 670 |
Images
Figure 1. The fluorescence response of MitoROS™ Brite 670 (10 µM) to Fenton Reagent (10 µM CuCl2 and 100 µM H2O2 in HH buffer) was assessed in HeLa cells. Fluorescence intensities were measured using a fluorescence microscope equipped with a Cy5 filter.
References
View all 50 references: Citation Explorer
Polygonatum sibiricum polysaccharide ameliorates skeletal muscle aging via mitochondria-associated membrane-mediated calcium homeostasis regulation.
Authors: Chen, Wenhao and Shen, Zile and Dong, Wenxi and Huang, Guowei and Yu, Dingye and Chen, Weizhe and Yan, Xialin and Yu, Zhen
Journal: Phytomedicine : international journal of phytotherapy and phytopharmacology (2024): 155567
Authors: Chen, Wenhao and Shen, Zile and Dong, Wenxi and Huang, Guowei and Yu, Dingye and Chen, Weizhe and Yan, Xialin and Yu, Zhen
Journal: Phytomedicine : international journal of phytotherapy and phytopharmacology (2024): 155567
Glutamine sustains energy metabolism and alleviates liver injury in burn sepsis by promoting the assembly of mitochondrial HSP60-HSP10 complex via SIRT4 dependent protein deacetylation.
Authors: Yang, Yongjun and Chen, Qian and Fan, Shijun and Lu, Yongling and Huang, Qianyin and Liu, Xin and Peng, Xi
Journal: Redox report : communications in free radical research (2024): 2312320
Authors: Yang, Yongjun and Chen, Qian and Fan, Shijun and Lu, Yongling and Huang, Qianyin and Liu, Xin and Peng, Xi
Journal: Redox report : communications in free radical research (2024): 2312320
Mitochondria-targeting peptide SS-31 attenuates ferroptosis via inhibition of the p38 MAPK signaling pathway in the hippocampus of epileptic rats.
Authors: Liu, Xue and Wang, Fei-Yu and Chi, Song and Liu, Tao and Yang, Hai-Lin and Zhong, Ru-Jie and Li, Xiao-Yu and Gao, Jing
Journal: Brain research (2024): 148882
Authors: Liu, Xue and Wang, Fei-Yu and Chi, Song and Liu, Tao and Yang, Hai-Lin and Zhong, Ru-Jie and Li, Xiao-Yu and Gao, Jing
Journal: Brain research (2024): 148882
Mitochondrial redox state, bioenergetics, and calcium transport in caloric restriction: A metabolic nexus.
Authors: Vilas-Boas, Eloisa A and Kowaltowski, Alicia J
Journal: Free radical biology & medicine (2024): 195-214
Authors: Vilas-Boas, Eloisa A and Kowaltowski, Alicia J
Journal: Free radical biology & medicine (2024): 195-214
Sex-related differences in SIRT3-mediated mitochondrial dynamics in renal ischemia/reperfusion injury.
Authors: Yao, Hanlin and Zhao, Hongchao and Du, Yang and Zhang, Ye and Li, Yanze and Zhu, Hengcheng
Journal: Translational research : the journal of laboratory and clinical medicine (2024): 1-12
Authors: Yao, Hanlin and Zhao, Hongchao and Du, Yang and Zhang, Ye and Li, Yanze and Zhu, Hengcheng
Journal: Translational research : the journal of laboratory and clinical medicine (2024): 1-12
The absence of the ribosomal protein Rpl2702 elicits the MAPK-mTOR signaling to modulate mitochondrial morphology and functions.
Authors: Liu, Ling and Wu, Yifan and Liu, Ke and Zhu, Mengdan and Guang, Shouhong and Wang, Fengsong and Liu, Xing and Yao, Xuebiao and He, Jiajia and Fu, Chuanhai
Journal: Redox biology (2024): 103174
Authors: Liu, Ling and Wu, Yifan and Liu, Ke and Zhu, Mengdan and Guang, Shouhong and Wang, Fengsong and Liu, Xing and Yao, Xuebiao and He, Jiajia and Fu, Chuanhai
Journal: Redox biology (2024): 103174
Interplay between hypoxia inducible Factor-1 and mitochondria in cardiac diseases.
Authors: Mialet-Perez, Jeanne and Belaidi, Elise
Journal: Free radical biology & medicine (2024): 13-22
Authors: Mialet-Perez, Jeanne and Belaidi, Elise
Journal: Free radical biology & medicine (2024): 13-22
Antitumor effects of polydopamine coated hydroxyapatite nanoparticles and its mechanism: Mitochondria-targeted ROS and calcium channels.
Authors: Wang, Jing and Wu, Yue and Li, Huishan and Kang, Wenjue and Li, Wenhao and Fu, Shijia
Journal: Biomaterials advances (2024): 213858
Authors: Wang, Jing and Wu, Yue and Li, Huishan and Kang, Wenjue and Li, Wenhao and Fu, Shijia
Journal: Biomaterials advances (2024): 213858
A role of ROS-dependent defects in mitochondrial dynamic and autophagy in carbon black nanoparticle-mediated myocardial cell damage.
Authors: Xu, Zehua and Li, Jing and Su, Bowen and Gao, Hongying and Ren, Miaomiao and Lin, Yi and Shen, Heqing
Journal: Free radical biology & medicine (2024): 249-261
Authors: Xu, Zehua and Li, Jing and Su, Bowen and Gao, Hongying and Ren, Miaomiao and Lin, Yi and Shen, Heqing
Journal: Free radical biology & medicine (2024): 249-261
Time-restricted feeding improves aortic endothelial relaxation by enhancing mitochondrial function and attenuating oxidative stress in aged mice.
Authors: Milan, Madison and Brown, Jacob and O'Reilly, Colleen L and Bubak, Matthew P and Negri, Sharon and Balasubramanian, Priya and Dhanekula, Arjune S and Pharaoh, Gavin and Reyff, Zeke and Ballard, Cade and Shi, Helen and Yabluchanskiy, Andriy and Rudolph, Michael C and Ungvari, Zoltan and Marcinek, David J and Miller, Benjamin F and Van Remmen, Holly and Tarantini, Stefano
Journal: Redox biology (2024): 103189
Authors: Milan, Madison and Brown, Jacob and O'Reilly, Colleen L and Bubak, Matthew P and Negri, Sharon and Balasubramanian, Priya and Dhanekula, Arjune S and Pharaoh, Gavin and Reyff, Zeke and Ballard, Cade and Shi, Helen and Yabluchanskiy, Andriy and Rudolph, Michael C and Ungvari, Zoltan and Marcinek, David J and Miller, Benjamin F and Van Remmen, Holly and Tarantini, Stefano
Journal: Redox biology (2024): 103189