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TMRM Sale

(Synonyms: 四甲基罗丹明甲酯) 目录号 : GC30553

TMRM是一种细胞渗透性阳离子荧光探针,特异性识别线粒体膜电位,最大激发光/发射光为552/575nm

TMRM Chemical Structure

Cas No.:115532-49-5

规格 价格 库存 购买数量
5mg
¥1,964.00
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Sample solution is provided at 25 µL, 10mM.

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实验参考方法

本方案仅提供一个指导,请根据您的具体需要进行修改。
1、制备TMRM染色液
(1)将低温保存的TMRM粉末置于室温回温至少20min(此步非常重要,请勿忽略操作),低速离心片刻使粉末沉至管底。
(2)染料储存液:使用DMSO将TMRM溶解成1-5mM的储存液。配置好的储存液分装后于-20或-80℃避光保存。
(3)染料工作液:用合适的缓冲液(如:无血清培养基,HBSS或PBS)稀释储存液,配制浓度为20nM~1μM的TMRM工作液。
注意:
①由于TMRM的使用浓度比较低,建议使用DMSO稀释,配制一个中间储存浓度(比如:100uM);
②请根据实际情况调整及优化工作液浓度,现用现配。
2、细胞悬浮染色(以6 孔板为例)
(1)悬浮细胞经1000g离心3-5min。弃去上清液,使用PBS清洗两次,每次5分钟。
(2)贴壁细胞使用PBS清洗两次,加入胰酶消化细胞,消化完成后经1000g离心3-5min。
(3)加入1mL染料工作液重悬细胞,室温避光孵育5-30min分钟,不同细胞最佳培养时间不同。
(4)孵育结束后,经1000g离心5分钟,去除上清液,加入PBS清洗2-3次,每次5分钟。
(5)使用无血清细胞培养基或PBS重悬细胞,通过荧光显微镜或流式细胞技术进行观察。
3、细胞贴壁染色
(1)在无菌盖玻片上培养贴壁细胞。
(2)从培养基中移走盖玻片,吸出过量的培养基,将盖玻片放在潮湿的环境中。(3)从盖玻片的一角加入100uL染料工作液,轻轻晃动使染料均匀覆盖所有细胞,室温避光孵育30-60min分钟。
(4)吸弃染料工作液,使用培养液清洗盖玻片2~3次,每次5分钟。
4、显微镜检测:TMRM在515和552 nm处有两个激发峰,最大激发光/发射光为552/575nm。

注意事项:
①对于荧光成像分析,常用的TMRM工作浓度范围是50-200nM;
②如果需测定某药物对膜电位的作用,需提前处理细胞,再用探针进行后续检测,同时需要设置药物未处理组和药物处理组;
③如果需要阳性对照,可选择FCCP(目录号:GC14328)或CCCP(目录号:GC14727),这两种化合物都是解偶联剂,能够降低线粒体膜电位,从而防止TMRM染色;
④荧光染料均存在淬灭问题,请尽量注意避光,以减缓荧光淬灭;
⑤为了您的安全和健康,请穿实验服并戴一次性手套操作。
References:
[1]. Michael B Schultz,et. Molecular and Cellular Characterization of SIRT1 Allosteric Activators. 2019:1983:133-149. doi: 10.1007/978-1-4939-9434-2_8.

产品描述

TMRM is a cell-permeable cationic red fluorescent probe that specifically recognizes mitochondrial membrane potential with a maximum excitation/emission light of 552/575nm[1]. TMRM can selectively label mitochondria and measure mitochondrial membrane potential, and is often used to evaluate mitochondrial function through live cell fluorescence microscopy or flow cytometry. TMRM incorporated into cells is preferentially retained in mitochondria, producing bright fluorescence, and the fluorescence intensity is proportional to the mitochondrial membrane potential. Loss of mitochondrial integrity or excessive opening of the mitochondrial permeability transition pore can cause the probe to leak out of the mitochondria, resulting in reduced fluorescence[2]. Rhodamine dye has low toxicity to cells at a certain concentration, so it is often used to detect mitochondria in animal cells, plant cells, and microorganisms[3].

TMRM是一种细胞渗透性阳离子红色荧光探针,特异性识别线粒体膜电位,最大激发光/发射光为552/575nm[1]。TMRM能够选择性标记线粒体以及测定线粒体膜电位,常被用于通过活细胞荧光显微镜或流式细胞术评估线粒体功能。掺入细胞的TMRM优先保留在线粒体中,产生明亮的荧光,并且荧光强度与线粒体膜电位成比例。线粒体完整性的丧失或线粒体通透性转换孔的过渡开放会导致探针从线粒体中渗出,从而导致荧光减弱[2]。在一定浓度下,罗丹明染料对细胞的毒性较低,因此常用于检测动物细胞、植物细胞和微生物中的线粒体[3]

Chemical Properties

Cas No. 115532-49-5 SDF
别名 四甲基罗丹明甲酯
Canonical SMILES O=C(C1=CC=CC=C1C2=C3C=CC(N(C)C)=CC3=[O+]C4=C2C=CC(N(C)C)=C4)OC
分子式 C25H25N2O3 分子量 401.48
溶解度 DMSO : 41.67 mg/mL (83.19 mM) 储存条件 Store at -20°C
General tips 请根据产品在不同溶剂中的溶解度选择合适的溶剂配制储备液;一旦配成溶液,请分装保存,避免反复冻融造成的产品失效。
储备液的保存方式和期限:-80°C 储存时,请在 6 个月内使用,-20°C 储存时,请在 1 个月内使用。
为了提高溶解度,请将管子加热至37℃,然后在超声波浴中震荡一段时间。
Shipping Condition 评估样品解决方案:配备蓝冰进行发货。所有其他可用尺寸:配备RT,或根据请求配备蓝冰。

溶解性数据

制备储备液
1 mg 5 mg 10 mg
1 mM 2.4908 mL 12.4539 mL 24.9078 mL
5 mM 0.4982 mL 2.4908 mL 4.9816 mL
10 mM 0.2491 mL 1.2454 mL 2.4908 mL
  • 摩尔浓度计算器

  • 稀释计算器

  • 分子量计算器

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*在配置溶液时,请务必参考产品标签上、MSDS / COA(可在Glpbio的产品页面获得)批次特异的分子量使用本工具。

计算

动物体内配方计算器 (澄清溶液)

第一步:请输入基本实验信息(考虑到实验过程中的损耗,建议多配一只动物的药量)
给药剂量 mg/kg 动物平均体重 g 每只动物给药体积 ul 动物数量
第二步:请输入动物体内配方组成(配方适用于不溶于水的药物;不同批次药物配方比例不同,请联系GLPBIO为您提供正确的澄清溶液配方)
% DMSO % % Tween 80 % saline
计算重置

Research Update

Measurement of Mitochondrial Membrane Potential with the Fluorescent Dye Tetramethylrhodamine Methyl Ester (TMRM)

The mitochondrial membrane potential (Δψm) drives the generation of ATP by mitochondria. Interestingly, Δψm is higher in many cancer cells comparted to healthy noncancerous cell types, providing a unique metabolic marker. This feature has also been exploited for therapeutic use by utilizing drugs that specifically accumulate in the mitochondria of cancer cells with high Δψm. As such, the assessment of Δψm can provide very useful information as to the metabolic state of a cancer cell, as well as its potential for malignancy. In addition, the measurement of Δψm can also be used to test the ability of novel anticancer therapies to disrupt mitochondrial metabolism and cause cell death.Here, we outline two methods for assessing Δψm in cancer cells using confocal microscopy and the potentiometric fluorescent dye tetramethylrhodamine methyl ester (TMRM). In the first protocol, we describe a technique to quantitatively measure Δψm, which can be used to compare Δψm between different cell types. In the second protocol, we describe a technique for assessing changes to Δψm over time, which can be used to determine the effectiveness of different therapeutic compounds or drugs in modulating mitochondrial function.

Labeling mitochondria with MitoTracker dyes

INTRODUCTION Membrane-potential-dependent dyes such as Rhodamine 123, tetramethylrhodamine methyl ester (TMRM), and tetramethylrhodamine ethyl ester (TMRE) are useful as long as the mitochondrion maintains its negative membrane potential. MitoTracker is a commercially available fluorescent dye (Invitrogen/Molecular Probes) that, like the aforementioned dyes, labels mitochondria within live cells utilizing the mitochondrial membrane potential. However, MitoTracker is chemically reactive, linking to thiol groups in the mitochondria. The dye becomes permanently bound to the mitochondria, and thus remains after the cell dies or is fixed. In addition, it can be used in experiments in which multiple labeling diminishes mitochondrial function. This protocol describes the labeling of mitochondria in live and fixed cells with MitoTracker dyes.

Analysis of Apoptosis and Necroptosis by Fluorescence-Activated Cell Sorting

Fluorescence-activated cell sorting (FACS) is a laser-based, biophysical technology that allows simultaneous multiparametric analysis. For the analysis of dying cells, fluorescently labeled Annexin V (Annexin V(FITC)) and propidium iodide (PI) are the most commonly used reagents. Instead of PI, 4',6-diamidino-2-phenylindole (DAPI) can also be used. DAPI is a fluorescent stain that binds strongly to A-T-rich regions in DNA. DAPI and PI only inefficiently pass through an intact cell membrane and, therefore, preferentially stain dead cells. DAPI can be combined with Annexin V(FITC)and the potentiometric fluorescent dye, tetramethylrhodamine methyl ester (TMRM), which measures mitochondrial permeability transition and mitochondrial membrane depolarization. TMRM is a cell-permeable fluorescent dye that is sequestered to active mitochondria, and hence labels live cells. On apoptosis or necroptosis the TMRM signal is lost. The advantage of using Annexin V(FITC)/DAPI/TMRM is that the entire cell population is labeled, and it is easy to distinguish living (TMRM + /Annexin V(FITC)-/DAPI-) from dying or dead cells (apoptosis: TMRM-/Annexin V(FITC)+ /DAPI-; necrosis: TMRM-/Annexin V(FITC)+ /DAPI+). This is important because cell debris (fluorescent negative particles) must be avoided to establish the correct parameters for the FACS analysis, otherwise incorrect statistical values will be obtained. To obtain information on the cell concentration or absolute cell counts in a sample, it is recommended to add an internal microsphere counting standard to the flow cytrometric sample. This protocol describes the FACS analysis of cell death in HT1080 and L929 cells, but it can be readily adapted to other cell types of interest.

Mitochondrial depolarization after acute ethanol treatment drives mitophagy in living mice

Ethanol increases hepatic mitophagy driven by unknown mechanisms. Type 1 mitophagy sequesters polarized mitochondria for nutrient recovery and cytoplasmic remodeling. In Type 2, mitochondrial depolarization (mtDepo) initiates mitophagy to remove the damaged organelles. Previously, we showed that acute ethanol administration produces reversible hepatic mtDepo. Here, we tested the hypothesis that ethanol-induced mtDepo initiates Type 2 mitophagy. GFP-LC3 transgenic mice were gavaged with ethanol (2-6 g/kg) with and without pre-treatment with agents that decrease or increase mtDepo-Alda-1, tacrolimus, or disulfiram. Without ethanol, virtually all hepatocytes contained polarized mitochondria with infrequent autophagic GFP-LC3 puncta visualized by intravital microscopy. At ~4 h after ethanol treatment, mtDepo occurred in an all-or-none fashion within individual hepatocytes, which increased dose dependently. GFP-LC3 puncta increased in parallel, predominantly in hepatocytes with mtDepo. Mitochondrial PINK1 and PRKN/parkin also increased. After covalent labeling of mitochondria with MitoTracker Red (MTR), GFP-LC3 puncta encircled MTR-labeled mitochondria after ethanol treatment, directly demonstrating mitophagy. GFP-LC3 puncta did not associate with fat droplets visualized with BODIPY558/568, indicating that increased autophagy was not due to lipophagy. Before ethanol administration, rhodamine-dextran (RhDex)-labeled lysosomes showed little association with GFP-LC3. After ethanol treatment, TFEB (transcription factor EB) translocated to nuclei, and lysosomal mass increased. Many GFP-LC3 puncta merged with RhDex-labeled lysosomes, showing autophagosomal processing into lysosomes. After ethanol treatment, disulfiram increased, whereas Alda-1 and tacrolimus decreased mtDepo, and mitophagy changed proportionately. In conclusion, mtDepo after acute ethanol treatment induces mitophagic sequestration and subsequent lysosomal processing.Abbreviations : AcAld, acetaldehyde; ADH, alcohol dehydrogenase; ALDH, aldehyde dehydrogenase; ALD, alcoholic liver disease; Alda-1, N-(1,3-benzodioxol-5-ylmethyl)-2,6-dichlorobenzamide; GAPDH, glyceraldehyde-3-phosphate dehydrogenase; GFP, green fluorescent protein; LAMP1, lysosomal-associated membrane protein 1; LMNB1, lamin B1; MAA, malondialdehyde-acetaldehyde adducts; MAP1LC3/LC3, microtubule-associated protein 1 light chain 3; MPT, mitochondrial permeability transition; mtDAMPS, mitochondrial damage-associated molecular patterns; mtDepo, mitochondrial depolarization; mtDNA, mitochondrial DNA; MTR, MitoTracker Red; PI, propidium iodide; PINK1, PTEN induced putative kinase 1; PRKN, parkin; RhDex, rhodamine dextran; TFEB, transcription factor EB; Tg, transgenic; TMRM, tetramethylrhodamine methylester; TOMM20, translocase of outer mitochondrial membrane 20; VDAC, voltage-dependent anion channel.

Mitochondrial autophagy and cell survival is regulated by the circadian Clock gene in cardiac myocytes during ischemic stress

Cardiac function is highly reliant on mitochondrial oxidative metabolism and quality control. The circadian Clock gene is critically linked to vital physiological processes including mitochondrial fission, fusion and bioenergetics; however, little is known of how the Clock gene regulates these vital processes in the heart. Herein, we identified a putative circadian CLOCK-mitochondrial interactome that gates an adaptive survival response during myocardial ischemia. We show by transcriptome and gene ontology mapping in CLOCK Δ19/Δ19 mouse that Clock transcriptionally coordinates the efficient removal of damaged mitochondria during myocardial ischemia by directly controlling transcription of genes required for mitochondrial fission, fusion and macroautophagy/autophagy. Loss of Clock gene activity impaired mitochondrial turnover resulting in the accumulation of damaged reactive oxygen species (ROS)-producing mitochondria from impaired mitophagy. This coincided with ultrastructural defects to mitochondria and impaired cardiac function. Interestingly, wild type CLOCK but not mutations of CLOCK defective for E-Box binding or interaction with its cognate partner ARNTL/BMAL-1 suppressed mitochondrial damage and cell death during acute hypoxia. Interestingly, the autophagy defect and accumulation of damaged mitochondria in CLOCK-deficient cardiac myocytes were abrogated by restoring autophagy/mitophagy. Inhibition of autophagy by ATG7 knockdown abrogated the cytoprotective effects of CLOCK. Collectively, our results demonstrate that CLOCK regulates an adaptive stress response critical for cell survival by transcriptionally coordinating mitochondrial quality control mechanisms in cardiac myocytes. Interdictions that restore CLOCK activity may prove beneficial in reducing cardiac injury in individuals with disrupted circadian CLOCK.Abbreviations: ARNTL/BMAL1: aryl hydrocarbon receptor nuclear translocator-like; ATG14: autophagy related 14; ATG7: autophagy related 7; ATP: adenosine triphosphate; BCA: bovine serum albumin; BECN1: beclin 1, autophagy related; bHLH: basic helix- loop-helix; CLOCK: circadian locomotor output cycles kaput; CMV: cytomegalovirus; COQ5: coenzyme Q5 methyltransferase; CQ: chloroquine; CRY1: cryptochrome 1 (photolyase-like); DNM1L/DRP1: dynamin 1-like; EF: ejection fraction; EM: electron microscopy; FS: fractional shortening; GFP: green fluorescent protein; HPX: hypoxia; i.p.: intraperitoneal; I-R: ischemia-reperfusion; LAD: left anterior descending; LVIDd: left ventricular internal diameter diastolic; LVIDs: left ventricular internal diameter systolic; MAP1LC3/LC3: microtubule-associated protein 1 light chain 3; MFN2: mitofusin 2; MI: myocardial infarction; mPTP: mitochondrial permeability transition pore; NDUFA4: Ndufa4, mitochondrial complex associated; NDUFA8: NADH: ubiquinone oxidoreductase subunit A8; NMX: normoxia; OCR: oxygen consumption rate; OPA1: OPA1, mitochondrial dynamin like GTPase; OXPHOS: oxidative phosphorylation; PBS: phosphate-buffered saline; PER1: period circadian clock 1; PPARGC1A/PGC-1α: peroxisome proliferative activated receptor, gamma, coactivator 1 alpha; qPCR: quantitative real-time PCR; RAB7A: RAB7, member RAS oncogene family; ROS: reactive oxygen species; RT: room temperature; shRNA: short hairpin RNA; siRNA: small interfering RNA; TFAM: transcription factor A, mitochondrial; TFEB: transcription factor EB; TMRM: tetra-methylrhodamine methyl ester perchlorate; WT: wild -type; ZT: zeitgeber time.