Quantification of both oxidized and reduced forms of glutathione (GSSG and GSH, respectively) has been achieved through the use of Ortho-phthalaldehyde (OPA). OPA becomes highly fluorescent once conjugated to GSH but is unable to conjugate GSSG until reduced. Here, we describe a multiparametric assay to quantify both using protein quantification for normalization.
Glutathione has long been considered a key biomarker for determining the antioxidant response of the cell. Hence, it is a primary marker for reactive oxygen species studies. The method utilizes Ortho-phthalaldehyde (OPA) to quantify the cellular concentration of glutathione(s). OPA conjugates with reduced glutathione (GSH) via sulfhydryl binding to subsequently form an isoindole, resulting in a highly fluorescent conjugate. To attain an accurate result of both oxidized glutathione (GSSG) and GSH, a combination of masking agents and reducing agents, which have been implemented in this protocol, are required. Treatments may also impact cellular viability. Hence, normalization via protein assay is presented in this multiparametric assay. The assay demonstrates a pseudo-linear detection range of 0.234 – 30µM (R2=0.9932±0.007 (N=12)) specific to GSH. The proposed assay also allows for the determination of oxidized glutathione with the addition of the masking agent N-ethylmaleimide to bind reduced glutathione, and the reducing agent tris(2-carboxyethyl) phosphine is introduced to cleave the disulfide bond in GSSG to produce two molecules of GSH. The assay is used in combination with a validated bicinchoninic acid assay for protein quantification and an adenylate kinase assay for cytotoxicity assessment.
Reactive oxygen species (ROS) are a primary inducer of oxidative stress; oxidative stress has been well established in the generation of DNA mutations, cellular aging/ death, various cancers, diabetes, neurological diseases (such as Parkinson's and Alzheimers), and several other life-debilitating conditions1,2,3,4,5. A key defense against ROS are thiolic, non-enzymatic antioxidants, which are capable of reducing oxidants or radicals by acting as proton donors6,7. Glutathione (GSH) and cysteine are the two most prevalent thiols found in mammals8, while various other low molecular weight thiols exist (such as ergothioneine), GSH and cysteine are the most commonly measured non-enzymatic antioxidants found in literature9,10,11 and hold greatest relevance for combatting ROS8,12,13,14.
When GSH is utilized as an antioxidant, two molecules of GSH are covalently linked together via a disulfide bond to make glutathione disulfide (GSSG). Depletion of GSH is often used as an indicator of oxidative stress15,16. This assessment can also be combined with the detection of GSSG, although increases in GSSG in cells are often limited by active export processes since GSSG can be relatively reactive in cells, leading to disulfide bond formation with other protein thiols16.
Traditional methods for measuring GSH and GSSG are not simple processes and require numerous steps, including cellular extraction using lytic reagents17,18. The protocol outlined here simplifies these methods and allows the accurate measurement of non-enzymatic thiols and normalization using the cellular protein content or adenylate kinase release. In addition, it is possible to measure cellular viability prior to GSH/GSSG extraction. Several methods have previously attempted to target and quantify reduced and oxidized non-enzymatic thiols efficiently; methods including the use of HPLC19,20,21, plate assay (biochemical)22,23,24,25, and which use common reagents for thiol conjugation, such as 5,5-dithio-bis-(2-nitrobenzoic acid) (DTNB/ Ellman's reagent)19, Monochlorobimane (mBCI)26,27,28. Several companies have also prepared proprietary kits for the detection of glutathione; however, they do not publish reagent incompatibilities, which presents issues dependent on the treatments used29.
This protocol outlines a multiparametric assay that detects reduced thiols (such as GSH) via ortho-phthalaldehyde (OPA) conjugation to produce a fluorescent signal detectable at 340/450 Ex/Em, respectively. This assay facilitates the detection of both GSH and GSSG simultaneously (in plate), through the use of masking agents (N-ethylmaleimide) and GSSG reducing agents (tris(2-carboxyethyl) phosphine). This multi-biomarker protocol also provides an opportunity during the cellular lysing stage to quantify proteins via bicinchoninic acid assay for the normalization of samples on completion of the final measurement or via an adenylate kinase assay from the cell media. This assay can be performed utilizing several reagents readily available in most laboratories and only requires a few additional uncommon chemicals to perform. The process is simple, accessible, and can be performed without laborious stages in less than 2 h.
In this protocol, various nanomaterials were chosen that were either previously shown to induce ROS or suspected to induce oxidative stress30,31. A concentration range was explored to see the effects of exposure of these nanomaterials on various cell lines and the effectiveness of the assay in quantifying antioxidant thiols.
NOTE: The following protocol has been designed with the capacity to be utilized in conjunction with a bicinchoninic acid (BCA) protein assay and an adenylate kinase (AK) assay to normalize samples to treatments. Ensure the operator is wearing appropriate attire and necessary safety equipment, such as a Howie lab coat, nitrile gloves, and class I safety glasses, throughout the preparation and use of materials. The protocol is divided into several stages.
1. Stock and working solutions preparations
2. Assay preparation
NOTE: This protocol uses human cell lines HepG2, A549, and J774, which were purchased commercially from ATCC. These cell lines were utilized under the approved guidelines outlined by the animal and tissue culture acts and regulations of the University.
Cell line | Seeding density (96-well plate) |
HepG2 | 10,000 cells / well |
A549 | 5,000 cells / well |
J774 | 10,000 cells / well |
Table 1: Suggested seeding densities for chosen cell lines. Demonstrated are different seeding densities for three different cell lines used in the represented data, specifically A549, J774, and HepG2.
Figure 1: Proposed layout for seeding of 96 well plates for the simultaneous determination of total Glutathione and Glutathione disulfide. Wells for calibration and controls are also demonstrated. Wells that are not utilized are represented with a cross. Please click here to view a larger version of this figure.
3. Nanomaterial treatment
4. Assay protocol
Total glutathione concentration lysis reagent mix | |
Component | Volume |
Lysis buffer | 50µL |
Total volume / well | 50µL |
Oxidised glutathione concentration lysis reagent mix | |
Component | Volume |
Lysis buffer | 49.5µL |
NEM (25mM) | 0.5µL |
Total volume / well | 50µL |
USE BOTH SOLUTIONS WITHIN 30 MINUTES OF MIXTURE COMPOSITION | |
OPA detection solution component | Volume |
OPA 3mg/mL | 5µL |
PBS (pH 9.0) | 165µL |
Total volume / well | 170µL |
Table 2: Necessary volumes of reagents for performing the protocol. Volumes required per well for the determination of total glutathione, glutathione disulfide, and working reagent required. Ensure required volumes are calculated, and an excess is included to account for volume loss through transfer.
Figure 2: Schematic representation of the protocol. (A) Initial seeding, incubation and treatment of cells. (B) Centrifugation to separate media from suspended solids. (C) Media transfer for Adenylate kinase assay. (D) Addition of glutathione concentrations for calibration range. (E) Washing stages and lysing reagent addition. (F) Buffer addition and tris(2-carboxyethyl) phosphine addition with shaking step. (G) Centrifugation of lysed cells for media removal for protein analysis. (H) Media removal to equalize volume across the plate. (I) Addition of ortho-phthalaldehyde working solution with shaking incubation. (J) Measurement of ortho-phthalaldehyde fluorescence via plate reader. (K) Incubation stages for Bicinchoninic acid assay for protein determination. (L) Measurement of protein concentration, allowing normalization of glutathione: glutathione disulfide values. Please click here to view a larger version of this figure.
Following this protocol, A549 and J774 cell lines were seeded at densities of 5,000 cells/ well and 10,000 cells/well, respectively and cultured at 37 °C in 5% CO2 for 48 h. The AK analysis after nanomaterials treatment is shown in Supplementary Table 1, and the protein concentration is shown in Supplementary Table 2.
Calibration graph
Shown in Figure 3 are three calibrations using the stated concentration range (0.234 – 30 µM final concentration) from three separate plates from three different cell types (though should not impact calibration) on three different, non-consecutive, days. While 3 samples are shown, an N of 12 was observed, and demonstrated similar linear regressions with an average R2 value of 0.9932 ± 0.007.
Figure 3: Glutathione calibration graphs for assay. Three calibration graphs from separate in-plate glutathione calibration ranges, each performed a week apart; error bars ± SD (n=3, N=12) n=technical replicates, N=Biological replicates. Please click here to view a larger version of this figure.
Sample results
HepG2, A549, and J774 cells were utilized in the assessment of various nanomaterials suspected of inducing changes to cellular mechanisms via oxidative stress. The detection and quantification protocol described were utilized.
The data received from the 3 measurements (AK, BCA, and GSH/GSSG) was handled as follows. The AK and BCA assay was implemented for normalization; the AK assay, using the recommended kit, will give the fastest, simplest data for the amount of AK released into the cell media. An increase in AK values is expected for increasing cell death. Hence, a -ve (Alive) and +ve (Dead) control is required. This will allow for normalization based on percentage.
The BCA assay is a longer process but will allow for quantifiable results to be acquired via protein quantification (mg/mL). This does not require a -ve or +ve control as in the AK but will still require a general -ve control (untreated cells) to allow for the normalization of values to be achieved.
In this representative results section, it was found that the treatment (nanomaterials) had the potential to cause interference with the AK assay. Hence, all normalization was performed using the BCA data. Therefore, information is presented as the concentration of detected species (GSH or GSH+GSSG (however, a subtraction of GSH concentration from total GSH+GSSG concentration is performed to get GSSG concentration) per mg/mL of protein (via BCA assay). If desired, this can then be converted into a ratio to assess the change in GSH: GSSG from the desired treatment.
Shown in Figure 4 is the GSH: GSSG ratio data from three different cell lines (A549, J774, and HepG2) acquired using the OPA protocol and normalized to protein expression via BCA (µg/mL), further data specifying additional GSH and GSSG values can be found in Supplementary Figure 1.
Figure 4: Glutathione: Glutathione disulfide ratiofrom performing the assay. Shown are the glutathione: Glutathione disulfide ratios of 3 cell lines, namely (A) A549, (B) J774, and (C) HepG2. Cells were incubated with treatments (various nanomaterials in serum-free media) for 4 h. Cells were processed using this protocol to quantify changes in glutathione and glutathione disulfide and normalized via protein quantification, error bars ± SE (n=3, N=3) Please click here to view a larger version of this figure.
The plate also contains a series of controls to ensure the assay has run correctly. NEM is added as an individual component to demonstrate a lack of interaction with OPA detection media. The calibration standard demonstrates a linear increase with GSH concentration, which demonstrates the effective capacity for the OPA detection reagent to effectively bind to increasing concentrations of GSH.
It must be noted that this assay specifically targets free sulfhydryl groups commonly found in thiols (such as GSH, which are commonly considered antioxidants). One potential interaction is the binding of OPA to protein thiols, which would result in inaccurate data gathering. Hence, the BCA assay is a crucial stage to normalize data to protein and allow accurate reflection of free GSH.
Supplementary Figure 1: Figures demonstrating glutathione, glutathione disulfide, and glutathione: glutathione disulfide ratio from 3 cell lines, namely, (A) A549, (B) J774, and (C) HepG2. Cells were incubated with treatments (various nanomaterials in serum-free media) for 4 h. Cells were processed using this protocol to quantify changes in glutathione and glutathione disulfide and normalized via protein quantification, error bars ± SE (n=3, N=3) Please click here to download this File.
Supplementary Table 1: Metadata of adenylate kinase values for A549 and J774 cells. Please click here to download this File.
Supplementary Table 2: Metadata of Bicinchoninic acid values with calibration for A549, J774, and HepG2 cells. Please click here to download this File.
As stated, the need to understand cellular redox, monitor states of oxidative stress, and the antioxidant response has always been crucial in understanding and preventing a myriad of diseases, such as cancers and neurodegeneration33,34. Demonstrated here is a means to improve upon the translational landscape by increasing the accessibility of accurate GSH: GSSG detection with fast, minimal preparation.
This protocol demonstrates a multiparametric sequence of assays for the determination of intracellular glutathione/ thiol species (reduced and oxidized), with 2 means of normalization via BCA protein assay and/or AK assay. This assay can also be modified to detect various other markers through the initial mediator extraction step and can be simplified in a manner that will simply give an oxidized/reduced thiol ratio with the exclusion of the calibration range.
When considering the evaluation of the analytes, both mBCI and OPA were explored and compared for use. While mBCl initially demonstrated good signal potential, significant limitations in use were discovered. Primarily, the use of live cells demonstrates the best use of mBCl; however, after cell lysis, the signal was found to be quenched and is generally diminished in a multiwell format compared to OPA35. Another issue is the measurement of GSSG via mBCl, literature is sparse regarding this, and through protocol optimization/ exploration, accurate detection of GSSG through mBCl was not achieved.
We have demonstrated that OPA assay presents significantly reliable calibration ranges, with an R2 average of 0.9932 ± 0.007 (N=12) across a 0.234 – 30 µM GSH concentration range. This range was chosen due to previous reference ranges found in the literature35. It is theoretically possible to detect glutathione outside of these ranges but will require modification to the concentration of reagents, incubation time, and potentially the equipment utilized in detection. It must be noted that each plate requires its own standard range for quantification; the slightest variance in time between plates performed on different days can have a significant effect on the values obtained during measurement.
Achieving accurate and reliable data from this protocol is dependent on several crucial steps being strictly adhered to. When constructing the various buffers required in the protocol, it is crucial that pH is accurate. Hence, buffers requiring a pH of 9 should have no deviation beyond ± 0.1 of this value. This is due to the potential for buffer components to precipitate out of the solution in the wrong pH; following this protocol exactly will prevent this issue.
Complete removal of treatment and accurate washing before lysing are also critical to prevent artifacts and inaccurate data acquisition during the plate reading stage. Once cells have been lysed (step 4.8), removal of treatment is not possible, and the plate will not be salvageable. Due to the volumes of buffers/reagents being added throughout the protocol varying between samples and standards, it is critical that the user is aware of the varied volumes, in step 4.12 and 4.13. The assay operator is also made aware of these varied volumes and instructed to ensure all volumes are the same to allow accurate measurement to be achieved. As the volumes between the samples and standards are not visibly significant, it can be an easy mistake to make with regard to having an excess solution in the sample well.
There are limitations to this protocol that rely on crucial steps, which are critical to acquiring accurate and reliable data. The users performing this assay need to possess a reasonable level of laboratory skills to prevent undesired problems, such as bubble formation. Bubble formation has a drastic impact on both the capacity for reactions to occur within the microplate and the measurement of fluorescence. The lysing agent used in this protocol contains a detergent, which presents difficulty to a novice researcher who may struggle to prevent bubble formation. Immediate centrifugation may salvage this error. The protocol is also potentially limited regarding cell type; cell lines A549, J774, and HepG2 were utilized to both optimize and produce data for this protocol. Other cell lines may require different seeding densities and optimization of the protocol to get accurate data.
This protocol offers numerous advantages over several existing assays. While the detection of thiols using Phthalaldehyde is not a novel concept, utilization in a combined assay format such as this, in a microplate, with limited required materials and equipment, offers great potential for all labs to access this protocol. Most Thiol/ GSH kits from commercial suppliers do not disclose the composition of their reagents. Hence, it can be difficult to foresee the potential for incompatibilities/ interference. Here, we present each component of all the utilized reagents to limit that potential.
This protocol is also performed rather rapidly upon completion of the initial treatment period. Accounting for user processing between incubation stages, the thiol quantification aspect of this protocol can be performed in under 1 h. Samples are simultaneously lysed and bound to prevent auto-oxidation of samples, which is optimal for these reaction species. While not specified in the protocol, samples can technically be lysed in a plate and sealed, allowing them to be frozen for future analysis. However, this alteration to the protocol has not been explored.
The authors have nothing to disclose.
This research was funded by the European projects GRACIOUS (GA760840) and SUNSHINE (GA952924). The authors would also like to acknowledge the efforts of all those who, in some way, assisted with the development of this protocol.
0.22µm filter (optional-For lysis buffer) | Fisher scientific | 12561259 | |
100mL volumetric flask | Fisher scientific | 15290866 | |
1L Volumetric flask | Fisher scientific | 15230876 | |
250mL beaker (optional-For lysis buffer) | Fisher scientific | 15409083 | |
8-Channel micropipette (20-200µL) | SLS | FA10011D2 | |
8-Channel micropipette (2-20µL) | SLS | B2B06492 | |
96 well plates – black with clear bottom, TC treated | Fisher scientific | 10000631 | Preferred plate for seeding and fluoresence, use TC treated clear if unavailable |
96 well plates – clear (TC treated and untreated) | Fisher scientific | 10141161 | If black plates with clear bottom is not available/ suitable use TC treated clear |
96 well plates – white, Not TC treated | Fisher scientific | 11457009 | |
A549 (lung carcinoma) cell line | ATCC | CCL-185 | |
Absolute ethanol | Merck (Sigma-Aldrich) | 1.08543 | |
Aluminium foil | Fisher scientific | 11779408 | For protecting plates from light |
BCA Assay Kit | Thermo | 23225 | |
Benchtop Centrifuge (with 96 plate rotor) | Eppendorf | 5804 | |
Ethylenediaminetetraacetic acid (EDTA) | Merck (Sigma-Aldrich) | E9884 | |
Glutathione (GSH) | Merck (Sigma-Aldrich) | G6013 | |
Glutathione disulfide (GSSG) | Merck (Sigma-Aldrich) | G4501 | |
Glycerol | Merck (Sigma-Aldrich) | G5516 | |
HCl, 37% | Merck (Sigma-Aldrich) | 258148 | Dilute to 1mM for GSH stock, pH adjustment also |
HepG2 (Hepatocarcinoma) cell line | ATCC | HB-8065 | |
IGEPAL CA-630 | Merck (Sigma-Aldrich) | 18896 | Use either IGEPAL CA-630 or NP-40 for solution, not both |
IP lysis buffer | Fisher scientific | 11825135 | |
J774 (monocyte, macrophage) cell line | ATCC | TIB-67 | |
KCl | Merck (Sigma-Aldrich) | P3911 | |
KH2PO4 | Merck (Sigma-Aldrich) | P0662 | |
Micropipette (20-200µL) | SLS | B2B06482 | |
Micropipette (2-20µL) | SLS | B2B06478 | |
Microplate shaker | VWR | 444-0041 | |
Na2HPO4 | Merck (Sigma-Aldrich) | S9763 | |
NaCl | Merck (Sigma-Aldrich) | S9888 | |
NaOH, 10M | Merck (Sigma-Aldrich) | 72068 | For pH adjustment only |
N-Ethylmaleimide (NEM) | Merck (Sigma-Aldrich) | E3876 | |
NP-40 | Merck (Sigma-Aldrich) | 492016 | Use either IGEPAL CA-630 or NP-40 for solution, not both. NP-40 alternative suggested |
Ortho -Phthaldialdehyde (OPA) | Merck (Sigma-Aldrich) | P1378 | |
PBS 0.1M | Merck (Sigma-Aldrich) | P2272 | PBS can either be acquired pre-made or made in house, see notes |
Plate reader (with fluoresence capacity) | Tecan | SPARK | |
Stir bar (optional-For lysis buffer) | Fisher scientific | 16265731 | |
Toxilight bioassay kit (AK assay) | Lonza | LT17-217 | |
Tris(2-carboxyethyl)phosphine hydrochloride (TCEP) 0.5M in H2O | Alfa Aesar | H51864 | Can also be purchased crystalised and suspended |
TRIS-HCl | Merck (Sigma-Aldrich) | 93363 | |
X100 phosphatase and protease cocktail | Fisher scientific | 10025743 |