This method describes sample preparation from cultured cells and animal tissues, extraction and derivatization of coenzyme A in the samples, followed by high pressure liquid chromatography for purification and quantification of the derivatized coenzyme A by absorbance or fluorescence detection.
Emerging research has revealed that the cellular coenzyme A (CoA) supply can become limiting with a detrimental impact on growth, metabolism and survival. Measurement of cellular CoA is a challenge due to its relatively low abundance and the dynamic conversion of free CoA to CoA thioesters that, in turn, participate in numerous metabolic reactions. A method is described that navigates through potential pitfalls during sample preparation to yield an assay with a broad linear range of detection that is suitable for use in many biomedical laboratories.
Coenzyme A (CoA) is an essential cofactor in all living organisms and is synthesized from pantothenic acid, also called pantothenate (the salt of pantothenic acid) or vitamin B5. CoA is the major intracellular carrier of organic acids, including short-chain acids such as acetate and succinate, branch-chain acids such as propionate and methylmalonate, long-chain fatty acids such as palmitate and oleate, very long-chain fatty acids such as polyunsaturated fatty acids, and xenobiotics such as valproic acid. The organic acid forms a thioester linkage enzymatically with CoA to enable its use as a substrate in over 100 reactions in intermediary metabolism1. CoA thioesters are also allosteric regulators and transcriptional activators. It is now appreciated2 that the cellular total CoA supply is regulated3,4; thus, CoA availability can be limiting, and that CoA deficiencies can be catastrophic, as exemplified by inherited genetic disorders that impact CoA biosynthesis5. Pantothenate kinase catalyzes the first step in CoA biosynthesis (Figure 1) and Pantothenate Kinase Associated Neurodegeneration, called PKAN, is caused by mutations in the PANK2 gene6. CoA synthase, encoded by the COASYN gene, catalyzes the last two steps in CoA biosynthesis (Figure 1) and COASY Protein-Associated Neurodegeneration, called CoPAN, is caused by a mutation in the COASYN gene7. Both PKAN and CoPAN are inherited neurodegenerative diseases associated with iron accumulation in the brain and CoA deficiencies underly the disease pathologies.
Cellular levels of total CoA vary among tissues8 and total CoA can increase or decrease under a variety of physiological, pathological and pharmacological states. Liver CoA increases during fuel switching from the fed to the fasted state9, and liver CoA levels are abnormally high in leptin-deficient obese mice10. Liver CoA decreases in response to chronic ethanol ingestion11. Brain CoA levels in the Pank2 knockout mouse model are depressed during the perinatal period, but later in the adult stage brain CoA content is equivalent to wild-type levels, indicating an adaptive CoA response during development12. Manipulation of tissue CoA content by transgenesis or gene delivery methods impacts metabolic and neural functions13,14,15. Preclinical development of potential therapies for PKAN or CoPAN includes cell or tissue CoA measurements as indicators of efficacy16,17,18,19,20. Evaluation of all of these conditions and their metabolic or functional consequences requires a quantitative method for measurement of total CoA.
An accurate, reliable assay for measuring CoA in biological samples is a technical challenge in many labs. Unfortunately, there are no probes available to evaluate or quantify CoA or CoA thioesters in intact cells, although analogs of natural CoA thioesters have been widely used as mechanistic probes in studies of CoA ester utilizing enzymes21. The conversion of CoA, with a free sulfhydryl (-SH) moiety, to a CoA thioester (or vice versa) is rapid in cells or animal tissues during transfer to a different environment and during cell lysis. Numerous acyl-CoA synthetases and acyl-CoA thioesterases in cells mediate the interconversions within the CoA pool, and additional enzymes that utilize CoA thioesters as substrates remain active in biological samples until quenched by chemical or physical means. The off-loading of acyl-groups from CoA to carnitine by acyl-transferases is one example within the network of reactions that can alter the CoA/CoA thioester distribution. Radioactive tracers can be used to measure rates of CoA synthesis in cells. Current methods for measuring CoA and CoA derivatives in biological samples have been reviewed22 and include coupled enzymatic spectrophotometric assays, high-pressure liquid chromatography and mass spectrometry-based procedures. However, these methods are often focused on particular CoA molecular species and are blind to variation of the total CoA pool. The coupled enzymatic assays generally require larger amounts of input material due to low detection sensitivities and have a limited range of linearity.
Our laboratory has developed a reliable procedure for quantification of total CoA in cultured cells and animal tissues. The strategy includes hydrolysis of all CoA thioesters to yield only free CoA during sample preparation, rather than making efforts to maintain and analyze the entire spectrum of CoA species. The procedure is a compilation of individual published methods for sample preparation, CoA derivatization, purification and identification following high-pressure liquid chromatography (HPLC), and quantification of the derivatized CoA by absorbance or fluorescence detection23,24,25. The CoA determinations obtained using this procedure have enabled our understanding of CoA regulation and the development of a therapeutic approach for treatment of CoA deficiencies.
The animal procedure referred to in this protocol was performed according to protocols 323 and 556 and specifically approved by the St. Jude Children's Research Hospital Institutional Animal Care and Use Committee.
1. Preparation of solutions
NOTE: Use ultrapure water for all solutions and when stated in procedures.
2. Preparation of CoA-bimane standard
3. Extraction and derivatization of CoA in cultured cells
4. Extraction and derivatization of CoA in tissues
5. Sample clean-up with solid phase extraction (SPE) column
6. HPLC purification and measurement of CoA-bimane
A relatively fast and reliable method for the detection of total CoA in cultured cells and tissues has been developed by derivatizing the thiol of CoA to a fluorescent agent using mBBr, and then purifying the derivatized CoA-bimane using reverse phase HPLC. A standard curve is first generated, where known and increasing amounts of the CoA-bimane standard are injected individually and the areas under the peaks in the CoA-bimane chromatograms are plotted as a function of the input CoA-bimane (Figure 4). CoA-bimane has an absorbance maximum at λ393 nM and a representative HPLC profile shows the retention time of the CoA-bimane standard on a C18 HPLC column (Figure 3) using the elution program in Table 1. Representative standard curves of CoA-bimane, detected by measuring absorbance or fluorescence units, are shown in Figure 4A and Figure 4B, respectively. The standard curve in Figure 4A reflects the magnitude of absorbance of CoA-bimane at λ393 nm and Figure 4B represents the fluorescence of CoA-bimane (λex = 393 nm and λem = 470 nm) plotted versus the input amount of CoA-bimane. The CoA-bimane standard can be detected from 0.01 to 12,000 pmol and covers a 106-fold range when detection using both absorbance and fluorescence is combined. While the lower limit of detection of the standard is 0.01 pmol, the lower limit of CoA-bimane quantitation in experimental samples is 0.2 pmol which is about 5-fold greater than the baseline or background fluorescence in the chromatogram. The choice of detection by absorbance or fluorescence of CoA-bimane depends on the amount of CoA normally present in tissues or cells, together with the practicality of working with larger or smaller sample sizes. Absorbance is generally useful for tissue samples because handling 40-50 mg of starting material yields better recovery than 5 mg tissue samples, whereas fluorescence is generally useful for cultured cell samples which are smaller in size and there is greater confidence in interpolation of values at the lower end of the fluorescence standard curve. Laboratories with only absorbance detection may consider increasing or decreasing the starting sample size, increasing the HPLC injection volume or decreasing the volume for sample resuspension (Section 5.9 above) for measurements in cultured cells.
The conditions for hydrolyzing acyl-CoAs from tissues and cultured cells were optimized by adjusting the KOH concentration, and the time and temperature of subsequent incubation (data not shown). The optimum condition was found to be 0.25 M at 55 °C for 2 hours. The thiol group of free CoA plus any CoA liberated from thioesters were derivatized by reaction with mBBr following adjustment of the pH. Subsequent HPLC separation and typical detection profiles for mouse liver or human cultured C3A cells are indicated in Figure 5 as red peaks, with a retention time between 11 and 12 minutes using the elution program described in Table 1. Typical amounts of biological starting material are 30-40 mg of murine liver (wet weight), 6-8 x 106 cells for human "liver-like" C3A cells, or ~1.3 x 107 cells for human HEK293T cells. The C3A cells were treated with a PanK experimental drug PZ-2891 at 10 uM which elevates CoA17 (Figure 6). The CoA measurements in HEK293T cells when PanK isoforms are overexpressed show CoA measurements over a wide range (431-6925 pmoles/µL) (Figure 6). The sample sizes required for this methodology are practical for application to many experimental contexts.
The area under the CoA-bimane peak was calculated using software provided with the HPLC. The peak limits can be determined automatically by the HPLC software pending proper adjustment of input values for baseline correction and peak definition, but our laboratory prefers to manually designate the CoA-bimane peak in each chromatogram, particularly for unfamiliar biological samples.
Time (min) | Flow Rate (mL/min) | % A | % B | Curve |
0 | 0.5 | 90 | 10 | 0 |
2 | 0.5 | 90 | 10 | 6 |
6 | 0.5 | 85 | 15 | 6 |
18 | 0.5 | 60 | 40 | 6 |
23 | 0.5 | 60 | 40 | 6 |
25 | 0.5 | 90 | 10 | 6 |
30 | 0.5 | 90 | 10 | 66 |
Table 1: HPLC Program for CoA-bimane Separation. Buffer A: 50 mM KH2PO4, pH 4.6; Buffer B: Acetonitrile. The mixing of Buffer A and Buffer B follows Curve 6 which is a linear gradient, with an intervening Curve 8 which is a medium concave gradient.
Figure 1. Coenzyme A biosynthesis pathway. Pantothenate kinase (PanK) catalyzes the phosphorylation of pantothenate (vitamin B5) to 4′-phosphopantothenate in the first step of CoA biosynthesis. Formation of phosphopantothenate is followed by condensation with cysteine catalyzed by 4′-phosphopantothenoylcysteine synthase and then decarboxylation to form 4′-phosphopantetheine by 4′-phosphopanthenoylcysteine decarboxylase. 4′-Phosphopantetheine is converted to Coenzyme A (CoA) in a two-step process catalyzed by CoA Synthase. Please click here to view a larger version of this figure.
Figure 2. mBBr Reaction with CoA. Monobromobimane (mBBr) is mixed with CoA-SH (free CoA) and incubated at room temperature for 2 hours in the dark. Non-fluorescent mBBr becomes fluorescent when bound to CoA to form CoA-bimane. Please click here to view a larger version of this figure.
Figure 3: Absorbance HPLC Trace of CoA-bimane Standard. CoA-bimane was separated on a Gemini C18 column using the HPLC program in Table 1. Typical retention time (min) is indicated by aborbance units (AU). Please click here to view a larger version of this figure.
Figure 4: CoA-bimane standard curves detected by absorbance or fluorescence. (A) The standard curve measured using absorbance detection units for CoA-bimane was measured at λ393 nm. Tissue samples are usually evaluated using the absorbance standard curve. (B) The standard curve measured using fluorescence detection units for CoA-bimane at λex = 393 nm, λem = 470 nm. Cultured cells are usually evaluated for CoA content using the fluorescence standard curve. Duplicate standards (and samples) are routinely evaluated. Please click here to view a larger version of this figure.
Figure 5: HPLC traces of typical liver or cultured cell samples. (A) CoA-bimane identification and quantification of content in mouse liver extract. Absorbance units (AU) are indicated. (B) CoA-bimane identification and quantification of content in HepG2/C3A cultured cells. Fluorescence emission units (EU) are indicated. The CoA-bimane peaks are shown in red. Please click here to view a larger version of this figure.
Figure 6. CoA levels in mouse liver, cultured C3A and HEK293T cells. (A) CoA measurement in mouse liver from pantothenate kinase knockout (Pank1-/-) and matched wild-type (WT) animals. Pank1-/- animals have lower CoA in the liver compared to WT animals due to the absence of Pank1 expression9. The data were obtained using 5 male mice per genotype and are represented as the mean ± SEM. (B) CoA levels in HepG2/C3A cells treated with either dimethylsulfoxide (vehicle control) or PZ-2891, an experimental drug that modulates PanK activity at 10 uM17. The cellular CoA level is elevated following 24-hour incubation with PZ-2891. (C) CoA levels in HEK293T cells transfected with either empty vector pcDNA3.1, or cDNAs encoding human PANK isoforms: PANK1β, PANK2m which is the mature, processed isoform of human PANK2, or PANK3. CoA levels are elevated by overexpression of all active PANK isoforms. The data in (B) and (C) are from independent triplicate samples and are represented as the mean ± SEM. The statistical analysis was done using the unpaired t-test and the values of significance are shown in red. The data in panels (B) and (C) are adapted from Sharma et al.12 Please click here to view a larger version of this figure.
Here we demonstrate a reliable, step-by-step procedure for quantifying total CoA in cells and animal tissues with a wide range of linear detection that is accessible in many laboratories that have an HPLC with either an absorbance or fluorescence output detector. Alternatively, mass spectrometry is a common technique for evaluating CoA and CoA thioesters, but is not widely available due to the cost of the instrumentation and the specialized knowledge required for development of methodology and interpretation of data. Isotopically labeled CoA that is suitable for use as an internal standard for quantification of free CoA in mass spectrometry is not commercially available, and free CoA is not detected by the instrument with the same sensitivity as CoA thioesters such as acetyl-CoA. Thus, free CoA levels are often grossly underestimated by mass spectrometry unless the output data are compared with a CoA standard calibration curve.
We compared the method described here with a different method previously used in our laboratory and found greater CoA recovery from mouse liver, 123.4 ± 7.9 pmol/mg wet weight, with this current method compared to ~80 pmol/mg wet weight using an enzymatic assay that derivatized free CoA with a radioactive tag28. The method for measuring total CoA that is described here is considerably less cumbersome, faster and easier to control compared to the method previously used in our lab28. Formerly, CoA was determined following hexane extraction of the cell lysate and subjected to enzymatic conversion to radioactive [14C]lauryl-CoA mediated by the Escherichia coli acyl-CoA synthetase (FadD). The acid-soluble short-chain acyl-CoAs and the acid-insoluble long-chain acyl-CoAs in the cell lysate were hydrolyzed with KOH to yield free CoA and then subjected to hexane extraction prior to the enzymatic conversion to free CoA29. Although this previous procedure had good specificity and sensitivity, in practice the task required 2 working days to complete and the recombinant E. coli acyl-CoA synthetase had to be prepared, purified and measured for enzymatic specific activity prior to the CoA analysis. It also required instrumentation capable of detecting and quantifying radioactive isotopes which is much less common in biomedical laboratories in more recent history. The current method as described here is most suitable for our research interest in pantothenate kinase (PanK). PanK controls the flux through the CoA biosynthetic pathway and so the total CoA level is the readout for the PanK activity in biological samples.
Quenching of metabolic reactions in a biological sample to maintain a true amount of CoA requires care and rapidity and is critical for this procedure. Rapid deproteinization with an acid or organic solvent, or flash-freezing of samples are two methods that have been used in the past30,31. In the present method, ice-cold ultrapure water is quickly added to ice-cold PBS-washed cells from cultures, and adherent cells plus water are then scraped off the culture dish before transfer to KOH. Freezing of the cultured cell suspension in [KOH + water] for storage at -80 °C prior to sample preparation is an acceptable stopping point. However, CoA values from frozen cell samples should be compared to those from freshly prepared samples to determine if there is substantial loss of the CoA signal. Loss of ≤ 10% CoA has occurred in our hands following cell sample freezing and may be related to the extended time of the sample in the KOH which needs to be controlled. Animal tissue pieces are quickly frozen on a small foil 'raft' floating on LN2 immediately following excision of the tissue from a euthanized animal. Sample sizes from 5 mg to 60 mg of frozen tissue are appropriate for this method with linear CoA yields. Once frozen, tissue samples stored at -80 °C are stable for at least 3 months, providing that intermittent thaw does not occur.
The sample preparation prior to the HPLC analysis is not high throughput and requires a full working half-day. It is recommended that the operator handles a maximum of 30 samples at one time, starting with homogenization of a set of 15 samples followed by homogenization of the second set of 15 samples during the 2 h incubation with KOH for the first set. The KOH incubation period was first optimized using purchased CoA thioesters with incubation times ranging from 30 min to 4 h, and then the 2 h incubation was chosen to accommodate the time for complete CoA thioester hydrolysis in a variety of tissue samples, ranging from skeletal muscle to liver8. Incubation for CoA derivatization with mBBr is set at 2 h at approximately pH 8 and a 20-fold excess of mBBr is added to completely convert the CoA in the biological samples. Sulhydryl moieties of proteins and metabolites other than CoA such as carnitine or glutathione in the sample will be derivatized in addition to CoA, and the 20-fold excess was calculated on the basis of the expected amount of total CoA liver which has the highest level among tissues. The pH is reduced prior to incubation with mBBr because bromobimanes in general are less reactive towards other nucleophiles like amines and carboxylates in more neutral aqueous solutions. The time of derivatization should not exceed 2 h to avoid or lessen reaction with protein thiols26. One needs to use nonnucleophilic buffers to reduce and maintain the pH because the presence of buffer anions at high concentrations can interfere with the mBBr derivatization of CoA.
Sample clean-up on the SPE column is done manually in our laboratory and can be performed with the aid of a vacuum manifold to shorten the time required for this step. Good recovery of derivatized CoA from the SPE column is routinely attainable and this was determined separately using radioactive [13C]CoA thioesters which are also retained on the SPE column. Recovery of [13C]acetyl-CoA was 97.6% and recovery of [13C] palmitoyl-CoA was 96.1%. Evaporation of the SPE-column eluate is usually performed under nitrogen gas overnight in our laboratory as a matter of convenience, but drying can be completed within 4 hours under nitrogen gas or using a speedvac concentrator. The most critical steps in the method are related to pH adjustment and can be checked with pH paper strips along the way. For the KOH hydrolysis, the pH needs to be ≥ 12 to achieve complete release of the thioester from CoA. The pH needs to be 7.8 – 8.5 to support the reactivity of the mBBr-derivatization, and after the derivatization is complete, the pH should be adjusted to become very acidic, about pH 1-2, in order for the CoA-bimane to bind to the SPE column. The SPE column cleans up the sample to eliminate excess unreacted mBBr and some unrelated biological substances.
The HPLC program is designed so that washing and re-equilibration of the C18 column is sufficient to eliminate background and carryover signals between samples. Water blank samples are inserted after every 5 samples in the experimental sample set as a precaution to monitor possible carryover between sets and to ensure column cleanliness. An occasional error from improper sample injection can occur when using an automated sample injector for the HPLC, and this can easily be checked by comparing the volumes remaining in the sample vials after injection or inspection of the non-CoA related peaks in the output chromatogram. If the CoA values exceed the linear range of the calibration curve for fluorescence detection, the values will most likely be in range for ultraviolet absorbance detection. If not, dilution of the sample with a known volume of water can reduce the signal to be in the linear range and calculations should take any dilution factor into account.
CoA levels will vary among inbred mouse strains with different genetic backgrounds, although the values are reproducible when biological samples are obtained from the same strain under the same conditions. We have estimated CoA in several different mouse lines in various studies10,12,16,17. CoA was also measured in several cultured cell lines16,17 using either primary or immortalized cells.
The authors have nothing to disclose.
The authors acknowledge funding for sponsored research provided by CoA Therapeutics, Inc., a subsidiary of BridgeBio LLC, the National Institutes of Health grant GM34496, and the American Lebanese Syrian Associated Charities.
2-(2-pyridyl)-ethyl silica gel SPE column | Millipore-Sigma | 54127-U | |
coenzyme A | Avanti Polar Lipids | 870700 | |
Gemini C18 3 μm 100 Å HPLC column | Phenomenex | 00F-4439-E0 | |
monobromobimane | ThermoFisher Scientific | M-1378 | |
Omni-Tip probe tissue disrupter | Omni International | 32750H | |
Parafilm | Fisher | S37440 | |
PowerGen 125 motorized rotor stator homogenizer | ThermoFisher Scientific | NC0530997 | |
Spin-X centrifuge tube filter | CoStar | 8161 | |
Trizma-HCl | Fisher | T395-1 | |
Waters 2475 fluorescence detector | Waters | 2475 | |
Waters 2489 UV-Vis detector | Waters | 2489 | |
Waters e2695 separations module | Waters | e2695 |