Here, we present a protocol to isolate the plasma membrane, cytoplasm and mitochondria of U937 cells without the use of high-speed centrifugation. This technique can be used to purify subcellular fractions for subsequent examination of protein localization via immunoblotting.
In this protocol we detail a method to obtain subcellular fractions of U937 cells without the use of ultracentrifugation or indiscriminate detergents. This method utilizes hypotonic buffers, digitonin, mechanical lysis and differential centrifugation to isolate the cytoplasm, mitochondria and plasma membrane. The process can be scaled to accommodate the needs of researchers, is inexpensive and straightforward. This method will allow researchers to determine protein localization in cells without specialized centrifuges and without the use of commercial kits, both of which can be prohibitively expensive. We have successfully used this method to separate cytosolic, plasma membrane and mitochondrial proteins in the human monocyte cell line U937.
Reliable identification of protein localization is often necessary when examining molecular pathways in eukaryotic cells. Methods to obtain subcellular fractions are utilized by researchers to more closely examine cellular components of interest.
The majority of existing cell fractionation methods generally fall into two broad categories, detergent-based1,2 and ultracentrifugation-based3,4,5, which can be differentiated by speed, precision and cost. Detergent based protocols rely on the use of buffers with increasing detergent strength to solubilize distinct components of the cell. This is a rapid and convenient method for processing samples and can be cost effective if the number and size of samples are small. Detergent-based kits can be purchased to isolate cytoplasmic, membrane/organelle (mixed fraction), and nuclear fractions from cells. However, several drawbacks associated with these kits limit their usefulness to researchers. They are designed to easily isolate one or two components of the cell, but are incapable of isolating all fractions from a sample concurrently. The use of detergents means that the plasma membrane and membrane-enclosed organelles will be equally solubilized and, therefore, unable to be separated from one another. An additional complication arises from the proprietary components in these kits which prevents researchers from altering conditions for specific applications. Lastly, they are limited in number of uses and may be prohibitively expensive for larger scale experiments. Non-detergent based kits exist for the isolation of mitochondria, however, they are not designed to isolate plasma membrane and the sample yield is significantly less than that from density centrifugation based isolation protocols6,7.
Methods that utilize ultracentrifugation to obtain fractions are more time consuming, but often result in purer fractions than detergent-based kits. To isolate plasma membranes from cells without first solubilizing them (resulting in contamination with membrane organelles) requires them to be lysed by a non-detergent method followed by separation of cellular components via differential centrifugation—with plasma membrane isolation requiring speeds of 100,000 × g to accomplish. In many cases, differential centrifugation must be followed by isopycnic density gradient centrifugation for further separation of cellular fractions or removal of contaminants. While these methods are thorough and modifiable, drawbacks include cost, time consumption, and the need for an ultracentrifuge for separation of fractions and further purification via density gradient centrifugation. Most high-speed centrifuges are at a cost that is prohibitive for individual investigators and are often shared, core equipment at academic institutions. Thus, ultracentrifuge availability becomes prohibitive in these situations.
In this fractionation protocol we demonstrate the isolation of subcellular fractions without the use of solubilizing detergents and without high speed centrifugation. This method will allow researchers to isolate the plasma membrane, mitochondria and cytoplasmic components of a eukaryotic cell with minimal contamination between fractions.
1. Prepare Buffers and Reagents
NOTE: See Table 1.
2. PBS Wash
3. Cytosolic Protein Isolation
4. Cell Homogenization
5. Differential Centrifugation
Successful fractionation of undifferentiated U9378 cells grown in suspension was accomplished using the protocol detailed above and illustrated in Figure 1. The samples obtained with this method were subjected to western blotting9 utilizing a wet transfer method to a polyvinylidene fluoride (PVDF) membrane. The membrane was subsequently probed with antibodies against cytoplasmic, mitochondrial and membrane localized protein markers (Figure 2, Figure 3, Figure 4). The successful extraction of cytoplasmic proteins can be verified by probing the blot with antibodies against the cytosolic protein glyceraldehyde-3-phosphate dehydrogenase10 (GAPDH), normally localized to the cytoplasm of the cell. As shown by the immunoblot (Figure 2; bottom panel, lanes 1 and 2), GAPDH is found only in the digitonin extracted samples and no contamination is observed in the 4,000 × g pellets (Figure 4; lanes 3 and 4 on the bottom panel) or 18,000 × g pellets (Figure 4; lanes 5 and 6 on the bottom panel). Probing for the voltage-dependent anion channel (VDAC), a protein localized to the outer mitochondrial membrane11, shows the successful isolation of mitochondria in the 4,000 × g pellets (Figure 4; lanes 3 and 4 on the middle panel), while the absence of this protein in other fractions shows the lack of mitochondrial contamination in the 18,000 × g pellets or digitonin-extracted samples. Probing for the Na/K-ATPase α1 subunit, part of an integral membrane heterodimer found primarily in the plasma membrane12, shows the majority of this protein located in the 18,000 × g pellets (Figure 4; lanes 5 and 6 on the top panel). This protein is also detected in the 4,000 × g pellets (Figure 4; lanes 3 and 4 of the top panel), suggesting possible contamination with plasma membrane, though this possibility is unlikely at the low speed with which this pellet was obtained. A more plausible explanation is the presence of endoplasmic reticulum (ER) in the 4,000 × g pellets sample, as transport of Na,K-ATPase subunits from the ER to the plasma membrane has been demonstrated by researchers13. The lack of Na,K-ATPase α1 protein in the digitonin extracted samples (Figure 4; lanes 1 and 2 on the top panel) demonstrates the purity of this fraction.
In contrast to the outcome observed during a successful fractionation (Figure 2), improper execution of the protocol can result in cross contamination of cellular components (Figure 3, Figure 4). A high concentration of Na,K-ATPase α1 protein in the 4,000 × g pellets, when compared to the 18,000 × g pellets (Figure 3 {top panel, lane 2-3] and Figure 4B [top panel, lanes 5-12]), indicates that the organelle fraction has been contaminated with plasma membrane proteins. The presence of GAPDH in any fraction other than the digitonin-extracted cytoplasmic sample (Figure 3 [bottom panel, lane 4] and Figure 4A [bottom panel, lanes 5-12] is an indicator of failure to remove cytoplasmic proteins in subsequent steps.
Figure 1: Diagram of the Cell Fractionation Protocol. An overview of the cell fractionation protocol represented as a flow chart. Please click here to view a larger version of this figure.
Figure 2: Successful Isolation of U937 Cell Cytoplasm, Organelle, and Membrane Fractions. Western blots of cell fractions isolated from two U937 cell cultures and probed for markers of membrane (Na, K-ATPase α1, top panel), mitochondria (VDAC, middle panel) and cytoplasm (GAPDH, bottom panel). Please click here to view a larger version of this figure.
Figure 3: Failure to Fractionate U937 Cell Components. Western blots of cell fractions isolated from a single U937 cell culture showing contamination of the organelle fraction (lane 2) with Na, K-ATPase α1 (top panel) and loss of cytoplasmic components into the supernatant of the membrane pellet (lane 4). Please click here to view a larger version of this figure.
Figure 4: Cross Contamination of Cytoplasmic and Membrane Components During Fractionation. (A) Fractionation attempt with cytoplasmic cross contamination of GAPDH in organelle (bottom panel, lanes 5-8) and membrane fractions (bottom panel, lanes 9-12). (B) Fractionation attempt with plasma membrane contamination of Na, K-ATPase in mitochondrial fractions (top panel, lanes 5-8). Please click here to view a larger version of this figure.
Name | Composition (stock concentration) | Final Concentration |
Buffer A | NaCl (150 mM) and HEPES (50 mM) | 1X (same as stock) |
Lysis Buffer B | HEPES (20 mM), KCl (10 mM), MgCl2 (2 mM), EDTA (1 mM), EGTA (1 mM), Mannitol (210 mM) and Sucrose (70 mM) | 1X (same as stock) |
Sample Buffer | Sodium dodecyl sulfate (0.1%) in Tris-buffered Saline | 1X (same as stock) |
Digitonin | Digitonin (250 µg/ml) in deionized water | 25 µg/ml |
Phenylmethanesulfonyl fluoride | Phenylmethanesulfonyl fluoride (100 mM) in 100% ethanol | 1 mM |
Protease Inhibitor Cocktail | Varies (See manufacturer product sheet) | 1X |
Sodium Orthovanadate | Sodium Orthovanadate (500 mM) in deionized water | 1 mM |
Table 1: Buffers and Solutions. Composition of buffers and required solutions for the procedure.
Protocol Step | Critical Factor | Explanation | Potential Issues | Possible Solutions |
Cell Preparation | Cell concentration | The optimal concentration of cells that this method can process must be determined empirically for the cell type being worked with in order to obtain the best results. | Highly concentrated cell suspensions may result in inefficient lysis, leading to low yields of mitochondria and membrane fractions. | Perform initial procedure with a range of cell concentrations to determine best results. |
Pre-processing of cells | Cells must be in suspension for the fractionation procedure, this requires detaching adherent cells from culture surfaces or homogenizing tissues. | Inefficient processing may result in low fraction yields, cross contamination between subcellular fractions or other unexpected results. | Ensure that the method employed results in sufficient cells for the procedure. Count cells in suspension to determine concentration after processing and adjust accordingly. | |
If the method employed compromises the plasma membrane, premature lysis may occur, resulting in cross contamination of fractions. | Ensure that plasma membrane integrity is maintained during cell harvest by using methods that avoid damaging the cell. Verify membrane integrity by examination under a microscope with the inclusion of a membrane impermeable dye (such as Trypan blue). | |||
Cytosolic Protein Isolation | Digitonin Concentration | The optimal concentration of digitonin must be determined to avoid lysis of cells while still allowing cytosolic protein extraction through pore formation. | High concentrations of digitonin may lead to membrane rupture, cell lysis and contamination of the cytosolic fraction. Suboptimal concentrations will result in inefficient extraction of cytosolic proteins and possible cross contamination of subsequent fractions. | The concentration of digitonin should be decreased if excessive cell lysis is observed. A small cell pellet obtained following digitonin incubation may indicate membrane rupture and cell lysis. |
Post-Extraction Wash | Removal of digitonin and cytosolic proteins from permeabilized cells must be performed to avoid cross contamination. | Failure to wash cells sufficiently after cytosolic extraction may result in carry over of cytosolic proteins to other fractions. | Additional washes with Buffer A following digitonin incubation will dilute digitonin and remaining cytosolic proteins. | |
Mitochondrial Isolation | Cell Lysis | Lysis methods must be thorough to release cellular contents, while maintaining mitochondrial integrity for subsequent isolation. | Mechanical lysis of cells may be inefficient, leaving cells intact and resulting in low yields of mitochondrial proteins. | The amount of force needed to lyse cells and release mitochondria must be determined empirically for different cell types. Large pellets obtained after the lysis step (as well as small mitochondrial and membrane pellets) may indicate suboptimal lysis. Increase the amount of force (pestle strokes, needle passages, etc.) to minimize the post lysis pellet. |
Too much mechanical force may lyse mitochondria, contaminating the plasma membrane fraction with mitochondrial membrane proteins. | Decrease the amount of force if mitochondrial protein markers are found in membrane samples. | |||
Debris Removal | Intact cells and larger fragments must be removed from the homogenate following lysis to avoid contaminating mitochondrial samples. | Mitochondrial samples may become contaminated with cytoplasmic components or plasma membrane proteins if debris and intact cells are not removed prior to pelleting mitochondria. | Increase the number of low speed centrifugation steps prior to the mitochondrial isolation spin. If mitochondrial yield is low, it may be necessary to save pellets from low speed spins and check via western blot for mitochondrial markers. | |
Post-Isolation Wash | Mitochondrial samples should be washed thoroughly to remove contaminating debris that may pellet with them. | Cell fragments may aggregate and associate with mitochondria, leading to cross contamination of cytoplasmic or membrane proteins. | Ensure that pellets are sufficiently washed with buffer to remove contaminants. | |
Membrane Isolation | Centrifugation Time | Centrifugation times may need to be extended to increase yield of membrane fraction sample. | Depending on the total number of processed cells and the efficiency of cell lysis, membrane fraction sample yield may be low. | Increasing the centrifugation time may improve yield of plasma membrane fraction. While the suggested time is sufficient for a large starting quantity of cells, longer times may be necessary for smaller quantities. |
Table 2: Critical Steps. Summary table of protocol steps, potential issues and possible solutions for troubleshooting the protocol.
The development of this protocol arose from an inability to separate mitochondrial and membrane samples, using commercially available kits, for analysis of protein localization during necroptosis14. The primary limitations of premade kits are their inability to be adapted to the needs of individual researchers, their cost per sample and limited number of samples able to be processed. The method presented here can be performed without the use of expensive reagents and without the necessity for expensive equipment. This method can be scaled to accommodate any number of cells and is capable of being altered to suit the needs of researchers. This allows the yield of each fraction to be increased, tailoring of steps to the research being performed and flexibility in execution of the method. The addition of sodium orthovanadate in the buffers can be omitted if researchers are not examining phosphorylation state of proteins in the final samples. The inclusion of SDS in the final buffer can likewise be omitted if researchers wish to further purify the samples via density gradient centrifugation. While we have only used this method to successfully fractionate U937 cells, a non-adherent monocyte cell line, the procedure should work with multiple cell lines and tissues, with minor alterations. Cells grown in suspension can be pelleted similarly to the U937 cells detailed here, while adherent cell lines require dissociation from the growth surface prior to beginning this protocol. Similarly, tissues must be thoroughly homogenized prior to fractionation of containing cells. This can be accomplished by utilizing a loose fitting Dounce homogenizer, a Potter-Elvehjem glass-polytetrafluoroethene homogenizer or by other (commercial) methods15.
There are a number of critical steps in the protocol that need careful attention to obtain optimal results and pure fractions (Table 2). The concentration of cells recommended here (steps 2.1.2, 2.1.4, 3.1.3, 3.2.1 and 4.1.2) are specific to U937 cells and were determined through trial and error. These values may need to be adjusted to accommodate different types of cells if suboptimal results are obtained when executing the protocol. During the cytoplasmic extraction step (step 3.1), the concentration of digitonin must be sufficient to permeabilize the plasma membrane without completely lysing the cells. Following this incubation, cells must be thoroughly washed to remove cytosolic proteins from subsequent steps or cross contamination will occur in downstream samples (Figure 4A). The homogenization step (step 4.1.4) can be accomplished with any form of mechanical lysis, although results presented here were obtained with a Dounce homogenizer. An alternative to using a Dounce homogenizer is to repeatedly pass cells through a narrow gauge needle (27 G recommended, 20-40 passes) until sufficient cell lysis is achieved. It may be necessary to increase the number of strokes (or syringe passes) if a large pellet of unbroken cells is obtained after homogenization (step 4.1.7). Researchers will likely need to determine the optimal amount of homogenization for the type of cell being fractionated. Removal of cellular debris following the homogenization must be thorough to avoid contamination of the organelle fraction with plasma membrane components (Figure 4B). If this occurs, additional low speed centrifugation steps should be performed to remove cellular debris. During development of this method up to 18 h of centrifugation at 18,000 × g was tested, with minimal increase of plasma membrane yield over the 3 h spins (Figure 2, lanes 5-6). Researchers may find it necessary to increase centrifugation times to obtain better yields of the plasma membrane sample.
The method presented here is limited in comparison to the more thorough purification methods involving ultracentrifugation. Without the use of isopycnic density centrifugation it is not possible to separate individual organelles obtained after cell homogenization. While the 4,000 × g fractions contain mitochondria (as evidenced by the presence of VDAC, Figure 2), they likely also contain ER, golgi and additional intracellular organelles. The organelle fraction should be verified by the use of additional antibodies to protein markers of other organelles if this is of importance to the research being performed.
The authors have nothing to disclose.
Work was supported by NIH-1R15HL135675-01 to Timothy J. LaRocca
Digitonin | TCI Chemicals | D0540 | For Cytoplasm Extraction |
D-Mannitol | Sigma-Aldrich | M4125 | For Lysis buffer B |
Dounce homogenizer | VWR | 22877-282 | For Homogenization |
end-over-end rotator | Barnstead | N/A | For Cytoplasm Extraction |
ethylene glycol-bis(β-aminoethyl ether)-N,N,N',N'-tetraacetic acid (EGTA) | Alfa Aesar | J61721 | For Lysis buffer B |
Ethylenediaminetetraacetic acid (EDTA) | Sigma-Aldrich | E7889 | For Lysis buffer B |
GAPDH (14C10) | Cell Signalling Technologies | 2118 | For detection of cytoplasmic fractions on western blot, dilution: 1:10000 |
HEPES | VWR | J848 | For Lysis buffers A and B |
KCl | Sigma-Aldrich | P9541 | For Lysis buffer B |
MgCl2 | Alfa Aesar | 12315 | For Lysis buffer B |
Na, K-ATPase a1 (D4Y7E) | Cell Signalling Technologies | 23565 | For detection of plasma membrane fractions on western blot, dilution: 1:1000 |
NaCl | Sigma-Aldrich | 793566 | For Lysis buffer A |
phenylmethanesulfonyl fluoride (PMSF) | VWR | M145 | For Cytoplasm Extraction and Homogenization Buffer |
probe sonicator | Qsonica | Q125-110 | For Final Samples |
Protease Inhibitor Cocktail, General Use | VWR | M221-1ML | For Cytoplasm Extraction |
refrigerated centrifuge | Beckman-Coulter | N/A | |
Sodium dodecyl sulfate (SDS) | VWR | 227 | For Sample buffer |
sodium orthovanadate (SOV) | Sigma-Aldrich | 450243 | For Lysis buffers A and B |
Sucrose | Sigma-Aldrich | S0389 | For Lysis buffer B |
Tris-buffered Saline (TBS) | VWR | 788 | For Sample buffer |
VDAC (D73D12) | Cell Signalling Technologies | 4661 | For detection of mitochondrial fractions on western blot, dilution: 1:1000 |