ion exchange chromatography
ion exchange chromatography
Ion exchange chromatography is a chromatographic method in which ion exchange genes (CM, SP, Q, DEAE, etc.) are bonded to certain inert carriers (cellulose, crosslinked dextran, crosslinked agarose, etc.), which are used as stationary phases, and the samples are separated according to the degree of interaction with the ion exchange groups on the stationary phases based on the differences in the charges they carry. Ion exchange chromatography has been widely used for the purification of proteins, peptides, oligonucleotides, viruses, phages, polysaccharides, and so on.
Operation method
ion exchange chromatography
Principle
Ion exchange chromatography is a chromatographic method in which ion exchange genes (CM, SP, Q, DEAE, etc.) are bonded to certain inert carriers (cellulose, crosslinked dextran, crosslinked agarose, etc.), which are used as stationary phases, and the samples are separated according to the degree of interaction with the ion exchange groups on the stationary phases based on the differences in the charges they carry. Ion exchange chromatography has been widely used for the purification of proteins, peptides, oligonucleotides, viruses, phages, polysaccharides, and so on. The ion exchanger is bonded to some ion exchange groups on the carrier, and the ion exchange groups release free ions through ionization in aqueous solution, which can be positively or negatively charged, and can be replaced by other ions with the same charge in the solution and have a strong binding force to the ion exchanger. The magnitude of the binding force is affected not only by the force between the ion and the ion exchanger, but also mainly by the ion concentration, the force in this process is electrostatic attraction, and the principle of ion exchange is electrostatic interaction. The retention time of proteins on ion exchange chromatography depends on the amount of electrostatic charge carried by proteins under the corresponding chromatographic conditions, and the amount of electrostatic charge carried by proteins is determined by the pI of the protein molecule and the pH of the solution environment in which it is located. Under acidic conditions, proteins are positively charged; under alkaline conditions, proteins are negatively charged. On the cation exchange column, only the proteins with pI greater than the pH of the mobile phase are retained on the column, while the proteins with pI less than or equal to the pH of the mobile phase are not retained, and even if their pI values differ from each other, they are all flushed out as solvent peaks at the same time directly. The order of the retained proteins is that those with small pI peak first and those with large pI peak later. The opposite is true for anion-exchange columns. The process of ion exchange chromatography is divided into four stages: equilibrium-adsorption-desorption-regeneration, in which adsorption and desorption are the main stages, and Q-Sepharose FF and SP-Sepharose FF, which are applied in the process of purifying TNF, are used as examples.
Materials and Instruments
TNF Move I. Preparation of reagents Common Problems I. Selection of ion exchangers 1. Selection of formulations For more product details, please visit Aladdin Scientific website.
Tris-HCl EDTA PB buffer Ammonium sulfate Dialysis solution Sodium chloride
Dialysis Bags Centrifuge Centrifuge Tubes Pipette Guns Tips Anion Exchange Matrix Q-Sepharose FF Protein Detector Cation Columns SP-Sepharose FF Test Tubes
1. Prepare pH 8.5 20 mmol/L Tris-HCl solution containing 1 mmol/L EDTA (or its reserve solution, just dilute it at the time of use) for use after filtration.
2. Prepare PB buffer pH 7.5 20 mmol/L, filter and use.II. Operational steps
1. Pre-treatment of samples
2. Equilibration of samples
The supernatant obtained by precipitation and centrifugation of 50% saturated ammonium sulfate in experiment I was placed in a dialysis bag in 20-40 times volume of buffer pH 8.5 20 mmol/L Tris-HCl, 1 mmol/L EDTA, stirred and dialyzed at 4°C for 24 h, with dialysate changed 3-4 times in the middle, and then centrifuged at 12 000 rpm at 4°C for 15 min, and the supernatant was collected to determine the protein concentration, and the volume was recorded.
3. Equilibration and sampling on anionic column Q-Sepharose FF
The column was loaded with anion-exchange matrix Q-Sepharose FF with a column volume of 5.4×20 cm and equilibrated with pH 8.5 20 mmol/L Tris-HCl 1 mmol/L EDTA buffer flow-washing the chromatographic column, and adjusted the range of the protein detector and the sensitivity of the recorder. The collected supernatant was upsampled at a flow rate of 8 ml/min. Equilibrate the slow liquid rinse until the effluent absorbance value returns to baseline. Collect across the peaks, measure the volume and measure the protein content.
4. Elution
Elution solution A was pH 8.5 20 mmol/L Tris-HCl, 1 mmol/L EDTA buffer, and elution solution B was a linear gradient elution of solution A containing a final concentration of 1 mol/L NaCl (according to the purification process set by the purification conditions), and the volume of the amount of each elution peak was collected, and the concentration of the proteins was measured, and the peaks where TNF was located were subjected to SDS-PAGE or to activity identification.
5. The active peak was dialyzed with pH 7.5 20 mmol/L PB for 24 h with 3 intermediate changes. Centrifugation was performed and the supernatant was taken and volume measured for protein concentration.
6. Equilibration and sampling on cationic column SP-Sepharose FF
Take the cation exchange matrix SP-Sepharose FF loaded column, column volume 2.5 × 10 cm, wash the equilibrium chromatography column with pH 7.5 20 mmol/L PB buffer flow, adjust the range of the protein detector and the sensitivity of the recorder, the peak solution of TNF after dialysis and centrifugation was up-sampled at the flow rate of 4 ml/min, washed with equilibrium solution to the baseline, collected across the peaks, measured volume , and measure the protein concentration.
7. Elution
The cation chromatography column SP-Sepharose FF was subjected to a linear gradient elution with eluent A of pH 7.5 20 mmol/L PB and eluent B of solution A containing 1 mol/L NaCl, and the elution peaks were collected, the volume was measured, and the protein concentration was measured and subjected to SDS-PAGE or activity identification.
8. Post-processing
The purity and activity of TNF are identified, and TNF products with certain potency are made by freeze-drying with excipients according to the requirements.
