How to Create Your Own Affinity Titer Column Kelly J. Flook*, Yury Agroskin and Chris Pohl Thermo Fisher Scientific, Sunnyvale, CA, USA
Overview HPLC compatible streptavidin coated monolith column allows easy preparation of an affinity column specifically designed for your application. Narrow concentrated peaks are a result of fast convective mass transfer with minimal diffusion and allow titer analysis over a wide concentration range. Applicable to many applications from small scale protein to antibody titer analysis. Introduction Affinity Separations Affinity separations take advantage of the reversible interaction between a protein and a ligand to isolate a specific compound typically from a more complex matrix. The active protein or ligand can be easily coupled to beads and 96 well plates so that the reversible interactions can be employed to perform pull-down assays such as ELISA. This separation mechanism has also been translated to chromatographic media primarily for the use of small-scale purification. In this context, the media is typically low pressure (FPLC) compatible but the eluted peaks are not efficient enough for accurate titer analysis. The HPLC compatible affinity media available for titer analysis is limited mainly to the antibody market. Biotin-Streptavidin An alternative to the antibody-antigen interaction is the streptavidin-biotin interaction, which has been extensively studied and characterized. Protein biotinylation is a straight forward technique with a plethora of commercially available reagents for performing the conjugation. The extraordinary affinity of avidins for biotin is one the strongest known non-covalent interactions of a protein and ligand (Ka=10 15 M -1 ) and allows biotincontaining molecules in a complex mixture to be discretely bound with avidin conjugates. The bond formation between biotin and avidin is very rapid, and once formed, it is unaffected by extremes in ph, temperature, organic solvents and other denaturing agents. For these reasons, it is one of the most popular mechanisms used for designing protein assays using proprietary ligands. This presents a straightforward method for creating designer assays for QC. HPLC methods are already extensively used for sample QC throughout the chemical and pharmaceutical industry. Unfortunately, the limited availability of affinity HPLC media often leads to the need to redevelop analysis methods when transitioning from bench based assays to automated HPLC. Polymer Monoliths Leveraging the benefits of reactive polymeric monoliths, affinity media can be created with low non-specific binding and a pore structure that provides excellent elution kinetics. Efficient convective mass transfer and minimal diffusion allows for much narrower elution bands, resulting in more concentrated fractions and a higher level of sensitivity required for titer analysis at low sample concentrations. In addition, high binding capacity extends the range of quantification limiting the need for sample dilution. FIGURE 1. Scanning Electron Microscope image and corresponding mercury intrusion porosimetry 3 Incremental Intrusion Volume, ml/g 2 1 0 100 10 1 0.1 Pore Size, µm 0.01 0.001 2 How to Create Your Own Affinity Titer Column
Experimental Sample Preparation Proteins biotinylated using Thermo Scientific Pierce Biotinylation Kits P/N 21455; EZ-Link NHS-PEG4 Biotinylation Kit or alternative. Method Instrument Set Up Thermo Scientific Dionex UltiMate 3000 HPLC system including: Dual Gradient micropump with the vacuum degas Thermostatted Chromatography Compartment Variable Wavelength UV Detector Pulled Loop Autosampler with Fraction Collection Thermo Scientific Dionex Chromeleon Chromatography Data System software Monoclonal Antibody Analysis Column: Thermo Scientific ProSwift Streptavidin, 5 30 mm, Prototype Ligand: Biotinylated Protein A Flow rate: 0.5 ml/min Eluent A: 50 mm sodium phosphate, 200mM sodium chloride, ph 7.3 Eluent B: 50 mm sodium phosphate, 200mM sodium chloride, ph 2.5 Gradient: 0%B for 0.5 minutes, 100% B for 1 minutes, 0%B for 2 minutes Detection: 280 nm Temperature: 25 C Inj. volume: 20 µl Sample: IgG, various concentrations Column Specifications Effective column length 22 mm Monolith bed volume 450 µl Pore volume - ~ 60% Operational pressure at 1 ml/min ~ 800 psi Thermo Scientific Poster Note PN20956_HPLC_2014_E_05/14S 3
Results Ligand Preparation and Addition preparation of an sfer with minimal titer analysis. en a protein and a atrix. The active that the reversible SA. This edia primarily for low pressure curate titer s is limited mainly tin interaction, ation is a straight or performing the ongest known ws biotinavidin conjugates. ormed, it is denaturing sed for designing rd method for ely used for sample y, the limited analysis methods can be created nt elution kinetics. h narrower elution ensitivity required capacity extends Biotinylation of Proteins Biotinylation is the process of attaching biotin to proteins or other macromolecules. Biotinylation reagents are available for targeting specific functional groups or residues, including primary amines, sulfhydryls, carboxyls and carbohydrates. The variety of biotinylation reagents with different functional group specificities is extremely diverse, allowing one to choose a reagent that does not inactivate the target macromolecule. Besides functional group specificity, biotinylation reagents are available with different solubility characteristics to focus biotinylation to distinct microenvironments either inside or outside cells. Kits Biotinylated B In order to dire commercially a biotinylated BS until breakthro Figure 4 shows approximately injecting 100 µ streptavidin. Custom Titer Antibody Tite General Biotinylation Process The method used for biotinylation depends greatly on the ligand to be biotinylated. Generally the biotinylation reagent is added to a protein solution (1-10 mg/ml) in 5 to 20-fold excess. After incubation for approximately 1 hour at room temperature (longer on ice) the excess biotin is removed either by size exclusion, dialysis or precipitation of the biotin-protein from solution and decanting the supernatant containing the excess biotin. Removal of excess biotin is essential as this will block potential binding sites from the biotinylated protein. To a small degree, free biotin can displace the biotin conjugate from the substrate. FIGURE 2. Schematic of monolith bound streptavidin, conjugated with biotinylated Protein A, used for antibody analysis Captured Antibody Once the biotin it can now be u curve based on sample can be Early in the de of harvest cell chromatograph concentration a analysis. The c to develop a ro HPLC compati The column in ~0.53 mg/ml s column using p by UV and no maximum capa specific biotiny In this case, th addition of 200 As the analyte protein eluting An elution wind clean up and p Biotinylated Protein A Covalently bound streptavidin ng mercury 1 µm Measuring Co FIGURE 5. Are Hydrophilic monolith backbone 100 Loading the Column with Biotinylated Ligand 20 For loading studies, 50 100µL of biotinylated protein was loaded onto the column using the autosampler. 50 Area [mau*min] mau For large volume loading a length of PEEK tubing, (1 ml volume) across the 10-position valve in the column oven was filled manually with sample. After switching the valve the sample was loaded onto the column using the micropump. After switching the valve back to its original position the same pump was then used for analysis. 75 10 0. 25 FIGURE 3. Instrument schematic demonstrating configuration for manual column loading allowing fraction collection during both loading and analysis 0.01 0.001 4 How to Create Your Own Affinity Titer Column -10 0.0 0 Conclus
FIGURE 3. Instrument schematic demonstrating configuration for manual column loading allowing fraction collection during both loading and analysis FIGURE 4. Loading of Biotinylated BSA onto ProSwift Streptavidin Column. Loading conditions: 100 µl at 250 µl/min with 50 mm sodium phosphate, 150 mm NaCl, ph 7 4.5 Cumulative Binding Breakthrough 90 4.0 80 Total Amount Bound, mg 3.5 3.0 2.5 2.0 1.5 1.0 0.5 70 60 50 40 30 20 10 0 Break though Amount, % of Amount Injected 0.0 0 1 2 3 4 5 6 Cumulative Loading, mg -10 Thermo Scientific Poster Note PN20956_HPLC_2014_E_05/14S 5
Results Measuring Column Capacity Biotinylated BSA In order to directly compare the loading capacity of the streptavidin column to commercially available streptavidin beads the columns was load with small volumes of biotinylated BSA (Thermo Scientific Pierce P/N 29130) in phosphate buffered saline, ph 7 until breakthrough was observed. Figure 4 shows excellent binding efficiency with 100% of the injected sample bound until approximately 80% breakthrough occurred. 100% breakthrough area was obtained by injecting 100 µl biotinylated BSA through a blank monolith column with no bound streptavidin. Custom Titer Columns Antibody Titer using Biotinylated Protein A Once the biotinylated ligand, in this case biotinylated Protein A, is loaded onto the column it can now be used to capture and release the target analyte. By generating a calibration curve based on peak area of known standards, the concentration, or titer, of the unknown sample can be determined. Early in the development of recombinant monoclonal antibodies (MAbs), a large number of harvest cell culture (HCC) samples must be screened for IgG titer. Affinity chromatography employing a Protein A/G or L ligand is often used to determine the MAb concentration as well as to purify it for downstream aggregate and charge variant analysis. The challenge facing the analytical laboratories in the pharmaceutical industry is to develop a robust titer assay when the ligand needed is proprietary and there is no HPLC compatible solution. The column in figure 5 was loaded with ~3.5 4 mg of biotinylated Protein A from a ~0.53 mg/ml solution. 4 x 1 ml loops were manually loaded and injected onto the column using phosphate buffered saline. The absorbance of the effluent was monitored by UV and no break though was observed indicating the column was not loaded to maximum capacity. In order to block the remaining streptavidin sites, free biotin or a non specific biotinylated species such as BSA can be loaded until break through is observed. In this case, the antibody used does not interact with the surface streptavidin with the addition of 200 mm salt. As the analyte band does not experience diffusion driven mass transfer effects the protein eluting from a non porous surface does so with a extremely narrow peak width. An elution window of 0.2 minutes (12 seconds, 100 µl) allows very effective sample clean up and pre-concentration. FIGURE 5. Area Dependence on IgG Loading 100 20.0 MAb 75 R 2 = 0.9994 0.4 mg/ml solution mau 50 Area [mau*min] 10.0 25 0.0 0.0 2.0 4.0 6.0 8.0 10.0 12.0 14.0 Amount MAb, µg Unbound -10 0.0 0.5 1.0 1.5 2.0 2.5 3.0 3.5 4.0 4.5 5.0 6 How to Create Your Own Affinity Titer Column
Conclusion Preactivation of a polymeric monolithic surface with streptavidin provides an ideal support for secondary conjugation with biotinylated ligands Custom affinity columns can be made quickly and easily Automated HPLC methods can be developed to compliment bench top pull down analysis The ProSwift Streptavidin column can bind over 8 mg/ml bed biotin-bsa Efficient binding kinetics result in minimal loss of precious ligand Excellent elution characteristics allow concentrated peaks to be collected for further analysis. References 1. Thermo Scientific Avidin-Biotin Technical Handbook. www.thermofisher.com 2016 Thermo Fisher Scientific Inc. All rights reserved. All trademarks are the property of Thermo Fisher Scientific Inc. and its subsidiaries. This information is presented as an example of the capabilities of Thermo Fisher Scientific Inc. products. It is not intended to encourage use of these products in any manners that might infringe the intellectual property rights of others. Specifications, terms and pricing are subject to change. Not all products are available in all countries. Please consult your local sales representative for details. Africa +43 1 333 50 34 0 Australia +61 3 9757 4300 Austria +43 810 282 206 Belgium +32 53 73 42 41 Brazil +55 11 3731 5140 Canada +1 800 530 8447 China 800 810 5118 (free call domestic) 400 650 5118 Denmark +45 70 23 62 60 Europe-Other +43 1 333 50 34 0 Finland +358 9 3291 0200 France +33 1 60 92 48 00 Germany +49 6103 408 1014 India +91 22 6742 9494 Italy +39 02 950 591 Japan +81 6 6885 1213 Korea +82 2 3420 8600 Latin America +1 561 688 8700 Middle East +43 1 333 50 34 0 Netherlands +31 76 579 55 55 New Zealand +64 9 980 6700 Norway +46 8 556 468 00 Russia/CIS +43 1 333 50 34 0 Singapore +65 6289 1190 Sweden +46 8 556 468 00 Switzerland +41 61 716 77 00 Taiwan +886 2 8751 6655 UK/Ireland +44 1442 233555 USA +1 800 532 4752 PN20956_E 07/16S