High-throughput screening methods for protein adsorption evaluation with microtiter filter plate

doi:10.11949/j.issn.0438-1157.20161789

Abstract

Abstract:

Aiming at the process optimization of chromatographic separation, the high-throughput screening methods of protein adsorption with microtiter filter plate were established for initial resin screening, adsorption properties evaluation, adsorption isotherms and adsorption kinetics measurement, and adsorption and elution conditions optimization. Firstly, the operation parameters of 96-well filter plate were optimized, and with two ion exchangers and two mixed-mode resins as the model, the bovine serum albumin adsorption was investigated with different resins and liquid conditions by means of microtiter filer plate. The binding capacity maps were obtained and the appropriate adsorption-desorption conditions were determined. Further, the microtiter filter plate was applied to measure the adsorption isotherms and adsorption kinetics with four resins at specific adsorption conditions, and the adsorption parameters were obtained. Finally, the elution conditions were optimized using microtiter filter plate. The microscale results were comparable to that with packed-bed separation, indicating that the methods developed in the present work were practicable. The results demonstrated that the high-throughput process development of protein adsorption with microtiter filer plate was feasible and can be used to fast screen the best reins and liquid conditions. New methods showed the advantages of low resource consumption, large experimental fluxes, short developing period, wide application and high stability, which would be one new method for development of the protein separation process.

Key words: high-throughput screening , microtiter filer plate, chromatography, adsorption, protein separation

摘要：

针对色谱分离过程优化，建立了基于微孔过滤板的蛋白吸附高通量筛选方法，用于介质初筛、吸附性能考察、吸附等温线和吸附动力学测定、吸附和洗脱条件优化等。首先优化了96孔过滤板的操作参数，以2种离子交换介质和2种混合模式介质为典型代表，采用微孔过滤板方法考察了不同介质和液相条件下牛血清白蛋白的吸附，得到结合载量分布图，确定了合适的蛋白吸附和解吸条件。进一步测定了4种介质在特定吸附条件下的吸附等温线和吸附动力学曲线，获得吸附相关参数。最后，采用微孔过滤板进行了洗脱条件优化，并与填充柱色谱分离进行比较，验证了方法的可靠性。结果表明，基于微孔过滤板的蛋白吸附高通量筛选是切实可行的，可以快速筛选色谱介质和液相，优化蛋白分离条件，具有资源消耗小、实验通量大、研发周期短、适用性广、稳定性高的特点，是蛋白色谱分离过程优化的一种新方法。

关键词: 高通量筛选, 微孔过滤板, 色谱分离, 吸附, 蛋白分离

CLC Number:

TQ028.8

CHU Wenning, LIN Dongqiang, YAO Shanjing. High-throughput screening methods for protein adsorption evaluation with microtiter filter plate[J]. CIESC Journal, 2017, 68(6): 2399-2406.

褚文宁, 林东强, 姚善泾. 基于微孔过滤板的蛋白吸附高通量筛选方法[J]. 化工学报, 2017, 68(6): 2399-2406.

References 30

[1]	COGDILL R P, DRENNEN J K. Risk-based Quality by Design (QbD): a Taguchi perspective on the assessment of product quality, and the quantitative linkage of drug product parameters and clinical performance[J]. Journal of Pharmaceutical Innovation, 2008, 3(1): 23-29.
[2]	SANAIE N, CECCHINI D, PIERACCI J. Applying high-throughput methods to develop a purification process for a highly glycosylated protein[J]. Biotechnology Journal, 2012, 7(10): 1242-1255.
[3]	HEALTH C, KISS R. Cell culture process development: advances in process engineering[J]. Biotechnology Progress, 2007, 23(1): 46-51.
[4]	何玉财, 周琼, 林春昕, 等. 一种腈水解酶的高通量筛选方法[J]. 高校化学工程学报, 2012, 26(5): 853-857.
	HE Y C, ZHOU Q, LIN C X, et al. One high-throughput screening strategy for nitrile-hydrolyzing enzymes[J]. Journal of Chemical Engineering of Chinese Universities, 2012, 26(5): 853-857.
[5]	ZHU Q, FAN A, WANG Y S, et al. Novel sensitive high-throughput screening strategy for nitrilase-producing strains[J]. Applied and Environmental Microbiology, 2007, 73(19): 6053-6057.
[6]	DANIELS C, RODRIGUEZ J, LIM E, et al. An integrated robotic system for high-throughput process development of cell and virus culture conditions: application to biosafety level 2 live virus vaccines[J]. Engineering in Life Sciences, 2016, 16(2): 202-209.
[7]	STROBEL R. High throughput cultivation of animal cells using shaken microplate techniques[M]//BOWDEN D, BRACEY M. Animal Cell Technology: From Target to Market. Netherlands: Springer, 2001: 307-312.
[8]	李晓璐, 范里, 赵亮, 等. 基于单纯型设计和部件搜索方法的CHO细胞无血清培养基的高通量优化[J]. 高校化学工程学报, 2014, 28(4): 777-783.
	LI X L, FAN L, ZHAO L, et al. High through-put screening and optimization of serum-free media development for CHO Cells using simplex lattice and elements dialogue design methods[J]. Journal of Chemical Engineering of Chinese Universities, 2014, 28(4): 777-783.
[9]	WIENDAHAL M, OELMEIRE S A, DIEMER F, et al. High-throughput screening-based selection and scale-up of aqueous two-phase systems for pDNA purification[J]. Journal of Separation Science, 2012, 35(22): 3197-3207.
[10]	COFFMAN J L, CABANNE C, KELLEY B D. High-throughput screening of chromatographic separations (Ⅰ): Method development and column modeling[J]. Biotechnology and Bioengineering, 2008, 100(4): 605-618.
[11]	WELSH J P, PETROFF M G, ROWICKI P, et al. A practical strategy for using miniature chromatography columns in a standardized high-throughput workflow for purification development of monoclonal antibodies[J]. Biotechnology Progress, 2014, 30(3): 626-635.
[12]	TREIER K, HANSEN S, RICHTER C, et al. High-throughput methods for miniaturization and automation of monoclonal antibody purification processes[J]. Biotechnology Progress, 2012, 28(3): 723-732.
[13]	DIEDERICH P, HOFFMANN M, HUBBUCH J. High-throughput process development of purification alternatives for the protein avidin[J]. Biotechnology Progress, 2015, 31(4): 957-973.
[14]	LACKI K M. High-throughput process development of chromatography steps: advantages and limitations of different formats used[J]. Biotechnology Journal, 2012, 7(10): 1192-1202.
[15]	REGE K, PEPSIN M, FALCON B, et al. High-throughput process development for recombinant protein purification[J]. Biotechnology and Bioengineering, 2006, 93(4): 618-630.
[16]	NFOR B K, NOVERRAZ M, CHIAMKURTHI S. High-throughput isotherm determination and thermodynamic modeling of protein adsorption on mixed mode adsorbents[J]. Journal of Chromatography A, 2010, 1217(44): 6829-6850.
[17]	BERGANDER T, NILSSON-VAELIMAA K, OBERG K, et al. High-throughput process development: determination of dynamic binding capacity using microtiter filter plates filled with chromatography resin[J]. Biotechnoly Progress, 2008, 24(3): 632-639.
[18]	CHHRTRE S, TITCHERNER-HOOKER N J. Review: microscale methods for high-throughput chromatography development in the pharmaceutical industry[J]. Journal of Chemical Technology & Biotechnology, 2009, 84(7):927-940.
[19]	姚善泾, 高栋, 林东强. 一种新的生物分离方法——混合模式吸附层析[J]. 化工学报, 2007, 58(9): 2169-2177.
	YAO S J, GAO D, LIN D Q. Novel technology in bioseparation process—mixed-mode chromatography[J]. Journal of Chemical Industry and Engineering (China), 2007, 58(9): 2169-2177.
[20]	庄甜甜, 夏海峰, 林东强, 等. 混合模式吸附层析从猪血浆中分离免疫球蛋白研究[J]. 化工学报, 2010, 61(2): 336-341.
	ZHUANG T T, XIA H F, LIN D Q, et al. Separation of immunoglobulin from porcine plasma with mixed-mode adsorption chromatography[J]. CIESC Journal, 2010, 61(2): 336-341.
[21]	陈振明, 林东强, 姚善泾. 新型混合模式层析介质制备及用于牛初乳免疫球蛋白分离[J]. 化工学报, 2012, 63(8): 2453-2459.
	CHEN Z M, LIN D Q, YAO S J. New mixed-mode absorbent and its application for search of bovine colostrum immunoglobulin[J]. CIESC Journal, 2012, 63(8): 2453-2459.
[22]	童红飞, 林东强, 姚善泾. 疏水性电荷诱导层析纯化免疫球蛋白IgY[J]. 化工学报, 2011, 62(6): 1574-1580.
	TONG H F, LIN D Q, YAO S J. Separation and purification of immunoglobulin IgY with hydrophobic charge induction chromatography[J]. CIESC Journal, 2011, 62(6): 1574-1580.
[23]	李菁, 林东强, 童红飞, 等. 疏水性电荷诱导层析分离抗HER2单克隆抗体研究[J]. 化工学报, 2014, 65(10): 3931-3937.
	LI J, LIN D Q, TONG H F, et al. Separation and purification of anti-HER2 monoclonal antibody with hydrophobic charge-induction chromatography[J]. CIESC Journal, 2014, 65(10): 3931-3937.
[24]	ZHANG Q L, ZHUANG T T, TONG H F, et al. Experimental and in silico studies on three hydrophobic charge-induction adsorbents for porcine immunoglobulin purification[J]. Chinese Journal of Chemical Engineering, 2016, 24(1): 151-157.
[25]	ZHAO G, DONG X Y, SUN Y. Ligands for mixed-mode protein chromatography: principles, characteristics and design[J]. Journal of Biotechnology, 2009, 144(1): 3-11.
[26]	YANG Y, GENG X. Mixed-mode chromatography and its applications to biopolymers[J]. Journal of Chromatography A, 2011, 1218(49): 8813-8825.
[27]	LIN F Y, CHEN C S, CHEN W Y, et al. Microcalorimetric studies of the interaction mechanisms between proteins and Q-Sepharose at pH near the isoelectric point (pI)—effects of NaCl concentration, pH value, and temperature[J]. Journal of Chromatography A, 2001, 912(2): 281-289.
[28]	LIU N, YU L L, SUN Y. Protein adsorption to poly(ethylenimine)-modified Sepharose FF (Ⅳ): Dynamic adsorption and elution behaviors[J]. Journal of Chromatography A, 2014, 1362: 218-224.
[29]	YANG K. Dynamic binary protein adsorption in ion-exchange media depicted with a parallel diffusion model derived from Maxwell-Stefan theory[J]. Chemical Engineering Science, 2016, 139: 163-172.
[30]	YANG K, SHI Q H, SUN Y. Modeling and simulation of protein uptake in cation exchanger visualized by confocal laser scanning microscopy[J]. Journal of Chromatography A, 2006, 1136(1): 19-28.

Related Articles 15

[1]	Yan GAO, Peng WU, Chao SHANG, Zejun HU, Xiaodong CHEN. Preparation of magnetic agarose microspheres based on a two-fluid nozzle and their protein adsorption properties [J]. CIESC Journal, 2023, 74(8): 3457-3471.
[2]	Bingchun SHENG, Jianguo YU, Sen LIN. Study on lithium resource separation from underground brine with high concentration of sodium by aluminum-based lithium adsorbent [J]. CIESC Journal, 2023, 74(8): 3375-3385.
[3]	Ruihang ZHANG, Pan CAO, Feng YANG, Kun LI, Peng XIAO, Chun DENG, Bei LIU, Changyu SUN, Guangjin CHEN. Analysis of key parameters affecting product purity of natural gas ethane recovery process via ZIF-8 nanofluid [J]. CIESC Journal, 2023, 74(8): 3386-3393.
[4]	Ji CHEN, Ze HONG, Zhao LEI, Qiang LING, Zhigang ZHAO, Chenhui PENG, Ping CUI. Study on coke dissolution loss reaction and its mechanism based on molecular dynamics simulations [J]. CIESC Journal, 2023, 74(7): 2935-2946.
[5]	Jie WANG, Xiaolin QIU, Ye ZHAO, Xinyang LIU, Zhongqiang HAN, Yong XU, Wenhan JIANG. Preparation and properties of polyelectrolyte electrostatic deposition modified PHBV antioxidant films [J]. CIESC Journal, 2023, 74(7): 3068-3078.
[6]	Shaoyun CHEN, Dong XU, Long CHEN, Yu ZHANG, Yuanfang ZHANG, Qingliang YOU, Chenglong HU, Jian CHEN. Preparation and adsorption properties of monolayer polyaniline microsphere arrays [J]. CIESC Journal, 2023, 74(5): 2228-2238.
[7]	Caihong LIN, Li WANG, Yu WU, Peng LIU, Jiangfeng YANG, Jinping LI. Effect of alkali cations in zeolites on adsorption and separation of CO₂/N₂O [J]. CIESC Journal, 2023, 74(5): 2013-2021.
[8]	Chenxin LI, Yanqiu PAN, Liu HE, Yabin NIU, Lu YU. Carbon membrane model based on carbon microcrystal structure and its gas separation simulation [J]. CIESC Journal, 2023, 74(5): 2057-2066.
[9]	Xuanjun WU, Chao WANG, Zijian CAO, Weiquan CAI. Deep learning model of fixed bed adsorption breakthrough curve hybrid-driven by data and physical information [J]. CIESC Journal, 2023, 74(3): 1145-1160.
[10]	Yu PAN, Zihang WANG, Jiayun WANG, Ruzhu WANG, Hua ZHANG. Heat and moisture performance study of Cur-LiCl coated heat exchanger [J]. CIESC Journal, 2023, 74(3): 1352-1359.
[11]	Jiahao JIANG, Xiaole HUANG, Jiyun REN, Zhengrong ZHU, Lei DENG, Defu CHE. Qualitative and quantitative study on Pb²⁺ adsorption by biochar in solution [J]. CIESC Journal, 2023, 74(2): 830-842.
[12]	Xiaowan PENG, Xiaonan GUO, Chun DENG, Bei LIU, Changyu SUN, Guangjin CHEN. Modeling and simulation of CH₄/N₂ separation process with two absorption-adsorption columns using ZIF-8 slurry [J]. CIESC Journal, 2023, 74(2): 784-795.
[13]	Jinlin MENG, Yu WANG, Qunfeng ZHANG, Guanghua YE, Xinggui ZHOU. Pore network model of low-temperature nitrogen adsorption-desorption in mesoporous materials [J]. CIESC Journal, 2023, 74(2): 893-903.
[14]	Wan XU, Zhenbin CHEN, Huijuan ZHANG, Fangfang NIU, Ting HUO, Xingsheng LIU. Study on synthesis, adsorption and desorption performance of linear temperature-sensitive segment polymer regulated intelligent $R e O 4 -$ ion-imprinted polymer [J]. CIESC Journal, 2023, 74(2): 941-952.
[15]	Xun JIAO, Cheng TONG, Cunpu LI, Zidong WEI. Kinetic regulation strategies in lithium-sulfur batteries [J]. CIESC Journal, 2023, 74(1): 170-191.