Preparation and performance evaluation of metal chelating chromatography media based on agarose microspheres

doi:10.16085/j.issn.1000-6613.2023-1528

Abstract

Abstract:

Agarose gel microspheres were used to prepare a series of metal-chelating affinity chromatography media by chemically cross-linking the microspheres and ligand attachment. Subsequently, their adsorption properties in model proteins were examined. Firstly, the effects of different reaction conditions on microsphere size were explored. The results showed that under the optimal conditions, the particle size of agarose microspheres was concentrated in the range of 45—160μm, with a yield of 95% and an average particle size of 91.2μm. Then, the crosslinked agarose microspheres 4FF(4 Fast Flow) and 6FF(6 Fast Flow) were prepared from agarose microspheres 4B and 6B, and the cross-linking agent dropping method was regulated to explore the effects of different factors on the mechanical strength of the cross-linked agarose microsphere 4FF. The maximum flow rates of 4FF and 6FF could reach 1190cm/h and 2228cm/h, respectively. In addition, the recovery performance and morphological characterization of the prepared 4FF microspheres were tested, and the retention volumes of different standard proteins were determined with the help of size-exclusion chromatography and the effective distribution coefficients were calculated. Finally, dextran-grafted metal chelating affinity chromatography media were prepared by using cross-linked agarose microspheres 6FF as a matrix, and monoclonal antibody Ig G was used as a model protein to explore the effects of different conditions on the dynamic protein loading of the media. The results showed that the highest dynamic protein loading of the medium could reach 44.8mg/mL gel. The present work provides a new idea for the controllable preparation and modification of agarose microspheres, as well as their application in the separation and purification of biological proteins, and lays a foundation for the subsequent scaled-up production.

Key words: agarose microspheres, metal chelation, chromatographic packing, optimization, protein

摘要：

以琼脂糖凝胶微球为研究对象，通过对微球进行化学交联与配体连接，制备系列金属螯合亲和层析介质，并测试其在模型蛋白中的吸附性能。首先，探究不同工艺条件对微球尺寸的影响。结果表明，在最优条件下，琼脂糖微球粒径集中在45~160μm之间，收率为95%，平均粒径为91.2μm。随后，以琼脂糖微球4B和6B为原料制备交联琼脂糖微球4FF（4 Fast Flow）和6FF（6 Fast Flow），调控交联剂滴加方式，探究不同因素对4FF微球机械强度的影响，所得4FF和6FF的最大流速分别达1190cm/h和2228cm/h。此外，本工作对制备的4FF微球进行复原性能测试及形貌表征，借助凝胶色谱法测定不同标准蛋白的保留体积，并计算有效分配系数。最后，以交联琼脂糖微球6FF为基质，制备葡聚糖接枝型金属螯合亲和层析介质，以单克隆抗体Ig G为模型蛋白，探究不同条件对介质动态蛋白载量的影响。结果表明，介质的最高动态蛋白载量可达44.8mg/mL gel。本工作为琼脂糖微球的可控制备、改性，以及在生物蛋白分离纯化中的应用提供了新思路，也为后续扩大化生产奠定了基础。

关键词: 琼脂糖微球, 金属螯合, 层析填料, 优化, 蛋白质

CLC Number:

TQ033

ZENG Zeyang, XU Cai, JIN Zijie, WANG Xiaozhong, CHEN Yingqi, DAI Liyan. Preparation and performance evaluation of metal chelating chromatography media based on agarose microspheres[J]. Chemical Industry and Engineering Progress, 2024, 43(10): 5693-5703.

曾泽阳, 徐偲, 金子杰, 王晓钟, 陈英奇, 戴立言. 基于琼脂糖微球金属螯合层析介质的制备及性能评价[J]. 化工进展, 2024, 43(10): 5693-5703.

Figures/Tables 21

References 23

1	CRAMER Steven M, HOLSTEIN Melissa A. Downstream bioprocessing: Recent advances and future promise[J]. Current Opinion in Chemical Engineering, 2011, 1(1): 27-37.
2	BAKARR KANU A. Recent developments in sample preparation techniques combined with high-performance liquid chromatography: A critical review[J]. Journal of Chromatography A, 2021, 1654: 462444.
3	ZHAO Xi, HUANG Lan, WU Jie, et al. Fabrication of rigid and macroporous agarose microspheres by pre-cross-linking and surfactant micelles swelling method[J]. Colloids and Surfaces B: Biointerfaces, 2019, 182: 110377.
4	Stellan HJERTÉN. The preparation of agarose spheres for chromatography of molecules and particles[J]. Biochimica et Biophysica Acta (BBA): Specialized Section on Biophysical Subjects, 1964, 79(2): 393-398.
5	WANG Lianyan, MA Guanghui, SU Zhiguo. Preparation of uniform sized chitosan microspheres by membrane emulsification technique and application as a carrier of protein drug[J]. Journal of Controlled Release, 2005, 106(1/2): 62-75.
6	ZHOU Qingzhu, WANG Lianyan, MA Guanghui, et al. Preparation of uniform-sized agarose beads by microporous membrane emulsification technique[J]. Journal of Colloid and Interface Science, 2007, 311(1): 118-127.
7	BENGTSSON S, PHILIPSON L. Chromatography of animal viruses on pearl-condensed agar[J]. Biochimica et Biophysica Acta (BBA): Specialized Section on Biophysical Subjects, 1964, 79(2): 399-406.
8	CAPRETTO L, MAZZITELLI S, TOSI A, et al. Preparation of microspheres based on alginate/agarose blends by microfluidic technique[J]. Journal of Controlled Release, 2008, 132(3): e55-e56.
9	赵岚. 按需设计的琼脂糖层析介质——制备、表征和应用[D]. 北京: 中国科学院大学, 2012.
	ZHAO Lan. Design of agarose chromatography media on demand-preparation, characterization and application[D].Beijing: University of Chinese Academy of Sciences, 2012.
10	宋振阳. 交联琼脂糖的制备及作为胆红素吸附剂的研究[D]. 大连: 大连理工大学, 2012.
	SONG Zhenyang. Preparation of cross-linking agarose and investigation on its application to bilirubin adsorption[D]. Dalian: Dalian University of Technology, 2012.
11	ZHAO Xi, WU Jie, GONG Fangling, et al. Preparation of uniform and large sized agarose microspheres by an improved membrane emulsification technique[J]. Powder Technology, 2014, 253: 444-452.
12	PORATH Jerker, JANSON Jan-Christer, Torgny LÅÅS. Agar derivatives for chromatography, electrophoresis and gel-bound enzymes[J]. Journal of Chromatography A, 1971, 60: 167-177.
13	YU Linling, SHI Qinghong, SUN Yan. Effect of dextran layer on protein uptake to dextran-grafted adsorbents for ion-exchange and mixed-mode chromatography[J]. Journal of Separation Science, 2011, 34(21): 2950-2959.
14	ZHAO Lan, ZHANG Jingfei, HUANG Yongdong, et al. Efficient fabrication of high-capacity immobilized metal ion affinity chromatographic media: The role of the dextran-grafting process and its manipulation[J]. Journal of Separation Science, 2016, 39(6): 1130-1136.
15	SCOBLE Judith A, SCOPES Robert K. Assay for determining the number of reactive groups on gels used in affinity chromatography and its application to the optimisation of the epichlorohydrin and divinylsulfone activation reactions[J]. Journal of Chromatography A, 1996, 752(1/2): 67-76.
16	ZHAO Liangshen, LI Shasha, LIANG Chao, et al. High-strength and low-crystallinity cellulose/agarose composite microspheres: Fabrication, characterization and protein adsorption[J]. Biochemical Engineering Journal, 2021, 166: 107826.
17	BURTON Simon Christopher, HARDING David Roger Kay. Bifunctional etherification of a bead cellulose for ligand attachment with allyl bromide and allyl glycidyl ether[J]. Journal of Chromatography A, 1997, 775(1/2): 29-38.
18	STONE Melani C, CARTA Giorgio. Protein adsorption and transport in agarose and dextran-grafted agarose media for ion exchange chromatography[J]. Journal of Chromatography A, 2007, 1146(2): 202-215.
19	ZHAO Lan, ZHU Kai, HUANG Yongdong, et al. Front Cover: Enhanced binding by dextran-grafting to Protein A affinity chromatographic media[J]. Journal of Separation Science, 2017, 40(7): NA.
20	卢慧丽, 林东强, 姚善泾. 琼脂糖-DEAE离子交换介质的配基密度和孔径对BSA吸附的影响[J]. 化工学报, 2011, 62(11): 3164-3170.
	LU Huili, LIN Dongqiang, YAO Shanjing. Influences of ligand density and pore size on BSA adsorption on agarose-based DEAE-ion-exchange resins[J]. CIESC Journal, 2011, 62(11): 3164-3170.
21	ÖĞRETMEN Özen Yusuf, DUYAR Hünkar Avni. The effect of different extraction methods and pre-treatments on agar yield and physico-chemical properties of Gelidium latifolium (Gelidiaceae, Rhodophyta) from Sinop Peninsula Coast of Black Sea, Turkey[J]. Journal of Applied Phycology, 2018, 30(2): 1355-1360.
22	STONE Melani C, TAO Yinying, CARTA Giorgio. Protein adsorption and transport in agarose and dextran-grafted agarose media for ion exchange chromatography: Effect of ionic strength and protein characteristics[J]. Journal of Chromatography A, 2009, 1216(20): 4465-4474.
23	KIELKOPF Clara L, BAUER William, URBATSCH Ina L. Purification of polyhistidine-tagged proteins by immobilized metal affinity chromatography[J]. Cold Spring Harbor Protocols, 2020, 2020(6): 102194.

油相	水油比（质量比）	乳化剂种类	乳化剂用量（质量分数）/%	搅拌转速/r·min^-1	参考文献
液体石蜡和石油醚	1∶3.6	PO-500	4	1000	[3]
甲苯	1∶6	吐温60	4	1500	[4]
液体石蜡	1∶3	复合乳化剂	6~12	500~600	[9]
液体石蜡和石油醚	1∶4	复合乳化剂	4	800	[10]
液体石蜡和石油醚	1∶8	PO-500	4	1000	[11]

油相	水油比（质量比）	乳化剂种类	乳化剂用量（质量分数）/%	搅拌转速/r·min^-1	参考文献
液体石蜡和石油醚	1∶3.6	PO-500	4	1000	[3]
甲苯	1∶6	吐温60	4	1500	[4]
液体石蜡	1∶3	复合乳化剂	6~12	500~600	[9]
液体石蜡和石油醚	1∶4	复合乳化剂	4	800	[10]
液体石蜡和石油醚	1∶8	PO-500	4	1000	[11]

琼脂糖编号	外观	干燥失重/%	灰分/%	硫酸根/%	凝胶强度（1.0%）/g·cm^-2
GS001	白色粉末	≤10	≤0.5	≤0.3	≥1200
SL901	淡黄-白	<10	<1.0	<0.2	800~1000
SL91	淡黄-白	<10	<1.0	<0.2	800~1000
LP-900	淡黄-白	<10	<1.0	<0.2	800~1000
ML900	淡黄-白	<18	<1.0	<0.3	800~1000
M900	淡黄-白	<18	<1.5	<0.4	800~1000

琼脂糖编号	外观	干燥失重/%	灰分/%	硫酸根/%	凝胶强度（1.0%）/g·cm^-2
GS001	白色粉末	≤10	≤0.5	≤0.3	≥1200
SL901	淡黄-白	<10	<1.0	<0.2	800~1000
SL91	淡黄-白	<10	<1.0	<0.2	800~1000
LP-900	淡黄-白	<10	<1.0	<0.2	800~1000
ML900	淡黄-白	<18	<1.0	<0.3	800~1000
M900	淡黄-白	<18	<1.5	<0.4	800~1000

分子名称	4B/mL	K_av,4B	4FF/mL	K_av,4FF	6FF/mL	K_av,6FF
蓝葡聚糖2000	18.67	0	23.19	0	24.22	0
甲状腺球蛋白	42.87	0.558	42.34	0.540	38.15	0.370
γ球蛋白	52.00	0.769	49.44	0.740	48.40	0.642
牛血清白蛋白	52.16	0.773	50.01	0.756	49.73	0.678
核糖核酸酶 A	57.36	0.892	54.80	0.891	56.87	0.867
氯化钠	62.01	1	58.67	1	61.86	1