合成生物学自动化装置iBioFoundry的构建与应用

doi:10.12211/2096-8280.2023-027

摘要/Abstract

摘要：

合成生物学是一门关于设计、改造和重新合成生命的交叉融合性学科。它以工程化理念对生物体进行有目标的设计、改造，使其拥有满足人类需求的生物功能，甚至创造新的“人造生命”。由于生命体的高度复杂性，为达预定目标往往需要进行大量人工试错性实验，导致研究成本高、进展缓慢。随着自动化合成生物技术的不断发展，目前全球各地有多个合成生物自动化设施已建成或在建中。本文从建设背景、设计构建、科研项目运行和应用前景等方面对浙江大学杭州国际科创中心建设的合成生物学自动化装置iBioFoundry进行介绍，通过大肠杆菌工程菌的批量构建和酶的定向进化及筛选案例对实验自动化方案制定、实验流程程序编写和上机运行的过程做简要描述和分析，并就装置耗材存储空间的分配、多实验任务并行和实验流程标准化建设等装置建设过程的一些思考做经验分享。合成生物学自动化装置可以帮助研究人员大幅提高实验效率，装置产生的大量高质量数据结合信息技术，有望高通量、低成本、多循环地实现合成生物学研究中“设计-构建-测试-学习”的自动化运行，加速合成生物学在基础及诸多应用领域的研究效率。

关键词: 合成生物学, 生物铸造厂, 自动化平台, 标准化实验流程

Abstract:

Synthetic biology is an interdisciplinary field that focuses on designing, modifying, and synthesizing biosystems. It uses engineering principles to design and modify biosystems and even create novel "artificial life" to provide biological functions that meet human needs. Due to the high complexity of biosystems, extensive trial and error experiments are often required to gradually realize the desired engineering goals, resulting in high research costs and slow progress. With the continuous development of automated synthetic biology technology, multiple automated synthetic biology facilities have been established or are under construction worldwide. Biofoundry is an integrated automated scientific facility that combines the principles of intelligent manufacturing with the theoretical foundation of synthetic biology. It enables fast construction and testing of reprogrammed living organisms through the integration of intelligent and automated high-throughput devices. This article introduces the background, design, operation, and application aspects of iBioFoundry, an automated synthetic biology facility established at ZJU-Hangzhou Global Scientific and Technological Innovation Center. The iBioFoundry adopts a modular design concept and integrates various peripheral devices with three track-mounted robotic arms to build four functional modules: sample library, DNA assembly, cell screening and cultivation, and analysis. To meet the requirements of different research tasks and maximize the utilization of the device, iBioFoundry has a multi-task process management function, which is able to track and record all the process handling information of the entire experimental process and achieve traceability of all samples. Through a brief description and analysis of the high throughput construction of engineered E. coli strains and the enzyme directed evolution and screening, the article discusses the formulation of experimental automation schemes, programming of experimental processes, and on-machine operation. The article also shares some thoughts on the allocation of consumable storage space, parallel execution of multiple experimental tasks, and standardization of experimental processes. Automated synthetic biology facilities can help researchers significantly improve experimental efficiency. By combining the large amount of high-quality data generated by the facility with information technology, the automated "design-build-test-learn (DBTL)" engineering cycle in synthetic biology research can be achieved in a high-throughput, low-cost, and multi-cycle manner, accelerating the research efficiency of synthetic biology in both fundamental and many biotechnological application fields.

Key words: synthetic biology, biofoundry, automation platform, standardized experimental process

中图分类号:

Q819

卢挥, 张芳丽, 黄磊. 合成生物学自动化装置iBioFoundry的构建与应用[J]. 合成生物学, 2023, 4(5): 877-891.

Hui LU, Fangli ZHANG, Lei HUANG. Establishment of iBioFoundry for synthetic biology applications[J]. Synthetic Biology Journal, 2023, 4(5): 877-891.

图/表 7

参考文献 25

1	SISMOUR A M, BENNER S A. Synthetic biology[J]. Expert Opinion on Biological Therapy, 2005, 5(11): 1409-1414.
2	张先恩. 中国合成生物学发展回顾与展望[J]. 中国科学:生命科学, 2019, 49(12): 1543-1572.
	ZHANG X E. Synthetic biology in China: Review and prospects[J]. Scientia Sinica (Vitae), 2019, 49(12): 1543-1572.
3	赵国屏. 合成生物学: 开启生命科学 "会聚" 研究新时代[J]. 中国科学院院刊, 2018, 33(11)1135-1149
	ZHAO G P. Synthetic biology: unsealing the convergence era of life science research[J]. Bulletin of the Chinese Academy of Sciences, 2018, 33(11)1135-1149.
4	CAMERON D E, BASHOR C J, COLLINS J J. A brief history of synthetic biology[J]. Nature Reviews Microbiology, 2014, 12(5): 381-390.
5	KHALIL A S, COLLINS J J. Synthetic biology: applications come of age[J]. Nature Reviews Genetics, 2010, 11(5): 367-379.
6	MARTIN V J J, PITERA D J, WITHERS S T, et al. Engineering a mevalonate pathway in Escherichia coli for production of terpenoids[J]. Nature Biotechnology, 2003, 21(7): 796-802.
7	WIN M N, SMOLKE C D. Higher-order cellular information processing with synthetic RNA devices[J]. Science, 2008, 322(5900): 456-460.
8	PADDON C J, WESTFALL P J, PITERA D J, et al. High-level semi-synthetic production of the potent antimalarial artemisinin[J]. Nature, 2013, 496(7446): 528-532.
9	CHAO R, MISHRA S, SI T, et al. Engineering biological systems using automated biofoundries[J]. Metabolic Engineering, 2017, 42: 98-108.
10	唐婷, 付立豪, 郭二鹏, 等. 自动化合成生物技术与工程化设施平台[J]. 科学通报, 2021, 66(3): 300-309.
	TANG T, FU L H, GUO E P, et al. Automation in synthetic biology using biological foundries[J]. Chinese Science Bulletin, 2021, 66(3): 300-309.
11	LE FEUVRE R A, SCRUTTON N S. A living foundry for Synthetic Biological Materials: a synthetic biology roadmap to new advanced materials[J]. Synthetic and Systems Biotechnology, 2018, 3(2): 105-112.
12	KANG D H, KO S C, HEO Y B, et al. RoboMoClo: a robotics-assisted modular cloning framework for multiple gene assembly in biofoundry[J]. ACS Synthetic Biology, 2022, 11(3): 1336-1348.
13	SI T, CHAO R, MIN Y H, et al. Automated multiplex genome-scale engineering in yeast[J]. Nature Communications, 2017, 8: 15187.
14	CHAO R, LIANG J, TASAN I, et al. Fully automated one-step synthesis of single-transcript TALEN pairs using a biological foundry[J]. ACS Synthetic Biology, 2017, 6(4): 678-685.
15	STORCH M, HAINES M C, BALDWIN G S. DNA-BOT: a low-cost, automated DNA assembly platform for synthetic biology[J]. Synthetic Biology, 2020, 5(1): ysaa010.
16	崔金明, 张炳照, 马迎飞, 等. 合成生物学研究的工程化平台[J]. 中国科学院院刊, 2018, 33(11): 1249-1257.
	CUI J M, ZHANG B Z, MA Y F, et al. Engineering platforms for synthetic biology research[J]. Bulletin of the Chinese Academy of Sciences, 2018, 33(11): 1249-1257.
17	HILLSON N, CADDICK M, CAI Y Z, et al. Building a global alliance of biofoundries[J]. Nature Communications, 2019, 10: 2040.
18	晁然, 原永波, 赵惠民. 构建合成生物学制造厂[J]. 中国科学:生命科学, 2015, 45(10): 976-984.
	CHAO R, YUAN Y B, ZHAO H M. Building biological foundries for next generation synthetic biology[J]. Scientia Sinica (Vitae), 2015, 45(10): 976-984.
19	张亭, 冷梦甜, 金帆, 等. 合成生物研究重大科技基础设施概述[J]. 合成生物学, 2022(1): 184-194.
	ZHANG T, LENG M T, JIN F, et al. Overview on platform for synthetic biology research at Shenzhen[J]. Synthetic Biology Journal, 2022(1): 184-194.
20	ZHANG J Z, CHEN Y C, FU L H, et al. Accelerating strain engineering in biofuel research via build and test automation of synthetic biology[J]. Current Opinion in Biotechnology, 2021, 67: 88-98.
21	WU F, JIN S T, JIANG Y H, et al. Pre-training of equivariant graph matching networks with conformation flexibility for drug binding[J]. Advanced Science, 2022, 9(33): 2203796.
22	WANG J, ZHANG X Q, CHENG L X, et al. An overview and metanalysis of machine and deep learning-based CRISPR gRNA design tools[J]. RNA Biology, 2020, 17(1): 13-22.
23	CARBONELL P, RADIVOJEVIC T, GARCÍA MARTÍN H. Opportunities at the intersection of synthetic biology, machine learning, and automation[J]. ACS Synthetic Biology, 2019, 8(7): 1474-1477.
24	ZHANG J, HANSEN L G, GUDICH O, et al. A microbial supply chain for production of the anti-cancer drug vinblastine[J]. Nature, 2022, 609(7926): 341-347.
25	CAI T, SUN H B, QIAO J, et al. Cell-free chemoenzymatic starch synthesis from carbon dioxide[J]. Science, 2021, 373(6562): 1523-1527.

编号	子任务名称	实验步骤	需编程的设备	程序名称
1	PCR反应	PCR反应体系配置	移液工作站	Pre_Target_PCR
		封膜
		离心
		PCR扩增	自动化PCR仪	Target_PCR
2	产物纯化	撕膜
		磁珠纯化	移液工作站	PCR_Product_Purification
3	核酸片段分析	核酸片段检测体系配置	移液工作站	Pre_Fragment_Analysis
		核酸片段分析	自动化核酸片段分析仪	Fragment_Analysis_50 to 6000 bp
4	DNA组装	样品筛选及试剂分装	移液工作站	Sample_Selection
		DNA组装反应体系配制	纳升级移液工作站	Pre_DNA_Assembly
		封膜
		离心
		DNA组装反应	自动化PCR仪	DNA_Assembly
5	质粒转化	撕膜
		质粒转化体系配置	移液工作站	Pre_Plasmid_Transforming
		封膜
		热激	自动化PCR仪	Plasmid_Transforming
		孵育
6	菌液涂布培养	8孔矩形培养板涂布	移液工作站	Dilution_Plating
		平板静置培养
7	克隆挑选与培养	培养基分装
		克隆挑选	移液工作站	Clone_Picking
		封膜
		菌液振荡培养
8	菌落鉴定	荧光定量PCR反应体系配置	移液工作站	Pre_Clone_Verification
		封膜
		离心
		荧光定量PCR检测	荧光定量PCR仪	Clone_Verification
9	菌株保存	开盖
		菌株挑选与保存	移液工作站	Positive_Sample_Selection
		关盖
		样本存储

编号	子任务名称	实验步骤	需编程的设备	程序名称
1	PCR反应	PCR反应体系配置	移液工作站	Pre_Target_PCR
		封膜
		离心
		PCR扩增	自动化PCR仪	Target_PCR
2	产物纯化	撕膜
		磁珠纯化	移液工作站	PCR_Product_Purification
3	核酸片段分析	核酸片段检测体系配置	移液工作站	Pre_Fragment_Analysis
		核酸片段分析	自动化核酸片段分析仪	Fragment_Analysis_50 to 6000 bp
4	DNA组装	样品筛选及试剂分装	移液工作站	Sample_Selection
		DNA组装反应体系配制	纳升级移液工作站	Pre_DNA_Assembly
		封膜
		离心
		DNA组装反应	自动化PCR仪	DNA_Assembly
5	质粒转化	撕膜
		质粒转化体系配置	移液工作站	Pre_Plasmid_Transforming
		封膜
		热激	自动化PCR仪	Plasmid_Transforming
		孵育
6	菌液涂布培养	8孔矩形培养板涂布	移液工作站	Dilution_Plating
		平板静置培养
7	克隆挑选与培养	培养基分装
		克隆挑选	移液工作站	Clone_Picking
		封膜
		菌液振荡培养
8	菌落鉴定	荧光定量PCR反应体系配置	移液工作站	Pre_Clone_Verification
		封膜
		离心
		荧光定量PCR检测	荧光定量PCR仪	Clone_Verification
9	菌株保存	开盖
		菌株挑选与保存	移液工作站	Positive_Sample_Selection
		关盖
		样本存储

类型	名称	数量	起始位置	结束位置
试剂	引物	2块	自动化低温冰箱1-[1-2]	6列耗材存储设备2-[1-2]
	DNA模板	1块	自动化低温冰箱1-[3]	6列耗材存储设备2-[3]
	大肠杆菌感受态细胞	1块	自动化低温冰箱1-[4]	耗材回收桶
	PCR反应试剂	1块	自动化低温冰箱1-[5]	自动化低温冰箱1-[5]
	DNA组装试剂	1块	自动化低温冰箱1-[6]	自动化低温冰箱1-[6]
	qPCR检测试剂	1块	自动化低温冰箱1-[7]	自动化低温冰箱1-[7]
耗材	50 μL黑色吸头	2盒	24列耗材存储设备1-[1-2]	耗材回收桶
	200 μL黑色吸头	7盒	24列耗材存储设备2-[1-7]	耗材回收桶
	50 μL透明吸头	4盒	24列耗材存储设备1-[3-6]	耗材回收桶
	200 μL透明吸头	3盒	24列耗材存储设备3-[1-3]	耗材回收桶
	8孔矩形培养板	12块	10列耗材存储设备1-[1-12]	自动化低温冰箱2-[1-12]
	96孔微孔板	4块	24列耗材存储设备4-[1-4]	自动化低温冰箱1-[8-11]
	96孔深孔板	8块	10列耗材存储设备2-[1-8]	10列耗材存储设备2-[1-8]
	96位样本架	3块	6列耗材存储设备1-[1-3]	Arktic冰箱
	384孔微孔板	4块	24列耗材存储设备4-[5-8]	6列耗材存储设备2-[4-7]

类型	名称	数量	起始位置	结束位置
试剂	引物	2块	自动化低温冰箱1-[1-2]	6列耗材存储设备2-[1-2]
	DNA模板	1块	自动化低温冰箱1-[3]	6列耗材存储设备2-[3]
	大肠杆菌感受态细胞	1块	自动化低温冰箱1-[4]	耗材回收桶
	PCR反应试剂	1块	自动化低温冰箱1-[5]	自动化低温冰箱1-[5]
	DNA组装试剂	1块	自动化低温冰箱1-[6]	自动化低温冰箱1-[6]
	qPCR检测试剂	1块	自动化低温冰箱1-[7]	自动化低温冰箱1-[7]
耗材	50 μL黑色吸头	2盒	24列耗材存储设备1-[1-2]	耗材回收桶
	200 μL黑色吸头	7盒	24列耗材存储设备2-[1-7]	耗材回收桶
	50 μL透明吸头	4盒	24列耗材存储设备1-[3-6]	耗材回收桶
	200 μL透明吸头	3盒	24列耗材存储设备3-[1-3]	耗材回收桶
	8孔矩形培养板	12块	10列耗材存储设备1-[1-12]	自动化低温冰箱2-[1-12]
	96孔微孔板	4块	24列耗材存储设备4-[1-4]	自动化低温冰箱1-[8-11]
	96孔深孔板	8块	10列耗材存储设备2-[1-8]	10列耗材存储设备2-[1-8]
	96位样本架	3块	6列耗材存储设备1-[1-3]	Arktic冰箱
	384孔微孔板	4块	24列耗材存储设备4-[5-8]	6列耗材存储设备2-[4-7]

存储设备	设备内载架类型（高度）	列数	板位数/列	功能
24列耗材存储设备	高位载架（69 mm）	10列	7 plates	可存放70盒SBS规格吸头盒
	中位载架（50 mm）	8列	10 plates	可存放80块SBS规格深孔板
	低位载架（23 mm）	6列	21 plates	可存放126块SBS规格微孔板
10列耗材存储设备	超高位载架（128 mm）	2列	4 plates	可存放8盒SBS规格吸头盒
	中位载架（50 mm）	5列	10 plates	可存放50块SBS规格深孔板
	低位载架（23 mm）	3列	21 plates	可存放63块SBS规格微孔板
6列耗材存储设备	高位载架（69 mm）	2列	8 plates	可存放16块SBS规格深孔板
6列耗材存储设备	低位载架（31 mm）	4列	15 plates	可存放60块SBS规格微孔板