Synthetic Biology Journal ›› 2025, Vol. 6 ›› Issue (3): 493-496.DOI: 10.12211/2096-8280.2025-063
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Received:2025-06-18Revised:2025-06-19Online:2025-06-27Published:2025-06-30
定量合成生物学:合成生物系统的理性设计之路
林一瀚1, 傅雄飞2, 刘陈立2, 欧阳颀3
- 1.北京大学定量生物学中心,北京大学-清华大学生命科学联合中心,北京大学前沿学科交叉研究院,北京 100871
2.中国科学院深圳先进技术研究院,定量合成生物学全国重点实验室,深圳合成生物学创新研究院,广东 深圳 518055
3.浙江大学物理学院,浙江 杭州 310027
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作者简介:林一瀚,北京大学定量生物学中心教授,北京大学-清华大学生命科学联合中心研究员。研究方向为定量系统生物学、合成生物学。
傅雄飞,研究员,博士生导师,中国科学院深圳先进技术研究院合成生物学研究所所长,定量合成生物学全国重点实验室副主任,深圳合成生物创新研究院副院长,深圳合成生物学协会会长。主要从事合成生物学、定量生物学、统计物理与复杂系统等多个交叉学科领域,聚焦随机涨落在细菌单细胞与多细胞有序空间结构形成过程中的作用,通过定量理论与合成重构结合,揭示跨尺度涌现性原理。
刘陈立,研究员,博士生导师,中国科学院深圳先进技术研究院院长,定量合成生物学全国重点实验室主任,国家生物制造产业创新中心主任。担任《合成生物学》执行主编,亚洲合成生物学协会联席主席。主持基金委基础科学中心B类、中国科学院战略科技先导专项B类、国家重点研发计划等科技任务。曾获谈家桢生命科学创新奖、中国科学院青年科学家奖、广东省自然科学一等奖等奖项。主要从事合成生物学研究,聚焦合成生物系统的理性设计原理等重要科学问题开展工作,特别是探索单细胞生命从头合成的设计原理,以及实体瘤的合成细菌治疗。
欧阳颀,中国科学院院士,浙江大学物理学院讲座教授,北京大学定量生物学中心教授。主要致力于应用非线性动力学、复杂系统理论、统计物理的概念以及微流控实验技术,研究方法探索生物控制网络的特性,包括网络拓扑学特性,网络动力学特性,网络功能特性以及三种特性之间的相互制约关系,并试图将研究中所总结的规律应用到合成生物学领域。
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林一瀚, 傅雄飞, 刘陈立, 欧阳颀. 定量合成生物学:合成生物系统的理性设计之路[J]. 合成生物学, 2025, 6(3): 493-496.
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| 1 | 罗楠, 赵国屏, 刘陈立. 合成生物学的科学问题[J]. 生命科学, 2021, 33(12): 1429-1435. |
| LUO N, ZHAO G P, LIU C L. Scientific questions for synthetic biology[J]. Chinese Bulletin of Life Sciences, 2021, 33(12): 1429-1435. | |
| 2 | LUO N, ZHAO G P, LIU C L. Quantitative synthetic biology[J]. Nature Reviews Bioengineering, 2024, 2(11): 911-913. |
| 3 | 刁雯蕙. “定量合成生物学” 开启理性设计新范式[N]. 中国科学报, 2024-07-31(1). |
| DIAO W H. “Quantitative Synthetic Biology” unveils a new paradigm for rational design[N]. China Science Daily, 2024-07-31(1). | |
| 4 | 李倩, FERRELL JR James E, 陈于平. 细胞质浓度: 细胞生物学的老问题、新参数[J]. 合成生物学, 2025, 6(3):497-515. |
| LI Qian, FERRELL JR James E, CHEN Y P. Cytoplasmic concentration: an old question and a new parameter in cell biology[J]. Synthetic Biology Journal,2025,6(3):497-515. | |
| 5 | 姜源旭,范盈盈,魏平. 生物振荡的设计原理与人工合成[J]. 合成生物学, 2025, 6(3):516-531. |
| JIANG Y X, FAN Y Y, WEI P. Design principles and artificial synthesis of biological oscillators[J]. Synthetic Biology Journal,2025,6(3):516-531. | |
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| TIAN X J, ZHANG R X. “Economics Paradox” with cells in synthetic gene circuits[J]. Synthetic Biology Journal,2025,6(3):532-546. | |
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| XIA C L, ZHANG Z C, GUAN X Y, et al. Protein structural bioinformatics empowered by statistical physics and artificial intelligence[J]. Synthetic Biology Journal,2025,6(3):547-565. | |
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| WU K, LUO J H, LI F R. Applications of machine learning in the reconstruction and curation of genome-scale metabolic models[J]. Synthetic Biology Journal,2025,6(3):566-584. | |
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| LI Y Z, CHEN Y. Advances and prospects in genome-scale models of yeast[J]. Synthetic Biology Journal,2025,6(3):585-602. | |
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| ZHANG C X. Challenges and opportunities in text mining-based protein function annotation[J]. Synthetic Biology Journal,2025,6(3):603-616. | |
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| 12 | 李明辰,钟博子韬,余元玺, 等. DeepSeek模型分析及其在AI辅助蛋白质工程中的应用[J]. 合成生物学, 2025, 6(3):636-650. |
| LI M C, ZHONG B Z T, YU Y X, et al. DeepSeek model analysis and its applications in AI-assistant protein engineering[J]. Synthetic Biology Journal,2025,6(3):636-650. | |
| 13 | 姜百翼,钱珑. 活细胞记录器在细胞谱系追踪中的应用和前景[J]. 合成生物学, 2025, 6(3):651-668. |
| JIANG B Y, QIAN L. Application and prospect of live cell DNA-based molecular recorders in cell lineage tracing[J]. Synthetic Biology Journal, 2025,6(3):651-668. | |
| 14 | 杨莹,李霞,刘立中. 合成生物学在干细胞早期胚胎发育模型中的应用[J]. 合成生物学, 2025, 6(3):669-684. |
| YANG Y, LI X, LIU L Z. Applications of synthetic biology to stem-cell-derived modeling of early embryonic development[J]. Synthetic Biology Journal,2025,6(3):669-684. | |
| 15 | 章益蜻,刘高雯. 合成生物学视角下的基因功能探索与酵母工程菌株文库构建[J]. 合成生物学, 2025, 6(3):685-700. |
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