如何工程化生物学

随着化学学科的发展和应用需求,化学工程应运而生;随着生物学的发展和工程化需求,代表着“生物学第三次革命”的合成生物学也随之诞生。合成生物学,即生物学的工程化,它从工程学角度设计创建元件、器件或模块,以及通过这些元器件改造和优化现有自然生物体系,但是如何对复杂生命进行工程化一直是合成生物学工作者不断探索的重大科学问题。本文系统地阐释了迄今为止工程化生物学的4个特点:①模块化和标准化;②正交性;③鲁棒性;④适配性及其对应研究进展。最后从“设计-构建-测试”循环的研究模式入手提出了今后如何进一步有效地工程化生物学。     

合成生物学研究进展

合成生物学是以工程化设计思路,构建标准化的元器件和模块,改造已存在的天然系统或者从头合成全新的人工生命体系,实现在化学品合成(包括材料、能源和天然化合物)、医学、农业、环境等领域的应用。人们利用基本的生物学元件设计和构建了基因开关、振荡器、放大器、逻辑门、计数器等合成器件,实现对生命系统的重新编程并执行特殊功能。模块化处理生物的代谢途径,并在底盘细胞上进行组装和优化,可以实现大宗化学品和精细化学品的合成。目前人们已经在丁醇、异丁醇、青蒿素和紫杉醇等化合物的生物合成上取得了重要进展。近年来还发展了多种基因组编辑和组装技术,可精确地对基因组进行编辑,人们还成功地合成了噬菌体基因组、支原体基因组和酵母基因组。在未来的50～100年内,合成生物学将对人类的医疗、化学品制造(含药品)、军事产生渐进性的、渗透性的但颠覆性的意义。     

Autonomous and Assisted Control for Synthetic Microbiology

The control of microbes and microbial consortia to achieve specific functions requires synthetic circuits that can reliably cope with internal and external perturbations. Circuits that naturally evolved to regulate biological functions are frequently robust to alterations in their parameters. As the complexity of synthetic circuits increases, synthetic biologists need to implement such robust control “by design”. This is especially true for intercellular signaling circuits for synthetic consortia, where robustness is highly desirable, but its mechanisms remain unclear. Cybergenetics, the interface between synthetic biology and control theory, offers two approaches to this challenge: external (computer-aided) and internal (autonomous) control. Here, we review natural and synthetic microbial systems with robustness, and outline experimental approaches to implement such robust control in microbial consortia through population-level cybergenetics. We propose that harnessing natural intercellular circuit topologies with robust evolved functions can help to achieve similar robust control in synthetic intercellular circuits. A “hybrid biology” approach, where robust synthetic microbes interact with natural consortia and—additionally—with external computers, could become a useful tool for health and environmental applications.     

Courses Based on iGEM/BIOMOD Competitions Are the Ideal Format for Research-Based Learning of Xenobiology

Synthetic biology and especially xenobiology, as emerging new fields of science, have reached an intellectual and experimental maturity that makes them suitable for integration into the university curricula of chemical and biological disciplines. Novel scientific fields that include laboratory work are perfect playgrounds for developing highly motivating research-based teaching modules. We believe that research-based learning enriched by digital tools is the best approach for teaching new emerging essentials of academic education. This is especially true when the scientific field as such is still not canonized with text books and best-practice examples. Our experience shows that iGEM/BIOMOD competitions represent an excellent basis for designing research-based courses in xenobiology. Therefore, we present a report on “iGEM–Synthetic Biology” offered at the Technische Universität Berlin as an example.     

合成生物学在医药及能源领域的应用

合成生物学是以工程学思想为指导,对天然生物系统进行重新设计与改造,同时设计并合成新的生物元件、模块和系统的崭新学科。合成生物学是自然科学发展到现阶段的产物,并已经在医药、能源等领域取得了一些显著成果。本文综述了在工程细胞中利用合成生物学方法构建抗疟疾药物青蒿素的前体物青蒿二烯,抗癌药物紫杉醇的前体物紫杉二烯,以及脂肪酸酯、脂肪醇、高级醇的合成途径等研究进展。此外,一些重要的合成生物学相关技术,大大加速工程细胞的重构与进化,为构建应用于生产领域的新功能细胞提供方便实用的工具。     

Metabolic Remodeling of Cell‐Surface Sialic Acids: Principles,Applications, and Recent Advances

Cell‐surface sialic acids are essential in mediating a variety of physiological and pathological processes. Sialic acid chemistry and biology remain challenging to investigate, demanding new tools for probing sialylation in living systems. The metabolic glycan labeling (MGL) strategy has emerged as an invaluable chemical biology tool that enables metabolic installation of useful functionalities into cell‐surface sialoglycans by “hijacking” the sialic acid biosynthetic pathway. Here we review the principles of MGL and its applications in study and manipulation of sialic acid function, with an emphasis on recent advances.     

Microfluidic technologies for synthetic biology

Microfluidic technologies have shown powerful abilities for reducing cost, time, and labor, and at the same time, for increasing accuracy, throughput, and performance in the analysis of biological and biochemical samples compared with the conventional, macroscale instruments. Synthetic biology is an emerging field of biology and has drawn much attraction due to its potential to create novel, functional biological parts and systems for special purposes. Since it is believed that the development of synthetic biology can be accelerated through the use of microfluidic technology, in this review work we focus our discussion on the latest microfluidic technologies that can provide unprecedented means in synthetic biology for dynamic profiling of gene expression/regulation with high resolution, highly sensitive on-chip and off-chip detection of metabolites, and whole-cell analysis.     

合成生物学在生物基塑料制造中的应用

合成生物学是以工程学思想为指导,对天然生物基因组进行改造和重构,合成新的生物元件,构建新的代谢途径,生产新产品或获得新表型的新兴学科。生物基塑料是以天然物质为原料在微生物作用或化学反应下生成的塑料。利用合成生物学改造工程菌株的方法制备合成生物基塑料已经成为学术界和产业界关注的热点。本文综述了合成生物学的发展和重要的合成生物学技术,重点综述了利用合成生物学技术构建聚羟基烷酸酯、尼龙、聚乳酸和丁二酸丁二醇酯等生物基塑料聚合物单体及其衍生物的代谢途径和工程优化领域的研究进展。     

Application of synthetic biology in manufacture of bio-based plastics

Synthetic biology is a new discipline that uses engineering ideas as a guide to transform and reconstruct natural biological genomes, synthesize new biological components, construct new metabolic routes, and produce novel products or obtain new phenotypes. Bio-based plastics are plastics produced under the action of microorganisms or the chemical reactions using natural materials as raw materials. The usage of synthetic biology to construct engineered strains to produce bio-based plastics has become a hot topic in academia and industry. This paper reviews the development of synthetic biology and important techniques in the field of synthetic biology, focusing on the research progress in the field of metabolic pathways and engineering optimization for the construction of bio-based plastic polymer monomers and derivatives such as polyhydroxyalkanoate, nylon, polylactic acid, and butylene glycol succinate using synthetic biological techniques.     

Fluorescent Probes for G‐Quadruplex Structures

Mounting evidence supports the presence of biologically relevant G‐quadruplexes in single‐cell organisms, but the existence of endogenous G‐quadruplex structures in mammalian cells remains highly controversial. This is due, in part, to the common misconception that DNA and RNA molecules are passive information carriers with relatively little structural or functional complexity. For those working in the field, however, the lack of available tools for characterizing DNA structures in vivo remains a major limitation to addressing fundamental questions about structure–function relationships of nucleic acids. In this review, we present progress towards the direct detection of G‐quadruplex structures by using small molecules and modified oligonucleotides as fluorescent probes. While most development has focused on cell‐permeable probes that selectively bind to G‐quadruplex structures with high affinity, these same probes can induce G‐quadruplex folding, thereby making the native conformation of the DNA or RNA molecule (i.e., in the absence of probe) uncertain. For this reason, modified oligonucleotides and fluorescent base analogues that serve as “internal” fluorescent probes are presented as an orthogonal means for detecting conformational changes, without necessarily perturbing the equilibria between G‐quadruplex, single‐stranded, and duplex DNA. The major challenges and motivation for the development of fluorescent probes for G‐quadruplex structures are presented, along with a summary of the key photophysical, biophysical, and biological properties of reported examples.     

pH responsive polymers with amino acids in the side chains and their potential applications

Design and synthesis of pH responsive polymeric materials has become an important subject in academia as well as in industrial field in recent years due to their applications in diverse field including controlled drug delivery, biomedical applications, membrane science, sensors and actuators, oil recovery, colloid stabilization, etc. Efforts have been made to incorporate stimuli‐responsive biomolecules in synthetic polymers to develop pH responsive “smart” non‐biological hybrid macromolecules with high water solubility, enhanced biocompatibility, bio‐mimetic structure and properties. This review is focused on the recent advances in side‐chain amino acid‐based pH responsive polymers synthesis and potential application aspects of these macromolecular architectures in drug and gene delivery, and other fields. © 2014 Wiley Periodicals, Inc. J. Appl. Polym. Sci. 2014 , 131, 41084.     

Tecto‐GIRz: Engineered Group I Ribozyme the Catalytic Ability of Which Can Be Controlled by Self‐Dimerization

RNA is a promising biomaterial for self‐assembly of nano‐sized structures with a wide range of applications in nanotechnology and synthetic biology. Several RNA‐based nanostructures have been reported, but most are unrelated to intracellular RNA, which possesses modular structures that are sufficiently large and complex to serve as catalysts to promote sophisticated chemical reactions. In this study, we designed dimeric RNA structures based on the Tetrahymena group I ribozyme. The resulting dimeric RNAs (tecto group I ribozyme; tecto‐GIRz) exhibit catalytic ability that depended on controlled dimerization, by which a pair of ribozymes can be activated to perform cleavage and splicing reactions of two distinct substrates. Modular redesign of complex RNA structures affords large ribozymes for use as modules in RNA nanotechnology and RNA synthetic biology.     

Synthetic biological system construction and green intelligent biological manufacturing

The production of chemicals in microbial cell factories is one of the effective ways to solve energy and environmental problems. Many chemical products have been produced by synthetic biology, but production ability and robustness of the strains still needs to been improved. Development of intelligent cell factory and realizing intelligent biological manufacturing is an important approach to improve the production and robustness. This review introduces the research status of intelligent biological manufacturing from five following aspects: protein design, biosensor, metabolism regulation, strain evolution and fermentation process. The development of biological “intelligence” will make an important contribution to improving the production level of industrial biological processes and process energy saving and emission reduction.     

合成生物系统构建与绿色生物“智”造

微生物细胞工厂生产化学品是解决能源和环境问题的有效方式之一。越来越多的化合物可通过合成生物系统实现在微生物中的合成,但菌株的生产能力和鲁棒性仍需进一步提高。提高细胞工厂的智能化,实现生物“智”造过程,将是解决菌株发酵生产能力不足和鲁棒性差的重要途径。本文从蛋白质设计的智能化、生物传感器的智能化、代谢调控的智能化、菌株进化的智能化以及发酵过程智能化等五个层面对生物“智”造的研究现状进行介绍。生物“智”造的发展将为提高工业生物过程的生产水平和过程节能减排做出重要贡献。     

Fabrication of Function‐Graded Proton Exchange Membranes for Direct Methanol Fuel Cells Using Electron Beam‐Grafting

Function‐graded proton exchange membranes (G‐PEMs) based on poly(tetrafluoroethylene‐co‐hexafluoropropylene) were fabricated for direct methanol fuel cells (DMFCs) via electron beam‐grafting using the heterogeneous energy deposition technique. The G‐PEMs had a water uptake gradient in the proton transfer direction, originating from the sulfonic acid group gradient. The distribution of sulfonic acid groups in the various G‐PEMs was evaluated using X‐ray photoelectron spectroscopy. Four types of PEMs (flat‐type, strong‐gradient, meso‐gradient, and weak‐gradient types) were fabricated. By varying the direction of the G‐PEMs, the methanol permeation test and DMFC operation were performed with two orientations of the sulfonic acid group gradient, decreasing from the methanol injection (anode) side (decrease‐type) or the other (cathode) side (increase‐type). The methanol permeability of the strong‐gradient, meso‐gradient, and weak‐gradient G‐PEMs was lower than that of Nafion®117 and the flat‐type PEM. The “increase‐type” orientation of the strong‐gradient G‐PEM resulted in the lowest methanol permeability. The DMFC performance of the G‐PEMs was influenced by the thickness direction, such as “decrease‐type” and “increase‐type.” The performance of the “decrease‐type” assembly was higher than that of the “increase‐type.” The “decrease‐type” assembly with P‐200 k (weak‐gradient G‐PEM) exhibited the highest performance of the fabricated PEMs, comparable to that of Nafion®117.     

Penicillin Acylase‐Catalyzed Solid‐State Ampicillin Synthesis

The ability of immobilized penicillin acylase from E. coli to retain a remarkable catalytic activity in solid‐state systems has been demonstrated. Stabilization of immobilized penicillin acylase by inorganic salt hydrates allowed us to exploit nearly the whole catalytic activity of the enzyme at a very low water content. Using this technique, enzymatic synthesis of ampicillin in solid‐state systems was performed with high yields (up to 70% starting from equimolar mixture of reagents) and rates comparable to the corresponding values in homogeneous solutions and heterogeneous systems, “aqueous solution‐precipitate”. Peculiarities of the enzymatic solid‐state acyl transfer process, such as absence of the clear‐cut maximum on the ampicillin accumulation curves and dependence of the synthetic efficiency on the enzyme loading, have been observed. The space‐time yield of solid‐state enzymatic ampicillin synthesis was shown to be up to ten times higher compared to the homogeneous solutions and heterogeneous “aqueous solution‐precipitate” systems.     

Synthesis,Characterization and Catalytic Applications of Organized Mesoporous Aluminas

The synthesis of organized mesoporous aluminas has opened a very interesting area for application of this type of materials, particularly as catalysts or catalyst supports. This review focuses on the individual synthesis routes to produce organized mesoporous aluminas with large surface areas and narrow pore size distributions, and on the evaluation of their textural, chemical and thermal properties and outlines examples of catalytic applications of organized mesoporous alumina‐based catalysts. We tried to rationalize the synthetic approaches to prepare organized mesoporous aluminas, to relate their properties to synthetic procedures used as well as to their catalytic behavior in different reactions. Utilization of various structure‐directing agents for “cationic,” “neutral,” “anionic,” “nanocasting,” and special approaches leading to scaffolding and lathlike organized mesoporous aluminas is discussed in the first part of this review, as well as textural and structural characterization and thermal stability of mesoporous aluminas synthesized by different synthetic approaches. In the second part, catalytic applications of organized mesoporous aluminas described in the open literature are evaluated from the standpoint of the importance of these reactions for technological applications.