国际基因工程机器大赛在中国

合成生物学是一门新兴的交叉学科,为培养合成生物学后备人才,国际基因工程机器(iGEM)大赛应运而生。2007年中国首次有5支队伍参加iGEM大赛,至今已经有11年的历史。然而,目前尚无全面总结中国iGEM队伍的相关文献。文中全面梳理和总结了iGEM大赛在中国的发展历程,包括参赛队伍的数量、地理分布、竞赛成绩、中国iGEM社群CCiC的发展情况,以及iGEM大赛对中国高等教育的促进和借鉴作用,并深度思考了iGEM大赛在中国的发展前景,提出了发展建议。随着我国高等教育"双一流"战略的实施,iGEM大赛在我国的发展具有光明的前景,可为培养新一代科学家作出更大的贡献。     

Special focus: Synthetic biology

Special focus: Synthetic biology What is synthetic biology? SynBERC – The Synthetic Biology Engineering Research Center Ars Synthetica iGEM – The International Genetically Engineered Machine competition Some synthetic biology companies Paper watch: Synthetic biology Building blocks for novel functions Knowledge-making distinctions in synthetic biology Scaffold design and manufacturing: From concept to clinic Peptidomimetics – a versatile route to biologically active compounds Metabolic engineering of E. coli E. coli needs safety valves Systems-level metabolic engineering Mammalian synthetic biology Chemical aspects of synthetic biology Synthesis of DNA fragments in yeast Synthetic biology and patentable subject matter Patenting artificial life? Metabolic effects of synthetic rewiring Engineering for biofuels Regulatory elements for synthetic biology Book highlight Systems Biology and Synthetic Biology     

Synthetic biology for plant genetic engineering and molecular farming

Many efforts have been put into engineering plants to improve crop yields and stress tolerance and boost the bioproduction of valuable molecules. Yet, our capabilities are still limited due to the lack of well-characterized genetic building blocks and resources for precise manipulation and given the inherently challenging properties of plant tissues. Advancements in plant synthetic biology can overcome these bottlenecks and release the full potential of engineered plants. In this review, we first discuss the recently developed plant synthetic elements from single parts to advanced circuits, software, and hardware tools expediting the engineering cycle. Next, we survey the advancements in plant biotechnology enabled by these recent resources. We conclude the review with outstanding challenges and future directions of plant synthetic biology.     

Engineering a novel self-powering electrochemical biosensor

This paper records the efforts of a multi-disciplinary team of undergraduate students from Glasgow University to collectively design and carry out a 10 week project in Synthetic Biology as part of the international Genetic Engineered Machine competition (iGEM). The aim of the project was to design and build a self-powering electrochemical biosensor called ‘ElectrEcoBlu’. The novelty of this engineered machine lies in coupling a biosensor with a microbial fuel cell to transduce a pollution input into an easily measurable electrical output signal. The device consists of two components; the sensor element which is modular, allowing for customisation to detect a range of input signals as required, and the universal reporter element which is responsible for generating an electrical signal as an output. The genetic components produce pyocyanin, a competitive electron mediator for microbial fuel cells, thus enabling the generation of an electrical current in the presence of target chemical pollutants. The pollutants tested in our implementation were toluene and salicylate. ElectrEcoBlu is expected to drive forward the development of a new generation of biosensors. Our approach exploited a range of state-of-the-art modelling techniques in a unified framework of qualitative, stochastic and continuous approaches to support the design and guide the construction of this novel biological machine. This work shows that integrating engineering techniques with scientific methodologies can provide new insights into genetic regulation and can be considered as a reference framework for the development of biochemical systems in synthetic biology.     

国际基因工程机器大赛高中赛道发展概况

国际基因工程机器大赛(international genetically engineered machine competition,简称iGEM竞赛)是合成生物学国际顶级大学生学术竞赛。iGEM竞赛赛况及项目成果受到Science、Nature、Scientific American、The Economist、英国广播公司(BBC)等顶级学术期刊或国际媒体的关注,具有广泛的国际影响力。吸引了来自世界40多个国家和地区的队伍参赛。2011年起开始有高中队参赛,参赛队伍数量逐年增加,高中生日益成为推动iGEM竞赛及合成生物学发展的重要力量之一,iGEM竞赛也成为培养中学生核心素养的重要平台。基于2017–2021年全球高中队参赛情况,本文总结了高中队赛道规则、选题倾向及获奖情况,进一步分析iGEM竞赛对高中生核心素养培养的意义,探究全球高中参赛队伍的发展趋势,为未来高中参赛队伍建设提供理论参考。     

合成生物学发展现状与前景

合成生物学是综合了科学与工程的一个崭新的生物学研究领域,为生命现象及其运动规律的解析提供了一种采用“白下而上”合成策略的正向工程学的研究思路和方法手段,在经济和社会发展中具有巨大的应用开发潜力。近年来,DNA合成与系统生物学技术的发展使生命系统复杂基因回路的设计、合成与组装逐步成为可能,并应用于生物基化学品、生物燃料、医药中间体、保健产品的生产和环境保护等领域。但是,合成生物学的研究仍然面临科学、技术和伦理的挑战,只有积极地应对这些问题,在加大研究开发支持力度的同时,做好必要的风险监管,才能真正把握合成生物学发展带来的历史机遇。     

合成生物学与国际遗传工程机器大赛对培养大学生双创思维与能力的影响

合成生物学是21世纪前沿交叉学科,是现代生物学最具发展空间的领域之一。随着合成生物学的迅速发展,国际基因工程机器大赛(International Genetically Engineered Machine, iGEM)应运而生。iGEM竞赛项目基于合成生物学学科基础,应用现代生物学技术手段,立足解决社区和身边的实际生物相关问题。近年来,随着参赛团队的不断增加,iGEM竞赛得到了广泛的关注与发展。本文基于合成生物学发展概况,通过对iGEM竞赛2018–2020年获奖项目情况进行分析,并结合西南交通大学iGEM团队的参赛经历,剖析iGEM竞赛在培养大学生双创思维和能力中的重要意义和实现途径。     

A follow-up study of women in the synthetic rubber industry: study methods

BACKGROUND: Concerns about the possible toxic effects of workplace exposures in the synthetic rubber industry have centered on 1,3-butadiene (BD), styrene and dimethyldithiocarbamate (DMDTC). Our previous mortality studies of over 17,000 male synthetic rubber workers found an excess of leukemia that may be due to BD or BD plus other chemicals. Experimental studies have shown that BD produces mammary tumors in female mice and rats and ovarian tumors in female mice. AIM: This paper presents the methods of a follow-up study that evaluates the mortality experience of women employed in the North American synthetic rubber industry. METHODS: Women employed for at least 1 day at any of eight North American styrene-butadiene rubber plants were followed up from 1943 to 2002. Identifying and work history information were obtained from personnel records. Estimated quantitative exposure to BD, styrene and DMDTC, developed for our previous study of men, were used in this study. External analyses use the standardized mortality ratios (SMRs) to compare the cohort's cause-specific mortality rates to the rates of the female general population of the states or the province where the plants are located. Internal analyses use the Poisson regression and Cox proportional hazards models to examine specific cancer mortality rates in relation to BD, styrene and DMDTC exposure, by comparing an exposed cohort subgroup with the rate of unexposed cohort members.     

2018 iGEM专栏序言

国际基因工程机器大赛(iGEM),作为一项以合成生物学为主题,集合了多种交叉学科的学生科研赛事,已成为了当今生物科研领域属于年轻人的最具活力和影响力的舞台。近年来,许多来自国内的大学和高中队伍不仅在比赛中取得了优异成绩,还做出了具有创新性的科研成果。为此,我们特组织出版了此iGEM专栏,集中报道近年来国内多支iGEM参赛队的研究工作,同时关注、探讨iGEM大赛在中国的发展情况和对大学生科研能力培养的启示。     

Possible Mechanisms of Adaptive Leaf Senescence

Abstract: Availability of nitrogen almost always limits plant growth. Therefore, efficient use of nitrogen is essential for the plants. In upright plants, especially when they form dense plant stands, old, lower leaves are shaded by young, upper leaves. Nitrogenous compounds in such shaded leaves are degraded and re-allocated to the developing young, upper leaves. These processes raise efficiency of nitrogen use in photosynthetic production of the plant. For this to occur in the most effective way, leaves would need to sense their photosynthetic status in a plant and increase, maintain or decrease their photosynthetic capacity accordingly. Hypotheses that explain how a leaf can sense its photosynthetic status in the plant are reviewed. They include systems involving phytochrome, sugar-sensing, or cytokinin. Our experimental results with Helianthus annuus and Phaseolus vulgaris plants, which were subject to various shading treatments, are examined in the light of these hypotheses. Our experimental results favoured the sugar-sensing hypothesis: A leaf can sense demand of other plant parts for photosynthates produced by it and nitrogen abundance or deficiency by monitoring its sugar concentration. Problems that are to be challenged in the near future are also pointed out.     

Toward scalable parts families for predictable design of biological circuits

Our current ability to engineer biological circuits is hindered by design cycles that are costly in terms of time and money, with constructs failing to operate as desired, or evolving away from the desired function once deployed. Synthetic biologists seek to understand biological design principles and use them to create technologies that increase the efficiency of the genetic engineering design cycle. Central to the approach is the creation of biological parts--encapsulated functions that can be composited together to create new pathways with predictable behaviors. We define five desirable characteristics of biological parts--independence, reliability, tunability, orthogonality and composability, and review studies of small natural and synthetic biological circuits that provide insights into each of these characteristics. We propose that the creation of appropriate sets of families of parts with these properties is a prerequisite for efficient, predictable engineering of new function in cells and will enable a large increase in the sophistication of genetic engineering applications.     

Crosstalk between endogenous and synthetic components--synthetic signaling meets endogenous components

Synthetic biology uses biological components to engineer new functionality in living organisms. We have used the tools of synthetic biology to engineer detector plants that can sense man-made chemicals, such as the explosive trinitrotoluene, and induce a response detectable by eye or instrumentation. A goal of this type of work is to make the designed system orthogonal, that is, able to function independently of systems in the host. In this review, the design and function of two partially synthetic signaling pathways for use in plants is discussed. We describe observed interactions (crosstalk) with endogenous signaling components. This crosstalk can be beneficial, allowing the creation of hybrid synthetic/endogenous signaling pathways, or detrimental, resulting in system noise and/or false positives. Current approaches in the field of synthetic biology applicable to the design of orthogonal signaling systems, including the design of synthetic components, partially synthetic systems that utilize crosstalk to signal through endogenous components, computational redesign of proteins, and the use of heterologous components, are discussed.     

Beyond directed evolution: Darwinian selection as a tool for synthetic biology

Synthetic biology is an engineering approach that seeks to design and construct new biological parts, devices and systems, as well as to re-design existing components. However, rationally designed synthetic circuits may not work as expected due to the context-dependence of biological parts. Darwinian selection, the main mechanism through which evolution works, is a major force in creating biodiversity and may be a powerful tool for synthetic biology. This article reviews selection-based techniques and proposes strict Darwinian selection as an alternative approach for the identification and characterization of parts. Additionally, a strategy for fine-tuning of relatively complex circuits by coupling them to a master standard circuit is discussed.     

Integrative Application of Soil Conditioners and Bio-augmentation for Enhanced Heavy Metal Stabilization from Wastewater and Improved Growth of Nicotiana alata L. and Petunia hydrida L.

Wastewater generated from industries contains numerous contaminants, among which heavy metals (HMs) are non-degradable. This research work highlights the use of commonly used ornamental plants, Nicotiana alata L. and Petunia hydrida L., with compost (C) and peat moss (M), and rhizospheric bacterial augmentation using Pseudomonas japonica, for the phytostabilization of HMs from synthetic wastewater. After plant–soil acclimatization, plants were exposed for 6 weeks to synthetic wastewater, containing cadmium, chromium, copper, lead, nickel, and zinc concentrations (based on the HMs level of wastewaters collected from textile and pharmaceutical industry). Physiological response, biochemical status, and enzymatic fluctuations of plants and the distribution of HMs in plant parts and soil, were quantified. With the combined use (5% each v/v conditioner/soil) of C and M, in bio-augmented soil, physiological response and enzymatic status of both plants improved, with decreased stress injury due to HMs. Further, the plant HMs uptake was reduced, with better stabilization of HM in soil. For better phytostabilization of HMs in wastewater, the use of compost, peat moss, and bacterial augmentation is recommended with Nicotiana alata L. and Petunia hydrida L.

     

生物元件的挖掘、改造与标准化

生物元件是合成生物学中的三大基本要素之一,是合成生物学的基石。现阶段,生物元件的挖掘、鉴定和改造仍然是合成生物学领域的重要研究方向之一。合成生物学与基因工程和代谢工程最显著的差别在于能够将大量的生物元件进行快速、随意的组装,而实现这一目标的前提是将生物元件标准化。目前,已经有大量基因组被解析,通过这些基因组数据库的注释与功能验证,并借助于各种生物信息学软件预测启动子、终止子、操纵了、转录因子和转录因子结合位点、核糖体结合位点以及蛋白质编码区等部件,为合成生物学提供丰富的生物元件信息资源。随着元基因组技术的兴起,大量未培养微生物中的基因和基因簇信息被解析,使得我们可以从占自然界中实际存在微生物总数99％的未知微生物中挖掘更多的生物元件。另外,生物元件可以从自然界分离出来,也可以对天然生物元件进行修饰、重组和改造后得到新的元件。酵母是异源蛋白表达的通用宿主和生物基产品生产的细胞工厂,但其本身可用的启动子非常有限,近年来各国学者在酵母启动子改造和文库构建方面做了很多工作,该文也将概述酵母启动子改造和在合成生物生物学研究领域中的应用方面的研究进展。     

Parts plus pipes: synthetic biology approaches to metabolic engineering

Synthetic biologists combine modular biological "parts" to create higher-order devices. Metabolic engineers construct biological "pipes" by optimizing the microbial conversion of basic substrates to desired compounds. Many scientists work at the intersection of these two philosophies, employing synthetic devices to enhance metabolic engineering efforts. These integrated approaches promise to do more than simply improve product yields; they can expand the array of products that are tractable to produce biologically. In this review, we explore the application of synthetic biology techniques to next-generation metabolic engineering challenges, as well as the emerging engineering principles for biological design.     

Targeting transgene expression in research,agricultural, and environmental applications: Promoters used in plant transformation

Summary Plant genetic engineering has contributed substantially to the understanding of gene regulation and plant development, in the generation of transgenic organisms for widespread usage in agriculture, and has increased the potential uses of crops for industrial and pharmaceutical purposes. As the application of geneticallly engineered plants has widened, so has the need to develop methods to fine-tune control of transgene expression. The availability of a broad spectrum of promoters that differ in their ability to regulate the temporal and spatial expression patterns of the transgene can dramatically increase the successful application of transgenic technology. Indeed, a variety of promoters in necessary at all levels of genetic engineering in plants, from basic research discoveries, concepts and question to development of economically viable crops and plant commodities, to addressing legitimate concerns raised about the safety and containment of transgenic plants in the environment. This review covers the characterization and usage of a broad range of promoters employed in plant genetic engineering, including the widespread use of plant promoters with viral and plant origin that drive constitutive expression. Also covered are selected tissue-specific promoters from fruit, seed and grain, tubers, flowers, pistils, anther and pollen, roots and root nodules, and leaves and green tissue. Topics also include organellar promoters, and those found in specific cell types, as well as the development and evaluation of inducible (endogenous and exogenous origin) and synthetic plant promoter systems. Discussions on the relevance and potential pitfalls within specific applications are included.