应用合成生物学构建蓝细菌细胞工厂的研究进展

蓝细菌是一类能进行放氧光合作用的原核微生物,具有生长速度快、光合效率高、易于基因遗传操作等特点。它们能够将捕获的光能和二氧化碳转化为生物能源分子,在解决当前社会面临的能源紧缺和环境污染等问题上有着重要的理论和应用研究价值。近年来,随着合成生物学的迅猛发展,构建以蓝细菌为底盘的“人工细胞工厂”用于合成各类生物能源和精细化学产品取得了令人瞩目的成绩。重点介绍了应用合成生物学构建蓝细菌细胞合成工厂的研究进展,并对“光合自养型细胞工厂”面临的两大问题——产物毒性问题以及细胞内氧化胁迫问题进行了重点讨论。     

The emerging age of cell-free synthetic biology

The engineering of and mastery over biological parts has catalyzed the emergence of synthetic biology. This field has grown exponentially in the past decade. As increasingly more applications of synthetic biology are pursued, more challenges are encountered, such as delivering genetic material into cells and optimizing genetic circuits in vivo. An in vitro or cell-free approach to synthetic biology simplifies and avoids many of the pitfalls of in vivo synthetic biology. In this review, we describe some of the innate features that make cell-free systems compelling platforms for synthetic biology and discuss emerging improvements of cell-free technologies. We also select and highlight recent and emerging applications of cell-free synthetic biology.     

Plant synthetic biology: One answer to global challenges

正In times of climate change, population growth and resource depletion, the future well-being of mankind will greatly depend on the ability to breed/engineer crop plants for high yield, low input and high quality.Based on the evaluation of historical yield increases, it seems that yield of major grain crops, such as rice or     

从DNA合成技术角度阐述合成生物学

合成生物学是一个拥有巨大潜力的新兴学科,合成生物学技术的发展将会对未来生物、医药、农业、能源、材料和环保等方面产生巨大的推进作用。基因合成是合成生物学中最基本和使用最多的一种技术手段,合成生物学的快速发展对基因合成能力提出了空前需求。综述基因合成技术的发展历史、现状和未来趋势,探讨基因合成技术存合成生物学以及整个生命科学研究中的应用和重要意义。     

无细胞合成生物学：革新生物医药产业的新策略

无细胞合成生物系统,能够在体外完成生命转录翻译过程,因体系灵活开放、便于控制、表达周期短、高耐受性等特点,可表达细胞系统难以表达的蛋白质。随着无细胞生物传感和体系冻干技术的不断发展,其在医药健康领域的应用不断拓展。本文综述了无细胞合成生物学在按需生物医药合成和便携式医疗检测等医药健康领域的研究进展,该体系的进一步发展有潜力实现更复杂后修饰蛋白质药物的合成、可丰富无细胞生物传感器类型并提高其灵敏性。无细胞合成生物学作为新兴工程策略,未来必将更好地应用于高通量医药蛋白质筛选、新型病原体的检测等医药健康领域。     

Enabling technology and core theory of synthetic biology

Synthetic biology provides a new paradigm for life science research(“build to learn”) and opens the future journey of biotechnology(“build to use”). Here, we discuss advances of various principles and technologies in the mainstream of the enabling technology of synthetic biology, including synthesis and assembly of a genome, DNA storage, gene editing, molecular evolution and de novo design of function proteins, cell and gene circuit engineering, cell-free synthetic biology, artificial intelligen...     

Vibrio natriegens: an ultrafast-growing marine bacterium as emerging synthetic biology chassis

The marine bacterium Vibrio natriegens is the fastest-growing non-pathogenic bacterium known to date and is gaining more and more attention as an alternative chassis organism to Escherichia coli. A recent wave of synthetic biology efforts has focused on the establishment of molecular biology tools in this fascinating organism, now enabling exciting applications – from speeding up our everyday laboratory routines to increasing the pace of biotechnological production cycles. In this review, we seek to give a broad overview on the literature on V. natriegens, spanning all the way from its initial isolation to its latest applications. We discuss its natural ecological niche and interactions with other organisms, unveil some of its extraordinary traits, review its genomic organization and give insight into its diverse metabolism – key physiological insights required to further develop this organism into a synthetic biology chassis. By providing a comprehensive overview on the established genetic tools, methods and applications we highlight the current possibilities of this organism, but also identify some of the gaps that could drive future lines of research, hopefully stimulating the growth of the V. natriegens research community.     

Do-it-yourself biology: challenges and promises for an open science and technology movement

The do-it-yourself biology (DIYbio) community is emerging as a movement that fosters open access to resources permitting modern molecular biology, and synthetic biology among others. It promises in particular to be a source of cheaper and simpler solutions for environmental monitoring, personal diagnostic and the use of biomaterials. The successful growth of a global community of DIYbio practitioners will depend largely on enabling safe access to state-of-the-art molecular biology tools and resources. In this paper we analyze the rise of DIYbio, its community, its material resources and its applications. We look at the current projects developed for the international genetically engineered machine competition in order to get a sense of what amateur biologists can potentially create in their community laboratories over the coming years. We also show why and how the DIYbio community, in the context of a global governance development, is putting in place a safety/ethical framework for guarantying the pursuit of its activity. And finally we argue that the global spread of DIY biology potentially reconfigures and opens up access to biological information and laboratory equipment and that, therefore, it can foster new practices and transversal collaborations between professional scientists and amateurs.     

Cell-free biology: exploiting the interface between synthetic biology and synthetic chemistry

Just as synthetic organic chemistry once revolutionized the ability of chemists to build molecules (including those that did not exist in nature) following a basic set of design rules, cell-free synthetic biology is beginning to provide an improved toolbox and faster process for not only harnessing but also expanding the chemistry of life. At the interface between chemistry and biology, research in cell-free synthetic systems is proceeding in two different directions: using synthetic biology for synthetic chemistry and using synthetic chemistry to reprogram or mimic biology. In the coming years, the impact of advances inspired by these approaches will make possible the synthesis of nonbiological polymers having new backbone compositions, new chemical properties, new structures, and new functions.     

The path to next generation biofuels: successes and challenges in the era of synthetic biology

Volatility of oil prices along with major concerns about climate change, oil supply security and depleting reserves have sparked renewed interest in the production of fuels from renewable resources. Recent advances in synthetic biology provide new tools for metabolic engineers to direct their strategies and construct optimal biocatalysts for the sustainable production of biofuels. Metabolic engineering and synthetic biology efforts entailing the engineering of native and de novo pathways for conversion of biomass constituents to short-chain alcohols and advanced biofuels are herewith reviewed. In the foreseeable future, formal integration of functional genomics and systems biology with synthetic biology and metabolic engineering will undoubtedly support the discovery, characterization, and engineering of new metabolic routes and more efficient microbial systems for the production of biofuels.     

Synthetic biology: challenges ahead

This expanding scientific discipline is proving extremely popularand is attracting engineering and system design experts to thefield of Biology. As Bioinformatics and Computational Biology will be essentialcomponents of new technical and scientific developments, itis vital to follow the discussion generated by the recent ESFExploratory Workshop (October 13–16, 2005, Constructingand de-constructing Life, Magalia, Spain) and the 2005 reportof the NEST High-Level Expert Group on Synthetic Biology: ApplyingEngineering to Biology http://www.eurosfaire.prd.fr/nest/documents/pdf/NEST_syntheticbiology_b5_eur21796_en.pdf) Synthetic Biology stands at the meeting-point of two cultures.The first, represented by those interested in ‘deconstructing     

Interfacing systems biology and synthetic biology

A report of BioSysBio 2009, the IET conference on Synthetic Biology, Systems Biology and Bioinformatics, Cambridge, UK, 23-25 March 2009.     

Immunobiology of Toll-like receptors: emerging trends

Toll-like receptors (TLR), a family of evolutionarily conserved pathogen recognition receptors, play pivotal role as primary sensors of invading pathogens. TLR identify molecular motifs of infectious agents (pathogen associated molecular patterns) and elicit an effective defensive response against them. Mammalian TLR derive their name from the Drosophila Toll protein, with which they share sequence similarity. So far, expression of 10 TLR is known in humans. The adaptor proteins, myeloid differentiation factor 88 and Toll IL-1 receptor (TIR) domain containing adaptor inducing IFN-beta (TRIF) are the key players in the TLR signalling cascade leading to the activation of nuclear factor (NF)-kappaB and interferon regulatory factor-3, respectively. Targeted manipulation of the TLR signalling pathway has immense therapeutic potential and may eventually prove to be a boon in the development of innovative treatments for diverse disease conditions. There is accumulating evidence that TLR agonists have tremendous potential as novel therapeutic targets. In this review, we have discussed the immunobiology of TLR and emphasize significant advances made within the ever-expanding field of TLR that provide intriguing insights efficacious in unravelling the complexities associated with TLR.