单萜类化合物的微生物合成

单萜类化合物是萜类化合物的一种,一般具有挥发性和较强的香气,部分单萜还具有抗氧化、抗菌、抗炎等生理活性,是医药、食品和化妆品工业的重要原料.近年来,利用微生物异源合成单萜类化合物的研究引起了科研人员的广泛关注,但因产量低、生产成本高等限制了其大规模应用.合成生物学的迅猛发展为微生物生产单萜类化合物提供了新的手段,通过改...     

酿酒酵母合成异源单萜类化合物的研究进展

单萜类化合物在食品、医药和工业等领域有重要的应用,具有可观的经济价值.随着合成生物学的日益发展,利用微生物作为细胞工厂合成单萜类化合物成为时下的研究热点.酿酒酵母是真核生物表达的模式菌株,其甲羟戊酸途径为单萜类化合物的合成提供直接前体,因此在酿酒酵母中构建异源单萜类化合物合成途径有较大优势.本文介绍了酿酒酵母细胞中异源单萜类化合物合成途径的构建.从甲羟戊酸途径代谢通量调控机制和融合酶调控酶催化反应效率两方面概述了酿酒酵母异源合成单萜类化合物的研究进展.     

谷氨酸棒状杆菌异源合成萜类化合物的研究进展

萜类化合物具有可观的商业价值,但生产过程复杂,产量低,利用微生物异源合成萜类化合物已成为热点。谷氨酸棒状杆菌内含合成萜类色素的途径,具有异源合成萜类化合物的天然优势和研究前景。首次对谷氨酸棒状杆菌合成萜类化合物进行了综述,从萜类合成途径、关键酶和全局调控机制三个方面进行了途经介绍。概述了谷氨酸棒状杆菌中单萜、倍半萜、四萜类化合物的异源合成,并对利用谷氨酸棒状杆菌高效合成萜类化合物所需解决的问题进行讨论,为谷氨酸棒状杆菌高效合成萜类化合物提供建议。     

萜类化合物的合成生物学研究进展

萜类化合物是种类最多的一类天然产物,具有抗癌、抗过敏等多种生物活性,在食品、日化、医疗等领域受到广泛关注,展现了巨大的应用潜力和广阔的市场前景。近年来,研究人员采用功能基因组学和代谢组学技术对不同萜类的合成途径进行了深入研究,为萜类的合成生物学研究提供了大量的数据支撑。目前,已经通过合成生物学方法构建出萜类高产的酵母工程菌株,实现了多种目标产物的高效生产,有效提高了萜类的总体生产水平。因此,采用合成生物学策略合成萜类化合物,有望成为植物源萜类生产的有效技术手段。首先介绍了合成生物学概念,进而总结了植物源萜类的重要功能和应用领域,并简述了不同萜类的合成途径,归纳了现有的萜类生产方式,然后深入探讨了萜类生物合成的设计策略,最后以几种常见的萜类为例,详细论述了不同萜类的合成生物学的研究进展。     

提高微生物合成萜类化合物产量的策略

萜类化合物种类繁多、结构复杂,在医药、能源等领域具有重要的应用价值。当前萜类化合物主要是从植物中提取或化学法合成,费效比较高,而微生物合成成本低、效率高,更具有发展潜力,但由于萜类代谢通路复杂、微生物自身代谢调控精细以致难以人为操控,多数萜类化合物尚未通过微生物合成获得可观的产量。对此,对提高微生物合成萜类化合物的策略进行综述,旨在为萜类化合物在微生物中的生产与研究提供参考。     

植物源二萜类化合物微生物合成研究进展

植物源二萜类天然产物结构复杂且功能多样,具有抗癌、抗炎和抗菌等多种药理活性,在药品、化妆品和食品添加剂等方面广泛应用。近年来,基于植物源二萜类化合物(diterpenoids)生物合成途径中功能基因的逐步揭示和合成生物技术的发展,科研人员采用代谢工程技术构建了多种二萜类化合物的微生物细胞工厂,且多个化合物达到克级产量。本文对植物源二萜类化合物微生物细胞工厂的构建情况进行综述,介绍并探讨植物源二萜类化合物微生物合成的研究进展和改造策略,为高产二萜类化合物细胞工厂构建和工业化生产提供参考。     

细胞区室化调控萜类化合物微生物合成

萜类化合物具有抗炎、抗氧化、抑制肿瘤细胞增殖等药学活性,在医药行业应用广泛。近年来,利用微生物合成萜类化合物受到广泛关注。在微生物中高效合成萜类化合物离不开代谢途径的调控与优化,其中细胞区室化是常用的调控策略之一,在微生物细胞工厂的构建中发挥着重要作用。代谢途径的细胞区室化具有许多优点,如增加酶和底物的局部浓度,抑制其向副产物转移和减少有毒中间体积累等,可实现萜类化合物的高效合成。近年来利用细胞区室化在微生物中合成萜类化合物的研究逐步展开,但目前对于区室化工程在构建细胞工厂中的应用总结较少。因此,围绕代谢途径区室化的作用,各种细胞器的生理特性及其在调控萜类化合物微生物合成中的应用进行了综述,讨论细胞区室化调控策略的发展、存在的问题及前景,以期为萜类化合物的高效微生物合成提供参考。     

萜类合成酶定向进化的新思路

萜类化合物是天然产物中种类最多且主要存在于植物和微生物体内的一类化合物。随着越来越多具有应用价值的萜类化合物被挖掘,其应用前景引起了人们的关注,但由于含量低、提取成本高等缺点,因此制约了萜类化合物的广泛应用。合成生物学的兴起,为异源合成具有应用价值的萜类化合物提供了新思路,使构建定向、高效的微生物细胞工厂成为现实。萜类合成酶常作为萜类化合物异源合成代谢调控的靶酶,但天然的萜类合成酶存在催化效率低、底物专一性差、立体/区域选择性差、稳定性差等问题,严重影响萜类化合物的产量。萜类合成酶的定向进化可以有效地解决上述问题,为实现微生物细胞工厂异源、高效合成萜类化合物奠定基础。本文综述了近年来酶的定向进化技术的最新进展及应用,并提出了萜类合成酶定向进化的策略。     

萜类生物合成的基因操作

萜类是一组结构迥异的化合物家族,其中很多具有较大的应用价值,如青蒿素和紫杉醇等,它们在多种微生物和植物中合成,但其天然产量低。萜类代谢工程通过DNA重组技术改造萜类合成细胞中的代谢途径,以提高萜类最终产量或在不含萜类的生物中合成萜类,为促进有用萜类合成提供了新的机会。以萜类化合物生物合成途径的基因转移与表达为切入点,综述了目前在微生物及植物中应用代谢工程提高萜类产量的研究进展。     

甲羟戊酸途径的代谢支路调控策略的研究进展

萜类化合物作为一大类重要天然产物,在食品、化工、医药和能源等领域广泛应用。微生物法合成萜类化合物因具有生产周期较短、可规模化生产等优点,是目前研究的热点。但是生产效率低严重制约着微生物法合成萜类化合物的工业化发展,而代谢调控是解决上述问题的主要有效手段之一。目前,多数学者集中于主路径的代谢调控研究,忽略了对于萜类化合物的生产至关重要的支路径。本文中,笔者围绕支路径调控直接相关的前体物质供应和辅助因子的协调、竞争途径的调控以及间接对代谢调控产生影响的宿主体的进化三个方面,综述萜类化合物甲羟戊酸途径的代谢途径支路调控策略研究进展,并对代谢路径支路调控的发展方向做进一步展望。     

代谢工程改造酿酒酵母合成植物萜类D-柠檬烯的策略

植物萜类化合物是以异戊二烯为结构单位的一大类植物天然的次生代谢产物。D-柠檬烯属于单萜类化合物,由于它具有抑菌、增香、抗癌、止咳、平喘等多种功能,已被广泛应用于食品、香料、医疗等行业。目前D-柠檬烯的工业生产主要是从植物的果皮或者果肉中提取的,但提取方法存在着分离纯化复杂、产率低、能耗大等缺点。而本世纪初合成生物学技术的兴起,为微生物异源合成天然活性化合物带来了全新的理念与工具,打破了物种间的界限,使微生物异源合成D-柠檬烯成为现实。构建定向、高效的异源合成D-柠檬烯的微生物细胞工厂,实现微生物发酵法替换传统的植物提取法,具有重要的经济与社会效益。本文主要回顾了近几年利用代谢工程改造酿酒酵母异源合成萜类化合物取得的成就,阐述了以酿酒酵母作为底盘微生物,利用代谢工程和合成生物学的手段构建高产D-柠檬烯的合成策略。     

Opportunities for yeast metabolic engineering: Lessons from synthetic biology

Constant progress in genetic engineering has given rise to a number of promising areas of research that facilitated the expansion of industrial biotechnology. The field of metabolic engineering, which utilizes genetic tools to manipulate microbial metabolism to enhance the production of compounds of interest, has had a particularly strong impact by providing new platforms for chemical production. Recent developments in synthetic biology promise to expand the metabolic engineering toolbox further by creating novel biological components for pathway design. The present review addresses some of the recent advances in synthetic biology and how these have the potential to affect metabolic engineering in the yeast Saccharomyces cerevisiae. While S. cerevisiae for years has been a robust industrial organism and the target of multiple metabolic engineering trials, its potential for synthetic biology has remained relatively unexplored and further research in this field could strongly contribute to industrial biotechnology. This review also addresses are general considerations for pathway design, ranging from individual components to regulatory systems, overall pathway considerations and whole-organism engineering, with an emphasis on potential contributions of synthetic biology to these areas. Some examples of applications for yeast synthetic biology and metabolic engineering are also discussed.     

Engineering microbial factories for synthesis of value-added products

Microorganisms have become an increasingly important platform for the production of drugs, chemicals, and biofuels from renewable resources. Advances in protein engineering, metabolic engineering, and synthetic biology enable redesigning microbial cellular networks and fine-tuning physiological capabilities, thus generating industrially viable strains for the production of natural and unnatural value-added compounds. In this review, we describe the recent progress on engineering microbial factories for synthesis of valued-added products including alkaloids, terpenoids, flavonoids, polyketides, non-ribosomal peptides, biofuels, and chemicals. Related topics on lignocellulose degradation, sugar utilization, and microbial tolerance improvement will also be discussed.     

2013合成生物学专刊序言

合成生物学目前在全球得到迅猛发展。在此专刊中,综述了一些相关技术在合成生物学领域的进展,其中有:链霉菌无痕敲除方法、基因合成技术、DNA组装新方法、最小化基因组的方法及分析、合成生物系统的组合优化。也讨论了应用合成生物学策略优化光合蓝细菌底盘、产溶剂梭菌分子遗传操作技术、蛋白质预算(Protein budget)作为合成生物学的成本标尺。最后,用几个例子说明了合成生物学的应用,包括复杂天然产物合成人工生物系统的设计与构建、微生物木糖代谢途径改造制备生物基化学品以及构建酿酒酵母工程菌合成香紫苏醇。     

酿酒酵母代谢工程技术

自20世纪90年代初期诞生以来,代谢工程历经了30年的快速发展。作为代谢工程的首选底盘细胞之一,酿酒酵母细胞工厂已被广泛应用于大量大宗化学品和新型高附加值生物活性物质的生物制造,在能源、医药和环境等领域取得了巨大的突破。近年来,合成生物学、生物信息学以及机器学习等相关技术也极大地促进了代谢工程的技术发展和应用。文中回顾了近30年来酿酒酵母代谢工程重要的技术发展,首先总结了经典代谢工程的常用方法和策略,以及在此基础上发展而来的系统代谢工程和合成生物学驱动的代谢工程技术。最后结合最新技术发展趋势,展望了未来酿酒酵母代谢工程发展的新方向。     

Advancing secondary metabolite biosynthesis in yeast with synthetic biology tools

Secondary metabolites are an important source of high-value chemicals, many of which exhibit important pharmacological properties. These valuable natural products are often difficult to synthesize chemically and are commonly isolated through inefficient extractions from natural biological sources. As such, they are increasingly targeted for production by biosynthesis from engineered microorganisms. The budding yeast species Saccharomyces cerevisiae has proven to be a powerful microorganism for heterologous expression of biosynthetic pathways. S. cerevisiae's usefulness as a host organism is owed in large part to the wealth of knowledge accumulated over more than a century of intense scientific study. Yet many challenges are currently faced in engineering yeast strains for the biosynthesis of complex secondary metabolite production. However, synthetic biology is advancing the development of new tools for constructing, controlling, and optimizing complex metabolic pathways in yeast. Here, we review how the coupling between yeast biology and synthetic biology is advancing the use of S. cerevisiae as a microbial host for the construction of secondary metabolic pathways.     

Genetic and metabolic engineering of microorganisms for the development of new flavor compounds from terpenic substrates

Throughout human history, natural products have been the basis for the discovery and development of therapeutics, cosmetic and food compounds used in industry. Many compounds found in natural organisms are rather difficult to chemically synthesize and to extract in large amounts, and in this respect, genetic and metabolic engineering are playing an increasingly important role in the production of these compounds, such as new terpenes and terpenoids, which may potentially be used to create aromas in industry. Terpenes belong to the largest class of natural compounds, are produced by all living organisms and play a fundamental role in human nutrition, cosmetics and medicine. Recent advances in systems biology and synthetic biology are allowing us to perform metabolic engineering at the whole-cell level, thus enabling the optimal design of microorganisms for the efficient production of drugs, cosmetic and food additives. This review describes the recent advances made in the genetic and metabolic engineering of the terpenes pathway with a particular focus on systems biotechnology.     

Perspectives and limits of engineering the isoprenoid metabolism in heterologous hosts

Terpenoids belong to the largest class of natural compounds and are produced in all living organisms. The isoprenoid skeleton is based on assembling of C5 building blocks, but the biosynthesis of a great variety of terpenoids ranging from monoterpenoids to polyterpenoids is not fully understood today. Terpenoids play a fundamental role in human nutrition, cosmetics, and medicine. In the past 10 years, many metabolic engineering efforts have been undertaken in plants but also in microorganisms to improve the production of various terpenoids like artemisinin and paclitaxel. Recently, inverse metabolic engineering and combinatorial biosynthesis as main strategies in synthetic biology have been applied to produce high-cost natural products like artemisinin and paclitaxel in heterologous microorganisms. This review describes the recent progresses made in metabolic engineering of the terpenoid pathway with particular focus on fundamental aspects of host selection, vector design, and system biotechnology.