多学科交叉发酵工程复合型研究生培养

发酵工程是利用对微生物或其他生物细胞进行改造,在特定的生物反应器内,培养生产某种特定产品的工业化生产过程和技术体系。发酵工程从纯粹依赖经验积累的古老的食品发酵,发展成为食品、农业、医药、化工等生产生活资料的重要生产方式,成为支撑人类可持续发展的关键技术,这离不开交叉学科技术的持续进步。多学科融合交叉和我国在全球产业链的不断上移,必然对新形势下发酵工程复合型人才培养提出更高要求。为不断完善多学科交叉的发酵工程复合型人才培养体系,近年来,研究室不断凝练与提升人才培养理念,积极深化人才培养体系改革。围绕培养方案、招生体系、师资背景、课题设置、科研实践、评价体系等方面展开了系统的研究和实践,推动了发酵工程和相关支撑行业的技术进步,为培养具有学科交叉知识的复合型人才,进而为我国从发酵大国向发酵强国的转变贡献了重要力量。     

微生物过氧化氢酶的发酵生产及其在纺织工业的应用

微生物过氧化氢酶是一种重要的工业酶制剂,可以催化分解过氧化氢生成水和氧气。这一酶制剂在食品、纺织、医药等领域表现出广泛的应用潜力。生物工程和基因工程技术的进步推动了微生物过氧化氢酶的发酵生产。以下综述了微生物过氧化氢酶发酵生产的进展及其在纺织工业中的应用,同时讨论了微生物过氧化氢酶的发酵生产和纺织工业应用的未来趋势。     

乳酸乳球菌NZ9000基因组规模代谢网络模型的构建与验证

随着后基因组时代的到来,工业微生物的代谢工程改造在工业生产上发挥着越来越重要的作用。而基因组规模代谢网络模型(Genome-scalemetabolicmodel,GSMM)将生物体体内所有已知代谢信息进行整合,为全局理解生物体的代谢状态、理性指导代谢工程改造提供了最佳的平台。乳酸乳球菌NZ9000(Lactococcuslactis NZ9000)作为工业发酵领域的重要菌株之一,由于其遗传背景清晰且几乎不分泌蛋白,是基因工程改造和外源蛋白表达的理想模式菌株。文中基于基因组功能注释和比较基因组学构建了L.lactisNZ9000的首个基因组规模代谢网络模型iWK557,包含557个基因、668个代谢物、840个反应,并进一步在定性和定量两个层次验证了iWK557的准确性,以期为理性指导L. lactis NZ9000代谢工程改造提供良好工具。     

Recent advances in biological production of erythritol

Erythritol is a natural sweetener commonly used in the food and pharmaceutical industries. Produced by microorganisms as an osmoprotectant, it is an ideal sucrose substitute for diabetics or overweight persons due to its almost zero calorie content. Currently, erythritol is produced on an industrial scale through the fermentation of sugars by some yeasts, such as Moniliella sp. However, the popularity of erythritol as a sweetener is still small because of its high retail price. This creates an opportunity for further process improvement. Recent years have brought the rapid development of erythritol biosynthesis methods from the low-cost substrates, and a better understanding of the metabolic pathways leading to erythritol synthesis. The yeast Yarrowia lipolytica emerges as an organism effectively producing erythritol from pure or crude glycerol. Moreover, novel erythritol producing organisms and substrates may be taken into considerations due to metabolic engineering. This review focuses on the modification of erythritol production to use low-cost substrates and metabolic engineering of the microorganisms in order to improve yield and productivity.     

生物热对传统固态发酵菌群演替及其代谢影响的研究进展

解析传统固态发酵中产生的生物热对微生物菌群代谢的影响,是认识发酵机制、调控发酵过程、保证发酵效率的关键之一。固态发酵过程中,微生物菌群代谢活动所产生的生物热及传热效率低等问题引起微环境温度升高,进而影响微生物的生长与代谢。然而,关于传统固态发酵微生物受生物热的影响及其适应机制仍不明晰。因此,本文以传统固态发酵体系为研究对象,阐述持续生物热介导的高温对固态发酵过程中微生物群落演替和代谢功能的影响,并提出复杂群落中具有多层次调控微生物代谢以适应高温环境的方式,主要从微生物群体与个体层面介绍可能存在的耐热机制。了解生物热对传统固态发酵微生物的影响及潜在的耐热机制,有助于靶向调控发酵过程、强化高温发酵等,以满足未来的工业化需求。     

Microbial production of riboflavin: Biotechnological advances and perspectives

Riboflavin is an essential nutrient for humans and animals, and its derivatives flavin mononucleotide (FMN) and flavin adenine dinucleotide (FAD) are cofactors in the cells. Therefore, riboflavin and its derivatives are widely used in the food, pharmaceutical, nutraceutical and cosmetic industries. Advances in biotechnology have led to a complete shift in the commercial production of riboflavin from chemical synthesis to microbial fermentation. In this review, we provide a comprehensive review of biotechnologies that enhance riboflavin production in microorganisms, as well as representative examples. Firstly, the synthesis pathways and metabolic regulatory processes of riboflavin in microorganisms; and the current strategies and methods of metabolic engineering for riboflavin production are systematically summarized and compared. Secondly, the using of systematic metabolic engineering strategies to enhance riboflavin production is discussed, including laboratory evolution, histological analysis and high-throughput screening. Finally, the challenges for efficient microbial production of riboflavin and the strategies to overcome these challenges are prospected.     

哺乳动物肠道微生物与碳水化合物的互作及其影响

肠道微生物具有调节宿主营养、免疫以及能量代谢等生理功能。饮食是影响哺乳动物的肠道微生物的一个重要因素。碳水化合物是哺乳动物食物能量的主要来源,因此研究肠道微生物与碳水化合物的代谢之间的关系及其影响具有重要意义。基于近年相关研究,本文从碳水化合物对肠道微生物组成的影响、肠道微生物对碳水化合物的代谢机制以及碳水化合物发酵产物短链脂肪酸对宿主的影响3个方面进行了综述。研究表明,肠道微生物可用于发酵的碳水化合物类型主要是抗性淀粉和非淀粉多糖;不同类型的碳水化合物会导致肠道菌群发生适应性变化;复杂多糖发酵产生的短链脂肪酸在调节宿主能量平衡和免疫应答方面发挥了重要作用。总结近年来相关研究,可加深对肠道菌群对宿主碳水化合物代谢贡献的理解,为哺乳动物机体健康状况的营养调控策略提供参考。     

Biotechnological production of enantiomeric pure lactic acid from renewable resources: recent achievements, perspectives, and limits

Lactic acid (LA) is an important and versatile chemical that can be produced from renewable resources such as biomass. LA is used in the food, pharmaceutical, and polymers industries and is produced by microorganism fermentation; however, most microorganisms cannot directly utilize biomass such as starchy materials and cellulose. Here, we summarize LA production using several kinds of genetically modified microorganisms, such as LA bacteria, Escherichia coli, Corynebacterium glutamicum, and yeast. Using gene manipulation and metabolic engineering, the yield and optical purity of LA produced from biomass has been significantly improved. In this review, the drawbacks as well as improvements of LA production by fermentation is discussed.     

高通量测序技术在食品微生物研究中的应用

高通量测序技术的快速发展对食品微生物发酵过程和机制研究产生了深刻的影响,主要体现在食品微生物生理功能、代谢能力和进化的研究以及食品微生物群落结构、动态变化及其对环境的响应机制等方面。另外,通过对食品微生物基因组和元基因组进行数据分析,也对食品发酵过程优化、微生物功能改造、食源性微生物疾病预防和控制等提供了重要的依据。本文总结了近年来利用高通量测序技术对食品微生物基因组和元基因组进行测序的研究,并探讨了测序技术的发展对食品微生物研究的影响及发展趋势。     

组学技术在产油微生物中的应用

微生物油脂是未来燃料和食品用油的重要潜在资源。近年来,随着系统生物学技术的快速发展,从全局角度理解产油微生物生理代谢及脂质积累的特征成为研究热点。组学技术作为系统生物学研究的重要工具被广泛用于揭示产油微生物脂质高效生产的机制研究中,这为产油微生物理性遗传改造和发酵过程控制提供了基础。文中对组学技术在产油微生物中的应用概况进行了综述,介绍了产油微生物组学分析常用的样品前处理及数据分析方法,综述了包括基因组、转录组、蛋白(修饰)组及代谢(脂质)组等在内的多种组学技术,以及组学数据基础上的数学模型在揭示产油微生物脂质高效生产机制中的研究,并对未来发展和应用进行了展望。     

Metabolic engineering of lactic acid bacteria: overview of the approaches and results of pathway rerouting involved in food fermentations.

Lactic acid bacteria such as Lactococcus lactis are the microorganisms of choice for performing metabolic engineering in relation to food fermentation. These bacteria are used extensively in food fermentations, they have a simple and therefore controllable metabolism and the molecular genetics of these food bacteria is well-developed. There have been recent successes in metabolic engineering in these lactic acid bacteria, including examples of changes in both primary metabolism (diacetyl and alanine) and secondary metabolism (exopolysaccharides and flavour).     

Genetic and metabolic engineering of isoflavonoid biosynthesis

Isoflavonoids are a diverse group of secondary metabolites derived from the phenylpropanoid pathway. These compounds are distributed predominantly in leguminous plants and play important roles in plant–environment interactions and human health. Consequently, the biosynthetic pathway of isoflavonoid compounds has been widely elucidated in the past decades. Up to now, most of the structural genes and some of the regulatory genes involved in this pathway have been isolated and well characterized. Nowadays, the protective effects of the legume isoflavonoids against hormone dependent cancers, cardiovascular disease, osteoporosis, and menopausal symptoms have generated considerable interest within the genetic and metabolic engineering fields to enhance the dietary intake of these compounds for disease prevention. Subsequently, there are some great progresses in genetic and metabolic engineering to improve their yields in leguminous and non-leguminous plants and/or microorganisms. Because of the field of flavonoid biosynthesis has been reviewed fairly extensively in the past, this review concentrates on the more recent development in the isoflavonoid branch of phenylpropanoid pathway, including gene isolation and characterization. In addition, we describe the state-of-the-art research with respect to genetic and metabolic engineering of isoflavonoid biosynthesis.     

萜烯生物合成中关键酶的研究进展*

萜烯类化合物是一类高度多样化的天然产物,具有抗肿瘤、抗氧化及免疫调节等生理活性,因此被广泛应用于医药健康、食品、化妆品领域。然而,直接从自然资源中获取萜烯类化合物效率低、成本高,且往往对生态环境产生不利影响,不能实现绿色可持续生产。微生物合成萜烯类化合物近年来备受关注,研究人员从合成途径的构建与调控、关键酶的理性及半理性改造、发酵工艺优化等多个方面进行了探究,取得了丰硕的成果。其中,合成途径中关键酶的催化效率是影响微生物生产萜烯类化合物的重要因素。针对关键酶的研究对于提高微生物合成萜烯类化合物的能力,推动该类天然产物微生物生产的大规模应用具有重要意义。对萜烯类化合物合成途径中的3-羟基-3-甲基戊二酰辅酶A还原酶(HMGR)、1-脱氧-D-木酮糖-5-磷酸合酶(DXS)、异戊二烯基二磷酸合成酶(IDS)和萜烯合酶(TPS)4种关键酶的研究进行了综述,并总结讨论了如何通过代谢工程和蛋白质工程手段以及合成生物学技术调节关键酶的催化活性,提高微生物合成萜烯类化合物的效率,对未来利用微生物合成萜烯类化合物的发展进行了展望。     

Factors affecting the competitiveness of bacterial fermentation

Sustainable production of chemicals and materials from renewable non-food biomass using biorefineries has become increasingly important in an effort toward the vision of ‘net zero carbon’ that has recently been pledged by countries around the world. Systems metabolic engineering has allowed the efficient development of microbial strains overproducing an increasing number of chemicals and materials, some of which have been translated to industrial-scale production. Fermentation is one of the key processes determining the overall economics of bioprocesses, but has recently been attracting less research attention. In this Review, we revisit and discuss factors affecting the competitiveness of bacterial fermentation in connection to strain development by systems metabolic engineering. Future perspectives for developing efficient fermentation processes are also discussed.     

L-苯丙氨酸生产的代谢工程研究

L-苯丙氨酸是一种重要的食品和医药中间体。工业上一般采用酶法和发酵法来生产L-苯丙氨酸。代谢工程的兴起,使得更加理性的改造菌株成为可能,这更加促进了发酵法的广泛应用。主要介绍了代谢工程在L-苯丙氨酸生产菌的改造中的应用情况,其中涉及苯丙氨酸生物合成途径中相关基因及其酶的调控、中央代谢途径的改造和芳香族氨基酸生物合成支路的修饰。并探讨了将来的发展前景。     

Sugar transporters in efficient utilization of mixed sugar substrates: current knowledge and outlook

There is increasing interest in production of transportation fuels and commodity chemicals from lignocellulosic biomass, most desirably through biological fermentation. Considerable effort has been expended to develop efficient biocatalysts that convert sugars derived from lignocellulose directly to value-added products. Glucose, the building block of cellulose, is the most suitable fermentation substrate for industrial microorganisms such as Escherichia coli, Corynebacterium glutamicum, and Saccharomyces cerevisiae. Other sugars including xylose, arabinose, mannose, and galactose that comprise hemicellulose are generally less efficient substrates in terms of productivity and yield. Although metabolic engineering including introduction of functional pentose-metabolizing pathways into pentose-incompetent microorganisms has provided steady progress in pentose utilization, further improvements in sugar mixture utilization by microorganisms is necessary. Among a variety of issues on utilization of sugar mixtures by the microorganisms, recent studies have started to reveal the importance of sugar transporters in microbial fermentation performance. In this article, we review current knowledge on diversity and functions of sugar transporters, especially those associated with pentose uptake in microorganisms. Subsequently, we review and discuss recent studies on engineering of sugar transport as a driving force for efficient bioconversion of sugar mixtures derived from lignocellulose.     

Fermentation for future food systems: Precision fermentation can complement the scope and applications of traditional fermentation

Modern biotechnology holds great potential for expanding the scope of fermentation to create novel foods and improve the sustainability of food production.

The growing human population and global warming pose an impending threat for global food security (Linder, 2019). This has prompted a critical re‐examination of the food supply chain from producers to consumers in order to increase the overall efficiency of food production, storage and transport. Much research in plant science consequently aims to increase production with new, high‐yield crop, fruit and vegetable varieties better adapted to changing climatic conditions. Yet, there is also much room for improving food safety by minimising food losses and recycling waste, valorising by‐products, improving nutritional value and increasing storage time. This is where fermentation comes in as a cost‐efficient, versatile and proven technology that extends the shelf life of food products and enhances their nutritional content. Moreover, there is enormous potential in fermentation to further increase efficiency and product range and even create new food products from non‐food biomass.

… there is enormous potential in fermentation to further increase efficiency and product range and even create new food products from non‐food biomass.

In a broader sense, fermentation can be defined as the cultivation of microorganisms such as bacteria, yeasts and fungi to break down complex molecules into simpler ones, notably organic acids, alcohols or esters. In a practical sense, it is one of the oldest food processing technologies to increase storage life along with cooking, smoking or air‐drying: fermentation was already fully industrialised for producing beer and bread millennia ago in ancient Mesopotamia and Egypt. It is also an elegant and simple technology as these microorganisms do most of the work without much human involvement.Louis Pasteur’s discovery that microorganisms cause fermentation laid the basis for further improvement of the technology from traditional spontaneous fermentation to the use of defined starter cultures. Fermentation is now widely used to produce alcoholic beverages, bread and pastry, dairy products, pickled vegetables, soy sauce and so on. More recent advances based on genomics and synthetic biology include precision and biomass fermentation to produce specific compounds for the food and chemical industry or medicinal use. This is not the limit though: when combined with genomics, fermentation has even greater potential for creating novel foods and other products.     

工业微生物遗传和环境扰动的调控和适应进化

开发工业微生物,使其利用可再生的原料生产生物燃料、大宗化学品、食品添加剂和营养品、药物以及工业酶等,是发展生物产业的基础。工业微生物高产和胁迫抗性等鲁棒性状受复杂遗传调控网络控制,其改造需要从全基因组尺度进行系统的全局的多位点的扰动,以达到快速积累多样性基因型突变并产生所期望的表型。文中对工业微生物鲁棒性状的遗传调控与胁迫响应机制、基因组全局扰动与多位点快速进化以及细胞水平氧还平衡的全局扰动进行了简要综述,未来需要继续借助系统生物学和合成生物学手段,进一步加强对工业环境下工业微生物鲁棒性状调控机理的解析与建模预测以及系统的工程改造。