《生物工程学报》2010年“代谢工程”专刊征稿通知

<正>代谢工程自1991年诞生以来,在改造植物、动物、微生物的代谢功能方面得到了广泛的应用。为了展现代谢工程科研工作者取得的最新进展,促进我国代谢工程研究的进步和发展,本刊2009年第9期设立了"代谢工程与细胞工厂"专栏,国内     

《生物工程学报》2010年“代谢工程”专刊征稿通知

<正>代谢工程自1991年诞生以来,在改造植物、动物、微生物的代谢功能方面得到了广泛的应用。为了展现代谢工程科研工作者取得的最新进展,促进我国代谢工程研究的进步和发展,本刊2009年第9期设立了"代谢工     

柠檬烯和红没药烯的微生物代谢工程

柠檬烯和红没药烯均为植物天然产物,分别属于单萜类和倍半萜类化合物,能够预防和治疗癌症等多种疾病。以其作为前体物,还可以转化合成多种具有高附加值的工业产品,例如药品、保健品、化妆品及生物燃料等。目前柠檬烯和红没药烯的工业生产主要是通过植物提取法实现的,但从植物组织中提取柠檬烯和红没药烯存在着产物含量低和分离纯化困难等缺点。微生物代谢工程的快速发展为这些植物天然产物的生产提供了一条更具潜力的生物合成路线。利用微生物代谢工程技术构建生产这些有价值的植物天然产物的微生物细胞工厂具有绿色清洁、可持续发展和经济效益好等独特优势。文中系统综述了近年来代谢工程技术在微生物合成柠檬烯和红没药烯过程中的应用进展,包括所涉及的宿主菌株、关键酶、代谢途径及其改造等,并探讨了其未来发展方向。     

《生物工程学报》2010年“代谢工程”专刊征稿通知

<正>代谢工程自1991年诞生以来,在改造植物、动物、微生物的代谢功能方面得到了广泛的应用。为了展现代谢工程科研工作者取得的最新进展,促进我国代谢工程研究的进步和发展,本刊2009年第9期设立了"代谢工程与细胞工厂"专栏,国内该领域著名学者对代谢工程的技术发展进行了总结,介绍了合成生物学等新理论和新技术,并发表了     

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。     

微生物合成黄酮糖苷类天然产物研究进展

黄酮糖苷类天然产物是植物中黄酮类化合物的主要存在形式,通过糖基化修饰,可以改变其水溶性、稳定性等,赋予其新的生物活性和功能。黄酮类化合物的糖基化修饰通常由植物源或微生物源的糖基转移酶催化,根据糖基的位置、类型和数量的不同,可形成多种类型的黄酮糖苷类产物。随着合成生物学和代谢工程的快速发展,在微生物中合成植物源黄酮糖苷类天然产物取得了重要进展。综述了糖基转移酶的聚类分析及糖基供体的途径改造,并对代谢工程优化黄酮糖苷类天然产物的微生物合成进行了分析讨论,并对其发展前景进行了展望。     

植物糖基转移酶及其在代谢工程中的应用

糖基转移酶催化植物次生代谢物合成,在植物的生长发育过程以及代谢工程应用方面起着重要作用。该文介绍糖基转移酶的基本特性,总结近年来研究植物糖基转移酶基因的克隆与功能分析的方法,详细阐述了微生物中3个C-糖基转移酶基因（UrdGT2、gilGT和iroA）的克隆和功能研究,概括糖基转移酶在代谢工程的研究进展,并展望今后的研究趋势,为植物C-糖基转移酶的生物学功能研究和代谢应用方面提供有益帮助。     

《生物工程学报》“代谢工程和细胞工厂”专刊征稿通知

代谢工程自1991年诞生以来,倍受科研工作者的关注,成为研究热点。随着生物技术的发展,代谢工程作为一门改善细胞性能的新兴学科,在植物、动物、微生物乃至人体组织细胞的基因治疗及代谢分析方面得到了广     

《生物工程学报》“代谢工程和细胞工厂”专刊征稿通知

代谢工程自1991年诞生以来,倍受科研工作者的关注,成为研究热点。随着生物技术的发展,代谢工程作为一门改善细胞性能的新兴学科,在植物、动物、微生物乃至人体组织细胞的基因治疗及代谢分析方面得到了广     

丝状真菌代谢工程研究进展

丝状真菌(Filamentous fungi)作为重要的工业发酵微生物,在有机酸、蛋白质及次级代谢产物等关键生物基产品生产方面发挥着重要作用。自20世纪90年代代谢工程理念提出以来,尤其是代谢工程使能技术的创新及发展,极大地促进了丝状真菌细胞工厂的构建及其在工业发酵领域的应用。文中将系统介绍近年来丝状真菌代谢工程技术的发展,及其在生物基化学品细胞工厂构建中的应用,最后讨论丝状真菌代谢工程中关键问题并展望其未来发展。     

Microbiological production of tocopherols: current state and prospects

Tocopherols are antioxidants that prevent various diseases caused by oxidative stress. Tocochromanols comprise four isoforms of tocopherols and four isoforms of tocotrienols but α-tocopherol is the most abundant and active isoform in human and animal tissues. Tocopherols are used as dietary supplements for human, as food preservatives, in manufacture of cosmetics, and for fortification of animal feed. Only photosynthetic cells are known to accumulate detectable concentrations of tocopherols. Tocopherols can be extracted and purified or concentrated from vegetable oils and other higher plant materials. However, the concentrations in these higher plant materials are very low and there are high proportions of the less-active homologues of tocopherols. Among the many strains of photosynthetic microorganisms known to accumulate tocopherols, Euglena gracilis is promising for commercial production of α-tocopherol. The growth rate and α-tocopherol contents are relatively high and α-tocopherol comprise more than 97% of all the tocopherols accumulated by Euglena gracilis. Although a lot of work has been done to increase the contents and composition of tocopherols in higher plants through genetic and metabolic engineering, work on genetic modification of microorganisms for increased tocopherol accumulation is scarce. Many cultivation systems have been investigated for efficient production of tocopherol by Euglena gracilis. However, those that involve heterotrophic metabolism are more promising. Bubble columns and flat-plate photobioreactors are more suitable for commercial production of tocopherols, than the tubular, internally illuminated, and open-air photobioreactors.     

抗菌肽Cecropin及其在转基因植物抗菌中的应用

Cecropin抗菌肽,又名天蚕素,是一类具有抗菌能力的小分子多肽,热稳定性好,抗菌谱广,在各个应用领域已经得到广泛的研究。本文就Cecropin抗菌肽结构与功能的关系、作用机制和其在转基因植物抗菌领域中的应用进行综述,转基因植物表达Cecropin抗菌肽具有应用优势和实用价值,Cecropin抗菌肽分子结构与作用机制探索的深入能进一步促进转基因植物抗菌研究的发展。     

Metabolic engineering of flavonoids in plants and microorganisms

Over 9,000 flavonoid compounds have been found in various plants, comprising one of the largest families of natural products. Flavonoids are an essential factor in plant interactions with the environment, often serving as the first line of defense against UV irradiation and pathogen attacks. Flavonoids are also major nutritional compounds in foods and beverages, with demonstrated health benefits. Some flavonoids are potent antioxidants, and specific flavonoid compounds are beneficial in many physiological and pharmacological processes. Therefore, engineering of flavonoid biosynthesis in plants or in microorganisms has significant scientific and economical importance. Construction of biosynthetic pathways in heterologous systems offers promising results for large-scale flavonoid production by fermentation or bioconversion. Genomics and metabolomics now offer unprecedented tools for detailed understanding of the engineered transgenic organism and for developing novel technologies to further increase flavonoid production yields. We summarize some of the recent metabolic engineering strategies in plants and microorganisms, with a focus on applications of metabolic flux analysis. We are confident that these engineering approaches will lead to successful industrial flavonoid production in the near future.     

Genetically modified crops: environmental and human health concerns

About 10,000 years ago subsistence farmers started to domesticate plants and it was only much later, after the discovery of the fundaments of genetics, those organisms were submitted to rational genetic improvement mainly by selecting of traits of interest. Breeders used appropriate gene combinations to produce new animal races, plant varieties and hybrids, as well as improved microorganisms such as yeasts. After the introduction of recombinant DNA techniques, the transfer of DNA between species belonging to different genera, families or kingdoms became possible. The release of transgenic plants has aroused debates about several aspects of the environmental and human risks that could result from the introduction of genetically modified crops. Less effort has been dedicated to evaluate the impact of transgenic plants on their associated microorganisms, some of which (e.g. nitrogen-fixing bacteria, mycorrhizal fungi and endophytic microbiota) are extremely important for the survival of the plant. Investigations have been made regarding the horizontal transfer of genetic material between transgenic plants and microorganisms and on the disturbance of useful symbiotic associations between plants and endophytic, epiphytic and rhizosphere communities. In most cases the results do no show any adverse effect of transgenic plants on autochthonous plant-associated microorganisms. Results from our laboratory show small changes caused by genetically modified endophytic bacteria on the indigenous endophytic population of the sweet orange Citrus sinensis. In tests using appropriated fungal strains preliminary results using extracts from transgenic plants indicate that these plants do not affect haploidization, mitotic crossing-over, mutation rate or chromosomal alterations.     

Signal Molecules of Plant-Inducers of Gene Expression of Bacteria

In process of the inter action between plants and microorganisms, microorganisms can take specific compound released by plants as chemical signal. The signal is soon effective on microorganisms. Therefore, the microorganism produce gene expression which is nece. ssary in order to attack host plants. Since Stachel (1985) first reported that acetosyringone and α-hydroxyace- tosyringone contained in percolating substance of wound cells in tobacco roots could activate toxic genes (vir), the conception, that signal molecules of the plant act as inducers of gene expression, has been suggested. Recent research advances on this field mentioned above have been summerized in present paper.     

强化产电微生物与电极间电子传递速率的研究进展

产电微生物是微生物燃料电池、电解池和电合成等微生物电化学技术(Microbial electrochemical technologies,METs)的研究基础。产电微生物与电极界面间的胞外电子传递(Extracellular electron transfer,EET)效率低以及生物被膜形成能力弱限制了METs在有机物降解、电能生产、海水淡化、生物修复和生物传感等方面的应用。因此,强化产电微生物与电极界面间的相互作用是过去几年的主要研究热点。针对近年的研究,本文系统概述了通过改造产电微生物来增强微生物-电极间相互作用的各种策略,重点分析了这些策略的适用性和局限性,并展望了强化产电微生物-电极界面作用在微生物电化学技术利用方面的研究前景。     

The obtainment and characteristics of <Emphasis Type="Italic">Kalanchoe pinnata</Emphasis> L. plants expressing the artificial gene of the cecropin P1 antimicrobial peptide

Kalanchoe pinnata L. plants bearing an artificial CP1 gene encoding the cecropin P1 antimicrobial peptide have been obtained. The presence of the CP1 gene in the plant genome has been confirmed by PCR. Cecropin P1 synthesis in transgenic plants has been shown by MALDI mass spectrometry and Western blotting. The obtained plants have been highly resistant to bacterial and fungal phytopathogens, and their extracts have demonstrated antimicrobial activity towards human and animal pathogens. It has been shown that transgenic plants bearing the CP1 gene can be colonized by the beneficial associative microorganisms Methylovorus mays.     

Metabolic engineering towards biotechnological production of carotenoids in microorganisms

Carotenoids are important natural pigments produced by many microorganisms and plants. Traditionally, carotenoids have been used in the feed, food and nutraceutical industries. The recent discoveries of health-related beneficial properties attributed to carotenoids have spurred great interest in the production of structurally diverse carotenoids for pharmaceutical applications. The availability of a considerable number of microbial and plant carotenoid genes that can be functionally expressed in heterologous hosts has opened ways for the production of diverse carotenoid compounds in heterologous systems. In this review, we will describe the recent progress made in metabolic engineering of non-carotenogenic microorganisms for improved carotenoid productivity. In addition, we will discuss the application of combinatorial and evolutionary strategies to carotenoid pathway engineering to broaden the diversity of carotenoid structures synthesized in recombinant hosts.