Engineering chloroplasts: an alternative site for foreign genes, proteins, reactions and products

Plant genetic engineering via the nucleus is a mature technology that has been used very productively for research and commercial biotechnology. By contrast, the ability to introduce foreign genes at specific locations on a chloroplast's chromosome has been acquired relatively recently. Certain limitations of nuclear genome transformation methods might be overcome by the site-specific introduction of genes into plastid chromosomes. In addition, plastids, mitochondria and other subcellular organelles might provide more favorable environments than the nuclear-cytoplasmic compartment for certain biochemical reactions and for accumulating large amounts of some gene and enzyme products.     

乳酸菌食品级表达载体的研究与应用

乳酸菌是能够发酵糖类产生大量有机酸的革兰氏阳性菌的通称,在发酵食品中有着悠久的应用历史。乳酸菌通常被认为是安全菌株,这些微生物的基因工程操作在食品、医学等方面具有广阔的应用前景。表达载体是基因工程中常用的工具之一,大多数乳酸菌的表达载体通常以抗生素抗性基因作为选择标记,然而抗性基因具有潜在的转移性,因此需要开发食品级表达载体。食品级表达载体不含有抗生素的抗性基因,仅包含来自同源宿主或通常被认为是安全生物的DNA。本文介绍了乳酸菌食品级表达载体的构成及其常用宿主,同时对乳酸菌食品级表达载体的应用进行了归纳总结。     

Understanding and engineering of microbial cells based on proteomics and its conjunction with other omics studies

The abilities of microorganisms to produce a wide variety of products ranging from human therapeutics to chemicals and to tolerate or detoxify exogenous stresses such as toxic compounds and pollutants are of great importance in fundamental and applied research. Proteomics has become an indispensable tool for large-scale protein analyses and can be used to understand the resulting physiological changes and uncover the mechanisms responsible for the cellular processes under various genetic and environmental conditions. Recent development of a multi-omic approach that combines proteomics with one or more of other omics is allowing us to better understand cellular physiology and metabolism at the systems-wide level, and consequently paving a way toward more efficient metabolic engineering. In this review, we describe the use of proteomics and its combination with other omics to broaden our knowledge on microorganisms in the field of bioscience and biotechnology. With the increasing interest in practical applications, the strategies of employing proteomics for the successful metabolic engineering of microorganisms toward the enhanced production of desired products as well as the approaches taken to identify novel bacterial components are reviewed with corresponding examples.     

酵母生物多样性开发及工业应用

酵母是一类包括酿酒酵母和非常规酵母在内的多种单细胞真菌的总称,其中酿酒酵母是应用较多的重要工业微生物,广泛应用于生物医药、食品、轻工和生物燃料生产等不同生物制造领域。近年来,研究者从不同生态环境中分离了大量的酵母菌株,鉴定了多个新种,也发现了抗逆性不同以及具有多种活性产物合成能力的菌株,证明天然酵母资源具有丰富的生物多样性和功能多样性。利用基因组挖掘以及转录组、蛋白组等多组学分析研究,可进一步开发利用酵母遗传多样性,获得酶和调节蛋白的基因以及启动子等遗传元件改造酵母菌株。除了利用酵母的天然遗传多样性,还可通过诱变、驯化、代谢工程改造及合成生物学等技术产生具有多种非天然多样性的菌株。此外,对天然遗传元件也可以进行突变和定向进化,所产生的新遗传元件可用于有效提升菌株的性能。开发利用酵母的生物多样性,对构建高效酵母细胞工厂,生产生物酶、疫苗以及多种活性天然产物等产品具有重要意义。文中对酵母生物多样性的研究现状进行综述,并对未来高效开发利用酵母菌株资源和遗传资源的研究进行了展望。文中所总结的研究方法和思路也可为研究其他工业微生物的多样性及进行高效菌株的选育提供参考。     

The origin of DNA:RNA hybridization

Conclusions Besides its use in basic research, the DNA:RNA hybridization technique has helped the development of genetic engineering: it is instrumental in the isolation of specific genes that can be inserted into foreign cells, thus modifying their genetic information. Plants, animals, and microorganisms can now be altered to yield improved crops, pest-resistant plants, and a cheaper source of important proteins or drugs. The social relevance of genetic engineering received official sanction in 1980 when the U.S. Supreme Court ruled that genetically modified organisms can be patented. In this article I have tried to describe the discovery of the DNA:RNA hybridization technique as the successful outcome of years of intelligent and patient research in many laboratories, of inductive and deductive processes in the minds of many biologists. The synthesis that led to the final result and to the early development of the technique was made possible by the coming together of two brilliant scientists, Sol Spiegelman and Benjamin Hall.     

Biodegradation of phenol and its derivatives by engineered bacteria: current knowledge and perspectives

Biodegradation of phenolic compounds is a promising alternative to physical and chemical methods used to remove these toxic pollutants from the environment. The ability of various microorganisms to metabolize phenol and its derivatives (alkylphenols, nitrophenols and halogenated derivatives) has therefore been intensively studied. Knowledge of the enzymes catalyzing the individual reactions, the genes encoding these enzymes and the regulatory mechanisms involved in the expression of the respective genes in bacteria serves as a basis for the development of more efficient degraders of phenols via genetic engineering methods. Engineered bacteria which efficiently degrade phenolic compounds were constructed in laboratories using various approaches such as cloning the catabolic genes in multicopy plasmids, the introduction of heterologous genes or broadening the substrate range of key enzymes by mutagenesis. Efforts to apply the engineered strains in in situ bioremediation are problematic, since engineered strains often do not compete successfully with indigenous microorganisms. New efficient degraders of phenolic compounds may be obtained by complex approaches at the organism level, such as genome shuffling or adaptive evolution. The application of these engineered bacteria for bioremediation will require even more complex analysis of both the biological characteristics of the degraders and the physico-chemical conditions at the polluted sites.     

Radical-generating coordination complexes as tools for rapid and effective fragmentation and fluorescent labeling of nucleic acids for microchip hybridization

DNA microchip technology is a rapid, high-throughput method for nucleic acid hybridization reactions. This technology requires random fragmentation and fluorescent labeling of target nucleic acids prior to hybridization. Radical-generating coordination complexes, such as 1,10-phenanthroline-Cu(II) (OP-Cu) and Fe(II)-EDTA (Fe-EDTA), have been commonly used as sequence nonspecific "chemical nucleases" to introduce single-strand breaks in nucleic acids. Here we describe a new method based on these radical-generating complexes for random fragmentation and labeling of both single- and double-stranded forms of RNA and DNA. Nucleic acids labeled with the OP-Cu and the Fe-EDTA protocols revealed high hybridization specificity in hybridization with DNA microchips containing oligonucleotide probes selected for identification of 16S rRNA sequences of the Bacillus group microorganisms.We also demonstrated cDNA- and cRNA-labeling and fragmentation with this method. Both the OP-Cu and Fe-EDTA fragmentation and labeling procedures are quick and inexpensive compared to other commonly used methods. A column-based version of the described method does not require centrifugation and therefore is promising for the automation of sample preparations in DNA microchip technology as well as in other nucleic acid hybridization studies.     

Growing Phototrophic Cells without Light

Many phototrophic microorganisms contain large quantities of high-value products such as n-3 polyunsaturated fatty acids and carotenoids but phototrophic growth is often slow due to light limitation. Some phototrophic microorganisms can also grow on cheap organic substrate heterotrophically. Heterotrophic cultivation can be well controlled and provides the possibility to achieve fast growth and high yield of valuable products on a large scale. Several strategies have been investigated for cultivation of phototrophic microorganisms without light. These include trophic conversion of obligate photoautotrophic microorganisms by genetic engineering, development of efficient cultivation systems and optimization of culture conditions. This paper reviews recent advances in heterotrophic cultivation of phototrophic cells with an emphasis on microalgae.     

益生菌的功能基因导入和基因编辑

益生菌已经在临床和食品领域应用多年,其安全性和有效性已经获得人们的认可。随着分子生物学技术的发展,采用益生菌作为载体进行基因导入或基因编辑,这些遗传改造的益生菌一部分已经作为新的药品或疫苗进入到临床应用阶段。携带功能基因的益生菌定殖于肠道进行表达和缓慢释放,这类益生菌作为活体药物获得益生菌和功能基因的双重功效,可用于治疗某些疑难病症。携带蛋白质抗原基因的益生菌定殖于肠道进行表达,可诱导肠道黏膜免疫、细胞免疫和体液免疫,这是一条更安全的口服疫苗途径。成簇的规则间隔短回文重复序列(clustered regularly interspaced short palindromic repeats, CRISPR)及其相关蛋白(CRISPR-associated protein, Cas)以其高效与便捷性推动了益生菌基因编辑的发展。这篇综述介绍了CRISPR-Cas9操作系统在益生菌方面的应用。对传统遗传操作较难的益生菌采用CRISPR-Cas9技术进行基因编辑,使其基因敲除和基因突变,基因敲入和基因调控等更为简单、高效和易操作。这些CRISPR/Cas9、CRISPRa和CRISPRi技术在...     

Suppression Subtractive Hybridization (SSH) and its modifications in microbiological research

Suppression subtractive hybridization (SSH) is an effective approach to identify the genes that vary in expression levels during different biological processes. It is often used in higher eukaryotes to study the molecular regulation in complex pathogenic progress, such as tumorigenesis and other chronic multigene-associated diseases. Because microbes have relatively smaller genomes compared with eukaryotes, aside from the analysis at the mRNA level, SSH as well as its modifications have been further employed to isolate specific chromosomal locus, study genomic diversity related with exceptional bacterial secondary metabolisms or genes with special microbial function. This review introduces the SSH and its associated methods and focus on their applications to detect specific functional genes or DNA markers in microorganisms.     

工业生物技术专刊序言

以生物催化和生物转化为核心的工业生物技术是实现社会和经济可持续发展的有效手段。本期专刊分别从基因工程、代谢工程与合成生物学、生理工程、发酵工程与生化工程、生物催化与生物转化、生物技术与方法等方面,介绍了我国在工业生物技术领域的最新研究进展。     

有机磷农药降解菌及其基因工程研究新进展

有机磷农药是目前我国使用量最大的农药,对农业的发展有重要的作用,但同时造成了严重的环境污染.利用微生物及其产生的降解酶来降解农药是行之有效的方法.随着分子生物学技术的深入利用,农药的微生物降解已在基因工程领域取得了很大进展.本文综述了有机磷农药降解微生物的筛选、降解酶和基因的克隆、基因工程菌的构建以及应用等几个方面的研究进展.     

The use of genetic probes to detect microorganisms in biomining operations

Summary Microorganisms are currently used for the recovery of copper from mining dumps of low-grade ore. One of the most important microorganisms involved in copper-solubilization isThiobacillus ferrooxidans, although many other microbial genera are also thought to be implicated. A mining dump poses some special problems for the industrial microbiologist because it represents a non-sterile and heterogeneous substrate. Consequently, to enhance our knowledge of the role of microorganisms in metal recovery we must identify the indigenous microorganisms and understand their respective contributions to the process. In addition, when a superior strain of microorganism is developed in the laboratory, by genetic engineering or by other means, we must have a method to evaluate the maintenance of such a strain in the mining dump. In this paper, we describe DNA homology studies, using dot blot and Southern blot analysis of hybridizations of both whole genomic DNA and cloned DNA sequences, to identify and enumerate several bioleaching microorganisms. We demonstrate that it is possible to identify different species of microorganisms and, in one case, to discriminate between different strains of a single species. It is also possible to identify and quantitate certain species in a mixed culture. DNA hybridization analysis has several advantages over the more conventional bacteriological methods of identification, especially in a complex bioleaching situation.     

Quality control of biotechnology-derived vaccines: technical and regulatory considerations

Vaccines for human use have been produced for decades using classical manufacturing methods including culture of viruses and bacteria followed by various concentration-, inactivation-, detoxification-, conjugation production processes. Availability of techniques for molecular biology and for the complete chemical synthesis of genes provides prospects of genetic engineering of microorganisms so as to generate novel biotechnological/biological-derived vaccines. The potential large-scale availability of biotechnology-derived vaccines makes feasible their evaluation in the prevention and/or treatment of various infectious, chronic, degenerative and cancer human diseases. There are potential safety concerns that arise from the novel manufacturing processes and from the complex structural and biological characteristics of the products. These products have distinguishing characteristics to which consideration should be given in a well-defined quality control testing programme. The evaluation of their quality, safety, efficacy and stability necessitate complex analytical methods and appropriate physicochemical, biochemical and immunochemical methods for the analysis of the molecular entity. A flexible approach to the control of these novel products is being developed by regulatory authorities so that recommendations can be modified in the light of experience of research and development in vaccinology, production and use of biotechnology products and with the further development of new technologies.     

花色改造基因工程

自1987年世界首例成功运用转基因技术改造矮牵牛花色以来,花色改造基因工程技术不断展现它在培育新花色品系上的无穷魅力。介绍了近年来运用基因工程技术成功改造花色的3种主要策略:(1)采用反义RNA及共抑制的方法来改变花颜色的深浅;(2)通过导入新基因产生新奇花色;(3)利用转座子构建特殊表达载体,随机激活花色合成的基因来产生嵌合花色。此外,还对转基因株花色不稳定原因进行了讨论。     

Adaptive laboratory evolution--harnessing the power of biology for metabolic engineering

Adaptive laboratory evolution (ALE) strategies allow for the metabolic engineering of microorganisms by combining genetic variation with the selection of beneficial mutations in an unbiased fashion. These ALE strategies have been proven highly effective in the optimization of production strains. In contrast to rational engineering strategies and directed modification of specific enzymes, ALE has the advantage of letting nonintuitive beneficial mutations occur in many different genes and regulatory regions in parallel. So far, the majority of applications of ALE in metabolic engineering have used well-characterized platform organisms such as Saccharomyces cerevisiae and Escherichia coli; however, applications for other microorganisms are on the rise. This review will focus on current applications of ALE as a tool for metabolic engineering and discuss advancements and achievements that have been made in this field.     

Rapid and simple detection of PCR product DNA: a comparison between Southern hybridization and fluorescence polarization analysis

The essential aim of this study was to compare two different methods, Southern hybridization and fluorescence polarization (FP) assay. They both detect specific hybridization and were examined using common asymmetric PCR products and probes. FP assay clearly showed the hybridization of probe DNAs with the asymmetric PCR products of their target genes. Southern blot patterns presented excellent consistency with the results of FP assay. In both methods, two types of Shiga toxin (vero toxin) genes held in enterohaemorrhagic Escherichia coli (EHEC) were used as target genes. For detection of the two genes, stx1 and stx2, two respective DNA probes were synthesized. Both in FP assay and in Southern hybridization, the probe for stx1 hybridized only with the product of stx1 and vice versa. The results of the DNA detection using different methods were completely in agreement. Moreover, FP assay makes it possible to detect the hybridization rapidly. In our high NaCl concentration condition, hybridization between the probes and the asymmetric PCR products could be monitored within about 15min.     

噬菌体在食品工业中的应用与危害防控

近年来,噬菌体由于其特异性侵染细菌的特性,在食品加工及保藏过程中有害微生物的控制和检测方面展现出良好的应用前景。例如在食品表面喷洒噬菌体或将噬菌体与食品包装材料结合,对食源性致病菌及腐败菌加以控制,以及利用基因工程手段构建报告噬菌体对食源性致病菌进行快速检测等。然而,噬菌体也是危害食品发酵的重要因素之一,轻则减产,重则引起整个发酵过程失败,造成巨大的经济损失。目前主要通过噬菌体消毒及灭活、发酵菌种变换等方式防止噬菌体污染。本文综述了食品工业中噬菌体应用及危害的研究现状,以期为拓宽噬菌体在食品工业中的应用途径及开发噬菌体污染防治的新技术提供理论依据。