乳酸菌生物技术研究进展——以基因工程为例

乳酸菌生物技术是21世纪各国竞相开拓的一个尖端领域,其主要包括基因工程、蛋白质工程、细胞工程和发酵工程方面的研究内容。其中,以DNA重组技术为核心的基因工程是乳酸菌生物技术众多分支中的重点。文章以基因工程为例,围绕重组乳酸菌表达外源基因的优势及其在防治常见疾病中的应用进行了综述。     

应用于乳酸菌的非抗生素抗性选择标记系统

 乳酸菌是一类重要的安全型微生物,在免疫载体疫苗开发及食品菌株改良等医疗、食品领域均有广泛的应用.非抗生素抗性选择标记是乳酸菌基因工程菌株构建中必不可少的关键组成部分,也是目前乳酸菌研究的前沿和热点.根据筛选时质粒和受体菌之间的表型关系及特征,主要分为显性选择标记、互补型选择标记、显性/互补型选择标记、双质粒选择标记4大类.其中显性选择标记中的细菌素抗性/免疫性选择标记及互补型选择标记中的糖类选择标记均有较大的发展潜力及应用空间;双质粒选择标记系统构建的筛选过程新颖独特,为整个选择标记系统的发展开辟了新的途径及思路.     

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。     

乳酸菌载体pMG36e的应用现状

乳酸乳球菌通用表达质粒pMG36e是一个经典的人工构建的组成型表达载体,是以乳酸乳球菌乳脂亚种蛋白酶基因的转录和翻译信号为基础构建而成的。它包含一个强启动子,能够在多种细菌中表达外源蛋白。已用于研究细菌素作用机制,乳酸菌基因工程菌株的改造以及口服疫苗的开发等,应用领域十分广泛,已成为乳酸菌基因工程研究的重要工具质粒之一。本文主要从载体构成、基因表达与食品级载体改造等三方面的应用对其进行综述,旨在为该质粒今后研究提供资料。     

乳酸菌合成叶酸的研究进展

叶酸普遍存在于各类食物中,但由于叶酸的不稳定性以及饮食习惯的差异性,各国叶酸缺乏现象普遍存在。叶酸是参与核酸合成及细胞分裂分化的重要物质,叶酸缺乏引起机体功能的混乱,由此引发癌症等一系列的疾病。大部分乳酸菌是叶酸缺陷型菌株,但越来越多的研究表明其很多种类都具有叶酸合成能力。本文主要概述产叶酸乳酸菌的分类,乳酸菌生物合成叶酸的机制,以及利用乳酸菌进行的叶酸基因工程研究进展。     

基因工程菌发酵生产L-乳酸研究进展

乳酸是重要的工业平台化学品。随着聚乳酸产业的兴起,对高质量L-乳酸的需求量也不断增加。为了进一步降低L-乳酸发酵成本,提高菌株的工业适应性,各种现代生物技术已经应用到L-乳酸发酵菌种的改造上来。文中简要综述了近年来使用乳酸菌、酵母、大肠杆菌及米根霉等基因工程菌株发酵生产L-乳酸的技术进展。     

低温环境中乳酸菌的开发利用

乳酸菌作为一种益生资源,越来越为人们所重视.在自然界存在的乳酸菌中,有一类虽然人们一直在利用,但是还没有充分的研究和开发,这类乳酸菌就是低温环境中生长的乳酸菌.国外目前所见有关低温乳酸菌的报道多集中于低温冷藏肉、鱼制品及泡菜中的乳酸菌,集中研究和应用的菌属主要包括Leuconostoc和Lactobacillus,而国内这方面的研究并不多见.笔者根据目前国内外低温乳酸菌的研究现状,阐述了其存在环境、种类及相应作用,并对其研究涉及的领域、趋势及应用前景进行了探讨和展望,以期为国内这类乳酸菌资源的研究开发提供参考和依据.     

H.pylori尿素酶B亚单位在保加利亚乳杆菌的表达与鉴定

目的构建表达幽门螺杆菌（Helicobacter pylori,H、pylori）尿素酶B亚单位（UreB）的基因工程乳杆菌,并对其进行初步的安全性评估。方法采用高保真PCR从H.pylori标准菌株NCTC 11637中扩增ureB基因,插入乳酸菌表达质粒pMG36e,将重组质粒电转入保加利亚乳杆菌L6032中,获得表达ureB的基因工程乳杆菌。在含乳糖的MRS培养基诱导目的蛋白表达,Western blot鉴定其免疫原性。连续传代培养60代,检测基因工程乳杆菌的稳定性、形态学与生理生化特性以进行初步的安全性评估。结果特异PCR、酶切和测序鉴定均证实ureB基因克隆入表达载体pMG36e,SDS-PAGE结果显示,重组质粒pMG36e-ureB电转入保加利亚乳杆菌所构建的基因工程乳杆菌能表达约64KD的蛋白,Western blot证明该蛋白能与抗H.priori ureB的兔血清反应。稳定性、形态学与生理生化特性检测结果表明,基因工程乳杆菌与原始菌株保加利亚乳杆菌完全一致。结论成功构建能表达H.pylori UreB的保加利亚乳杆菌L6032-UreB,该基因工程菌在形态与生理生化特性上未发生任何变异,从而为探索幽门螺杆菌感染的益生菌制剂调理疗法奠定了坚实的基础。     

典型环境污染物修复基因工程菌的构建及应用

随着人类活动的增加,对有机物和重金属的应用越来越广泛,同时造成的环境污染程度越来越严重.综述了石油、农药、表面活性剂及重金属类污染物治理中基因工程菌的构建及应用的研究进展,指出利用基因工程菌解决环境中的石油、农药、表面活性剂及重金属的污染问题已成为环境污染修复领域的研究热点,并提出基因工程菌的构建及应用过程中的难点及发展趋势.     

基因工程制药的研究现状与发展前景

简要叙述了近年来基因工程技术在医药工业中的应用进展,主要包括基因工程技术在药物生产、新药开发及药物生产工艺改进的应用.随着基因组和蛋白质组研究的深入,基因工程药物将有更多的机会获得突破性进展.     

Engineering metabolic highways in Lactococci and other lactic acid bacteria

Lactic acid bacteria (LAB) are widely used in industrial food fermentations and are receiving increased attention for use as cell factories for the production of food and pharmaceutical products. Glycolytic conversion of sugars into lactic acid is the main metabolic highway in these Gram-positive bacteria and Lactococcus lactis has become the model organism because of its small genome, genetic accessibility and simple metabolism. Here we discuss the metabolic engineering of L. lactis and the value of metabolic models compared with other LAB, with a particular focus on the food-grade production of metabolites involved in flavour, texture and health.     

Metabolic pathway engineering in lactic acid bacteria

Lactic acid bacteria (LAB) display a relatively simple carbon and energy metabolism where the sugar source is converted mainly to lactic acid. In Lactococcus lactis metabolic engineering has been very successful in the re-routing of lactococcal pyruvate metabolism to products other than lactic acid. Current metabolic engineering approaches tend to focus on more complex, biosynthetic pathways leading to end-products that generate a health benefit for the consumer (nutraceuticals). Several examples of research on these minor pathways in L. lactis have illustrated the potential of LAB as producers of these metabolites. Whole genome sequencing efforts and corresponding global technologies will have an impact on metabolic engineering in the future.     

Engineering Tools for the Development of Recombinant Lactic Acid Bacteria

Lactic acid bacteria (LAB) is mainly used in food fermentation. In addition, LAB fermentation technology has been studied in the development of industrial food additives, nutrients, or enzymes used in food processing. In the field of red biotechnology, LAB is approved and is generally recognized as a safe organism and is considered safe for biotherapeutic treatments. Recent clinical trials have demonstrated the medicinal value of therapeutic recombinant LAB and the suitability of innate mechanisms of secretion and anchoring for therapeutic applications such as antibody or vaccine production. However, the gram‐positive phenotypic trait of LAB creates challenges for genetic modifications when compared to other conventional workhorse bacteria, resulting in exclusive developments of genetic tools for engineering LAB. In this review, several distinct approaches in gene expression for engineering LAB are discussed.     

乳酸菌基因组学研究进展

乳酸菌广泛应用于食品发酵工业中,其中有些菌种是重要的益生菌。目前,对乳酸菌的研究已从最初的形态学研究进入到了分子水平的研究。乳酸菌全基因组测序研究已在全球展开。乳酸菌基因组研究有助于揭示乳酸菌的遗传和代谢机制,加速重要益生功能基因的挖掘,同时为乳酸菌的应用提供众多可能性。本文就乳酸菌基因组研究的概况、重要乳酸菌基因组、乳酸菌的功能基因组以及比较基因组进行了综述。     

Isolation and identification of lactic acid bacteria from soil using an enrichment procedure

AIMS: To survey, and identify and classify the ecological distribution of lactic acid bacteria from soil in Japan and Taiwan. METHODS AND RESULTS: Acid-producing bacteria were isolated from 68 soil samples, collected from Japan and Taiwan, in the rhizospheres of fruit trees, from the floor of a henhouse and around a horse farm. All isolates were identified by physiological and genetic tests. Thirty-two of the 54 isolates were identified as lactic acid bacteria (LAB), 16 as spore-forming lactic acid bacteria, five as Clostridium and one as Bacillus. These lactic acid bacteria represent five genera: Lactobacillus, Lactococcus, Enterococcus, Leuconostoc and Weissella. CONCLUSIONS: A high rate of isolating lactic acid bacteria was obtained from soil. SIGNIFICANCE AND IMPACT OF THE STUDY: This study suggests that soil may be a common source for the isolation of lactic acid bacteria.     

The genomics of lactic acid bacteria

The lactic acid bacteria (LAB) are one of the most industrially important groups of bacteria. These organisms are used in a variety of ways, including food production, health improvement and production of macromolecules, enzymes and metabolites. The genome sequencing of 20 LAB provides an expanded view of their genetic and metabolic capacities and enables researchers to perform functional and comparative genomic studies. This review highlights some of the findings from these analyses in the context of the numerous roles the LAB play.     

Mucosal delivery of therapeutic and prophylactic molecules using lactic acid bacteria

Studies of lactic acid bacteria (LAB) as delivery vehicles have focused mainly on the development of mucosal vaccines, with much effort being devoted to the generation of genetic tools for antigen expression in different bacterial locations. Subsequently, interleukins have been co-expressed with antigens in LAB to enhance the immune response that is raised against the antigen. LAB have also been used as a delivery system for a range of molecules that have different applications, including anti-infectives, therapies for allergic diseases and therapies for gastrointestinal diseases. Now that the first human trial with a Lactococcus strain that expresses recombinant interleukin-10 has been completed, we discuss what we have learnt, what we do not yet understand and what the future holds for therapy and prophylaxis with LAB.     

Current approaches on the roles of lactic acid bacteria in crop silage

Lactic acid bacteria (LAB) play pivotal roles in the preservation and fermentation of forage crops in spontaneous or inoculated silages. Highlights of silage LAB over the past decades include the discovery of the roles of LAB in silage bacterial communities and metabolism and the exploration of functional properties. The present article reviews published literature on the effects of LAB on the succession, structure, and functions of silage microbial communities involved in fermentation. Furthermore, the utility of functional LAB in silage preparation including feruloyl esterase-producing LAB, antimicrobial LAB, lactic acid bacteria with high antioxidant potential, pesticide-degrading LAB, lactic acid bacteria producing 1,2-propanediol, and low-temperature-tolerant LAB have been described. Compared with conventional LAB, functional LAB produce different effects; specifically, they positively affect animal performance, health, and product quality, among others. In addition, the metabolic profiles of ensiled forages show that plentiful probiotic metabolites with but not limited to antimicrobial, antioxidant, aromatic, and anti-inflammatory properties are observed in silage. Collectively, the current knowledge on the roles of LAB in crop silage indicates there are great opportunities to develop silage not only as a fermented feed but also as a vehicle of delivery of probiotic substances for animal health and welfare in the future.     

青藏高原垂穗披碱草青贮饲料中乳酸菌的多样性及低温发酵菌株的筛选

【目的】探究青藏高原垂穗披碱草青贮饲料中乳酸菌的多样性,筛选在低温条件下(10、15和25°C)生长性能较好的优良菌株。【方法】将垂穗披碱草青贮饲料中分离纯化的乳酸菌进行形态特征观察及16S r RNA基因测序鉴定;用MRS液体培养基在10、15和25°C条件下分离、初筛乳酸菌,选取高吸光度值的菌株作为优势菌株。用绿汁发酵液在10、15和25°C条件下培养测定其p H值,选取低p H值菌株作为优势菌株,并综合MRS培养基筛选结果确定优良菌株。【结果】从不同温度和发酵阶段的垂穗披碱草青贮饲料中共分离得到108个乳酸菌菌株,它们分属于6个属、18个种。其中,清酒乳杆菌LS-24在15°C条件下发酵液p H值显著降低(P0.05),戊糖片球菌PP-63在发酵初期生长速度较快,植物乳杆菌LP-21在15°C条件下发酵液p H值降至3.9且有最大活菌数。【结论】在青藏高原垂穗披碱草青贮饲料中发现的乳酸菌属基本涵盖了前人在常温青贮饲料中发现的所有属,但种数略少;在108株菌中,清酒乳杆菌LS-24、戊糖片球菌PP-63和植物乳杆菌LP-21在低温条件下均表现出较好的繁殖和发酵特性,可作为青贮饲料低温发酵的备选菌株。