基因工程半成品中大肠杆菌蛋白残余量测定方法研究—双抗体夹心ELISA法

用大肠杆菌ＤＨ５α菌体蛋白免疫家兔制备抗血清,建立了双抗体夹心ＥＬＩＳＡ方法。经初步测定,该方法的灵敏度为１．５ｎｇ／ｍｌ,与间接ＥＬＩＳＡ法的灵敏度相似,比聚丙烯酰胺凝胶电泳的考马斯亮兰染色方法的灵敏度高将近７００倍,比银染色方法的灵敏度高将近３０倍。在２０～１００００ｎｇ／ｍｌ范围内呈直线关系,直线相关系数为０．９９６。经八次重复测定,显示很好的重复性。该方法可用于测定基因工程产品中ＤＨ５α菌体蛋白的残余量。     

抗噬菌体工程菌的筛选

噬菌体污染常引起溶菌,造成人力物力浪费。应用自发突变的原理成功地从溶菌液中筛选到抗噬菌体的工程菌株;在发酵罐中培养,该菌株生长行为和表达水平没有变化。     

Metabolic engineering of Escherichia coli for the production of fumaric acid

Fumaric acid is a naturally occurring organic acid that is an intermediate of the tricarboxylic acid cycle. Fungal species belonging to Rhizopus have traditionally been employed for the production of fumaric acid. In this study, Escherichia coli was metabolically engineered for the production of fumaric acid under aerobic condition. For the aerobic production of fumaric acid, the iclR gene was deleted to redirect the carbon flux through the glyoxylate shunt. In addition, the fumA, fumB, and fumC genes were also deleted to enhance fumaric acid formation. The resulting strain was able to produce 1.45 g/L of fumaric acid from 15 g/L of glucose in flask culture. Based on in silico flux response analysis, this base strain was further engineered by plasmid‐based overexpression of the native ppc gene, encoding phosphoenolpyruvate carboxylase (PPC), from the strong tac promoter, which resulted in the production of 4.09 g/L of fumaric acid. Additionally, the arcA and ptsG genes were deleted to reinforce the oxidative TCA cycle flux, and the aspA gene was deleted to block the conversion of fumaric acid into L ‐aspartic acid. Since it is desirable to avoid the use of inducer, the lacI gene was also deleted. To increase glucose uptake rate and fumaric acid productivity, the native promoter of the galP gene was replaced with the strong trc promoter. Fed‐batch culture of the final strain CWF812 allowed production of 28.2 g/L fumaric acid in 63 h with the overall yield and productivity of 0.389 g fumaric acid/g glucose and 0.448 g/L/h, respectively. This study demonstrates the possibility for the efficient production of fumaric acid by metabolically engineered E. coli. Biotechnol. Bioeng. 2013; 110: 2025–2034. © 2013 Wiley Periodicals, Inc.     

生物转化合成苯乳酸工程菌的培养条件优化

本研究旨在优化重组大肠杆菌Escherichia coli BL21 (DE3) harboring pRSF-aad-ldh10-fdh菌株的培养条件,获得高密的供生物转化苯丙氨酸为苯乳酸的细胞。实验考察了摇瓶发酵培养基碳源、氮源种类和浓度,3 L发酵罐中转速和通气量及恒速补料、DO-stat和pH-stat等不同分批补料策略对菌体密度的影响。结果表明,当碳源为4 g/L葡萄糖,氮源为24 g/L安琪酵母浸粉FM802,细胞干重最大可达9.24 g/L;当转速为400 r/min和通气量为1.5 vvm时,细胞干重最大可达10.18 g/L;以4 g/(L·h)恒速流加葡萄糖时,细胞干重最大可达13.71 g/L。本研究还对工程菌酶表达的诱导条件进行了优化,菌体培养2 h后,添加终浓度为0.08 mmol/L IPTG诱导剂,在25℃下诱导培养14 h所得细胞有利于生物转化。底物苯丙氨酸浓度为60 g/L,转化为苯丙酮酸的转化率为50.2%,转化为苯乳酸的转化率为35.2%。     

The mechanism of inhibition by EDTA and EGTA of methanol oxidation by methylotrophic bacteria

Ethyleneglycol (aminoethylether) tetra-acetic acid (EGTA) was shown to be a potent competitive inhibitor of electron transfer between methanol dehydrogenase (MDH) and its electron acceptor cytochrome cL. Addition of Ca2+ ions relieved the inhibition by removal of the inhibitory EGTA. Removal of EGTA by gel filtration completely relieved the inhibition. EGTA did not remove the tightly bound Ca2+ present in the MDH. Indo-1, a fluorescent analogue of EGTA, bound tightly to MDH in a 1:1 ratio but not to cytochrome cL; binding was prevented by EGTA. It was concluded that EGTA inhibits methanol oxidation by binding to lysyl or arginyl residues on MDH thus preventing docking with cytochrome cL.     

大肠杆菌产琥珀酸基因工程研究进展

生物合成琥珀酸摆脱了对不可再生战略资源石油的依赖,以其社会、经济和环境效益展现出良好的发展前景。野生型大肠杆菌的琥珀酸生产强度难以满足生物合成琥珀酸工业化的要求,但遗传背景清楚,容易改造。近年来,人们深入研究了大肠杆菌的琥珀酸代谢途径,通过强化大肠杆菌琥珀酸合成途径、抑制琥珀酸旁路代谢途径、构建产琥珀酸乙醛酸循环和有氧生产体系等多种基因工程策略,对大肠杆菌进行菌株改造和代谢进化筛选,提高了琥珀酸产量。综述了大肠杆菌产琥珀酸的基因工程研究进展。     

植物耐冷性基因工程

温度决定物种的分布,同时还影响作物的产量和品质。植物耐冷的机制涉及到许多方面,包括膜脂组成的变化、可混溶溶质的积累、抗氧化酶活性的提高、低温相关基因的诱导表达等。由于植物的耐冷性状由多基因控制,采用传统的育种方法往往难以取得理想的结果,而植物基因工程技术的发展及应用则提供了另外可能的途径,可以通过转移耐冷性状形成的关键基因从而对植物进行改良。本文从膜脂组成、可混溶溶质、抗冻蛋白、抗氧化酶和诱导植物低温相关基因的转录因子等方面对植物耐冷性的基因工程研究进行了综述,以期为植物育种者和从事冷胁迫机制研究的工作者提供参考。     

大肠杆菌生产异戊二烯的代谢工程研究进展

异戊二烯作为一种重要的化工原料,主要用于合成橡胶。此外,还广泛应用于医药或化工中间体、食品、粘合剂及航空燃料等领域。利用微生物法生产异戊二烯因具有环境友好、利用廉价的可再生原料、可持续发展等优势而成为当今研究的热点。这里介绍了大肠杆菌生产异戊二烯的代谢途径及关键酶,从代谢工程的角度出发综述了目前为提高大肠杆菌异戊二烯产量所应用到的方法和策略,并对今后的发展方向进行了展望。     

Metabolic engineering of acetoin and meso-2, 3-butanediol biosynthesis in E. coli

The functional reconstruction of acetoin and meso-2,3-butanediol (meso-2,3-BD) biosynthetic pathways in Escherichia coli have been explored systematically. Pathway construction involved the in vsivo screening of prospective pathway isozymes of yeast and bacterial origin. After substantial engineering of the host background to increase pyruvate availability, E. coli YYC202(DE3) ldhA⁽ ilvC( expressing ilvBN from E. coli and aldB from L. lactis (encoding acetolactate synthase and acetolactate decarboxylase activities, respectively) was able to produce up to 870 mg/L acetoin, with no coproduction of diacetyl observed. These strains were also found to produce small quantities of meso-2,3-BD, suggesting the existence of endogenous 2,3-BD dehydrogenase activity. Finally, the coexpression of bdh1 from S. cerevisiae, encoding 2,3-BD dehydrogenase, in this strain resulted in the production of up to 1120 mg/L meso-2,3-BD, with glucose a yield of 0.29 g/g. While disruption of the native lactate biosynthesis pathway increased pyruvate precursor availability to this strain, increased availability of NADH for acetoin reduction to meso-2,3-BD was found to be the most important consequence of ldhA deletion.     

Genetic diversity of Escherichia coli recovered from the oral cavity of beef cattle and their relatedness to faecal E. coli

AIMS: To determine the genetic diversity of generic Escherichia coli recovered from the oral cavities of beef cattle and their relatedness to E. coli isolated from the faeces of cattle during pasture grazing and feedlot finishing. METHODS AND RESULTS: A total of 484 E. coli (248 oral and 236 faecal isolates) were obtained from eight beef cattle after 1 and 5 months of grazing on pasture and after 1 and 5 months in a feedlot. The random amplification of polymorphic DNA (RAPD) method was used to genetically characterize these isolates. The RAPD patterns showed that ca 60% of E. coli recovered from the oral cavities and faeces during pasture and feedlot shared a close genetic relatedness. A number of E. coli with unique RAPD types were also found either in the oral cavities or faeces. Most of the E. coli RAPD types recovered from the oral cavities were shared among animals, but there were also RAPD types which were unique to individual animals. The E. coli populations of the oral cavities were genetically diverse and changed over time. CONCLUSIONS: This study indicates that there are large numbers of E. coli carried in the oral cavities of beef cattle and those E. coli are closely related to strains found in the faeces. The oral cavities of cattle harbour a genetically diverse E. coli population. SIGNIFICANCE AND IMPACT OF THE STUDY: The oral cavity may be an important reservoir of enteric pathogens which may transfer to meat during carcass dressing. A better understanding of the molecular ecology of E. coli in cattle would assist the design of approaches to control pathogenic strains during beef production and processing.     

Anaerobic fermentation of glycerol by Escherichia coli: a new platform for metabolic engineering

The worldwide surplus of glycerol generated as inevitable byproduct of biodiesel fuel and oleochemical production is resulting in the shutdown of traditional glycerol-producing/refining plants and new applications are needed for this now abundant carbon source. In this article we report our finding that Escherichia coli can ferment glycerol in a pH-dependent manner. We hypothesize that glycerol fermentation is linked to the availability of CO(2), which under acidic conditions is produced by the oxidation of formate by the enzyme formate hydrogen lyase (FHL). In agreement with this hypothesis, glycerol fermentation was severely impaired by blocking the activity of FHL. We demonstrated that, unlike CO(2), hydrogen (the other product of FHL-mediated formate oxidation) had a negative impact on cell growth and glycerol fermentation. In addition, supplementation of the medium with CO(2) partially restored the ability of an FHL-deficient strain to ferment glycerol. High pH resulted in low CO(2) generation (low activity of FHL) and availability (most CO(2) is converted to bicarbonate), and consequently very inefficient fermentation of glycerol. Most of the fermented glycerol was recovered in the reduced compounds ethanol and succinate (93% of the product mixture), which reflects the highly reduced state of glycerol and confirms the fermentative nature of this process. Since glycerol is a cheap, abundant, and highly reduced carbon source, our findings should enable the development of an E. coli-based platform for the anaerobic production of reduced chemicals from glycerol at yields higher than those obtained from common sugars, such as glucose.     

Metabolic engineering of E. coli for improving mevalonate production to promote NADPH regeneration and enhance acetyl-CoA supply

Microbial production of mevalonate from renewable feedstock is a promising and sustainable approach for the production of value-added chemicals. We describe the metabolic engineering of Escherichia coli to enhance mevalonate production from glucose and cellobiose. First, the mevalonate-producing pathway was introduced into E. coli and the expression of the gene atoB, which encodes the gene for acetoacetyl-CoA synthetase, was increased. Then, the deletion of the pgi gene, which encodes phosphoglucose isomerase, increased the NADPH/NADP⁺ ratio in the cells but did not improve mevalonate production. Alternatively, to reduce flux toward the tricarboxylic acid cycle, gltA, which encodes citrate synthetase, was disrupted. The resultant strain, MGΔgltA-MV, increased levels of intracellular acetyl-CoA up to sevenfold higher than the wild-type strain. This strain produced 8.0 g/L of mevalonate from 20 g/L of glucose. We also engineered the sugar supply by displaying β-glucosidase (BGL) on the cell surface. When cellobiose was used as carbon source, the strain lacking gnd displaying BGL efficiently consumed cellobiose and produced mevalonate at 5.7 g/L. The yield of mevalonate was 0.25 g/g glucose (1 g of cellobiose corresponds to 1.1 g of glucose). These results demonstrate the feasibility of producing mevalonate from cellobiose or cellooligosaccharides using an engineered E. coli strain.     

氨基酸生产的代谢工程研究进展与发展趋势

氨基酸发酵是我国发酵工业的支柱产业,近年来,随着代谢工程的快速发展,氨基酸的代谢工程育种蓬勃发展。传统的正向代谢工程、基于组学分析与计算机模拟的反向代谢工程以及借鉴自然进化的进化代谢工程,都有越来越多的应用。在氨基酸的工业生产中涌现出了一系列具有高效生产、抗逆性强等优良性状的菌株。日益剧烈的市场竞争对菌株的选育提出了新的要求,如开发高附加值氨基酸品种、菌株代谢的动态调控、适应新工艺的要求等。文中介绍了氨基酸生产相关的代谢工程研究进展以及未来的发展趋势。     

Pulsed electric field treatment as a potential method for microbial inactivation in scaffold materials for tissue engineering: the inactivation of bacteria in collagen gel

Aims: To investigate the effectiveness of pulsed electric field (PEF) treatment as a new method for inactivation of micro-organisms in complex biomatrices and to assess this by quantifying the inactivation of Escherichia coli seeded in collagen gels. Methods and Results: PEF was applied to E. coli seeded collagen gels in static (nonflowing) chambers. The influence of electric field strength, pulse number and seeded cell densities were investigated. The highest level of inactivation was obtained at the maximum field strength of 45 kV cm⁻¹. For low levels of E. coli contamination (10³ CFU ml⁻¹), PEF treatment resulted in no viable E. coli being recovered from the gels. However, PEF treatment of gels containing higher cell densities (≥10⁴ CFU ml⁻¹) did not achieve complete inactivation of E. coli. Conclusions: PEF treatment successfully inactivated E. coli seeded in collagen gels by 3 log₁₀ CFU ml⁻¹. Complete inactivation was hindered at high cell densities by the tailing effect observed. Significance and Impact of the Study: PEF shows potential as a novel, nondestructive method for decontamination of collagen-based matrices. Further investigation is required to ensure its compatibility with other proteins and therapeutic drugs for tissue engineering and drug delivery applications.     

Metabolic engineering strategies for butanol production in Escherichia coli

The global market of butanol is increasing due to its growing applications as solvent, flavoring agent, and chemical precursor of several other compounds. Recently, the superior properties of n-butanol as a biofuel over ethanol have stimulated even more interest. (Bio)butanol is natively produced together with ethanol and acetone by Clostridium species through acetone-butanol-ethanol fermentation, at noncompetitive, low titers compared to petrochemical production. Different butanol production pathways have been expressed in Escherichia coli, a more accessible host compared to Clostridium species, to improve butanol titers and rates. The bioproduction of butanol is here reviewed from a historical and theoretical perspective. All tested rational metabolic engineering strategies in E. coli to increase butanol titers are reviewed: manipulation of central carbon metabolism, elimination of competing pathways, cofactor balancing, development of new pathways, expression of homologous enzymes, consumption of different substrates, and molecular biology strategies. The progress in the field of metabolic modeling and pathway generation algorithms and their potential application to butanol production are also summarized here. The main goals are to gather all the strategies, evaluate the respective progress obtained, identify, and exploit the outstanding challenges.     

Genetic and chemical approaches for surface charge engineering of enzymes and their applicability in biocatalysis: A review

Surface charge engineering has received considerable interest from the scientific and industrial community in the last few decades. Although it was previously hypothesized that the surface charge–charge interactions were not a fundamental force to determine protein folding and stability, many studies today show that surface charge plays a key role determining protein structure and activity. This review aims to (a) highlight the value of surface charged engineering of proteins to improve enzyme stability and activity in aqueous media and in the presence of ionic liquids (ILs) and organic solvents, (b) describe the existing approaches (genetic engineering or chemical modifications) for surface charged engineering, and (c) demonstrate the applicability of these surface charged enzymes in biocatalysis. The review provides a new foundation for the scientific and research community to exploit the surface engineering of protein concept for the development of new enzymes that are more active and stable in the presence of ILs and organic solvents, thereby offering new opportunities for industrial biocatalysis. Furthermore, this review is a useful tool for researchers to decide the best available technology to improve their enzyme system/process.     

Genetic engineering of plant signal transduction mechanisms

Signal transduction is used by plants to coordinate their development and to sense and respond to fluctuations in their surroundings. Of prime importance is the ability to defend against pathogens and other environmental hazards such as cold temperatures, drought or wounding. Many transduction pathways are now characterized and the underlying genes are known. This suggests an obvious question—can we engineer signal transduction mechanisms for plant improvement? We address this question by presenting a rationale for an engineering approach and by discussing results from recent attempts to apply this approach. Calmodulin-like domain protein kinase (CDPK) and mitogen-activated protein kinase (MAPK) pathways are used as primary examples. New technology that will aid these efforts is also covered.