大肠杆菌基因组基因无痕敲除的优化方法

目的：优化大肠杆菌基因组基因无痕敲除的方法,提高无痕敲除的效率。方法：以无痕敲除大肠杆菌nanKETA基因簇为模型,利用Red同源重组系统和核酸内切酶I-SceI的筛选作用,通过两步连续同源重组无痕敲除大肠杆菌CLM37基因组中的nanKETA基因,优化无痕敲除时同源DNA长度与诱导用于筛选阳性克隆I-SceI表达的诱导剂浓度。通过比较敲除nanKETA基因前后菌株的生长曲线,研究大肠杆菌CLM37缺失nanKETA基因后的生长状态。结果：成功无痕敲除大肠杆菌CLM37基因组中的nanKETA基因,并在无痕化处理时,通过延长与基因组同源DNA的长度,由通常使用的80碱基对延长到684碱基对;并通过提高诱导筛选基因表达的四环素的浓度,由500 μg/ml提高到1000 μg/ml后,使无痕敲除效率高达90%以上。生长曲线研究表明,缺失nanKETA基因后的菌株生长状态与原菌株基本一致。结论：通过延长与基因组同源的双链核苷酸的长度和诱导筛选基因表达的四环素的浓度可显著提高无痕敲除的效率。     

大肠杆菌基因无痕敲除技术及策略

基因敲除技术是大肠杆菌基因组减小和代谢途径改造的有效手段,其中基于同源重组原理的基因无痕敲除技术显现出其他技术所不具备的应用优势和发展潜力。该技术可以快速敲除大肠杆菌基因组中的目标基因,并且在基因组中不残留任何外源片段,所以不会干扰后续的基因操作。我们分类介绍了无痕敲除技术中所涉及载体的结构、功能及其相应的敲除策略,着重介绍了无痕敲除技术的原理及载体构建方法。     

大肠杆菌无痕重组的策略与应用

Red同源重组技术发展迅速,已经广泛应用于大肠杆菌基因的敲除、插入与替换。与传统的DNA有痕重组技术相比,基于Red重组原理的DNA无痕重组技术,能够更为精确、快速、高效地修饰大肠杆菌基因组中的目标基因,且在基因组中不残留任何外源片段,因此不会影响后续的基因操作与基因表达。从Red同源重组的原理出发,简要综述了近年来在大肠杆菌中广泛使用的无痕重组技术的原理及操作策略,并对比分析了各种方法的优势与不足;同时,还介绍了DNA无痕重组技术在大肠杆菌基因修饰中的应用情况。     

Pseudomonas plecoglossicida NyZ12基因无痕敲除方法的建立

旨在建立一种适合环己胺降解菌NyZ12基因无痕敲除的可靠方法。通过overlapping PCR技术将目的基因上下游同源臂融合并克隆到自杀载体pEX18km上,将重组质粒转化到大肠杆菌S17pir中,再通过接合转移到假单胞菌NyZ12菌株内,经pEX18km质粒上sacB基因的反向筛选得到突变株并通过PCR方法和测序鉴定。结果显示,成功构建了假单胞菌NyZ12菌株orf4637的基因突变株(NyZ12Δ4637)。通过自杀载体同源重组可以成功获得敲除的无痕突变株,且突变株基因组上没有任何抗性筛选标记残留,为环己胺降解菌NyZ12基因功能研究提供了可靠的基因敲除技术。     

利用细菌人工染色体同源重组对小鼠基因进行条件型敲除

目的:探索通过细菌人工染色体(BAC)同源重组系统构建条件基因敲除载体的高效率方法,提高条件基因敲除小鼠(Flox小鼠)的构建效率。方法:利用作者自己构建的噬菌体重组酶系统,通过BAC同源重组进行条件型基因敲除载体构建工作。首先通过亚克隆构建了一系列载体含有同源臂的靶向质粒,线性化后,打靶片段经电穿孔法转入大肠杆菌内,与相应的BAC同源重组,再经过三步同源重组和一步位点特异性重组,构建小鼠条件型基因敲除载体。结果:高效率构建了小鼠基因的最终条件基因敲除载体。结论:通过BAC同源重组高效构建条件基因敲除载体,为条件基因敲除载体的构建提供了全新思路,并为FLox小鼠的建立,及相应基因在发育、生理、致病机制等方面的功能研究奠定了基础。     

谷氨酸棒状杆菌CRISPR-Cpf1和Cre/loxP基因敲除技术的比较

【背景】谷氨酸棒状杆菌的基因敲除系统较为匮乏且效率不高,难以对其进行代谢工程改造,不利于高性能工业菌株的构建及规模生产。【目的】分别采用CRISPR-Cpf1和Cre/loxP基因敲除系统对谷氨酸棒状杆菌ATCC13032(CorynebacteriumglutamicumATCC13032)基因组上的argR和argF基因进行敲除,比较两种敲除方法的优缺点,为合理选择敲除系统提供依据。【方法】特异性重组的Cre/loxP敲除系统是首先利用同源重组将基因组上的靶基因替换为两端带有重组位点loxP的kanR片段,然后由重组酶Cre识别loxP位点并发生重组反应,从而去除替换到基因组上的kanR片段,进一步利用质粒的温敏特性将其消除,从而实现靶基因的敲除。CRISPR-Cpf1敲除系统是利用Cpf1对pre-crRNA进行加工,形成的成熟crRNA引导Cpf1识别和结合到靶DNA的特定序列上并切割双链DNA分子,通过同源重组作用去除靶基因,基于质粒自身的温敏特性将其消除,从而完成基因敲除的整个过程。【结果】Cre/lox P系统可在8N+2 d内完成N轮迭代基因敲除,而CRISPR-Cpf1系统可在5N+2d内完成N轮迭代基因无痕敲除,理论上还可以一次对多个靶位点进行编辑,效率更高,但存在同源重组效率较低、假阳性率高等缺点。【结论】与Cre/loxP系统相比,CRISPR-Cpf1辅助的同源重组基因敲除方法可省时、省力地实现基因的无痕敲除,理论上还可实现多个基因的同时敲除、总体效率更高,然而编辑效率还有提高的空间。     

副溶血性弧菌基因敲除方法的建立及应用

目的摸索出一套副溶血性弧菌基因敲除的可靠方案,副溶血性弧菌致病相关基因的敲除对深入研究其致病机制有重要意义。方法通过融合PCR技术将目的基因上下游同源臂融合并克隆到自杀载体pDS132上,将重组质粒转化大肠杆菌S17λpir中,再接合转移到副溶血性弧菌菌株内,经pDS132质粒上sacB基因的反向筛选得到突变株。结果成功构建了副溶血性弧菌RIMD2210633菌株ΔopaR,ΔtoxR和ΔaphA三个基因突变株。结论通过自杀载体同源重组成功获得精确敲除的无痕突变株更有利于基因功能的研究,使后续副溶血性弧菌突变株与野生株的对比研究成为可能。     

利用Red重组系统敲除大肠杆菌 O157:H7的waaL 基因

目的:利用λ噬菌体Red重组系统敲除大肠杆菌O157:H7的waaL基因。方法:以pKD4为模板扩增出与waaL基因上下游同源的、含有卡那霉素抗性基因的PCR产物。然后电击转化到大肠杆菌 O157:H7 中,利用Red重组系统,通过卡那霉素抗性基因两侧的waaL基因序列在体内与waaL基因发生同源重组,置换了 O157:H7 基因组中的waaL基因。并进一步利用卡那霉素抗性基因两侧的FRT位点,通过FLP位点专一性重组将卡那霉素抗性基因敲除。结果:成功构建了敲除waaL基因且不带卡那霉素抗性基因的菌株。     

Cre/LoxP重组系统的改造及在树干毕赤酵母中的应用

为了实现在P.stipitis中进行无痕基因敲除,以Cre/LoxP系统为研究对象,首先通过同源重组构建尿嘧啶营养缺陷型树干毕赤酵母(ura3-);同时通过定点突变pSH47-Hpt质粒的hpt基因和cre基因,将CDS区CTG突变为TTG;最后以乙醛脱氢酶基因为靶基因,验证突变后的Cre/LoxP系统在P.stipitis进行无痕基因敲除的可行性。结果表明:本文在P.stipitis中成功使用潮霉素B抗性标记,经过修饰后的Cre/LoxP敲除系统能够在P.stipitis中无痕敲除目的基因,为后续研究P.stipitis功能基因和改造代谢途径提供了一种试验方法和筛选标记。     

基因编辑技术对大肠杆菌yjjW基因点突变的两步法策略

【目的】为了实现对大肠杆菌靶基因的点突变,本研究将同源重组系统与CRISPR-Cas9技术相结合,探索一种高效、简捷的两步法策略。【方法】将靶基因的上下游同源臂和标记基因(amp)与pKOV质粒连接,获得pKOV-HR重组质粒。将pKOV-HR转化至大肠杆菌,借助其自身RecA重组系统,介导DNA发生同源重组,获得靶基因敲除菌株。随后,靶基因的点突变采用pSGKP-km和pCasKP-apr双质粒系统。首先,设计与amp结合具有定向引导作用的spacer序列,并利用overlap PCR获得带有靶基因点突变的同源臂,将spacer和同源臂与pSGKP-km质粒连接,获得重组质粒pSGKP-km-spacer-HR;接着,将pSGKP-km-spacer-HR和pCasKP-apr质粒转化至上述敲除菌株;最后,利用质粒表达的Cas9切割蛋白和λ-Red重组蛋白,发生DNA同源重组,获得靶基因点突变菌株。【结果】利用上述方法,既成功获得了大肠杆菌yjjW敲除菌株D7ΔyjjW::ampR,又实现了yjjW第24位碱基T到C的点突变,获得点突变菌株D7yjjW-24。【结论】本研究建立了一种高效、简捷的大肠杆菌靶基因点突变方法,amp基因的插入提供了有效的筛选标记,此外该方法建立的重组质粒pSGKP-km-spacer,可应用于同种菌株其他靶基因的点突变,能够缩短后续实验操作,为基因编辑技术的发展提供了科学理论以及实验操作基础。     

Characterization of the ftsZ gene from Mycoplasma pulmonis, an organism lacking a cell wall.

The ftsZ gene is required for cell division in Escherichia coli and Bacillus subtilis. In these organisms, FtsZ is located in a ring at the leading edge of the septum. This ring is thought to be responsible for invagination of the septum, either causing invagination of the cytoplasmic membrane or activating septum-specific peptidoglycan biosynthesis. In this paper, we report that the cell division gene ftsZ is present in two mycoplasma species, Mycoplasma pulmonis and Acholeplasma laidlawii, which are eubacterial organisms lacking a cell wall. Sequencing of the ftsZ homolog from M. pulmonis revealed that it was highly homologous to other known FtsZ proteins. The M. pulmonis ftsZ gene was overexpressed, and the purified M. pulmonis FtsZ bound GTP. Using antisera raised against this purified protein, we could demonstrate that it was expressed in M. pulmonis. Expression of the M. pulmonis ftsZ gene in E. coli inhibited cell division, leading to filamentation, which could be suppressed by increasing expression of the E. coli ftsZ gene. The implications of these results for the role of ftsZ in cell division are discussed.     

Borrelia burgdorferi ftsZ plays a role in cell division

ftsZ is essential for cell division in many microorganisms. In Escherichia coli and Bacillus subtilis, FtsZ plays a role in ring formation at the leading edge of the cell division septum. An ftsZ homologue is present in the Borrelia burgdorferi genome (ftsZ(Bbu)). Its gene product (FtsZ(Bbu)) is strongly homologous to other bacterial FtsZ proteins, but its function has not been established. Because loss-of-function mutants of ftsZ(Bbu) might be lethal, the tetR/tetO system was adapted for regulated control of this gene in B. burgdorferi. Sixty-two nucleotides of an ftsZ(Bbu) antisense DNA sequence under the control of a tetracycline-responsive modified hybrid borrelial promoter were cloned into pKFSS1. This construct was electroporated into a B. burgdorferi host strain carrying a chromosomally located tetR under the control of the B. burgdorferi flaB promoter. After induction by anhydrotetracycline, expression of antisense ftsZ RNA resulted in generation of filamentous B. burgdorferi that were unable to divide and grew more slowly than uninduced cells. To determine whether FtsZ(Bbu) could interfere with the function of E. coli FtsZ, ftsZ(Bbu) was amplified from chromosomal DNA and placed under the control of the tetracycline-regulated hybrid promoter. After introduction of the construct into E. coli and induction with anhydrotetracycline, overexpression of ftsZ(Bbu) generated a filamentous phenotype. This suggested interference of ftsZ(Bbu) with E. coli FtsZ function and confirmed the role of ftsZ(Bbu) in cell division. This is the first report of the generation of a B. burgdorferi conditional lethal mutant equivalent by tetracycline-controlled expression of antisense RNA.     

Cloning and characterization of Bacillus subtilis homologs of Escherichia coli cell division genes ftsZ and ftsA.

The Bacillus subtilis homolog of the Escherichia coli ftsZ gene was isolated by screening a B. subtilis genomic library with anti-E. coli FtsZ antiserum. DNA sequence analysis of a 4-kilobase region revealed three open reading frames. One of these coded for a protein that was about 50% homologous to the E. coli FtsZ protein. The open reading frame just upstream of ftsZ coded for a protein that was 34% homologous to the E. coli FtsA protein. The open reading frames flanking these two B. subtilis genes showed no relationship to those found in E. coli. Expression of the B. subtilis ftsZ and ftsA genes in E. coli was lethal, since neither of these genes could be cloned on plasmid vectors unless promoter sequences were first removed. Cloning the B. subtilis ftsZ gene under the control of the lac promoter resulted in an IPTGs phenotype that could be suppressed by overproduction of E. coli FtsZ. These genes mapped at 135 degrees on the B. subtilis genetic map near previously identified cell division mutations.     

Analysis of cell division gene ftsZ (sulB) from gram-negative and gram-positive bacteria.

The ftsZ (sulB) gene of Escherichia coli codes for a 40,000-dalton protein that carries out a key step in the cell division pathway. The presence of an ftsZ gene protein in other bacterial species was examined by a combination of Southern blot and Western blot analyses. Southern blot analysis of genomic restriction digests revealed that many bacteria, including species from six members of the family Enterobacteriaceae and from Pseudomonas aeruginosa and Agrobacterium tumefaciens, contained sequences which hybridized with an E. coli ftsZ probe. Genomic DNA from more distantly related bacteria, including Bacillus subtilis, Branhamella catarrhalis, Micrococcus luteus, and Staphylococcus aureus, did not hybridize under minimally stringent conditions. Western blot analysis, with anti-E. coli FtsZ antiserum, revealed that all bacterial species examined contained a major immunoreactive band. Several of the Enterobacteriaceae were transformed with a multicopy plasmid encoding the E. coli ftsZ gene. These transformed strains, Shigella sonnei, Salmonella typhimurium, Klebsiella pneumoniae, and Enterobacter aerogenes, were shown to overproduce the FtsZ protein and to produce minicells. Analysis of [35S]methionine-labeled minicells revealed that the plasmid-encoded gene products were the major labeled species. This demonstrated that the E. coli ftsZ gene could function in other bacterial species to induce minicells and that these minicells could be used to analyze plasmid-endoced gene products.     

Red重组系统在痢疾杆菌基因敲除中的应用研究

利用λ噬菌体的Red系统在细菌中进行基因敲除的技术,最近发展较快,但多在大肠杆菌中进行。以alkA、wcaJ、yphF和dam 4个基因为例,分别在大肠杆菌和痢疾杆菌中利用Red系统进行基因敲除。对于大肠杆菌,除dam基因外,其余3个基因均能被有效敲除,而在痢疾杆菌中只能敲除一个alkA基因。结果表明,为使该系统能有效地应用于痢疾杆菌和其它细菌,还需对该系统进行改进。