酿酒酵母基因组位置效应对外源基因表达的影响

外源基因元件和模块在底盘细胞中发挥特定功能是合成生物学研究的基本过程,而外源元件和模块在基因组中的位置对其功能的实现具有显著影响。为了系统、全面地表征酿酒酵母基因组位置效应对外源基因的表达影响,以绿色荧光蛋白为报告基因,通过双交换同源重组方法,对酿酒酵母单基因敲除库进行高通量转化,构建酿酒酵母基因组单位点荧光标记菌株库。结合流式细胞术和高通量测序技术对单位点荧光标记库菌株进行分析,构建高表达位点库和低表达位点库,共发现促进绿色荧光蛋白表达的位点428个,抑制绿色荧光蛋白表达的位点444个。通过分析高、低表达位点在酵母染色体上的分布,从全基因组尺度上对酿酒酵母基因组整合位置对基因表达的影响进行表征。本研究可为酿酒酵母基因组位置效应的分布规律和产生机理研究提供重要参考,对外源蛋白工业生产和合成生物学中的基因表达精细调控也具有重要的指导意义。     

一种快速精确编辑疱疹病毒基因组的方法

为了快速且准确地对疱疹病毒基因组进行基因敲除、插入或者点突变等修饰,通过同源重组将马立克氏病病毒 (MDV) 超强毒株Md5基因组克隆到细菌人工染色体 (BAC)。将筛选的阳性重组体DNA电转进DH10B菌株,用PCR及限制性片段多态分析 (RFLP) 方法鉴定含Md5全基因组的BAC克隆。将阳性重组体DNA转染入鸡胚成纤维细胞 (CEF),拯救出重组病毒,命名为Md5BAC。进一步利用Red酶介导的两步法基因重组技术构建MDVlorf10基因敲除毒株。为了验证被敲除基因功能的特异性,将lorf10插入原位点以构建基因复原毒株。将构建的重组毒株分别感染CEF细胞,用间接免疫荧光试验确认重组病毒均包装成功;病毒生长曲线结果表明,lorf10敲除不影响病毒的体外增殖。总之,这为其他疱疹病毒的基因组编辑提供了技术参考。     

酿酒酵母NST1基因敲除菌的构建及其对抗氧化的影响

构建一株酿酒酵母(Saccharomyces cerevisiae)NST1基因缺失菌株并研究其对抗氧能力的影响。以酿酒酵母BY4741中的NST1基因为研究对象,利用Cre-LoxP基因敲除系统将NST1基因与G418抗性基因(kan~r)相替换,实现目的基因的敲除。通过稀释点样实验、荧光电子显微镜检测和荧光定量PCR等技术分析NST1基因在酿酒酵母抗氧化体系中的作用。经过G418抗性筛选和基因组PCR鉴定,成功获得了NST1基因缺失菌株nst1Δ,实验数据显示nst1Δ重组菌胞内ROS增多,并且降低了细胞壁完整性信号通路(CWI)途径下游基因RLM1的表达水平,表明NST1基因的敲除对酿酒酵母BY4741的抗氧化性能有影响。     

代谢工程与全基因组重组构建酿酒酵母抗逆高产乙醇菌株

将酿酒酵母海藻糖代谢工程与全基因组重组技术相结合,改良工业酿酒酵母菌株的抗逆性和乙醇发酵性能。对来源于二倍体出发菌株Zd4的两株优良单倍体Z1和Z2菌株进行杂交获得基因组重组菌株Z12,并对Z1和Z2先进行(1)过表达海藻糖-6-磷酸合成酶基因 (TPS1) ,(2)敲除海藻糖水解酶基因 (ATH1), (3)同时过表达 TPS1和敲除ATH1, 经此三种基因工程操作后再进行杂交获得代谢工程菌株的全基因组重组菌株Z12ptps1、Z12 Δath1和Z12pTΔA。与亲株Zd4相比,Z12及结合代谢工程获得的菌株在高糖、高乙醇浓度与高温条件下生长与乙醇发酵性能都有不同程度的改进。对比研究结果表明:在高糖发酵条件下,同时过表达 TPS1和敲除ATH1 的双基因操作工程菌株胞内海藻糖积累、乙醇主发酵速率和乙醇产量相对于亲株的提高幅度要大于只过表达 TPS1,或敲除ATH1 的工程菌。结合了全基因组重组后获得的二倍体工程菌株Z12pTΔA,与原始出发菌株Zd4及重组子Z12相比,主发酵速率分别提高11.4%和6.3%,乙醇产量提高7.0%和4.1%,与其胞内海藻糖含量高于其它菌株、在胁迫条件下具有更强耐逆境能力相一致。结果证明,海藻糖代谢工程与杂交介导的全基因组重组相结合,是提高酿酒酵母抗逆生长与乙醇发酵性能的有效策略与技术途径。     

合成型酿酒酵母染色体重排技术及应用

人工合成酿酒酵母染色体中引入大量lox Psym位点构成的SCRa Mb LE系统,在Cre重组酶的诱导下可以发生删除、反转、移位、复制等基因组重排,实现基因组的快速进化,为染色体结构变异和功能分析提供全新的研究平台。对合成型酵母染色体重排技术的最新研究和应用进行综述,该技术有望促进酿酒酵母在化学品和医药领域的产业化应用。     

酿酒酵母蔗糖关键代谢途径suc2基因的敲除及其蔗糖代谢特性的变化分析

蔗糖基生物质是热带和亚热带地区重要的生物质材料,因而在微生物发酵和微生物代谢原料中具有重要的地位。酿酒酵母(Saccharomyces cerevisiae)具有以蔗糖为原料进行代谢的能力,在酿酒酵母的基因组中蔗糖水解酶基因共有6个结构基因。本研究以酿酒酵母INVSC1为出发菌株,首先利用基因敲除技术构建suc2基因缺失菌株,然后将suc2基因回补,从而研究suc2基因对酿酒酵母蔗糖关键代谢途径及蔗糖代谢特性的影响。以蔗糖为碳源的发酵培养基中,在静置条件下发酵,suc2基因缺失菌株失去了利用蔗糖代谢的能力,回补菌株则恢复了对蔗糖的代谢;而且回补菌株对蔗糖的利用率及乙醇产量均比出发菌株有所提高。suc2基因是酿酒酵母蔗糖代谢的关键基因,对蔗糖的代谢具有决定性作用,可以作为蔗糖代谢途径改造的一个关键点。     

酿酒酵母ADH3基因的敲除

设计含有与酿酒酵母(Saccharomyces cerevisiae)编码乙醇脱氢酶Ⅲ的ADH3基因ORF两侧序列同源的长引物,以质粒pUG6为模板进行PCR构建带有Cre/loxP系统的敲除组件。转化酿酒酵母YS3(Saccharomyces cerevisiae),并将质粒pSH65转入阳性克隆子。半乳糖诱导表达Cre酶切除Kanr基因,在YPD培养基中连续传代培养丢失pSH65质粒,在原ORF处留下一个loxP位点,获得ADH3单倍体缺陷型菌株。利用同样的方法再次敲除双倍体的另一个等位基因。最终获得ADH3双倍体基因缺陷型突变株YS3-ADH3。     

酿酒酵母Mbp1缺陷型菌株的构建及其乙醇发酵特性

【目的】研究酿酒酵母(Saccharomyces cerevisiae)工业菌株Mbp1基因的功能,探讨Mbp1基因对酿酒酵母乙醇发酵性能的影响。【方法】以酿酒酵母MF1015为出发菌株,用PCR方法构建Mbp1基因敲除组件Loxp-KanMX-Loxp,将敲除组件转化两种配型的酿酒酵母单倍体,通过单倍体复倍获得敲除Mbp1基因的二倍体突变菌株,研究突变菌株形态变化及乙醇发酵特性。【结果】敲除Mbp1基因后突变菌株生长曲线无显著变化,出芽率降低,细胞体积增大19.2%,对饥饿更敏感,较早出现假菌丝。甘蔗糖蜜在静置条件下发酵,突变菌株的乙醇产量明显低于野生型;在130 r/min的条件下发酵,突变菌株和野生型发酵液中的乙醇产量基本相同。【结论】Mbp1基因缺失使酿酒酵母的乙醇发酵能力下降并影响细胞的形态分化。     

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。     

采用基因敲除和反义技术抑制酿酒酵母ERG7基因表达

酿酒酵母(Saccharomyces cerevisiae)固有的甲羟戊酸(MVA)/麦角甾醇代谢途径生成的中间体2,3-氧化鲨烯是三萜类化合物的合成前体,以酿酒酵母为底盘细胞通过合成生物学技术组建这些化合物的代谢途径时,需要下调2,3-氧化鲨烯流向麦角甾醇的代谢流。在酿酒酵母中由羊毛甾醇合酶(ERG7)催化的2,3-氧化鲨烯环化是麦角甾醇和三萜类化合物生物合成分支形成的关键位点。采用基因敲除和反义RNA 2种技术对ERG7基因的表达进行下调。设计含有与ERG7基因ORF两侧序列同源的长引物,以质粒PUG66为模板进行PCR扩增,构建带有loxP-Marker-loxP的ERG7基因敲除组件,采用LiAc/SS Carrier DNA/PEG方法转化双倍体酿酒酵母INVSc1,通过同源重组的方式获得酿酒酵母ERG7基因单倍体缺失突变株,并对其进行了分子生物学确证。大量培养野生型和突变型菌株,菌体冷干后在碱醇溶液中90℃回流1h,正己烷萃取后旋蒸干溶剂,甲醇溶解残留物麦角甾醇。通过TLC和HPLC方法比较麦角甾醇含量,结果表明:与野生型菌株相比,突变型菌株的麦角甾醇含量明显降低。     

Population genomics and speciation in yeasts

The advent of efficient whole genome sequencing and the large molecular and genetic toolbox available for studies in Saccharomyces cerevisiae and related species have allowed unprecedented analysis of big issues such as: what causes reproductive isolation and eventual speciation? The species complex encompassing S. cerevisiae and relatives consists of six species and several naturally occurring hybrids, which have nearly collinear genomes. They fit the biological species definition of within species fertility and between species sterility. There are examples of chromosome rearrangements and of genetic incompatibilities between species of the complex, which contribute to reproductive isolation but these are not universally present. In addition, simple sequence divergence has been shown to cause reproductive isolation via the action of the mismatch repair system. Although all three of these mechanisms contribute to extant reproductive isolation, which if any, drive the speciation process is still an open question. Population genomic surveys of whole genome sequences reveal introgressions and horizontal gene transfers between species, indicating that the species barriers are not complete. This gene flow between species, although infrequent, brings into question the nature of yeast species.     

URA3基因影响青蒿酸酿酒酵母工程菌中试发酵产量

CRISPR/Cas9基因编辑技术已经被广泛应用于工程酿酒酵母的基因插入、基因替换和基因敲除,通过使用选择标记进行基因编辑具有简单高效的特点。前期利用CRISPR/Cas9系统敲除青蒿酸生产菌株酿酒酵母(Saccharomyces cerevisiae) 1211半乳糖代谢负调控基因GAL80,获得菌株S. cerevisiae 1211-2,在不添加半乳糖诱导的情况下,青蒿酸摇瓶发酵产量达到了740 mg/L。但在50 L中试发酵实验中,S. cerevisiae 1211-2很难利用对青蒿酸积累起到决定性作用的碳源-乙醇,青蒿酸的产量仅为亲本菌株S.cerevisiae 1211的20%–25%。我们推测因遗传操作所需的筛选标记URA3突变,影响了其生长及青蒿酸产量。随后我们使用重组质粒pML104-KanMx4-u连同90 bp供体DNA成功恢复了URA3基因,获得了工程菌株S. cerevisiae 1211-3。S. cerevisiae 1211-3能够在葡萄糖和乙醇分批补料的发酵罐中正常生长,其青蒿酸产量超过20g/L,与亲本菌株产量相当。研究不但获得了不加半乳糖诱导的青...     

Genome-wide mapping of unexplored essential regions in the Saccharomyces cerevisiae genome: evidence for hidden synthetic lethal combinations in a genetic interaction network

Despite systematic approaches to mapping networks of genetic interactions in Saccharomyces cerevisiae, exploration of genetic interactions on a genome-wide scale has been limited. The S. cerevisiae haploid genome has 110 regions that are longer than 10 kb but harbor only non-essential genes. Here, we attempted to delete these regions by PCR-mediated chromosomal deletion technology (PCD), which enables chromosomal segments to be deleted by a one-step transformation. Thirty-three of the 110 regions could be deleted, but the remaining 77 regions could not. To determine whether the 77 undeletable regions are essential, we successfully converted 67 of them to mini-chromosomes marked with URA3 using PCR-mediated chromosome splitting technology and conducted a mitotic loss assay of the mini-chromosomes. Fifty-six of the 67 regions were found to be essential for cell growth, and 49 of these carried co-lethal gene pair(s) that were not previously been detected by synthetic genetic array analysis. This result implies that regions harboring only non-essential genes contain unidentified synthetic lethal combinations at an unexpectedly high frequency, revealing a novel landscape of genetic interactions in the S. cerevisiae genome. Furthermore, this study indicates that segmental deletion might be exploited for not only revealing genome function but also breeding stress-tolerant strains.     

Genome-wide identification of the targets for genetic manipulation to improve l-lactate production by Saccharomyces cerevisiae by using a single-gene deletion strain collection

To identify genome-wide targets for gene manipulation for increasing l-lactate production in recombinant Saccharomyces cerevisiae strains, we transformed all available single-gene deletion strains of S. cerevisiae with a plasmid carrying the human l-lactate dehydrogenase gene, and examined l-lactate production in the obtained transformants. The thresholds of increased or decreased l-lactate production were determined based on l-lactate production by the standard strain in repetitive experiments. l-lactate production data for 4802 deletion strains were obtained, and deletion strains with increased or decreased l-lactate production were identified. Functional category analysis of genes whose deletion increased l-lactate production revealed that ribosome biogenesis-related genes were overrepresented. Most deletion strains for genes related to ribosome biogenesis exhibited increased l-lactate production in 200-ml batch cultures. We deleted the genes related to ribosome biogenesis in a recombinant strain of S. cerevisiae with a genetic background different from that of the above deletion strains, and examined the effect of target gene deletion on l-lactate production. We observed that deletion of genes related to ribosome biogenesis leads to increased l-lactate production by recombinant S. cerevisiae strains, and the single-gene deletion strain collection could be utilized in identifying target genes for improving l-lactate production in S. cerevisiae recombinant strains.     

High-resolution cytological mapping of the long arm of chromosome 5A in common wheat using a series of deletion lines induced by gametocidal (Gc) genes of Aegilops speltoides

Gametocidal (Gc) genes of Aegilops in the background of the wheat genome lead to breakage of wheat chromosomes. The Q gene of wheat was used as a marker to select 19 deletion lines for the long arm of chromosome 5A of common wheat, Triticum aestivum cv. Chinese Spring (CS). The extents of deleted segments were cytologically estimated by the C-banding technique. The DNAs of deletion lines were hybridized with 22 DNA probes recognizing sites on the long arm of the chromosome (5AL) to determine their physical order. Based on the breeding behavior of the deletion lines, the location of a novel gene (Pv, pollen viability) affecting the viability of the male gamete was deduced. The segment translocated from 4AL to 5AL in CS was cytologically estimated to represent 13% of the total length of 5AL. Although DNA markers were almost randomly distributed along the chromosome arm, DNA markers located around the centromere and C-banded regions were obtained only rarely. Some deletion lines were highly rearranged in chromosome structure due to the effect(s) of the Gc gene. Applications of Gc genes for manipulating wheat chromosomes are discussed.     

酿酒酵母中基于CRISPR/Cas9工具的基因编辑与代谢调控研究进展

CRISPR/Cas9系统已广泛用于各种生物体的基因编辑和代谢工程。本文综述了CRISPR/Cas9在酿酒酵母中的基本原理和实际应用。首先总结了CRISPR/Cas9技术的发展历史、酿酒酵母基因组中基因缺失和多DNA片段插入的成功案例。这一先进的系统减少了劳动力,增强了对分子遗传学的理解,加速了微生物工程的发展。其次总结了基于CRISPR/Cas9的系统在生产高附加值化学品和提高酿酒酵母耐应激性方面的研究进展。该综述对酿酒酵母的遗传和合成生物学研究具有重要的参考价值。     

Excision of pIJ408 from the chromosome of Streptomyces glaucescens and its transfer into Streptomyces lividans

Summary Streptomyces glaucescens GLA000 contains the integrated 15 kb DNA element pIJ408 which, during mating of the parent strain with S. lividans, can be transferred into recipient cells. In S. lividans cells, pIJ408 was found in an autonomously replicating form and in a chromosomally integrated state. In the majority of the S. lividans transconjugants studied, a deletion derivative pIJ408. 1 (12.4 kb) occurred. The deletion form was found in some strains only as a free plasmid, in others it was also chromosomally integrated. The integration region of pIJ408 was subcloned and precisely mapped by hybridization, restriction and sequencing analyses. The DNA junction fragments of the integrated plasmid in S. glaucescens, as well as the DNA fragment containing the attachment site of the S. lividans chromosome, were also cloned, submitted to detailed restriction analysis and sequenced. The attachment site of pIJ408 (attP) and the junctions of its integrated form with the chromosomal DNA in S. glaucescens (attL and attR) contain an identical 43 bp sequence. The chromosomal attachment site in S. lividans (attB) differs from the S. glaucescens att sequence by a single base substitution. The similarities between attachment sites of SLP1, pMEA100, pSAM2 and pIJ408 are discussed.     

Comparative genetics of yeasts: A novel β-fructosidase gene <Emphasis Type="Italic">SUC8</Emphasis> in <Emphasis Type="Italic">Saccharomyces cerevisiae</Emphasis>

Molecular and genetic analyses revealed that the distillers race XII, which is an ancestor of Saccharomyces cerevisiae Peterhof and Gatchina genetic lines, has three polymeric β-fructosidase genes: SUC2, SUC5, and SUC8. The latter gene located on the X chromosome was identitied in this work for the first time. The presence of the single SUC2 gene in yeasts used in the international project on sequencing of the S. cerevisiae genome is discussed.     

Use of site-specific recombination to regenerate selectable markers

Summary A method which allows the repeated use of a single selectable marker in DNA transformations was demonstrated. This marker regeneration method employed portions of the Saccharomyces cerevisiae 2 m circle plasmid: the inverted repeat sequences (FRTs), and the FLP gene whose product, a site-specific recombinase, catalyzes recombination events between FRTs. When FRTs were oriented as direct repeats and integrated into the genome of the yeast Pichia pastoris, FLP-mediated recombination resulted in the efficient and precise deletion of DNA located between the repeats. In the example described, the S. cerevisiae ARG4 gene, placed between a set of FRTs and integrated into Pichia in a prior transformation, was deleted by FLP, thereby regenerating an arginine-requiring phenotype in the P. pastoris strain.