植物转基因整合座位的结构

通过农杆菌和直接DNA转移技术所获得的转基因植株都具有复杂的转基因座位, 转基因整合染色体和染色体区段是随机的, 但组织培养的选择作用表现为非随机性, 偏向整合于染色体的基因富集区。转基因座位除少数含有完整的单拷贝转基因之外, 大多数转基因座位中外源转基因片段、基因组片段和填充DNA相间而存在。转基因座位中转基因及基因组DNA片段产生缺失、重复和染色体的重排, 转基因的完整性对转基因表达具有重要作用。     

大麦转基因座位结构的研究

利用质粒营救法获得基因枪法转化的4种转绿色荧光蛋白基因(green fluorescent protein,GFP)大麦的转基因座位序列,序列分析显示4种材料的转基因座位中均有完整栽体的串联重复现象,表明转基因整合是同源重组的结果.同时转基因座位中也存在不完整载体片段、基因组片段的混杂排列,说明转基因整合时也发生异常重组.微粒轰击的转基因整合是由异常重组和同源重组共同完成的.     

植物中转基因的整合机制

转基因在植物基因组中的整合分两步:在整合前阶段,转化的完整质粒及转基因片段经重组连接形成转基因串联子(transgenearray),其中不含任何植物基因组序列,连接反应由植物细胞本身的酶催化,仅依赖于游离的DNA末端,CaMV35S启动子和TDNA边界序列中的特定序列可能充当重组热点;在整合阶段,转基因DNA通过微同源介导的异常重组整合到植物基因组中,最初的整合位点作为整合热点,引导随后的转基因分子在该位点附近整合,不同转基因位点可被1～10kb植物DNA隔开,形成转基因簇(transgenecluster)。     

精准高效外源DNA整合技术研究进展

精准高效整合技术是将外源DNA片段插入到目的细胞基因组特定位置的一项转基因技术。早期通过细胞基因组与外源DNA同源序列发生重组来完成靶向整合的目的。伴随基因编辑技术发展,特别是CRISPR/Cas9技术的出现,精准高效的外源DNA整合技术日益成熟,广泛应用到功能基因组学、转基因动物及遗传疾病治疗的研究中。围绕基因编辑研究进展、引导RNA修饰技术、单碱基整合技术、转座子技术和外源DNA整合效率等方面对精准靶向和高效整合技术进行综述。     

动物基因组定点整合转基因技术研究进展

传统转基因技术,如显微注射、转座子、慢病毒转染等将目的基因插入基因组内的整合方式是随机的,这些随机整合对后期转基因动物品系组建和育种带来诸多不利,因此有研究人员提出了定点整合转基因技术。目前该技术的定点整合效率非常低,主要取决于两个方面：一是靶位点产生DNA双链断裂(double-strand break, DSB)的效率;二是断裂后的靶位点与携带同源臂及外源基因的供体质粒发生同源重组的效率,其中同源重组修复(homologous recombination repair, HDR)是基因组定点整合最为依赖的修复机制。靶位点产生DSB后,机体的DNA修复既可能发生HDR,也可能发生非同源末端连接(nonhomologous end joining, NHEJ),并且两者之间存在竞争关系,因此激活HDR或抑制NEHJ都可提高定点整合转基因的效率。本文结合影响定点整合的因素,对提高定点整合效率最新探索方面进行了综述。     

噬菌体重组酶介导的DNA同源重组工程

来源于噬菌体的遗传操作工具在基因工程中具有非常重要的地位,例如位点特异性重组酶、柯斯质粒DNA文库及同源重组酶等。其中,来源于lambda噬菌体的同源重组酶Redα/Redβ和来源于Rac原噬菌体的同源重组酶RecE/RecT能够高效地介导35–50 bp短同源臂之间的重组。基于噬菌体同源重组酶Redα/Redβ和RecE/RecT开发的DNA同源重组工程（Recombineering）能够对靶标DNA分子进行快速、精准、高效的修饰,不受限制性内切酶识别位点和DNA分子大小限制,已发展成为一种新型的基因工程技术。本文主要综述了噬菌体同源重组酶及其作用机制、在大肠杆菌及其他细菌中的应用和开发,以及在微生物次级代谢产物的挖掘、动植物转基因、病毒基因组克隆和修饰等方面的应用。原位激活沉默基因簇需要宿主特异性的DNA同源重组工程进行启动子和调控元件的修饰;异源表达次级代谢产物的首要步骤一般是通过RecET直接克隆大的DNA片段;动植物转基因复杂载体的构建效率在有了Red同源重组系统以后有了革命性的发展;RecET直接克隆和Red同源重组介导的感染性克隆构建和修饰方法,不仅有利于病毒基因组功能研究,同时也为载体疫苗开发提供了最优方案。     

染色体外同源重组结合细胞质注射途径研制转基因小鼠

以绵羊β-乳球蛋白基因(B—Lactoglobulin,β-LG)为转基因表达框架,将人G-CSF,(Human Granulocyte Colony Stimulating Factor,4G-CSF)基因与报告基因一增强型绿色荧光蛋白(Enhanced Green Fluorescenct Protein,EGFP)基因作为双表达单元拼接到口β-LG基因的第一外显子处,并在G-GSF基因两侧引入同源重组位点loxP、fox2272,将打靶基因表达构件β-LG-hG-GSF-IRES-EGFP(总长9．3kb)分为两段进行构建,片段Ⅰ(长5．9kb)与片段Ⅱ(长5．6kb)两段重叠部分为2．2kb。向小鼠受精卵细胞质共注射构件片段Ⅰ、Ⅱ和NLS(核定位信号)3个基因片段。对仔鼠进行整合与表达的检测。PCR-Southem杂交检测结果表明,片段I的整合率为62．3％(86／138),片段Ⅱ的整合率为54．3％(75／138),片段Ⅰ、Ⅱ共整合(包括两片段分别整合和染色体外同源重组两种情况)的小鼠为62只,整合率为44．9％(62／138),其中在双阳性转基因小鼠中发生染色体外同源重组的几率为80．6％(50／62)。RT-PCR-Southem检测了10只发生染色体外同源重组的转基因雌性小鼠,hG-GSF基因的表达率为90％(9／10),EGFP基因的表达率为100％(10／10),通过对其乳汁紫外吸收光谱的检测,EGFP基因的表达率为50％(5／10)。上述结果表明,染色体外同源重组结合细胞质注射技术研制转基因动物是简便实用的转基因途径。     

离子束重组酵母菌Ar_Han0458的RAPD与SSH的初步研究

通过低能氩离子注入介导蓝麻黄基因组DNA转化异常汉逊酵母菌,获得了遗传稳定的产麻黄碱的重组酵母菌株Ar_Han0458。RAPD分子检测结果表明重组菌株和出发菌株基因组之间存在多态性变化,从重组菌株DNA中分离得到一个439 bp的差异条带。经PCR验证,其5'端150 bp片段来源于麻黄基因组。通过SSH实验,从重组菌株DNA中分离获得9条差异基因表达片段,BLAST同源比对分析,其中5条差异表达基因片段功能分别为:乙醇脱氢酶、二氢鞘氨醇羟化酶、分子伴侣蛋白、亚精铵转运蛋白和NAD依赖的差向异构酶/脱水酶,另外4条差异表达基因在数据库中无同源序列。     

减数分裂与基因遗传三定律

我们知道,染色体是遗传物质DNA的主要载体,基因则是有遗传效应的DNA片段。每个基因在染色体上都有一定的座位,等位基因则位于一对同源染色体的相同座位上。不同对的等位基因之间互为非等位基因,它们既可以位于非同源染色体上,又可以位于一对同源染色体的不同座位上,位于同一条染色体上的非等位基因通常称为连锁基因。正因为染色体是基因的载体,所以,在减数分裂过程中染色体动态与基因行为之间存在着必然联系,即染色体的遗传动态成为基因遗传行为的细胞学基础。下面仅就减数分裂与基因遗传三定律的     

采用玉米Ubi-1启动子获得低拷贝转基因玉米植株

通过基因枪粒子轰击和草丁膦（PPT）选择获得可育的玉米转基因植株,并分析了外源基因在转化体中的拷贝数与启动子之间的关系。用玉米Ubi-1启动子驱动外源基因,玉米转化体中外源基因的拷贝数较低;可能的原因为Ubi-1启动子通过与其内部同源序列发生重组而被定点整合进玉米基因组,共转化的两种质粒DNA在整合至玉米染色体DNA之前已重构成为一个整体。结果显示使用某一植物自身基因的启动子可以降低外源基因在该物种转基因个体中的拷贝数,进而避免基因沉默现象的发生。目前已得到第二代转基因玉米种子。     

Complex transgene locus structures implicate multiple mechanisms for plant transgene rearrangement

To more fully characterize the internal structure of transgene loci and to gain further understanding of mechanisms of transgene locus formation, we sequenced more than 160 kb of complex transgene loci in two unrelated transgenic oat (Avena sativa L.) lines transformed using microprojectile bombardment. The transgene locus sequences from both lines exhibited extreme scrambling of non-contiguous transgene and genomic fragments recombined via illegitimate recombination. A perfect direct repeat of the delivered DNA, and inverted and imperfect direct repeats were detected in the same transgene locus indicating that homologous recombination and synthesis-dependent mechanism(s), respectively, were also involved in transgene locus rearrangement. The most unexpected result was the small size of the fragments of delivered and genomic DNA incorporated into the transgene loci via illegitimate recombination; 50 of the 82 delivered DNA fragments were shorter than 200 bp. Eleven transgene and genomic fragments were shorter than the DNA lengths required for Ku-mediated non-homologous end joining. Detection of these small fragments provided evidence that illegitimate recombination was most likely mediated by a synthesis-dependent strand-annealing mechanism that resulted in transgene scrambling. Taken together, these results indicate that transgene locus formation involves the concerted action of several DNA break-repair mechanisms.     

Transgene integration in plants: poking or patching holes in promiscuous genomes?

Transgene integration in plants transformed by either Agrobacterium or direct DNA delivery methods occurs through illegitimate recombination (IR). The precise mechanism(s) for IR-mediated transgene integration and the role of host double-strand break repair enzymes remain unknown. A recent wealth of sequenced transgene loci and investigations aimed at genetically dissecting transgene integration mechanism(s) have provided new insights into the process.     

The structures of integration sites in transgenic rice

Extensive genomic sequencing and sequence motif analysis have been conducted over the integration sites of two transgenic rice plants, #478 and #559, carrying the luciferase gene and/or hygromycin phosphotransferase gene. The transgenes reside in a region with inverted structure and a large duplication of rice genome over 2 kb. Integration was found at the AT-rich region and/or at the repetitive sequence region, including a SAR-like structure, retrotransposon and telomere repeats. The presence of a patch of sequence homology between plasmid and target DNA, and a small region of duplication involving the target DNA around the recombination site, implicated illegitimate recombination in the process of gene integration. Massive rearrangement of genomic DNA including deletion or translocation was also observed at the integration site and the flanking region of the transgene. The recognition sites of DNA topoisomerases I or II were observed in the rearranged sequences. Since only three junctions of transgenic rice were implicated in the illegitimate recombination and extensive rearrangement of the rice genome, rice protoplasts may be active in this process.     

MAR‐Mediated transgene integration into permissive chromatin and increased expression by recombination pathway engineering

Untargeted plasmid integration into mammalian cell genomes remains a poorly understood and inefficient process. The formation of plasmid concatemers and their genomic integration has been ascribed either to non‐homologous end‐joining (NHEJ) or homologous recombination (HR) DNA repair pathways. However, a direct involvement of these pathways has remained unclear. Here, we show that the silencing of many HR factors enhanced plasmid concatemer formation and stable expression of the gene of interest in Chinese hamster ovary (CHO) cells, while the inhibition of NHEJ had no effect. However, genomic integration was decreased by the silencing of specific HR components, such as Rad51, and DNA synthesis‐dependent microhomology‐mediated end‐joining (SD‐MMEJ) activities. Genome‐wide analysis of the integration loci and junction sequences validated the prevalent use of the SD‐MMEJ pathway for transgene integration close to cellular genes, an effect shared with matrix attachment region (MAR) DNA elements that stimulate plasmid integration and expression. Overall, we conclude that SD‐MMEJ is the main mechanism driving the illegitimate genomic integration of foreign DNA in CHO cells, and we provide a recombination engineering approach that increases transgene integration and recombinant protein expression in these cells. Biotechnol. Bioeng. 2017;114: 384–396. © 2016 The Authors. Biotechnology and Bioengineering published by Wiley Periodicals, Inc.     

Complete sequence analysis of transgene loci from plants transformed via microprojectile bombardment

A substantial literature exists characterizing transgene locus structure from plants transformed via Agrobacterium and direct DNA delivery. However, there is little comprehensive sequence analysis of transgene loci available, especially from plants transformed by direct delivery methods. The goal of this study was to completely sequence transgene loci from two oat lines transformed via microprojectile bombardment that were shown to have simple transgene loci by Southern analysis. In line 3830, transformed with a single plasmid, one major and one of two minor loci were completely sequenced. Both loci exhibited rearranged delivered DNA and flanking genomic sequences. The minor locus contained only 296 bp of two non-contiguous fragments of the delivered DNA flanked by genomic (filler) DNA that did not originate from the integration target site. Predicted recognition sites for topoisomerase II and a MAR region were observed in the transgene integration target site for this non-functional minor locus. Line 11929, co-transformed with two different plasmids, had a single relatively simple transgene locus composed of truncated and rearranged sequences from both delivered DNAs. The transgene loci in both lines exhibited multiple transgene and genomic DNA rearrangements and regions of scrambling characteristic of complex transgene loci. The similar characteristics of recombined fragments and junctions in both transgenic oat lines implicate similar mechanisms of transgene integration and rearrangement regardless of the number of co-transformed plasmids and the level of transgene locus complexity.     

Topoisomerase I involvement in illegitimate recombination in Saccharomyces cerevisiae.

Chromosome aberrations may cause cancer and many heritable diseases. Topoisomerase I has been suspected of causing chromosome aberrations by mediating illegitimate recombination. The effects of deletion and of overexpression of the topoisomerase I gene on illegitimate recombination in the yeast Saccharomyces cerevisiae have been studied. Yeast transformations were carried out with DNA fragments that did not have any homology to the genomic DNA. The frequency of illegitimate integration was 6- to 12-fold increased in a strain overexpressing topoisomerase I compared with that in isogenic control strains. Hot spot sequences [(G/C)(A/T)T] for illegitimate integration target sites accounted for the majority of the additional events after overexpression of topoisomerase I. These hot spot sequences correspond to sequences previously identified in vitro as topoisomerase I preferred cleavage sequences in other organisms. Furthermore, such hot spot sequences were found in 44% of the integration events present in the TOP1 wild-type strain and at a significantly lower frequency in the top1delta strain. Our results provide in vivo evidence that a general eukaryotic topoisomerase I enzyme nicks DNA and ligates nonhomologous ends, leading to illegitimate recombination.     

Label-free amperometric immunosensor for the detection of human serum chorionic gonadotropin based on nanoporous gold and graphene

Identifying a good transgenic event from the pool of putative transgenics is crucial for further characterization. In transgenic plants, the transgene can integrate in either single or multiple locations by disrupting the endogenes and/or in heterochromatin regions causing the positional effect. Apart from this, to protect the unauthorized use of transgenic plants, the signature of transgene integration for every commercial transgenic event needs to be characterized. Here we show an affinity-based genome walking method, named locus-finding (LF) PCR (polymerase chain reaction), to determine the transgene flanking sequences of rice plants transformed by Agrobacterium tumefaciens. LF PCR includes a primary PCR by a degenerated primer and transfer DNA (T-DNA)-specific primer, a nested PCR, and a method of enriching the desired amplicons by using a biotin-tagged primer that is complementary to the T-DNA. This enrichment technique separates the single strands of desired amplicons from the off-target amplicons, reducing the template complexity by several orders of magnitude. We analyzed eight transgenic rice plants and found the transgene integration loci in three different chromosomes. The characteristic illegitimate recombination of the Agrobacterium sp. was also observed from the sequenced integration loci. We believe that the LF PCR should be an indispensable technique in transgenic analysis.     

Integration of heterologous plasmid DNA into multiple sites on the genome of Campylobacter coli following natural transformation.

The efficiency of homologous recombination in Campylobacter coli following the introduction of DNA by natural transformation was determined by using a series of nonreplicating integrative vectors containing DNA fragments derived from the C. coli catalase gene. Homologous recombination occurred with as little as 286 homologous bp present and was not detected when 270 bases of homology was provided. Instead, when plasmids with little or no homology to the chromosome were introduced by natural transformation, the vector DNA became chromosomally integrated at random sites scattered throughout the C. coli genome. Southern analysis and nucleotide sequencing revealed that recombination had occurred between nonhomologous sequences and can therefore be described as illegitimate. There were at least five different recombination sites on plasmid pSP105. The ability of C. coli to acquire heterologous plasmids by natural transformation, and maintain them by chromosomal integration following illegitimate recombination, has fascinating implications for the genomic diversity and evolution of this species.     

Genomic interspersions determine the size and complexity of transgene loci in transgenic plants produced by microprojectile bombardment.

The structure of transgene loci in six transgenic allohexaploid oat (Avena sativa L.) lines produced using microprojectile bombardment was characterized using fluorescence in situ hybridization (FISH) on extended DNA fibers (fiber-FISH). The transgene loci in five lines were composed of multiple copies of delivered DNA interspersed with genomic DNA fragments ranging in size from ca. 3 kb to at least several hundred kilobases, and in greater numbers than detected using Southern blot analysis. Although Southern analysis predicted that the transgene locus in one line consisted of long tandem repeats of the delivered DNA, fiber-FISH revealed that the locus actually contained multiple genomic interspersions. These observations indicated that transgene locus size and structure were determined by the number of transgene copies and, possibly to a greater extent, the number and the length of interspersing genomic DNA sequences within the locus. Large genomic interspersions detected in several lines were most likely the products of chromosomal breakage induced either by tissue culture conditions or, more likely, by DNA delivery into the nucleus using microprojectile bombardment. We propose that copies of transgene along with other extrachromosomal DNA fragments are used as patches to repair double-strand breaks (DSBs) in the plant genome resulting in the formation of transgene loci.     

Frequency and character of alternative somatic recombination fates of paralogous genes during T-DNA integration

A synthetic RBCSB gene cluster was transformed into Arabidopsis in order to simultaneously evaluate the frequency and character of somatic illegitimate recombination, homologous recombination, and targeted gene replacement events associated with T-DNA-mediated transformation. The most frequent type of recombination event observed was illegitimate integration of the T-DNA without activation of the silent ΔRBCS1B: LUC transgene. Sixteen luc⁺ (firefly luciferase positive) T1 plants were isolated. Six of these were due to illegitimate recombination events resulting in a gene trapping effect. Nine resulted from homologous recombination between paralogous RBCSB sequences associated with T-DNA integration. The frequency of somatic homologous recombination associated with T-DNA integration was almost 200 times higher than previously reported rates of meiotic homologous recombination with the same genes. The distribution of (somatic homologous) recombination resolution sites generally fits a fractional interval length model. However, a small region adjacent to an indel showed a significant over-representation of resolution sites, suggesting that DNA mismatch recognition may also play an important role in the positioning of somatic resolution sites. The frequency of somatic resolution within exon-2 was significantly different from that previously observed during meiotic recombination. Electronic Supplementary Material Supplementary material is available for this article at