"睡美人"转座子系统研究进展

转座子在脊椎动物中的应用远落后于在其他生物系统中的应用。“睡美人”转座子(sleeping beauty transposon)是Tc1/mariner转座因子超家族中的一员,是存在于鲑鱼基因组中的1个已经失活的转座子。1997年,Ivics等将这个转座子进行重建并恢复了它的活性。短短几年内的有关研究表明,“睡美人”转座子是目前在脊椎动物中转座活性最高的转座子。结合该转座子系统逐步显示出的广阔应用前景,本文重点论述了其结构、转座机制及应用,并提出了应用“睡美人”转座子系统须注意的问题。     

睡美人转座子在草鱼CIK细胞中介导的高效基因整合

为研究睡美人(Sleeping Beauty, SB)转座子系统在草鱼(Ctenopharyngodon idellus)肾脏细胞(CIK)中介导的整合特性, 构建了SB转座子和转座酶在两个质粒的二元反式(trans)转座子系统, 以及转座子和转座酶元件在同一个质粒的一元顺式(cis)转座子系统; 通过转染CIK细胞, 用荧光显微镜、流式细胞仪和荧光定量PCR分析了转染2d后及嘌呤霉素筛选4周后的细胞, 测定DsRed转染效率和整合效率, 并结合高效热不对称交互式PCR扩增获得SB转座子整合位点的序列。结果表明, SB二元转座子系统的整合效率远高于一元系统; SB转座子与转座酶比例为1﹕2时, 外源基因DsRed的整合效率最高; SB转座子偏向于插入草鱼基因组TA序列处。研究表明优化SB转座子和转座酶的比例能提高外源基因在草鱼细胞中的整合效率并快速获得突变细胞, 同时为在鱼类细胞中采用SB转座子建立突变体文库提供理论基础。     

“睡美人”转座系统研究进展

“睡美人 (SleepingBeauty ,SB)”转座系统是Tc1/mariner转座因子超家族中的一员 ,是目前唯一取材于脊椎动物的具有活性的转座系统 .对近年来有关“睡美人”的研究进展作一个综述 ,并针对存在的问题提出相应的解决方案 .     

转座子Sleeping Beauty和PiggyBac

近10年来,得益于转座子Sleeping Beauty(SB)和PiggyBac(PB)的发现和完善,转座子作为一种遗传工程工具在脊椎动物的基因遗传研究中得到广泛应用.SB和PB宿主范围极其广泛,从单细胞生物到哺乳动物都能够发挥作用.转座过程需要转座序列和转座酶的存在,类似于"剪切"、"粘贴"的方式.转座子载体系统转座时可携带一段外源DNA序列,利用这一特性可以用于实现目的基因的转移,现已广泛用于转基因动物、基因功能研究、基因治疗等领域.当转座系统与基因捕获技术相结合,不仅可研究插入突变基因的功能,还能通过所携带的报告基因获得捕获基因的表达图谱.作为非病毒载体的SB和PB转座系统,由于具有高容量、高效率和高安全性等优势,并且PB在转座后不留任何足迹,不会造成遗传物质的不可预测改变,在动物基因工程以及基因治疗方面具有诱人的前景.     

一种包含转座子Sleeping Beauty和PiggyBac的新型多功能载体的构建

DNA转座子作为一种遗传学工具对脊椎动物的转基因、突变体产生、癌基因发现和基因治疗方面都有巨大的贡献. 目前,哺乳动物中应用最为广泛、活性最高的DNA转座子为重构于鲑鱼的Sleeping Beauty (SB)转座子和来源于甘蓝蠖度尺蛾 (cabbage looper moth Trichoplusia ni)的PiggyBac (PB)转座子. 本研究中,我们成功构建了包含PB和SB两种转座子的杂合转座载体,命名为PBSBD. 在杂合转座载体中融入了基因捕获框及loxp/Frt元件,用以实现转座过程中的基因捕获和条件性敲除. 在HepG2细胞中通过检测报告基因的表达情况及阳性克隆的定位,对构建的杂合转座载体PBSBD进行了活性的初步验证. 结果表明,PBSBD能够有效被2种转座酶识别,并能检测到报告基因的表达. 本研究所构建的杂合转座载体PBSBD结合2种转座酶,可以应用于大规模筛选突变基因和研究基因功能. 并且该杂合转座载体还可以利用SB转座酶的邻近转座特性,结合载体内所包含的loxp/Frt元件用以邻近区域DNA片段的条件性敲除,研究大片段DNA在生物体中的作用.     

Tol1转座子研究进展

Tol1和Tol2是在青鳉基因组中发现的具有自主活性的DNA转座子,而Tol1转座子的自主活性是新近才发现的,因此对它的报道较少。较之Tol2,Tol1可以携带更大片段的DNA进行转座,且Tol1的转座不受转座酶"过量表达抑制"的影响。研究已证实,Tol1转座子在秀丽线虫、斑马鱼、爪蟾和人等多种生物中具有转座活性。因此,在动物转基因和基因功能研究等方面有重要的应用前景。从Tol1转座子的结构特征、转座机制和作为基因转移载体的优点,以及应用研究等方面进行了简要的综述。     

细菌中介导多重耐药的Tn7转座子研究进展

转座子是介导细菌耐药性传播的重要可移动遗传元件。Tn7转座子与细菌耐药密切相关,其携带转座模块和Ⅱ类整合子系统。Tn7编码转座相关蛋白TnsABCDE进行“剪切-粘贴”机制转座,转座核心TnsABC也可与三链DNA或Cas-RNA复合物结合实现转座。近年来新发现了多种介导多重耐药的Tn7转座子,其在介导细菌抗生素、消毒剂和重金属抗性基因的获得、传播扩散等方面发挥了重要作用。本文综述了细菌中Tn7转座子的遗传结构、转座机制、流行以及新发现的介导多重耐药的Tn7转座子,以期为细菌中Tn7转座子的深入研究提供参考。     

Mutator转座子及MULE在植物基因与基因组进化中的作用

Mutator（Mu）转座子是植物中已发现的转座最活跃的转座子,其高的转座频率及趋向于单拷贝功能基因转座的特性,使该转座子成为玉米功能基因克隆的主要方法.Mu转座子的同源类似因子广泛存在于被子植物基因组中,而且同一基因组中往往具有多种变异类型.它不仅具有其他DNA转座子在基因和基因组进化中的普遍作用,而且具有能够承载基因组内功能基因和基因片段的载体功能,这种载体Mu转座子（Pack-MuLEs）能够在基因组内移动众多的基因片段,从而对基因和基因组进化产生作用.Mu转座子的同源序列发生在水稻与狗尾草之间的水平转移提供了高等植物核基因水平转移的首个例证.对Mu转座子的了解促进了我们对动态基因组概念的认识.文章对Mutator转座子的发现、转座特征、基因标签应用等的研究进展进行了综述,对Mu转座子家族的同源序列进行了分类,讨论了该转座子在基因组进化中的作用,分析了应加强研究的问题.     

转座子PiggyBac在哺乳动物中的应用

DNA转座子作为一种遗传工程工具已广泛应用于多物种的转基因及产生插入突变等研究。目前,在哺乳动物中有转座活性的转座子可分为三类：1）hAT样转座子;2）Tcl样转座子包括Sleeping Beauty和FrogPrince;3）PiggyBac转座子家族。其中甘蓝蠖度尺蛾（Cabbage looper moth Trichoplusia ni）来源的PiggyBac转座子是目前在哺乳动物中活性最高的转座子,并且可以携带十几kb的外源基因转座而不影响其效率,使其在哺乳动物的转基因、癌基因的发现、基因治疗研究方面具有巨大的应用潜力。此外,PB的无痕迹转座对于无转基因、无遗传物质改变的诱导多潜能干细胞（iPS）研究也具有非常重要的意义。本文主要对针对PB在哺乳动物中的应用现状及前景作一介绍。     

Tc1/Mariner转座子超家族的研究进展

随着高通量测序技术的迅猛发展,越来越多的生物基因组注释结果表明：转座子几乎存在于所有生物的基因组中,是大多数生物基因组的重要组分。其中,Tc1/Mariner转座子是自然界中分布最广泛的一类DNA转座子超家族,在自然界已经发现14个有活性的Tc1/Mariner转座子(如Minos,Mos1等),另外通过分子重构也获得高活性的人工转座子,如睡美人转座子(Sleeping Beauty, SB)。SB和Mos1等转座子作为基因转移载体已被广泛应用于转基因、基因捕获和基因治疗等领域的研究中,并取得了很好的应用效果。本文将重点综述Tc1/Mariner转座子的结构、分类、分布、转座机制、活性转座子的挖掘,及其在转基因、基因捕获和基因治疗等研究领域的应用。     

Alternative conformations of a nucleic acid four-way junction

Sleeping Beauty (SB), a member of the Tc1/mariner superfamily of transposable elements, is the only active DNA-based transposon system of vertebrate origin that is available for experimental manipulation. We have been using the SB element as a research tool to investigate some of the cis and trans-requirements of element mobilization, and mechanisms that regulate transposition in vertebrate species. In contrast to mariner transposons, which are regulated by overexpression inhibition, the frequency of SB transposition was found to be roughly proportional to the amount of transposase present in cells. Unlike Tc1 and mariner elements, SB contains two binding sites within each of its terminal inverted repeats, and we found that the presence of both of these sites is a strict requirement for mobilization. In addition to the size of the transposon itself, the length as well as sequence of the DNA outside the transposon have significant effects on transposition. As a general rule, the closer the transposon ends are, the more efficient transposition is from a donor molecule. We have found that SB can transform a wide range of vertebrate cells from fish to human. However, the efficiency and precision of transposition varied significantly among cell lines, suggesting potential involvement of host factors in SB transposition. A positive-negative selection assay was devised to enrich populations of cells harboring inserted transposons in their chromosomes. Using this assay, of the order of 10,000 independent transposon insertions can be generated in human cells in a single transfection experiment. Sleeping Beauty can be a powerful alternative to other vectors that are currently used for the production of transgenic animals and for human gene therapy.     

Excision of Sleeping Beauty transposons: parameters and applications to gene therapy

A major problem in gene therapy is the determination of the rates at which gene transfer has occurred. Our work has focused on applications of the Sleeping Beauty (SB) transposon system as a non-viral vector for gene therapy. Excision of a transposon from a donor molecule and its integration into a cellular chromosome are catalyzed by SB transposase. In this study, we used a plasmid-based excision assay to study the excision step of transposition. We used the excision assay to evaluate the importance of various sequences that border the sites of excision inside and outside the transposon in order to determine the most active sequences for transposition from a donor plasmid. These findings together with our previous results in transposase binding to the terminal repeats suggest that the sequences in the transposon-junction of SB are involved in steps subsequent to DNA binding but before excision, and that they may have a role in transposase-transposon interaction. We found that SB transposons leave characteristically different footprints at excision sites in different cell types, suggesting that alternative repair machineries operate in concert with transposition. Most importantly, we found that the rates of excision correlate with the rates of transposition. We used this finding to assess transposition in livers of mice that were injected with the SB transposon and transposase. The excision assay appears to be a relatively quick and easy method to optimize protocols for delivery of genes in SB transposons to mammalian chromosomes in living animals.     

Germline mutagenesis mediated by <Emphasis Type="Italic">Sleeping Beauty</Emphasis>transposon system in mice

Following the descovery of its transposition activity in mammalian culture systems, the Sleeping Beauty (SB) transposon has since been applied to achieve germline mutagenesis in mice. Initially, the transposition efficiency was found to be low in cultured systems, but its activity in germ cells was unexpectedly high. This difference in transposition efficiency was found to be largely dependent on chromosomal status of the host genomic DNA and transposon vector design. The SB transposon system has been found to be suitable for comprehensive mutagenesis in mice. Therefore, it is an effective tool as a forward genetics screen for tagged insertional mutagenesis in mice.     

The Folding of the Specific DNA Recognition Subdomain of the Sleeping Beauty Transposase Is Temperature-Dependent and Is Required for Its Binding to the Transposon DNA

The reaction of DNA transposition begins when the transposase enzyme binds to the transposon DNA. Sleeping Beauty is a member of the mariner family of DNA transposons. Although it is an important tool in genetic applications and has been adapted for human gene therapy, its molecular mechanism remains obscure. Here, we show that only the folded conformation of the specific DNA recognition subdomain of the Sleeping Beauty transposase, the PAI subdomain, binds to the transposon DNA. Furthermore, we show that the PAI subdomain is well folded at low temperatures, but the presence of unfolded conformation gradually increases at temperatures above 15°C, suggesting that the choice of temperature may be important for the optimal transposase activity. Overall, the results provide a molecular-level insight into the DNA recognition by the Sleeping Beauty transposase.     

Size matters: versatile use of <Emphasis Type="Italic">PiggyBac</Emphasis> transposons as a genetic manipulation tool

Transposons have been promising elements for gene integration, and the Sleeping Beauty (SB) system has been the major one for many years, although there have been several other transposon systems available, for example, Tol2. However, recently another system known as PiggyBac (PB) has been introduced and developed for fulfilling the same purposes, for example, mutagenesis, transgenesis and gene therapy and in some cases with improved transposition efficiency and advantages over the Sleeping Beauty transposon system, although improved hyperactive transposase has highly increased the transposition efficacy for SB. The PB systems have been used in many different scientific research fields; therefore, the purpose of this review is to describe some of these versatile uses of the PiggyBac system to give readers an overview on the usage of PiggyBac system.     

NMR solution structure of the RED subdomain of the Sleeping Beauty transposase

DNA transposons can be employed for stable gene transfer in vertebrates. The Sleeping Beauty (SB) DNA transposon has been recently adapted for human application and is being evaluated in clinical trials, however its molecular mechanism is not clear. SB transposition is catalyzed by the transposase enzyme, which is a multi‐domain protein containing the catalytic and the DNA‐binding domains. The DNA‐binding domain of the SB transposase contains two structurally independent subdomains, PAI and RED. Recently, the structures of the catalytic domain and the PAI subdomain have been determined, however no structural information on the RED subdomain and its interactions with DNA has been available. Here, we used NMR spectroscopy to determine the solution structure of the RED subdomain and characterize its interactions with the transposon DNA.     

Characterization of Sleeping Beauty transposition and its application to genetic screening in mice

The use of mutant mice plays a pivotal role in determining the function of genes, and the recently reported germ line transposition of the Sleeping Beauty (SB) transposon would provide a novel system to facilitate this approach. In this study, we characterized SB transposition in the mouse germ line and assessed its potential for generating mutant mice. Transposition sites not only were clustered within 3 Mb near the donor site but also were widely distributed outside this cluster, indicating that the SB transposon can be utilized for both region-specific and genome-wide mutagenesis. The complexity of transposition sites in the germ line was high enough for large-scale generation of mutant mice. Based on these initial results, we conducted germ line mutagenesis by using a gene trap scheme, and the use of a green fluorescent protein reporter made it possible to select for mutant mice rapidly and noninvasively. Interestingly, mice with mutations in the same gene, each with a different insertion site, were obtained by local transposition events, demonstrating the feasibility of the SB transposon system for region-specific mutagenesis. Our results indicate that the SB transposon system has unique features that complement other mutagenesis approaches.     

Sleeping beauty transposase has an affinity for heterochromatin conformation

The Sleeping Beauty (SB) transposase reconstructed from salmonid fish has high transposition activity in mammals and has been a useful tool for insertional mutagenesis and gene delivery. However, the transposition efficiency has varied significantly among studies. Our previous study demonstrated that the introduction of methylation into the SB transposon enhanced transposition, suggesting that transposition efficiency is influenced by the epigenetic status of the transposon region. Here, we examined the influence of the chromatin status on SB transposition in mouse embryonic stem cells. Heterochromatin conformation was introduced into the SB transposon by using a tetracycline-controlled transrepressor (tTR) protein, consisting of a tetracycline repressor (TetR) fused to the Kruppel-associated box (KRAB) domain of human KOX1 through tetracycline operator (tetO) sequences. The excision frequency of the SB transposon, which is the first step of the transposition event, was enhanced by approximately 100-fold. SB transposase was found to be colocalized with intense DAPI (4',6'-diamidino-2-phenylindole) staining and with the HP1 family by biochemical fractionation analyses. Furthermore, chromatin immunoprecipitation analysis revealed that SB transposase was recruited to tTR-induced heterochromatic regions. These data suggest that the high affinity of SB transposase for heterochromatin conformation leads to enhancement of SB transposition efficiency.     

Mutational analysis of the N-terminal DNA-binding domain of sleeping beauty transposase: critical residues for DNA binding and hyperactivity in mammalian cells

The N-terminal domain of the Sleeping Beauty (SB) transposase mediates transposon DNA binding, subunit multimerization, and nuclear translocation in vertebrate cells. For this report, we studied the relative contributions of 95 different residues within this multifunctional domain by large-scale mutational analysis. We found that each of four amino acids (leucine 25, arginine 36, isoleucine 42, and glycine 59) contributes to DNA binding in the context of the N-terminal 123 amino acids of SB transposase, as indicated by electrophoretic mobility shift analysis, and to functional activity of the full-length transposase, as determined by a quantitative HeLa cell-based transposition assay. Moreover, we show that amino acid substitutions within either the putative oligomerization domain (L11A, L18A, L25A, and L32A) or the nuclear localization signal (K104A and R105A) severely impair its ability to mediate DNA transposition in mammalian cells. In contrast, each of 10 single amino acid changes within the bipartite DNA-binding domain is shown to greatly enhance SB's transpositional activity in mammalian cells. These hyperactive mutations functioned synergistically when combined and are shown to significantly improve transposase affinity for transposon end sequences. Finally, we show that enhanced DNA-binding activity results in improved cleavage kinetics, increased SB element mobilization from host cell chromosomes, and dramatically improved gene transfer capabilities of SB in vivo in mice. These studies provide important insights into vertebrate transposon biology and indicate that Sleeping Beauty can be readily improved for enhanced genetic research applications in mammals.