水稻第4号染色体不同位置的Ds转座子转座行为的分析

使用农杆菌介导的方法转化粳稻品种中花11,构建了在第4号染色体不同位置插入了Ds（dissociation）因子的水稻转化群体和带有Ac（activator）转座酶基因的转化植株。将携带了Ac转座酶基因的植株与不同Ds转化植株杂交,杂交F1代同时带有Ac转座酶和Ds因子（Ac／Ds植株）。用PCR方法检测了杂交F1代Ds的切离频率,结果发现靠近第4号染色体着丝粒附近的Ds转座子切离频率低,而靠近第4号染色体末端区域的Ds转座子切离频率高,这表明Ds转座子的原始插入位置对其杂交后代的切离频率有很大的影响,推测与原始插入位点附近的染色体结构有关。     

不同启动子控制下Ac转座酶基因的表达对玉米Ds因子在水稻中切离频率的影响

用水稻愈伤组织比较了Ac启动子、35S启动子与Ubi启动子控制下Ac转座酶基因（Ts）的表达对Ds因子切离频率的影响。结果表明Ubi启动子与Ac转座酶编码区嵌合基因（Ubipro-Ts)反式激活Ds因子的切离频率最高,达到了72．9％。通过杂交将Ubipro-Ts基因导入Ds因子转化植株,得到9株Ubipro-Ts基因与Ds因子共存的F1代杂交水稻植株,其中有8株Ds因子发生了切离。用Inverse-PCR的方法从其中一株杂交植株中克隆到Ds因子的旁邻序列,其DNA顺序与亲本中Ds因子原插入位点的序列不同,表明Ds因子转座到了新的基因组位点。     

不同启动子控制下Ac转座酶基因的表达对玉米Ds因子在水稻中切离频率的影响

用水稻愈伤组织比较了Ac启动子、35S启动子与Ubi启动子控制下Ac转座酶基因（Ts）的表达对Ds因子切离频率的影响。结果表明Ubi启动子与Ac转座酶编码区嵌合基因（Ubipro-Ts）反式激活Ds因子的切离频率最高,达到了72.9%。通过杂交将Ubipro-Ts基因导入Ds因子转化植株,得到9株Ubipro-Ts基因与Ds因子共存的F1代杂交水稻植株,其中有8株Ds因子发生了切离。用Inverse-PCR的方法从其中一株杂交植株中克隆到Ds因子的旁邻序列,其DNA顺序与亲本中Ds因子原插入位点的序列不同,表明Ds因子转座到了新的基因组位点。     

玉米Ac双因子转座标签系统的构建及其转化烟草后代的遗传分析

用使质粒ｐＫＵ３所携带的玉米Ａｃ因子５‘末端和中间编码转座酶的基因片段分别发生缺失的方法构建成质业ＰＫＵ３和ＰＫＵ３。质业所推人的ＡＣ因了单独存在时都无转座能力,但当ＡＣ和ＡＣ共存了于一个细胞时,由于ＡＣ产生转座酶的互补作用促使恢复转从能力,而当ＡＣ和ＡＣ因子一即获得ＡＣ 了的稳定插入突 可克服因突变不稳定崦给用转从因子标签法分离基因所造成的困难。将双因了系统导入烟草原生质体并猩财生株,从而选得卡     

插入玉米Ds转座因子的水稻转化群体及其分子分析

转座子标签法是一种利用转座因子插入高等植物基因组中造成基因突变,然后通过分离转座因子插入的旁邻顺序,进而克隆出突变基因的策略。这种策略在高等植物功能基因组学的研究中是十分有用的。为此目的,将玉米的Ds因子及bar基因连接至载体pCAMBIA1300的T-DNA区域中,构建成重组Ti质粒pDsBar1300。pDsBar1300中T-DNA区域中的潮霉素抗性基因可在转化过程中用作水稻转化植株的选择标记。插入在Ds因子中的bar基因可追踪转化后代的Ds因子。pDsBar1300通过根瘤农杆茵介导引入水稻品种中花11号的幼胚组织。从各转化愈伤组织中获得了1400株独立的Ds水稻转化植株。通过PPT抗性检测和PCR分析证明了水稻转化植株中Ds因子的整合。Southernblot分析了转化植株基因组中Ds因子的插入拷贝数,其中单拷贝插入比率约占70％。这些插有Ds因子的水稻转化植株,当引入自主型的Ac因子反式活化Ds因子后,可使Ds因子跳跃到不同位点上,就可得到更多的突变植株。     

插入玉米Ds转座因子的水稻转化群体及其分子分析

转座子标签法是一种利用转座因子插入高等植物基因组中造成基因突变,然后通过分离转座因子插入的旁邻顺序,进而克隆出突变基因的策略。这种策略在高等植物功能基因组学的研究中是十分有用的,为此目的,将玉米的Ｄｓ因子及ｂａｒ基因连接至载体ｐＣＡＭＢＩＡ１３００的Ｔ－ＤＮＡ区域中,构建成重组Ｔｉ质粒ｐＤｓＢａｒ１３００。ｐＤａＢａｒ１３００中Ｔ－ＤＮＡ区域中的潮霉素抗性基因可在转化过程中用作水稻转化植株的选择标     

Ac/Ds转座系统在水稻转化群体中的转座活性及转座子插入位点旁侧序列的分析

利用本实验室构建的转Ac(AcTPase)及Ds(Dissociation)的水稻(Oryza sativa L.)转化群体,配置了Ac×Ds的杂交组合354个.检测了转基因植株的T-DNA插入位点右侧旁邻序列,研究了Ac/Ds转座系统在水稻转化群体中的转座活性.结果表明,有些转化植株T-DNA插入位点相同或相距很近,插入位点互不相同的占65.4%.检测到T-DNA可插入到编码蛋白的基因中.在Ac×Ds的F2代中,Ds因子的转座频率为22.7%.对Ac×Ds杂交子代中Ds因子旁侧序列的分析,进一步表明了Ds因子在水稻基因组中的转座活性,除了从原插入位点解离并转座到新的位点之外,还有复制--转座和不完全切离等现象.获得的旁侧序列中,有些序列与GenBank中的数据没有同源性,目前有2个DNA片段在GenBank登录.探讨了构建转座子水稻突变体库进行水稻功能基因组学研究的策略.     

玉米转座因子Ac在单倍体烟草中转座的研究

把玉米转座因子Ａｃ插入花椰菜花叶病毒３５Ｓ启动子和链霉素抗性基因（ＳＰＴ）之间，构建带嵌合基因Ａｃ∷ＳＰＴ的双元载体ｐＳＡＣ１１。从普通烟草的花粉植株取单倍体组织，通过农杆菌转化法分别转化嵌合基因Ａｃ∷ＳＰＴ和Ａｃ∷ＧＵＳ（来自双元载体ｐＳＬＪ７２１），得到单倍体转基因植株。对转化Ａｃ∷ＳＰＴ的单倍体叶组织进行链霉素抗性分析，同时对转化Ａｃ∷ＧＵＳ的单倍体作ＧＵＳ活性鉴定，分别检测到Ａｃ从Ａｃ∷ＳＰＴ和Ａｃ∷ＧＵＳ处切离。Ｓｏｕｔｈｅｒｎ杂交表明，Ａｃ切离后在单倍体基因组的不同位点整合。上述烟草单倍体的转化体系的建立以及对Ａｃ因子转座的分析，将有助于在单倍体细胞中进行转座因子标签研究。     

Ac／Ds转座系统在水稻转化群体中的转座活性及转座子插入位点旁侧序列的分析

利用本实验室构建的转Ac(Ac TPase)及Ds(Dissociation)的水稻(Oryza sativa L.)转化群体,配置了Ae×Ds的杂交组合354个。检测了转基因植株的T-DNA插入位点右侧旁邻序列,研究了Ac/Ds转座系统在水稻转化群体中的转座活性。结果表明,有些转化植株T-DNA插入位点相同或相距很近,插入位点互不相同的占65.4％。检测到T-DNA可插入到编码蛋白的基因中。在Ac×Ds的F2代中,Ds因子的转座频率为22.7％。对Ac×Ds杂交子代中Ds因子旁侧序列的分析,进一步表明了Ds因子在水稻基因组中的转座活性,除了从原插入位点解离并转座到新的位点之外,还有复制——转座和小完全切离等现象。获得的旁侧序列中,有些序列与GenBank中的数据没有同源性,目前有2个DNA片段在GenBank登录。探讨了构建转座子水稻突变体库进行水稻功能基因组学研究的策略。     

细菌插入序列的转座酶和转座机制

插入序列（insertion sequence, IS）是细菌中最简单的移动遗传因子,由两端的反向重复序列（inverted repeats, IR）和中间的转座酶 (transposase)编码序列组成。在细菌中,因为插入序列的转座酶催化活性中心氨基酸序列不同,所以将其转座酶分为DDE转座酶、DEDD转座酶、HUH转座酶和丝氨酸转座酶。在转座过程中,根据插入序列是否有复制,将插入序列的转座分为复制型转座（replicative -ansposition）和非复制型转座（non-replicative transposition）,而将形成夏皮罗中间体（Shapiro intermediate）的非复制型转座称为保守型转座（conservative transposition）。此外,插入序列通过不同的转座机制插入到基因编码区导致基因突变、缺失和倒置;或者插入到基因上游,通过自身启动子或与基因形成杂交启动子来影响插入序列下游基因的表达,从而帮助细菌抵抗复杂的环境变化。本文主要围绕细菌插入序列的特征、转座酶、转座机制和转座影响展开综述,以期为进一步研究插入序列的机制和插入序列在细菌中所起的作用提供参考。     

植物转座子及其在番茄功能基因组的应用

转座子作为插入突变原或分子标签被广泛应用于基因的分离和克隆,已成为发现新基因和基因功能分析的有效工具。该文综述了植物转座子及其在基因分离中的研究进展,并讨论其在番茄功能基因遗传资源、功能基因组分离等研究中的应用。     

Use of Illumina sequencing to identify transposon insertions underlying mutant phenotypes in high‐copy Mutator lines of maize

High‐copy transposons have been effectively exploited as mutagens in a variety of organisms. However, their utility for phenotype‐driven forward genetics has been hampered by the difficulty of identifying the specific insertions responsible for phenotypes of interest. We describe a new method that can substantially increase the throughput of linking a disrupted gene to a known phenotype in high‐copy Mutator (Mu) transposon lines in maize. The approach uses the Illumina platform to obtain sequences flanking Mu elements in pooled, bar‐coded DNA samples. Insertion sites are compared among individuals of suitable genotype to identify those that are linked to the mutation of interest. DNA is prepared for sequencing by mechanical shearing, adapter ligation, and selection of DNA fragments harboring Mu flanking sequences by hybridization to a biotinylated oligonucleotide corresponding to the Mu terminal inverted repeat. This method yields dense clusters of sequence reads that tile approximately 400 bp flanking each side of each heritable insertion. The utility of the approach is demonstrated by identifying the causal insertions in four genes whose disruption blocks chloroplast biogenesis at various steps: thylakoid protein targeting (cpSecE), chloroplast gene expression (polynucleotide phosphorylase and PTAC12), and prosthetic group attachment (HCF208/CCB2). This method adds to the tools available for phenotype‐driven Mu tagging in maize, and could be adapted for use with other high‐copy transposons. A by‐product of the approach is the identification of numerous heritable insertions that are unrelated to the targeted phenotype, which can contribute to community insertion resources.     

High-throughput linkage analysis of Mutator insertion sites in maize

Insertional mutagenesis is a cornerstone of functional genomics. High-copy transposable element systems such as Mutator ( Mu ) in maize ( Zea mays ) afford the advantage of high forward mutation rates but pose a challenge for identifying the particular element responsible for a given mutation. Several large mutant collections have been generated in Mu -active genetic stocks, but current methods limit the ability to rapidly identify the causal Mu insertions. Here we present a method to rapidly assay Mu insertions that are genetically linked to a mutation of interest. The method combines elements of MuTAIL (thermal asymmetrically interlaced) and amplification of insertion mutagenized sites (AIMS) protocols and is applicable to the analysis of single mutants or to high-throughput analyses of mutant collections. Briefly, genomic DNA is digested with a restriction enzyme and adapters are ligated. Polymerase chain reaction is performed with TAIL cycling parameters, using a fluorescently labeled Mu primer, which results in the preferential amplification and labeling of Mu -containing genomic fragments. Products from a segregating line are analyzed on a capillary sequencer. To recover a fragment of interest, PCR products are cloned and sequenced. Sequences with lengths matching the size of a band that co-segregates with the mutant phenotype represent candidate linked insertion sites, which are then confirmed by PCR. We demonstrate the utility of the method by identifying Mu insertion sites linked to seed-lethal mutations with a preliminary success rate of nearly 50%.     

Establishment of the Self-incompatibility (S) Locus-directed Transposon Tagging System in Antirrhinum

In order to perform mutational studies on genes from the self-incompatibility (S) locus, an S locus-directed transposon tagging system was established in Antirrhinum. Cultivated lines of Antirrhinum majus contain many molecularly well-characterized transposons, but are self compatible due to the presence of a nonfunctional S locus (Sc). In this study, an active transposon (Tam5) from the Cycloidea (Cyc) locus controlling flower asymmetry in A. majus was introduced to a position tightly linked to the functional S locus from self incompatible interspecific hybrids (A. majus×hispanicum) through genetic recombination. RFLP (restriction fragment length polymorphism) analysis showed that the transposon is 3 cM (centiMorgan) away from the S locus and retains high transpositional activity with a germinal excision frequency of 20%. Possible implications of the linkage between the S locus and genes controlling floral phenotypes were discussed. An active transposon tightly linked to the S locus constructed here will facilitate the generation of insertional mutants of the S locus encoded genes and may lead to dissecting their precise roles during self-incompatible reactions.     

转座子Tn917插入位点侧翼序列的扩增

为了克隆到生防菌株的抗病基因,以一株对灰葡萄孢菌表现很高拮抗活性的蜡样芽孢杆菌B-02菌株为材料,利用转座子标签技术得到拮抗性消失的突变体,进而利用TAIL-PCR技术扩增出Tn917插入位点两侧的未知序列,利用生物信息学分析扩增序列,为进一步研究该基因片段与菌株拮抗性之间的关系奠定了基础。     

利用转座标签mTn-lacZ/leu2插入突变发酵性丝孢酵母2.1368-Leu?筛选高效产油突变株

为提高微生物油脂产率,降低其生产成本,以转座标签mTn-lacZ/leu2插入突变发酵性丝孢酵母2.1368-Leu?筛选高效产油突变株。利用LacZ显色反应、脂肪酸合成酶抑制剂Cerulenin和磷酸香草醛反应,最终在玉米秸秆糖化液中筛选出一株高效产油突变株2.1368-Leu?-7。结果表明其油脂含量为38.30％,比对照的29.33％高了8.97％,而其产油率为8.35％,比对照的6.92％提高了20.63％;在玉米秸秆糖化液中的糖利用率为77％,每100 g玉米秸秆可转化油脂8.32 g。可为未来生物柴油产业提供了廉价原料。     

植物转座子及其在功能基因组学中的应用

转座子作为插入突变原或分子标签被广泛应用于基因的分离和克隆,且因其 独特的性质已成为发现新基因和基因功能分析的有效工具。本文综述了植物转座子及其作为基因分离和克隆工具的研究进展,并讨论其在植物基因功能研究方面的应用。 Abstract:Transposons have been widely used for gene isolation and gene cloning as insertional mutagens or molecular tagging.Furthermore,due to special characteristics of transposons,transposons techniques will be a powerful tool for new gene discovery and gene functional analysis.This paper reviewed the developments of plant transposons in gene isolating and cloning,as well as its use in studying gene function in plant.     

Germinal virus vector WDV (wheat dwarf virus)-mediated multiple insertions of a maize transposon,Ds (dissociation), in rice

Wheat dwarf virus (WDV) is a monocot-infecting geminivirus that replicates in infected tissue as double-stranded DIMA. We evaluated whether the WDV vector system bearingDs could be used as an effective insertional mutagen in rice. Molecular data showed thatDs was excised from WDV vectors once the WDV-carryingDs (WDV::Ds) and the genomicAc vector were co-introduced into rice calli. Mature TO and T1 transgenic plants were analyzed for the distribution and inheritance ofDs inserts. Southern analysis indicated that theDs elements excised from WDV vectors were stably inserted into genomes. The number of transposedDs ranged from zero to three copies, among independent transformants. Meanwhile, untransposedDs (WDV::Ds) were present in multiple-copies in genomes. Southern analysis of the selfed progeny of T0 plants demonstrated that most WDV::Ds were co-segregated among siblings. This indicated that these elements were integrated into the same single loci. However, a fewDs were found to segregate independently from the majority ofDs. In this report, we discuss the efficiency of WDV vectors in generating multicopyDs in rice genomes.