蒺藜苜蓿株高控制基因COSTIN的克隆及功能研究

株高是影响植物株型建成的重要农艺性状之一,直接决定作物的倒伏性和生物产量,但目前关于苜蓿等豆科牧草株高性状形成的分子调控机制尚不清楚。通过定向筛选豆科模式植物蒺藜苜蓿Tnt1逆转座子插入突变体库,分离鉴定了一个蒺藜苜蓿矮化突变体compact stalk internodes(costin),该突变体的矮化表型是由于茎节伸长受到抑制所致。通过基因表型连锁分析成功克隆了COSTIN基因,该基因编码一个钙离子交换蛋白,与拟南芥的CALCIUM EXCHANGER 7(CAX7) 基因高度同源。qRT-PCR检测发现COSTIN基因在茎、叶和果荚等组织中有较高的表达。进一步研究发现在costin突变体中赤霉素合成途径关键基因MtCPS、MtKAO1、MtGA20ox4、MtGA20ox7和MtGA3ox1表达下调;外施赤霉素GA3可以恢复costin突变体的矮化表型。上述研究表明COSTIN基因通过影响植物激素赤霉素的生物合成来调控蒺藜苜蓿的茎节伸长。     

蒺藜苜蓿糖基转移酶基因SMALL AND EMERALD1的克隆和功能研究

类黄酮代谢对于植物生长发育和植物-环境互作至关重要,其中糖基转移酶介导的糖基化修饰在类黄酮代谢中发挥着重要作用。为了研究蒺藜苜蓿中糖基转移酶的生物学功能,通过定向筛选蒺藜苜蓿Tnt1逆转座子插入突变体库,获得了一类植株矮小、叶片深绿的突变体small and emerald1 (se1)。通过基因表型连锁性分析成功克隆了SE1基因,该基因编码1个糖基转移酶,与拟南芥中调控类黄酮生物合成的AtUGT84A1氨基酸同源性为52.8%。对野生型和se1突变体叶片的类黄酮含量进行测定发现类黄酮总量在se1突变体中显著降低(P<0.01)。进一步研究发现在se1突变体中类黄酮合成途径关键基因CHS、F3H和F3’H表达水平下降。亚细胞定位显示SE1可能在细胞质和细胞核中发挥生物学功能。研究表明糖基转移酶基因SE1可能参与蒺藜苜蓿类黄酮合成代谢调控,进而影响其生长发育。此外,研究还发现SE1基因对于叶绿素合成可能具有负向调控作用。     

植物反转录转座子及其在功能基因组学中的应用

高等植物中的反转录转座子是构成植物基因组的重要成分之一.它分病毒家族和非病毒家族两类,病毒家族包括反转录病毒和类似于反转录病毒的非病毒转座子,病毒家族中的反转录转座子可再细分为Ty3-gypsy类和Ty1-copia类;非病毒家族可细分为LINE类和SINE类.正常情况下大部分反转录转座子不具有活性,某些生物或非生物因素胁迫可激活部分反转录转座子转座.反转录转座子自身编码反转录酶进行转录,以"拷贝-粘贴"的转座模式导致基因组扩增和进化.具有活性的反转录转座子通过插入产生新的突变,可作为一种基因标签技术,应用于功能基因组学研究,并成为研究植物基因功能和表达的重要技术平台.本文综述了近几年来在植物反转录转座子方面的研究进展,主要包括植物反转录转座子的结构、特征、活性及其对基因组的影响和它们在功能基因组学中的应用.     

植物活性长末端重复序列反转录转座子研究进展

长末端重复序列(Long terminal repeat,LTR)反转录转座子是真核生物基因组中普遍存在的一类可移动的DNA序列,它们以RNA为媒介,通过"复制粘贴"机制在基因组中不断自我复制。在高等植物中,许多活性的LTR反转录转座子已被详尽研究并应用于分子标记技术、基因标签、插入型突变及基因功能等分析。本文对植物活性LTR反转录转座子进行全面的调查,并对其结构、拷贝数和分布以及转座特性进行系统的归纳,分析了植物活性LTR反转录转座子的gag(种属特异抗原)和pol(聚合酶)序列特征,以及LTR序列中顺式调控元件的分布。研究发现自主有活性的LTR反转录转座子必须具备LTR区域以及编码Gag、Pr、Int、Rt和Rh蛋白的基因区。其中两端LTR区域具有高度同源性且富含顺式调控元件;Rt蛋白必备RVT结构域;Rh蛋白必备RNase_H1_RT结构域。这些结果为后续植物活性LTR反转录转座子的鉴定和功能分析奠定了重要基础。     

反转录转座子标记及在作物遗传育种中的应用

反转录转座子通过RNA中间体进行反转录而转座,广泛分布于各种植物基因组中,拷贝数多,异质性高,在种内和种间表现出较高的序列差异性和丰富的插入多态性。针对这些特点,开发出了几种基于反转录转座子的分子标记,如SSAP、RIVPI、RAP、REMAP和RBIP等。由于反转录转座子标记能揭示出丰富的多态性,因而在遗传多样性和系谱研究、遗传连锁图谱构建及性状基因定位等方面得到了应用。随着分离技术的不断改进,获取序列信息更加容易,反转录转座子作为分子标记用于作物遗传育种将具有广阔前景。     

植物LTR类反转录转座子序列分析识别方法

LTR类反转录转座子(Long terminal repeat retrotransponson)是真核生物中的一类重要转座元件,具有分布广泛、异质性高等特点,在真核生物基因组进化中起着重要作用,现广泛应用于植物的基因功能分析和遗传多样性研究等方面。LTR类反转录转座子的序列识别是其应用的前提条件,因此对LTR类反转录转座子的序列鉴定和分析方法的研究具有重要的理论意义和实际应用价值。LTR类反转录转座子序列的生物信息学分析软件按原理可大致分为序列比对分析和相关序列保守区域识别鉴定两类。比对软件如BLAST、DNAstar等,是一种序列相似性搜索程序,通过与已知的反转录转座子序列比对后的序列相似性来判断未知序列是否是反转录转座子序列,但这类软件不能直接获得具体的LTR等特征序列的相关信息,不能对反转录转座子序列的全长进行识别。识别鉴定软件按原理可分为从头算起法、比较基因组法、同源搜索法和结构基础法4种,如LTR-Finder等基于从头算起法的识别鉴定软件,可对LTR类反转录转座子全序列进行较准确地预测和注释,RepeatMasker等基于同源搜索法的软件,通过与数据库中的序列的相似性比对后发现可能存在的LTR类反转录转座子。文章对不同的LTR类反转录转座子预测方法进行了比较和分析,在此基础上归纳总结出一套分析LTR类反转录转座子序列的操作流程,旨在为LTR类反转录转座子序列的分析提供参考。     

高等植物转座子的超家族及其应用(综述)

转座子是广泛存在于高等植物基因组中的可移动的DNA分子。文中主要介绍高等植物的各种转座子超家族,包括LTR类反转录转座子、hAT、CACTA因子、Mutator和MULEs、Tc1/mariner、微小反向重复转座子MITEs等;另外还阐述了植物转座子标签体系和筛选方法,以及转座子在生物多样性与遗传连锁分析、植物基因组学研究与植物性状改良方面中的应用。     

植物LTR反转录转座子的研究进展

反转录转座子是真核生物基因组中普遍存在的一类可移动的遗传因子,它们以RNA为媒介,在基因组中不断自我复制。在高等植物中,反转录转座子是基因组的重要成分之一。反转录转座子可以分为5大类型,其中以长末端重复（LTR）类型报道较多。LTR类型由于其首尾具有长末端重复序列,内部含有PBS、PPT、GAG和POL开放阅读框、TSD等结构,可以采用生物信息学软件进行预测。LTR反转录转座子的活性受到自身甲基化和环境因素的影响,DNA甲基化抑制反转录转座子转座,而外界环境的刺激能够激活转座子,从而影响插入位点周边基因的表达。同时由于LTR反转录转座子在植物中普遍存在,丰富的拷贝数以及多态性为新型分子标记（RBIP、SSAP、IRAP、REMAP）的开发提供了良好的素材。该文对近年来国内外有关植物反转录转座子的类型、结构特征、 LTR反转录转座子的活性及其影响因素、 LTR反转录转座子的预测以及标记开发等方面的研究进展进行综述。     

水稻插入突变库构建研究进展

水稻是单子叶植物基因组研究的一种模式植物 ,其全基因组测序已经完成 ,在此基础上开展功能基因组的研究。水稻插入突变体库的建立是功能基因组研究的一个重要内容 ,在此基础上也能进行正向遗传学及反向遗传学的研究。水稻插入突变体库构建的方法有T DNA插入突变、Ac Ds系统插入突变、Tos1 7插入突变。分别介绍三种方法的原理及其在水稻突变体库构建中的应用和研究进展。     

转座子标签法在构建G-细菌突变体库中的应用

应用转座子标签法以水稻黄单胞菌 (Xoo)为研究对象 ,构建了Xoo的突变体库 ,为革兰氏阴性细菌突变体库的建立 ,验证了一个较新的方法和思路。经分子生物学检测 ,此方法简便易得、高效稳定 ,可以定向突变 ,为研究G-细菌的各项功能提供了良好的素材 ,加快了研究进程。     

Efficient transposition of the Tnt1 tobacco retrotransposon in the model legume Medicago truncatula

The tobacco element, Tnt1, is one of the few active retrotransposons in plants. Its transposition is activated during protoplast culture in tobacco and tissue culture in the heterologous host Arabidopsis thaliana. Here, we report its transposition in the R108 line of Medicago truncatula during the early steps of the in vitro transformation-regeneration process. Two hundred and twenty-five primary transformants containing Tnt1 were obtained. Among them, 11.2% contained only transposed copies of the element, indicating that Tnt1 transposed very early and efficiently during the in vitro transformation process, possibly even before the T-DNA integration. The average number of insertions per transgenic line was estimated to be about 15. These insertions were stable in the progeny and could be separated by segregation. Inspection of the sequences flanking the insertion sites revealed that Tnt1 had no insertion site specificity and often inserted in genes (one out of three insertions). Thus, our work demonstrates the functioning of an efficient transposable element in leguminous plants. These results indicate that Tnt1 can be used as a powerful tool for insertion mutagenesis in M. truncatula.     

Large-scale insertional mutagenesis using the Tnt1 retrotransposon in the model legume Medicago truncatula

Medicago truncatula is a fast-emerging model for the study of legume functional biology. We used the tobacco retrotransposon Tnt1 to tag the Medicago genome and generated over 7600 independent lines representing an estimated 190 000 insertion events. Tnt1 inserted on average at 25 different locations per genome during tissue culture, and insertions were stable during subsequent generations in soil. Analysis of 2461 Tnt1 flanking sequence tags (FSTs) revealed that Tnt1 appears to prefer gene-rich regions. The proportion of Tnt1 insertion in coding sequences was 34.1%, compared to the expected 15.9% if random insertions were to occur. However, Tnt1 showed neither unique target site specificity nor strong insertion hot spots, although some genes were more frequently tagged than others. Forward-genetic screening of 3237 R₁ lines resulted in identification of visible mutant phenotypes in approximately 30% of the regenerated lines. Tagging efficiency appears to be high, as all of the 20 mutants examined so far were found to be tagged. Taking the properties of Tnt1 into account and assuming 1.7 kb for the average M. truncatula gene size, we estimate that approximately 14 000–16 000 lines would be sufficient for 90% gene tagging coverage in M. truncatula . This is in contrast to more than 500 000 lines required to achieve the same saturation level using T-DNA tagging. Our data demonstrate that Tnt1 is an efficient insertional mutagen in M. truncatula , and could be a primary choice for other plant species with large genomes.     

Recent Progress in Development of Tnt1 Functional Genomics Platform for Medicago truncatula and Lotus japonicus in Bulgaria

Legumes, as protein-rich crops, are widely used for human food, animal feed and vegetable oil production. Over the past decade, two legume species, Medicago truncatula and Lotus japonicus, have been adopted as model legumes for genomics and physiological studies. The tobacco transposable element, Tnt1, is a powerful tool for insertional mutagenesis and gene inactivation in plants. A large collection of Tnt1-tagged lines of M. truncatula cv. Jemalong was generated during the course of the project 'GLIP': Grain Legumes Integrated Project, funded by the European Union (www.eugrainlegumes.org). In the project 'IFCOSMO': Integrated Functional and COmparative genomics Studies on the MOdel Legumes Medicago truncatula and Lotus japonicus, supported by a grant from the Ministry of Education, Youth and Science, Bulgaria, these lines are used for development of functional genomics platform of legumes in Bulgaria. This review presents recent advances in the evaluation of the M. truncatula Tnt1 mutant collection and outlines the steps that are taken in using the Tnt1-tagging for generation of a mutant collection of the second model legume L. japonicus. Both collections will provide a number of legume-specific mutants and serve as a resource for functional and comparative genomics research on legumes. Genomics technologies are expected to advance genetics and breeding of important legume crops (pea, faba bean, alfalfa and clover) in Bulgaria and worldwide.     

A Medicago truncatula Tobacco Retrotransposon Insertion Mutant Collection with Defects in Nodule Development and Symbiotic Nitrogen Fixation

A Tnt1-insertion mutant population of Medicago truncatula ecotype R108 was screened for defects in nodulation and symbiotic nitrogen fixation. Primary screening of 9,300 mutant lines yielded 317 lines with putative defects in nodule development and/or nitrogen fixation. Of these, 230 lines were rescreened, and 156 lines were confirmed with defective symbiotic nitrogen fixation. Mutants were sorted into six distinct phenotypic categories: 72 nonnodulating mutants (Nod-), 51 mutants with totally ineffective nodules (Nod+ Fix-), 17 mutants with partially ineffective nodules (Nod+ Fix+/-), 27 mutants defective in nodule emergence, elongation, and nitrogen fixation (Nod+/- Fix-), one mutant with delayed and reduced nodulation but effective in nitrogen fixation (dNod+/- Fix+), and 11 supernodulating mutants (Nod++Fix+/-). A total of 2,801 flanking sequence tags were generated from the 156 symbiotic mutant lines. Analysis of flanking sequence tags revealed 14 insertion alleles of the following known symbiotic genes: NODULE INCEPTION (NIN), DOESN'T MAKE INFECTIONS3 (DMI3/CCaMK), ERF REQUIRED FOR NODULATION, and SUPERNUMERARY NODULES (SUNN). In parallel, a polymerase chain reaction-based strategy was used to identify Tnt1 insertions in known symbiotic genes, which revealed 25 additional insertion alleles in the following genes: DMI1, DMI2, DMI3, NIN, NODULATION SIGNALING PATHWAY1 (NSP1), NSP2, SUNN, and SICKLE. Thirty-nine Nod- lines were also screened for arbuscular mycorrhizal symbiosis phenotypes, and 30 mutants exhibited defects in arbuscular mycorrhizal symbiosis. Morphological and developmental features of several new symbiotic mutants are reported. The collection of mutants described here is a source of novel alleles of known symbiotic genes and a resource for cloning novel symbiotic genes via Tnt1 tagging.