激发标签技术在植物功能基因组研究中的应用

获得突变体是研究植物功能基因组的有效方法。与传统的T-DNA插入功能缺失突变相比, 建立在功能获得突变基础之上的激发标签技术具有独特的优势, 主要表现为可以获得功能冗余基因的显性突变体并方便地克隆相关基因。文章对激发标签技术的原理, 及其在拟南芥、水稻等植物功能基因组研究中的进展进行了综述, 并介绍了激发标签技术在植物抗逆、抗病和生长发育机理研究方面的新进展。文章最后探讨了激发标签技术的发展前景。     

转座子标签法克隆分离植物基因的研究进展

转座子标签法是克隆与分离植物基因的一项十分有效的方法。概述了转座子标签技术克隆与分离植物基因的基本原理与方法 ,介绍了可用于转座子标签技术的转座子 ,对于转座子标签系统以及在克隆与分离异源植物基因方面的主要成就进行了综述 ,并对将来的研究方向进行了讨论。     

T-DNA标签在植物基因克隆和功能分析中的应用

在植物功能基因组学的研究中,插入突变已成为迅速识别和研究标签基因的一个有效遗传工具.本文介绍了T-DNA标签的概念及应用前提,详细论述了T-DNA标签在大规模植物基因功能分析中的应用以及使用启动子和增强子诱捕技术分离时空特异性启动子和表达基因,另外还分析了利用其特殊形式激活标签进行基因克隆和功能分析的优越性,并展望了T-DNA标签的应用前景.     

基因克隆技术的研究进展

为能快速而准确地克隆目的基因,综述了一些基因克隆常用技术,包括差异表达基因分离技术、转座子标签技术、图位克隆技术、同源序列技术、表达序列标签技术的原理、应用及应用潜力,并对其作了简要的评价.这些技术有利有弊,应根据不同的实验目的和水平来选择相应的技术.     

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.     

转座子标签及其在酿酒酵母基因功能研究中的应用

转座子标签(transposontagging)技术是研究功能基因的有效的工具之一。介绍了几种在酿酒酵母(Saccharomycescerevisiae)基因功能研究中应用的转座子标签:mTn3标签、miniMu噬菌体标签和Ty转座子标签,阐述了转座子标签的构建原理、应用策略和转座子标签插入位点的鉴定方法。     

植物抗病基因克隆研究进展

随着分子生物学及其相关技术的飞速发展,人们对植物与病原微生物相互作用的分子机制了解得越来越透彻。本文对植物过敏性反应和系统获得抗性作了简要概述,并着重讨论了植物抗病基因克隆的进展,涉及到转座子标签技术、定位克隆技术、染色体步行、染色体登陆等方法和策略,归纳了克隆到的植物抗病基因及其产物结构,概述了这些基因产物所共有的特点,并简要介绍了植物抗病基因工程的进展。     

表达序列标签及基因芯片技术在植物抗性基因研究中的应用

表达序列标签和基因芯片技术是基因组学研究的重要手段。表达序列标签是cDNA的3’或5’端的一段序列,通过表达序列标签可以寻找在某种胁迫条件下特异表达的基因并推测其可能的功能。基因芯片技术是指将大量基因探针分子固定于载体上并与标记的样品分子进行杂交,通过检测每个探针分子的杂交信号强度获取样品分子数量和序列信息,通过基因芯片技术,可以研究基因在不同的条件下的表达量,进而研究植物抗性机理。     

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。     

植物逆境胁迫耐受性功能基因组研究进展

为了更加高效地利用基因工程技术提高植物对逆境胁迫的耐受性,需要在全基因组水平上对植物逆境胁迫耐受性的复杂机制进行整合性研究.植物逆境胁迫耐受性功能基因组的研究可概括为：利用胁迫特异性的表达序列标签(EST)及cDNA微阵列（或基因芯片）技术筛选与胁迫相关的候选基因,然后利用反向遗传学等技术对候选基因的功能进行研究,利用酵母双杂交、正向遗传学等技术对基因及基因产物间的相互关系进行研究.通过这些研究可以全面地了解植物对胁迫（渗透、干旱、极端温度）响应的复杂机制和相互作用以及相应的信号转导途径,从而为更加高效地利用基因工程技术提高植物对逆境胁迫的耐受性奠定基础.     

Gene Tagging with Random Amplified Polymorphic DNA (RAPD) Markers for Molecular Breeding in Plants

Markers are of interest to plant breeders as a source of genetic information on crops and for use in indirect selection of traits to which the markers are linked. In the classic breeding approach, the markers were invariably the visible morphological and other phenotypic characters, and the breeders expended considerable effort and time in refining the crosses as the tight linkage or association of the desired characters with the obvious phenotypic characters was never unequivocally established. Furthermore, indirect selection for a trait using such morphological markers was not practical due to (1) a paucity of suitable markers, (2) the undesirable pleiotropic effects of many morphological markers on plant phenotype, and (3) the inability to score multiple morphological mutant traits in a single segregating population. With the advancement in molecular biology, the use of molecular markers in plant breeding has become very commonplace and has given rise to “molecular breeding”. Molecular breeding involves primarily “gene tagging”, followed by “marker-assisted selection” of desired genes or genomes. Gene tagging refers to the identification of existing DNA or the introduction of new DNA that can function as a tag or label for the gene of interest. In order for the DNA sequences to be conserved as a tag, important prerequisites exist. This review also summarizes the achievements in gene tagging that have been made over the last 7 to 8 years.     

利用RAPD技术进行植物性状标记及辅助选择

近等基因系、混合分离群体法是ＲＡＰＤ 标记的主要策略。目前,ＲＡＰＤ标记广泛用于抗线虫、抗病、雄性不育等辅助选择的研究中,取得了可喜的成绩。由于遗传距离的不同,使ＲＡＰＤ 标记具有基因型的差异。寻找无重组的ＲＡＰＤ 标记或将ＲＡＰＤ标记转化为ＲＦＬＰ标记,可以解决这一问题。随着连锁程度的降低选择效率也随着降低。相斥相的ＲＡＰＤ标注可提高选择效率将ＲＡＰＤ标记转化为ＳＣＡＲｓ、ＡＰＳＰｓ 标记,可以解决ＲＡＰＤ 标记稳定性差的问题。来源于ＲＡＰＤ 标记的ＳＣＡＲｓ 标记将在辅助选择中发挥巨大的作用。     

The utility of transposable elements as tools for the isolation of plant genes

Transposable elements are segments of DNA which have the unique capability of being able to excise from one site in the genome and reintegrate into new, different sites elsewhere in the genome. When transposition takes place and integration occurs within a gene locus, mutations are frequently generated producing variegated or recessive phenotypes. This ability of transposable elements to act as mutagenic agents through their association with particular gene sequences has lead to the development of the procedure of transposon tagging or gene tagging in higher plants. Through this technique, transposable elements can be used to clone and isolate genes of interest for which little or nothing is known about the final product (i.e., polypeptide). This offers tremendous potential for the isolation of a variety of agronomically important genes, which are virtually impossible to recover by other currently available gene cloning methodologies. To date, the technique has been used successfully to isolate genes from corn and snapdragon. Using gene transfer technologies, the potential now exists to extend this approach to clone genes from other plant species. Advantages and limitations of transposon tagging for isolating plant genes will be discussed.     

Insertional mutagenesis in Arabidopsis thaliana

Recently, a number of mutant gene loci in the Arabidopsis thaliana plant genome have been identified through insertional mutagenesis. In this review, we evaluate different methods used for Agrobacterium tumefaciens-mediated T-DNA insertional mutagenesis with regard to their mutation frequencies and conclude that a major breakthrough in the isolation of genes involved in plant development has been acheived. To provide a specific example, we summarize recent progress made in the understanding of flower morphogenesis at the molecular level through the study of homeotic genes obtained via gene tagging. T-DNA gene fusion vectors are being discussed that will allow the isolation of plant regulatory sequences with particular cell or tissue specificity, or that are controlled by specific external stimuli. Finally, we report on the approaches followed to convert the maize transposons Ac/Ds into valuable gene tags for use in a heterologous host such as Arabidopsis.     

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。     

Analysis of developmentally interesting genes cloned from higher plants by insertional mutagenesis

The ability of transposable elements to generate gene mutations by excising from one site in the genome and reintegrating into new, different sites elsewhere in the genome has led to the development of procedures whereby the elements can be used to tag specific gene sequences for eventual isolation and analysis through gene cloning. This transposon tagging strategy is particularly useful in those situations where limited knowledge of the biochemistry of the target gene precludes gene cloning by conventional strategies. This approach, in conjunction with the more general insertional mutagenesis approach using T-DNA, has led to the cloning and subsequent analysis of several genes from higher plants involved in particular developmental processes. Studies of this nature should eventually shed light on the precise molecular mechanisms utilized to regulate and control cellular differentiation in plants.     

激活标签法及其在植物基因工程上的应用

激活标签法是新近发展起来的一种用于基因分离和鉴定的方法。它通过诱变使特定内源基因发生过量表达,而产生显性功能获得型突变,从而对基因进行鉴定和分析。因为具有独特的性质已使其成为发现新基因和进行基因功能分析的有效工具。本文综述了激活标签法的原理、研究现状和在植物基因工程上的应用。 Abstract:Activation tagging is a new method for isolation and functional identification.It can generate dominant gain-of-function mutants by overexpression of a particular endogenous gene.Due to this special characteristics of activation tagging,this method has been a powerful tool for new gene discovery and gene functional analysis.This paper reviewed the principle and study conditions of activation tagging,as well as its use in plant genetic engineering.     

植物抗病基因克隆的研究进展

本从抗病基因克隆技术,抗病基因的产物和结构,抗病基因介导的抗病信号传导以及抗病基因进化等方面入手,综述了近几年来植物抗病基因克隆的研究进展,并对转座子标签法和定位克隆法做了较为详细的阐述。