植物抗病基因克隆与功能研究进展

植物抗病基因（R基因）是分子植物病理学和植物基因工程研究的热点之一,R基因的克隆及其在抗病反应中的功能研究为揭示植物抗病机制和有效－控制植物病害奠定了基础,本文介绍了R基因的成功克隆方法和克隆新策略,对R基因编码产物的功能进行了分类分析,并对通过遗传工程途径发展R基因介导的抗病植物新品种进行了展望。     

植物与病原真菌互作的分子生物学及其研究进展

本文从病原真菌致病基因、无毒基因及产物的互作,植物抗性基因、防卫基因及产物间的互作,系统获得抗性,信号传导系统等方面,对植物与病原真菌互作的分子生物学及其进展进行了综合论述。     

植物——病原互作系统中基因对基因识别研究

从自然植物种群对Ｒ基因的选择和淘汰、对属和种的专化性、抗病基因的复杂性、抗病基因的分子专化性、信号传导中基因的相互作用,以及Ｒ基因的开发利用与持久抗性战略等方面总结评述了当前在植物－病原互作系统中基因对基因识别研究领域的新进展,并且提出了需进一步研究的问题。     

转录后基因沉默--植物抵御外来病毒入侵的一种机制

基因沉默是近几年来在转基因植物中发现的一种后生遗传现象。基因沉默大体可以分为两类：位置效应引起的基因沉默和同源依赖的基因沉默。其中,同源依赖的基因沉默又可以分为转录水平的基因沉默和转录后水平的基因沉默。基因沉默的发现使得人们对植物和病毒的相互关系有了一个新的认识。基因沉默研究中所发现的转录后基因沉默现象是植物抵御病毒入侵、保持自身基因组完整性的一种防御机制,是植物与病毒共进化的结果。对于沉默产生的机理,尤其是转录后基因沉默,已经提出不少模型,但是都未能较全面地解释基因沉默中出现的各种实验现象。该文现就实验所取得的相关结果、转录后基因沉默机制和植物对病毒防御机制的相互关系,以及其研究进展进行综述。     

植物抗病基因(R)与病原物无毒基因(Avr)相互作用机制的研究进展

PTI和ETI是植物在长期进化过程中形成的两类抵抗病原物的机制。基因对基因假说的抗病方式属于ETI抗性机制的一种,该假说认为具有保守NB-LRR结构域的R蛋白识别病原物非保守的无毒蛋白效应子(Avr),激活防卫反应信号途径,导致过敏性坏死。植物抗病基因(R)与病原菌无毒基因(Avr)产物间的直接或间接相互作用而产生的基因对基因抗性是植物抗病性的重要形式,该文对植物抗病蛋白与无毒蛋白相互作用机制进行了综述。其中,间接相互作用模式是主要方式。     

cDNA-AFLP技术在植物耐盐基因鉴定上的应用

cDNA-AFLP技术是近年来广泛应用于植物基因分离与表达研究的mRNA指纹图谱技术,在分离植物特异性基因等生物技术研究中发挥了巨大作用.在植物耐盐基因鉴定方面,该技术的应用处于新兴初始阶段,但已取得了诸多成效.本文在概述植物耐盐响应机制的基础上,着重对利用cDNA-AFLP技术鉴定的植物耐盐相关基因及其相应作用机制进行了阐述,并对其在植物耐盐分子生物学研究上的应用前景进行了展望.     

植物抗病分子机制研究进展

植物抗病机制是目前研究的热点。在长期的进化过程中,植物形成了一系列复杂有效的防御机制来抵御、破坏病原物的侵染。植物抗病基因在植物抗性反应中起着重要的作用,植物一旦监测到病原物马上起始防御反应,并伴随着植物体内一系列细胞和生理生化的变化。近年来,基因沉默作为一个重要的细胞内防御外源核酸的机制,越来越受到科学家重视。综述了植物抗病基因和基因沉默机制在植物抗病反应中的重要作用,并对研究植物抗病机制的前景做了展望。     

植物抗病分子机制研究进展

近十年来,植物抗病分子机制研究取得显著进展。综述了植物抗病基因的克隆及其结构分析、病原菌无毒基因及其相关致病因子的克隆与研究、信号传导相关因子的克隆及其结构分析以及植物-病原菌的相互作用研究,重点介绍了以植物特异抗病基因为介导的诱导防卫作用机制(包括抗病基因编码毒素蛋白,进而抑制病原菌的繁殖;显性基因编码病原菌致病性的靶标物;抗病基因表达产物直接引发抗病反应和基因对基因的抗病作用机制等)的研究进展,以期为植物抗病育种提供有益的信息。     

植物抗虫基因工程研究进展

植物抗虫基因工程为防治农业害虫提供了一条崭新途径。本文对植物抗虫基因工程近年来所取得的某些研究进展,包括目前已发现和利用的抗虫基因、提高抗虫基因在植物体内表达的方法以及防止或延缓害虫产生抗性的策略等方面进行了综合评述,并对植物抗虫基因工程中有待解决的问题和发展前景提出了自己的看法。     

植物与病原真菌互作的分子生物学及其研究进展

本文从病原真菌致病基因、无毒基因及产物的互作,植物抗性基因、防卫基因及产物间的互作,系统获得抗性,信号传导系统等方面,对植物与病原真菌互作的分子生物学及其进展进行了综合论述。     

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。     

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.     

植物基因分离方法

植物基因分离一直是当今生物技术研究的热点。分离作物重要农艺性状的功能基因利于对基因的结构和表达进行研究,并可以经转基因技术进行分子育种。根据中心法则,介绍了从DNA、RNA到蛋白质的三个层次进行植物基因分离的方法。     

Simple and reliable system for transient gene expression for the characteristic signal sequences and the estimation of the localization of target protein in plant cell

The efficiency of transient gene expression in plants credibly demonstrated characteristics of gene functions in numerous studies. Two key strategies of transient expression became favorites among researchers: protoplast transfection and agroinfiltration. Each of them, alongside the advantages, has its own constraints. In this work, an easy, rapid, and reliable system for characterization of the signal sequences and determinations of target protein localization in a plant cell is proposed and tested. This system—called the AgI–PrI—implies production of protoplasts from plant tissues after agroinfiltration. Reliability of the proposed system for transient gene expression has been proved using characterized signal sequences in Nicotiana benthamiana cells. The corresponding protocol is less expensive and depends to a lesser degree on the professional skills in the area of protoplast isolation and transfection; furthermore, it may be applicable to other plant species with either available efficient methods of agroinfiltration and protoplast isolation or with the potential for one of the protocols to be supplemented. Thus, the AgI–PrI technique makes it possible to combine the advantages of two widely used methods for the transient gene expression in plants—agroinfiltration and protoplast isolation and transfection—and concurrently avoids their critical points.     

Evidence for sexual isolation as a prezygotic barrier to gene flow between morphologically divergent species of Rhagoletis fruit flies

1. Certain groups of fruit flies in the genus Rhagoletis (Diptera: Tephritidae) are exemplars for sympatric speciation via host plant shifting. Flies in these species groups are morphologically similar and overlap in their geographic ranges, yet attack different, non‐overlapping sets of host plants. Ecological adaptations related to differences in host choice and preference have been shown to be important prezygotic barriers to gene flow between these taxa, as Rhagoletis flies mate on or near the fruit of their respective host plants. Non‐host‐related assortative mating is generally absent or present at low levels between these sympatrically diverging fly populations. 2. However, some Rhagoletis taxa occasionally migrate to ‘non‐natal’ plants that are the primary hosts of other, morphologically differentiated fly species in the genus. These observations raise the question of whether sexual isolation may reduce courtship and copulation between morphologically divergent species of Rhagoletis flies, contributing to their prezygotic isolation along with host‐specific mating. 3. Using reciprocal multiple‐choice mating trials, we measured sexual isolation among nine species pairs of morphologically differentiated Rhagoletis flies. Complete sexual isolation was observed in eight of the nine comparisons, while partial sexual isolation was observed in the remaining comparison. 4. We conclude that sexual isolation can be an effective prezygotic barrier to gene flow contributing to substantial reproductive isolation between many morphologically distinct Rhagoletis species, even in the absence of differential host plant choice and host‐associated mating.     

HABITAT AVOIDANCE: OVERLOOKING AN IMPORTANT ASPECT OF HOST‐SPECIFIC MATING AND SYMPATRIC SPECIATION?

Understanding speciation requires discerning how reproductive barriers to gene flow evolve between previously interbreeding populations. Models of sympatric speciation for phytophagous insects posit that reproductive isolation can evolve in the absence of geographic isolation as a consequence of an insect shifting and ecologically adapting to a new host plant. One important adaptation contributing to sympatric differentiation is host-specific mating. When organisms mate in preferred habitats, a system of positive assortative mating is established that facilitates sympatric divergence. Models of host fidelity generally assume that host choice is determined by the aggregate effect of alleles imparting positive preferences for different plant species. But negative effect genes for avoiding nonnatal plants may also influence host use. Previous studies have shown that apple and hawthorn-infesting races of Rhagoletis pomonella flies use volatile compounds emitted from the surface of fruit as key chemosensory cues to recognize and distinguish between their host plants. Here, we report results from field trials indicating that in addition to preferring the odor of their natal fruit, apple and hawthorn flies, and their undescribed sister species infesting flowering dogwood (Cornus florida), also avoid the odors of nonnatal fruit. We discuss the implications of nonnatal fruit avoidance for the evolutionary dynamics and genetics of sympatric speciation. Our findings reveal an underappreciated role for habitat avoidance as a potential postmating, as well as prezygotic, barrier to gene flow.