植物染色体原位杂交技术及其在稻属研究中的应用

本文介绍了植物染色体原位杂交技术,以及该技术在稻属特定DNA序列定位、基因组间关系、外源染色体鉴定等研究中的应用.     

荧光原位杂交技术在植物细胞遗传学和绘制基因图谱中的应用现状与展望

荧光原位杂交是在分子水平上检测外源染色质的一种有效方法。其探针主要有染色体重复序列、总基因组DNA、寡单拷贝序列和染色体涂色集中等,该技术在研究植物细胞遗传学、基因扩增、基因作图及植物进化和亲缘关系的鉴定上已广泛应用。简要概述了荧光原位杂交技术在植物细胞遗传学和绘制基因图谱中的应用现状与展望。     

在植物粗线期染色体和DNA纤维上的荧光原位杂交技术

介绍了两种荧光原位杂交技术的详细实验步骤。第一种技术是在减数分裂粗线期染色体上的荧光原位杂交,包括从花粉母细胞中制备粗线期染色体和在这种染色体上定位ＤＮＡ序列,其分辨率水平能够达到１００ｋｂ。第二种技术是从植物细胞核中制备ＤＮＡ纤维,并在上面进行原位杂交,能够直接分析ＤＮＡ序列的分子排列关系,其分辨率水平能达到几个ｋｂ。为了说明这两种原位杂交技术在研究基因组和染色体结构、构建高分辨率的ＤＮＡ物理图谱上的能力,将展示用该技术直接分析番茄染色体端粒重复序列和端粒联接重复序列的染色体定位和ＤＮＡ分子排列。     

自身基因组原位杂交揭示植物基因组重复DNA沿染色体的分布

重复DNA沿染色体的分布是认识植物基因组的组织和进化的要素之一。本研究采用一种改良的基因组原位杂交程序,对基因组大小和重复DNA数量不同的6种植物进行了自身基因组原位杂交(self-genomic in situ hybridization,self-GISH)。在所有供试物种的染色体都观察到荧光标记探针DNA的不均匀分布。杂交信号图型在物种间有明显的差异,并与基因组的大小相关。小基因组拟南芥的染色体几乎只有近着丝粒区和核仁组织区被标记。基因组相对较小的水稻、高粱、甘蓝的杂交信号分散分布在染色体的全长,但在近着丝粒区或近端区以及某些异染色质臂的分布明显占优势。大基因组的玉米和大麦的所有染色体都被密集地标记,并在染色体全长显示出强标记区与弱标记或不标记区的交替排列。此外,甘蓝染色体的所有近着丝粒区和核仁组织区、大麦染色体的所有近着丝粒区和某些臂中间区还显示了增强的信号带。大麦增强的信号带带型与其N-带带型一致。水稻自身基因组原位杂交图型与水稻Cot-1DNA在水稻染色体上的荧光原位杂交图型基本一致。研究结果表明,自身基因组原位杂交信号实际上反映了基因组重复DNA序列对染色体的杂交,因而自身基因组原位杂交技术是显示植物基因组中重复DNA聚集区在染色体上的分布以及与重复DNA相关联的染色质分化的有效方法。     

BAC-FISH在植物基因组研究中的应用

细菌人工染色体与荧光原位杂交合成技术(BAC-FISH)是90年代开始发展起来的一种新的定位技术.由于该技术较常规荧光原位杂交(FISH)技术的信号检出率高得多,近年来在植物基因组研究中得到了越来越多的应用.运用该技术已将一些重要的功能基因定位到相应植物染色体上.     

荧光原位杂交技术的研究进展

荧光原位杂交(FISH)是在染色体、间期细胞核和DNA纤维上进行DNA序列定位的一种有效手段。近年来,围绕提高检测的分辨率和灵敏性,不断将免疫染色、量子点和微流控芯片等物理化学技术引入到荧光原位杂交中,促进了它的快速发展。本文主要综述了荧光原位杂交的基本原理和发展历程,重点介绍了免疫染色-荧光原位杂交(immuno-FISH)、量子点-荧光原位杂交(QD-FISH)和微流控芯片-荧光原位杂交(FISH on microchip)等多种新技术及其检测特点,如快速、灵敏、动态、多样化等。随着荧光原位杂交技术的不断完善与发展,将在细胞遗传学、表观遗传学及分子生物学等领域发挥更加重要的作用。     

Fiber-FISH在植物基因组研究中的应用

FiberFISH是近几年发展起来的一项高分辨率和高灵敏度的荧光原位杂交技术,已被广泛应用于人类及动植物基因组的研究。本文对FiberFISH在植物基因组研究中的特点及其在染色体物理图谱的构建,染色体结构与分子构成分析和在比较基因组中的应用等进行了探讨。     

利用高灵敏的TSA—FISH在玉米中定位bz1、bz2基因

植物中,程序性细胞死亡(PCD）发生在植物生殖和发育的许多方面,已有的研究表明,在玉米种子的发育过程中,胚肥组织经历了程序性细胞死亡的过程。bz1(bronze)和bz2是与种子的糊粉层发育相关的花青素生物合成基础,在玉米基因组中,bz1基因所在区域是重组热点,bz2与类黄酮的酰化、糖基化、转运、沉积等有关,基因的物理定位有利于基因的分离和克隆。TSA－FISH（Tyramide signal amplification fluorescence in situ hybridization）是一种新颖的高灵敏度的荧光原位杂交技术,它的主要反应原理是辣根过氧化物酶催化过氧化氢和标记的酪胺分子（tyramide)的苯环部分反应,使荧光标记的酪胺分子在直接带有或间接带有HRP报告分子的探针周围沉积,信号因此得以极大的放大,从而大大提高了荧光原位杂交技术的灵敏度,90年代中期开始引入动物和人类组织化学和细胞遗传学研究中,2001年才应用于植物细胞遗传学的研究。利用这一技术,我们将bz1基因定位于玉米的第9染色体的短臂和第1染色体的长臂上,其信号点距着丝粒的百分距离分别为40．2,75．4;bz2基因定位于玉米的第1染色体的长臂和第5染色体的短臂上,其信号点距着丝粒的百分距离分别为21．6,15．3。本文讨论了TSA－FISH技术在植物中小的、低拷贝的DNA序列定位上的应用。     

BAC-FISH在植物基因组研究中的应用

细菌人工染色体荧光原位杂交(BAC-FISH)是将包含不同特性的BAC克隆直接定位到染色体上的技术,其在植物基因组学和分子细胞遗传学研究中具有不可替代的作用。综述其在各种植物染色体鉴定和核型分析、图谱构建、植物起源与进化分析、基因定位以及FISH的分辨率等植物基因组学研究的应用进展。     

荧光原位杂交技术在植物多倍体起源与进化研究中的应用

多倍化是植物物种形成与多样化的重要原动力。研究植物特别是一些重要经济作物和园艺植物多倍体的起源与进化,不仅对于揭示多倍体形成过程中性状变异的分子机制具有重要意义,而且可为植物遗传资源的保护与利用提供理论和技术支持。作为连接基因组序列片段到染色体组的桥梁,荧光原位杂交技术长期被广泛用来研究多倍体形成与进化过程中相关特异基因或序列的表达定位、外源染色体检测和鉴定、基因组结构变异等科学问题。因此,在简单介绍荧光原位杂交技术发展历史和植物多倍体主要类型的基础上,主要总结了荧光原位杂交技术在植物多倍体起源与进化相关研究上的应用。     

Plant cytogenetics at the dawn of the 21st century

The years 1996-1997 saw advances in plant chromosome handling, structure, behaviour and manipulation. Improved protocols were developed for flow sorting, microdissection and microcloning. Fibre FISH was used to map a range of DNA sequences at a resolution of a few kilobases. Over 400 wheat deletion stocks were reported and healing of broken chromosomes by de novo addition of telomeric sequences was demonstrated. Centromeric DNA sequences were identified. The role of telomeric ends in pairing was demonstrated. Apparently unusually long chromosome arms can interfere with mitosis. Novel phenomena and potential of wide hybrids for genome analysis were noteworthy.     

High-resolution mapping on pachytene chromosomes and extended DNA fibres by fluorescencein-situ hybridisation

This article describes two protocols for high-resolution physical mapping of DNA sequences in tomato using fluorescencein situ hybridisation (FISH). The first technique involves FISH to spread chromosomes from pollen mother cells at pachytene and proves to be an excellent method for assigning DNA sequences to chromosome regions at a resolution of up to a few hundred kilobase. An even higher resolution was obtained for extended DNA fibre, prepared from interphase nuclei and used as hybridising component. This technique permits strong enhancement of physical map resolution to values of a few kilobase. The power of both methods simultaneously applied for the same material was demonstrated with the combination of the telomeric repeat and the tomato specific telomere-associated repeat TGR1 as example.     

Construction of a bacterial artificial chromosome (BAC) library for potato molecular cytogenetics research.

Lack of reliable techniques for chromosome identification is the major obstacle for cytogenetics research in plant species with large numbers of small chromosomes. To promote molecular cytogenetics research of potato (Solanum tuberosum, 2n = 4x = 48) we developed a bacterial artificial chromosome (BAC) library of a diploid potato species S. bulbocastanum. The library consists of 23,808 clones with an average insert size of 155 kb, and represents approximately 3.7 equivalents to the potato genome. The majority of the clones in the BAC library generated distinct signals on specific potato chromosomes using fluorescence in situ hybridization (FISH). The hybridization signals provide excellent cytological markers to tag individual potato chromosomes. We also demonstrated that the BAC clones can be mapped to specific positions on meiotic pachytene chromosomes. The excellent resolution of pachytene FISH can be used to construct a physical map of potato by mapping molecular marker-targeted BAC clones on pachytene chromosomes.     

High-resolution single-copy gene fluorescence in situ hybridization and its use in the construction of a cytogenetic map of maize chromosome 9

High-resolution cytogenetic maps provide important biological information on genome organization and function, as they correlate genetic distance with cytological structures, and are an invaluable complement to physical sequence data. The most direct way to generate a cytogenetic map is to localize genetically mapped genes onto chromosomes by fluorescence in situ hybridization (FISH). Detection of single-copy genes on plant chromosomes has been difficult. In this study, we developed a squash FISH procedure allowing successful detection of single-copy genes on maize (Zea mays) pachytene chromosomes. Using this method, the shortest probe that can be detected is 3.1 kb, and two sequences separated by approximately 100 kb can be resolved. To show the robust nature of this protocol, we localized nine genetically mapped single-copy genes on chromosome 9 in one FISH experiment. Integration of existing information from genetic maps and the BAC contig-based physical map with the cytological structure of chromosome 9 provides a comprehensive cross-referenced cytogenetic map and shows the dramatic reduction of recombination in the pericentromeric heterochromatic region. To establish a feasible mapping system for maize, we also developed a probe cocktail for unambiguous identification of the 10 maize pachytene chromosomes. These results provide a starting point toward constructing a high-resolution integrated cytogenetic map of maize.     

Methods of molecular cytogenetics for studying interphase chromosomes in human brain cells

One of the main genetic factors determining the functional activity of the genome in somatic cells, including brain nerve cells, is the spatial organization of chromosomes in the interphase nucleus. For a long time, no studies of human brain cells were carried out until high-resolution methods of molecular cytogenetics were developed to analyze interphase chromosomes in nondividing somatic cells. The purpose of the present work was to assess the potential of high-resolution methods of interphase molecular cytogenetics for studying chromosomes and the nuclear organization in postmitotic brain cells. A high efficiency was shown by such methods as multiprobe and quantitative fluorescence in situ hybridization (Multiprobe FISH and QFISH), ImmunoMFISH (analysis of the chromosome organization in different types of brain cells), and interphase chromosome-specific multicolor banding (ICS-MCB). These approaches allowed studying the nuclear organization depending on the gene composition and types of repetitive DNA of specific chromosome regions in certain types of brain cells (in neurons and glial cells, in particular). The present work demonstrates a high potential of interphase molecular cytogenetics for studying the structural and functional organizations of the cell nucleus in highly differentiated nerve cells. Analysis of interphase chromosomes of brain cells in the normal and pathological states can be considered as a promising line of research in modern molecular cytogenetics and cell neurobiology, i. e., molecular neurocytogenetics.     

Current status and the future of fluorescence in situ hybridization (FISH) in plant genome research.

Fluorescence in situ hybridization (FISH), which allows direct mapping of DNA sequences on chromosomes, has become the most important technique in plant molecular cytogenetics research. Repetitive DNA sequence can generate unique FISH patterns on individual chromosomes for karyotyping and phylogenetic analysis. FISH on meiotic pachytene chromosomes coupled with digital imaging systems has become an efficient method to develop physical maps in plant species. FISH on extended DNA fibers provides a high-resolution mapping approach to analyze large DNA molecules and to characterize large genomic loci. FISH-based physical mapping provides a valuable complementary approach in genome sequencing and map-based cloning research. We expect that FISH will continue to play an important role in relating DNA sequence information to chromosome biology. FISH coupled with immunoassays will be increasingly used to study features of chromatin at the cytological level that control expression and regulation of genes.     

Integration of Genetic and Cytological Maps and Development of a Pachytene Chromosome-based Karyotype in Papaya

A significant amount of genetic and genomic resources have been developed in papaya (Carica papaya, $ {\hbox{2n = 2}} \times { = 18} $ ), including genetic linkage maps consisting of nine major and three minor linkage groups. However, the 12 genetic linkage groups have not been integrated with the nine chromosomes of papaya. Bacterial artificial chromosome (BAC) clones associated with each linkage group were recently isolated. These linkage group-specific BACs were mapped to meiotic pachytene chromosomes of papaya using fluorescence in situ hybridization (FISH). The FISH mapping results integrated the 12 linkage groups into the nine papaya chromosomes. We developed a pachytene chromosome-based high resolution karyotype for the hermaphrodite plant genome of papaya cultivar SunUp. The chromosomal distribution of heterochromatin in the papaya genome is provided in the karyotype with the X chromosome representing the most euchromatic chromosome in the papaya genome. FISH mapping also revealed a significant amplification of sequences related to the 5S ribosomal RNA genes, which was detected in the male-specific region of the Y chromosome, but not in the corresponding region in the X chromosome.     

High-resolution FISH on super-stretched flow-sorted plant chromosomes

A novel high-resolution fluorescence in situ hybridisation (FISH) strategy, using super-stretched flow-sorted plant chromosomes as targets, is described. The technique that allows longitudinal extension of chromosomes of more than 100 times their original metaphase size is especially attractive for plant species with large chromosomes, whose pachytene chromosomes are generally too long and heterochromatin patterns too complex for FISH analysis. The protocol involves flow cytometric sorting of metaphase chromosomes, mild proteinase-K digestion of air-dried chromosomes on microscopic slides, followed by stretching with ethanol:acetic acid (3 : 1). Stretching ratios were assessed in a number of FISH experiments with super-stretched chromosomes from barley, wheat, rye and chickpea, hybridised with 45S and 5S ribosomal DNAs and the [GAA]n microsatellite, the [TTTAGGG]n telomeric repeat and a bacterial artificial chromosome (BAC) clone as probes. FISH signals on stretched chromosomes were brighter than those on the untreated control, resulting from better accessibility of the stretched chromatin and maximum observed sensitivity of 1 kbp. Spatial resolution of neighbouring loci was improved down to 70 kbp as compared to 5-10 Mbp after FISH on mitotic chromosomes, revealing details of adjacent DNA sequences hitherto not obtained with any other method. Stretched chromosomes are advantageous over extended DNA fibres from interphase nuclei as targets for FISH studies because they still retain chromosomal integrity. Although the method is confined to species for which chromosome flow sorting has been developed, it provides a unique system for controlling stretching degree of mitotic chromosomes and high-resolution bar-code FISH.