A Review of Fluorescence in Situ Hybridization (FISH): Current Status and Future Prospects

Fluorescence in situ hybridization (FISH) is a powerful technique for detecting DNA or RNA sequences in cells, tissues and tumors. This molecular cytogenetic technique enables the localization of specific DNA sequences within interphase chromatin and metaphase chromosomes and the identification of both structural and numerical chromosome changes. FISH is quickly becoming one of the most extensively used cytochemical staining techniques owing to its sensitivity and versatility, and with the improvement of current technology and cost effectiveness, its use will surely continue to expand. Here we review the wide variety of current applications and future prospects of FISH technology.     

Variations in alphoid DNA sequences escape detection of aneuploidy at interphase by FISH technique.

The advent of a new staining technique, termed fluorescence in situ hybridization (FISH), allows the rapid identification of the genomic constitution of an individual with aneuploidy even in interphase nuclei through the use of a series of chromosome-specific DNA probes, an approach termed "interphase cytogenetics." However, alphoid DNA sequences of every centromere are polymorphic (heteromorphic), and the number of targeted sequences may be below the detection level of a specific DNA probe, thus escaping detection and resulting in the imprecise identification of the chromosomal constitution at interphase. The limitations associated with the FISH technique have dire consequences which are emphasized here with an example in which the presence of an additional chromosome 21 in two siblings born consecutively with trisomy 21 (Down syndrome) was not detected by "interphase cytogenetics." The copy number of alphoid DNA sequences of one of the paternal chromosomes 21 was low and resulted in discordance between domain numbers at interphase and actual chromosome numbers at metaphase in both children. This is an isolated incident that could have led to a misdiagnosis if FISH were the only test employed. Although the advantages of this technology are undeniably enormous, the present finding has made it apparent that precise standards and reliability of the procedure must be established prior to its routine application.     

Simultaneous Detection of FISH Signals and Bromo-Deoxyuridine Incorporation in Fixed Tissue Cultured Cells

FISH (Fluorescence in situ hybridization) is a powerful technique that detects and localises specific DNA sequences on metaphase chromosomes, interphase nuclei or chromatin fibres. When coupled to BrdU (5-Bromo 2-deoxy-uridine) labeling of newly replicated DNA, the replication properties of different DNA sequences can be analysed. However, the technique for the detection of BrdU incorporation is time consuming, and relies on acidic pH buffer treatments, that prevent use of pH sensitive fluorochromes such as FITC (Fluoro-isothiocianate) during FISH. In this work, we describe a simplified protocol that allows the simultaneous detection of FISH signals and BrdU incorporation. Since the technique does not involve paraformaldehyde for cell fixation, or formamide for denaturation of the target DNA and in post-hybridisation washes, it represents a safer alternative to classical FISH techniques.     

植物荧光原位杂交技术的发展及其在植物基因组分析中的应用

荧光原位杂交(FISH)是在染色体、间期核和DNA纤维上定位特定DNA序列的一种有效而精确的分子细胞遗传学方法。20年来,植物荧光原位杂交技术发展迅速:以增加检测的靶位数为目的,发展了双色FISH、多色FISH和多探针FISH鸡尾酒技术;为增加很小染色体目标的检测灵敏度,发展了BAC-FISH和酪胺信号放大FISH(TSA-FISH)等技术;以提高相邻杂交信号的空间分辨力为主要目的,发展了高分辨的粗线期染色体FISH、间期核FISH、DNA纤维FISH和超伸展的流式分拣植物染色体FISH技术。在植物基因组分析中,FISH技术发挥了不可替代的重要作用,它可用于:物理定位DNA序列,并为染色体的识别提供有效的标记;对相同DNA序列进行比较物理定位,探讨植物基因组的进化;构建植物基因组的物理图谱;揭示特定染色体区域的DNA分子组织;分析间期核中染色质的组织和细胞周期中染色体的动态变化;鉴定植物转基因。     

A new FISH protocol with increased sensitivity for physical mapping with short probes in plants

Fluorescence in situ hybridization (FISH) is a well-established technique used for the detection of specific DNA regions, that has been applied to interphase nuclei, pachytene and metaphase chromosomes as well as to extended DNA fibres. This technique allows the physical mapping of specific DNA sequences both on individual chromosomes and extended fibres. A new FISH protocol is described here that enhances the sensitivity of the method. Probes for small unique DNA sequences of less than 2 kb give high signal-to-noise ratio with this method, and can be visualized easily by means of conventional fluorescence microscopy.     

Imaging the unimaginable: leveraging signal generation of CRISPR-Cas for sensitive genome imaging

Fluorescence in situ hybridization (FISH) is the gold standard for visualizing genomic DNA in fixed cells and tissues, but it is incompatible with live-cell imaging, and its combination with RNA imaging is challenging. Consequently, due to its capacity to bind double-stranded DNA (dsDNA) and design flexibility, the clustered regularly interspaced short palindromic repeats (CRISPR)-CRISPR-associated protein 9 (CRISPR-Cas9) technology has sparked enormous interest over the past decade. In this review, we describe various nucleic acid (NA)- and protein-based (amplified) signal generation methods that achieve imaging of repetitive and single-copy sequences, and even single-nucleotide variants (SNVs), next to highly multiplexed as well as dynamic imaging in live cells. With future progress in the field, the CRISPR-(d)Cas9-based technology promises to break through as a next-generation cell-imaging technique.     

Application of primed in situ DNA synthesis (PRINS) with telomere human commercial kit in molecular cytogenetics of Equus caballus and Sus scrofa scrofa

Recently, molecular techniques have become an indispensable tools for cytogenetic research. Especially, development of in situ techniques made possible detection at the chromosomal level, genes as well as repetitive sequences like telomeres or the DNA component of telomeres. One of these methods is primed in situ DNA synthesis (PRINS) using an oligonucleotide primer complementary to the specific DNA sequence. In this report we described application of PRINS technique with telomere human commercial kit to telomere sequences identification. This commercial kit may be use to visualization of interstitial telomeric signal in pig genome. PRINS is attractive complement to FISH for detection of DNA repetitive sequences and displays lower level of non-specific hybridization than conventional FISH.     

FISH技术在贝类分子生物学研究中的应用

在牡蛎和其它的海产贝类中,基因组研究的许多重要领域,如：利用非整倍体在牡蛎种间进行基因转移,三体牡的分离,牡蛎和其它贝类的连锁图的建立,三倍体的基因组稳定性和染色体缺失的分析等在缺少可靠的方法鉴定染色体而受到了限制,传统的带型技术很难鉴定牡的染色体。一种新的生物学技术－荧光原位杂交（FISH）为其提供了新的机遇。通过将DNA序列直接杂交到染色体上,FISH不仅是鉴定染色体的一个有力的工具,也是许多基因组研究如基因定位的一种有效的方法,结合最新研究成果,概述了FISH技术在贝类中的应用背景、现状和展望。     

FISH physical mapping with barley BAC clones

Fluorescence in situ hybridization (FISH) is a useful technique for physical mapping of genes, markers, and other single- or low-copy sequences. Since clones containing less than 10 kb of single-copy DNA do not reliably produce detectable signals with current FISH techniques in plants, a bacterial artificial chromosome (BAC) partial library of barley was constructed and a FISH protocol for detecting unique sequences in barley BAC clones was developed. The library has a 95 kb average barley insert, representing about 20% of a barley genome. Two BAC clones containing hordein gene sequences were identified and partially characterized. FISH using these two BAC clones as probes showed specific hybridization signals near the end of the short arm of one pair of chromosomes. Restriction digests of these two BAC clones were compared with restriction patterns of genomic DNA; all fragments contained in the BAC clones corresponded to bands present in the genomic DNA, and the two BAC clones were not identical. The barley inserts contained in these two BAC clones were faithful copies of the genomic DNA. FISH with four BAC clones with inserts varying from 20 to 150 kb, showed distinct signals on paired chromatids. Physical mapping of single- or low-copy sequences in BAC clones by FISH will help to correlate the genetic and physical maps. FISH with BAC clones also provide an additional approach for saturating regions of interest with markers and for constructing contigs spanning those regions.     

Comet-FISH for the evaluation of plant DNA damage after mutagenic treatments

The aim of this study was to perform a comparative investigation of the actions of three mutagens that are widely used in plant mutagenesis using the comet-FISH technique. The comet-FISH technique was used for the analysis of DNA damage and the kinetics of repair within specific DNA sequences. FISH with rDNA and telomeric/centromeric DNA probes was applied to comets that were obtained from an alkaline/neutral comet assay. Migration within specific DNA sequences was analysed after treatment with two chemical mutagens-maleic hydrazide (MH) and N-nitroso-N-methylurea (MNU), and γ-rays. Barley was used as a model plant in this study. The possible utility of specific DNA sequences in a comparative assessment of the distribution of DNA damage within a plant genome was evaluated. This study proved that the comet-FISH technique is suitable for a detailed quantification of DNA damage and repair within specific DNA sequences in plant mutagenesis. The analysis of FISH signals demonstrated that the involvement of specific DNA sequences in DNA damage was different and was dependent on the mutagen used. We showed that 5S rDNA and telomeric DNA sequences are more sensitive to mutagenic treatment, which was expressed by a stronger fragmentation and migration in comparison to the other probes used in the study. We found that 5S rDNA and telomeric DNA probes are more suitable for testing the genotoxicity of environmental factors. A comparison of the involvement of specific chromosome domains in direct DNA breakage/repair and in chromosome aberration formation after mutagen treatment indicates the compatibility of the results.     

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.     

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.     

Fiber-FISH技术及其在植物基因组研究中的应用

Fiber_FISH(fiber based fluorescent in situ hybridization DNA纤维荧光原位杂交)是近年来发展起来的一项直接在DNA纤维上进行荧光原位杂交的技术,其分辨率和灵敏度可分别达到1～2 kb和200 bp。描述了Fiber_FISH的技术要点,念珠状信号形成的可能原因,以及这一技术在植物基因组研究中的应用。     

Sexing using single blastomere derived from IVF bovine embryos by fluorescence in situ hybridization (FISH)

Fluorescence in situ hybridization (FISH) is a sensitive technique for molecular diagnosis of chromosomes on single cells and can be applied to sex determination of embryos. The objective has been to develop an accurate and reliable bovine Y chromosome-specific DNA probe in order to sex biopsed blastomeres derived from IVF bovine embryos by FISH. Bovine Y chromosome-specific PCR product derived from BtY2 sequences was labeled with biotin-16-dUTP (BtY2-L1 probe), and FISH was performed on karyoplasts of biopsed blastomeres and matched demi-embryos. Our FISH signal was clearly detected in nuclei of blastomeres of male embryos. FISH analysis of bovine embryos gave high reliability (96%) between biopsied blastomeres and matched demi-embryos. These results indicated that the BtY2-L1 bovine Y chromosome-specific FISH probe was an effective probe for bovine embryo sexing, and the FISH technique of probe detection could improve the efficiency and reliability.     

Construction of a swine artificial chromosome: a novel vector for transgenesis in the pig

A de novo SAC was constructed by making use of YAC technology and a humanized yeast strain. The construct (about 310 kb) contained pig centromeric DNA and the Neo gene. The construct was introduced into a pig cell line by yeast-mammalian cell fusion and G418 resistant clones were obtained. One clone was characterized by FISH and shown to contain an episomally located microchromosome containing YAC, Neo and pig centromere sequences. FISH analysis over time showed that the SAC was mitotically stable for at least 34 generations in the absence of selection. The size of the SAC was determined by confocal microscopy of the SAC and shown to be approximately 7 Mb, which is about 25-fold greater than the size of the original YAC. From its behavior in pulsed field gel electrophoresis, FISH analysis of stretched DNA fibers, and its appearance under scanning confocal microscopy, it was concluded that the SAC is a circularized and multimerized derivative of the original YAC. Possible applications as vectors for animal transgenesis are discussed.     

Grid technology in tissue-based diagnosis: fundamentals and potential developments

DNA fluorescence in situ hybridization (FISH) technology is used to study chromosomal and genomic changes in fixed cell suspensions and tissue block preparations. The technique is based on specific hybridization of small labeled DNA fragments, the probes, to complementary sequences in a target DNA molecule. Demand for FISH assays in formalin-fixed, paraffin-embedded tissues has been increasing, mainly in conditions in which diagnosis is not achieved in cell smears or tissue imprints, such as solid tumors. Moreover, the development of molecular targeted therapies in oncology has expanded the applicability of tests to predict sensitivity or resistance to these agents. The efficient use of tyrosine kinase inhibitors (TKI) of the epidermal growth factor receptor (EGFR) as therapeutical agents in advanced non-small cell lung cancer (NSCLC) depends on identification of patients likely to show clinical benefit from these specific treatments. The EGFR gene copy number determined by FISH has been demonstrated as an effective predictor of outcome from NSCLC patients to EGFR TKIs; however there are pending challenges for standardization of laboratory procedures and definition of the scoring system. This methodology article focuses on the EGFR FISH assay. It details the scoring system used in the studies conducted at the University of Colorado Cancer Center in which a significant association was found between increased EGFR copy numbers and clinical outcome to TKIs, and proposes interpretative guidelines for molecular stratification of NSCLC patients for TKI therapy.     

玉米有丝分裂染色体上玉米BAC探针的FISH杂交体系的构建

本研究分别探讨了玉米和水稻基因组c 0t DNA对探针的封阻、杂交后洗脱的严谨度、杂交液中FAD的浓度变化对BAC-FISH杂交的影响;探讨了玉米BAC探针中重复序列含量对FISH信号的影响.初步形成了一套以玉米BAC探针在玉米有丝分裂染色体上进行FISH杂交的优化技术体系.结果表明,玉米基因组c 0t DNA对探针封阻的c 0t值应小于50;而降低杂交液中FAD浓度和适度控制杂交后洗脱的严谨度,尤其是使用水稻基因组的c 0t 100 DNA封阻探针重复序列对BAC-FISH杂交信号特异性的改善具有明显的效果;同时,验证了选择重复序列含量较少的玉米BAC作为FISH杂交的探针也是获得特异性杂交信号的重要条件.     

Fluorescence intensity profiles of in situ hybridization signals depict genome architecture within human interphase nuclei

An approach towards construction of two-dimensional (2D) and three-dimensional (3D) profiles of interphase chromatin architecture by quantification of fluorescence in situ hybridization (FISH) signal intensity is proposed. The technique was applied for analysis of signal intensity and distribution within interphase nuclei of somatic cells in different human tissues. Whole genomic DNA, fraction of repeated DNA sequences (Cot 1) and cloned satellite DNA were used as probes for FISH. The 2D and 3D fluorescence intensity profiles were able to depict FISH signal associations and somatic chromosome pairing. Furthermore, it allowed the detection of replicating signal patterns, the assessment of hybridization efficiency, and comparative analysis of DNA content variation of specific heterochromatic chromosomal regions. The 3D fluorescence intensity profiles allowed the analysis of intensity gradient within the signal volume. An approach was found applicable for determination of assembly of different types of DNA sequences, including classical satellite and alphoid DNA, gene-rich (G-negative bands) and gene-poor (G-positive bands) chromosomal regions as well as for assessment of chromatin architecture and targeted DNA sequence distribution within interphase nuclei. We conclude the approach to be a powerful additional tool for analysis of interphase genome architecture and chromosome behavior in the nucleus of human somatic cells. The text was submitted by the authors in English.     

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。     

Oestradiol, a new hapten for detecting nucleic acid sequences by FISH

 Oestradiol has been conjugated to allylamine-dUTP with an 11-atom spacer to allow enzymatic incorporation of the label into DNA sequences. In a comparative DNA and mRNA FISH study we have used DNA probes that were either labelled with digoxigenin, biotin or oestradiol. Results show that oestradiol-labelled probes can detect DNA and RNA sequences in FISH equally well as digoxigenin- and biotin-labelled probes. Further, no crossreactivity between the various hapten-specific antibodies and the three haptens were observed. Binding of the rabbit anti-oestradiol antibody to endogenous oestrogen in various tissues was not observed under the conditions tested. In view of the increasing demands for multi-colour DNA and mRNA FISH applications, oestradiol is a welcome addition to the collection of haptens employed in FISH. Accepted 20 June 1997