Multiplex-FISH (M-FISH): technique, developments and applications

Multiplex FISH (M-FISH) represents one of the most significant developments in molecular cytogenetics of the past decade. Originally designed to generate 24 colour karyotyping, the technique has spawned many variations and an equally diverse range of applications. In tumour and leukaemia cytogenetics, the two groups that have been targeted represent both ends of the cytogenetic spectrum: those with an apparently normal karyotype (suspected of harbouring small rearrangements not detectable by conventional cytogenetics) and those with a complex aberrant karyotype (which are difficult to karyotype accurately due to the sheer number of aberrations). In research, mouse M-FISH provides a powerful tool to characterize mouse models of a disease. In addition, the ability to accurately karyotype single metaphases without selection makes M-FISH the perfect tool in chromosome breakage studies and for characterizing clonal evolution of tumours. Finally, M-FISH has emerged as the perfect partner for the developing genomic microarray (array CGH) technologies, providing a powerful approach to gene discovery.     

Chromosomes in the flow to simplify genome analysis

Nuclear genomes of human, animals, and plants are organized into subunits called chromosomes. When isolated into aqueous suspension, mitotic chromosomes can be classified using flow cytometry according to light scatter and fluorescence parameters. Chromosomes of interest can be purified by flow sorting if they can be resolved from other chromosomes in a karyotype. The analysis and sorting are carried out at rates of 10(2)-10(4) chromosomes per second, and for complex genomes such as wheat the flow sorting technology has been ground-breaking in reducing genome complexity for genome sequencing. The high sample rate provides an attractive approach for karyotype analysis (flow karyotyping) and the purification of chromosomes in large numbers. In characterizing the chromosome complement of an organism, the high number that can be studied using flow cytometry allows for a statistically accurate analysis. Chromosome sorting plays a particularly important role in the analysis of nuclear genome structure and the analysis of particular and aberrant chromosomes. Other attractive but not well-explored features include the analysis of chromosomal proteins, chromosome ultrastructure, and high-resolution mapping using FISH. Recent results demonstrate that chromosome flow sorting can be coupled seamlessly with DNA array and next-generation sequencing technologies for high-throughput analyses. The main advantages are targeting the analysis to a genome region of interest and a significant reduction in sample complexity. As flow sorters can also sort single copies of chromosomes, shotgun sequencing DNA amplified from them enables the production of haplotype-resolved genome sequences. This review explains the principles of flow cytometric chromosome analysis and sorting (flow cytogenetics), discusses the major uses of this technology in genome analysis, and outlines future directions.     

Molecular cytogenetic definition of the chicken genome: the first complete avian karyotype

Chicken genome mapping is important for a range of scientific disciplines. The ability to distinguish chromosomes of the chicken and other birds is thus a priority. Here we describe the molecular cytogenetic characterization of each chicken chromosome using chromosome painting and mapping of individual clones by FISH. Where possible, we have assigned the chromosomes to known linkage groups. We propose, on the basis of size, that the NOR chromosome is approximately the size of chromosome 22; however, we suggest that its original assignment of 16 should be retained. We also suggest a definitive chromosome classification system and propose that the probes developed here will find wide utility in the fields of developmental biology, DT40 studies, agriculture, vertebrate genome organization, and comparative mapping of avian species.     

Molecular cytogenetic characterization of Ciona intestinalis chromosomes

The compact genome of the ascidian Ciona intestinalis has been sequenced. Chromosome karyotype and mapping of the genome sequence information on each of the 14 pairs of chromosomes are essential for genome-wide studies of gene expression and function in this basal chordate. Although the small chromosome size (most pairs measuring less than 2 mum) complicates accurate chromosome pairing based on morphology alone, the present results suggest that 20 chromosomes are metacentric and 8 are submetacentric or subtelocentric, and two pairs of large chromosomes (#1 and #2) were defined. The characterization of chromosomes by FISH and staining with propidium iodide indicated that 18S/28S ribosomal gene repeats are present in the short arms of three pairs of chromosomes and that the short arms of these pairs show remarkable size polymorphism. In addition, each chromosome was characterized molecular cytogenetically by mapping representative BAC clones with FISH. The present study is therefore a first step in expanding the karyotype analysis and entire physical mapping of the genome sequence of Ciona intestinalis.     

Characterization of double minute chromosomes’ DNA content in a human high grade astrocytoma cell line by using comparative genomic hybridization and fluorescence in situ hybridization

The presence of double minute chromosomes (dmin) in cancer cells is known to be correlated with gene amplifications. In human high grade astrocytomas or glioblastomas, about 50% of cytogenetically characterized cases display dmin. G5 is a cell line which has been established from a human glioblastoma containing multiple dmin. In order to identify the DNA content of these dmin, three techniques were successively used: conventional cytogenetic analysis, comparative genomic hybridization (CGH), and fluorescent in situ hybridization (FISH). The karyotype of G5 cells showed numerical chromosome changes (hypertriploidy), several marker chromosomes, and multiple dmin. CGH experiments detected two strong DNA amplification areas located in 9p21-22 and 9p24, as well as an underrepresentation of chromosomes 6, 10, 11, 13, 14, and 18q. By using FISH with a chromosome 9-specific painting probe to metaphase chromosomes of the G5 cell line, dmin were shown to contain DNA sequences originating from chromosome 9. This study demonstrates the usefulness of a combination of classical karyotyping, CGH, and FISH to identify the chromosomal origin of amplified DNA sequences in dmin. Received: 30 October 1994 / Revised: 25 February 1996     

"Bar-coding" primate chromosomes: molecular cytogenetic screening for the ancestral hominoid karyotype

Two recently introduced multicolor FISH approaches, cross-species color banding (also termed Rx-FISH) and multiplex FISH using painting probes derived from somatic cell hybrids retaining fragments of human chromosomes, were applied in a comparative molecular cytogenetic study of higher primates. We analyzed these "chromosome bar code" patterns to obtain an overview of chromosomal rearrangements that occurred during higher primate evolution. The objective was to reconstruct the ancestral genome organization of hominoids using the macaque as outgroup species. Approximately 160 individual and discernible molecular cytogenetic markers were assigned in these species. Resulting comparative maps allowed us to identify numerous intra-chromosomal rearrangements, to discriminate them from previous contradicting chromosome banding interpretations and to propose an ancestral karyotype for hominoids. From 25 different chromosome forms in an ancestral karyotype for all hominoids of 2N=48 we propose 21. Probes for chromosomes 2p, 4, 9 and Y were not informative in the present experiments. The orangutan karyotype was very similar to the proposed ancestral organization and conserved 19 of the 21 ancestral forms; thus most chromosomes were already present in early hominoid evolution, while African apes and human show various derived changes.     

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。     

Karyotype of maize (Zea mays L.) mitotic metaphase chromosomes as revealed by fluorescencein situ hybridization (FISH) with cytogenetic DNA markers

Here we demonstrate fluorescencein situ hybridization (FISH) of chromosome-specific cytogenetic DNA markers for chromosome identification in maize using repetitive and single copy probes. The fluorescently labeled probes, CentC and pZm4–21, were shown to be reliable cytogenetic markers in the maize inbred line KYS for identification of mitotic metaphase chromosomes. The fluorescent strength of CentC signal, relative position, knob presence, size and location were used for the karyotyping. Based on direct visual analysis of chromosome length and position of FISH signals, a metaphase karyotype was constructed for maize inbred line KYS. All chromosomes could be identified unambiguously. The knob positions in the karyotype agreed well with those derived from traditional cytological analyses except chromosomes 3, 4 and 8. One chromosome with a telomeric knob on the short arm was assigned to 3. A chromosome with a knob in the middle of the long arm was assigned number 4 by simultaneous hybridization with a knob-specific probe pZm4–21 and a chromosome 4-specific probe Cent 4. On chromosome 8, we found an additional small telomeric knob on the short arm. In addition, chromosome-specific probes were employed to identify chromosome 6 (45S rDNA) and chromosome 9 (single-copy probeumc105a cosmid).     

Cloning and Characterization of Chromosomal Markers from a Cot-1 Library of Peanut ( Arachis hypogaea L.)

The cultivated peanut, Arachis hypogaea (AABB, 2n = 40), is an allotetraploid which was probably originated from a hybridization event between 2 ancestors, A. duranensis (A genome) and A. ipaensis (B genome) followed by chromosome doubling. The wild species in the Arachis section are useful genetic resources for genes that confer biotic and abiotic stress resistance for peanut breeding. However, the resource is not well exploited because little information on the genetic, cytogenetic, and phylogenetic relationships between cultivated peanut and its wild relatives is known. Characterization of its chromosome components will benefit the understanding of these issues. But the paucity of information on the DNA sequence and the presence of morphologically similar chromosomes impede the construction of a detailed karyotype for peanut chromosome identification. In our study, a peanut Cot-1 library was constructed to isolate highly and moderately repetitive sequences from the cultivated peanut, and the chromosomal distributions of these repeats were investigated. Both genome and chromosome specific markers were identified that allowed the distinguishing of A and B genomes in tetraploid peanut and a possible karyotyping of peanut chromosomes by FISH. In particular, a 115-bp tandem repetitive sequence was identified to be a possible centromere repetitive DNA, mainly localized in the centromeres of B chromosomes, and a partial retrotransposable element was also identified in the centromeres of B chromosomes. The cloning and characterization of various chromosomal markers is a major step for FISH-based karyotyping of peanut. The FISH markers are expected to provide a reference tool for sequence assembly, phylogenetic studies of peanut and its wild species, and breeding.     

Paint-assisted microdissection-FISH: Rapid and simple mapping of translocation breakpoints in the embryonal rhabdomyosarcoma cell line RD.

BACKGROUND: Spectral karyotyping and multiple fluorophore fluorescence in situ hybridisation (M-FISH) facilitate identification of inter-chromosomal rearrangements, but are of low cytogenetic resolution in mapping translocation breakpoints. Reverse chromosome painting yields increased cytogenetic information but isolation of aberrant chromosomes is technically difficult. We have developed the technique of paint-assisted microdissection FISH (PAM-FISH), which enables microdissection of aberrant chromosomes to be carried out easily and rapidly using relatively simple apparatus. METHODS: A selected chromosome paint is hybridised to abnormal metaphases to label a chromosome of interest, which is then microdissected, amplified, labelled by polymerase chain reaction (PCR), and reverse painted onto extended normal metaphases. RESULTS: PAM-FISH was used to reassess structural chromosomal abnormalities identified by molecular cytogenetics in the rhabdomyosarcoma cell line RD. PAM-FISH improved the analysis of virtually all structural abnormalities, identifying six novel translocations and indicating that seven previously described rearrangements were in fact not present in RD. Accuracy of the breakpoint mapping obtained was confirmed by bacterial artificial chromosome-FISH. CONCLUSIONS: PAM-FISH is ideally suited to analysis of tumour metaphases as it is not affected by poor chromosome morphology. Reagents generated by PAM-FISH are also suitable for other investigations, such as mapping using sequence tagged-site PCR or genomic microarrays. PAM-FISH is technically straightforward and could readily be adopted in a routine cytogenetics laboratory for accurate high-throughput analysis of chromosome breakpoints.     

Integration of chicken cytogenetic and genetic maps: 18 new polymorphic markers isolated from BAC and PAC clones

As an approach to integrate the chicken genetic and cytogenetic maps, bacterial artificial chromosome (BAC) and P1-derived artificial chromosome (PAC) clones were localized by fluorescence in situ hybridization (FISH) on chromosomes and by genetic mapping on the East Lansing and Compton reference families. Some of the clones used in this study were previously selected for the presence of potentially polymorphic (CA)n repeats and a microsatellite marker was developed when possible for genetic mapping. For other clones, a single strand conformational polymorphism (SSCP) was developed and used for this purpose. Between the two approaches, 18 markers linking the cytogenetic and genetic maps, seven on macrochromosomes and 11 on microchromosomes, were generated. Our results enabled the assignment and orientation of a linkage group to chromosome 3, together with the assignment of linkage groups to eight different microchromosomes, a fraction of the genome lacking mapping data and for which the degree of coverage by the genetic map was not well estimated previously.     

The Bombyx mori karyotype and the assignment of linkage groups

Lepidopteran species have a relatively high number of small holocentric chromosomes (Bombyx mori, 2n = 56). Chromosome identification has long been hampered in this group by the high number and by the absence of suitable markers like centromere position and chromosome bands. In this study, we carried out fluorescence in situ hybridization (FISH) on meiotic chromosome complements using genetically mapped B. mori bacterial artificial chromosomes (BACs) as probes. The combination of two to four either green or red fluorescence-labeled probes per chromosome allowed us to recognize unequivocally each of the 28 bivalents of the B. mori karyotype by its labeling pattern. Each chromosome was assigned one of the already established genetic linkage groups and the correct orientation in the chromosome was defined. This facilitates physical mapping of any other sequence and bears relevance for the ongoing B. mori genome projects. Two-color BAC-FISH karyotyping overcomes the problem of chromosome recognition in organisms where conventional banding techniques are not available.     

Cryptic terminal chromosome rearrangements in colorectal carcinoma cell lines detected by subtelomeric FISH analysis

Epithelial tumour karyotypes are often difficult to study by standard cytogenetic methods because of poor chromosome preparation quality and the high complexity of their genomic rearrangements. Subtelomeric fluorescence in situ hybridisation (FISH) has proved to be a useful method for detecting cryptic constitutional chromosomal rearrangements but little is known about its usefulness for tumour cytogenetic analysis. Using a combination of chromosome banding, multicolour karyotyping and subtelomeric FISH, five colorectal cancer cell lines were characterised. The resulting data were compared to results from previous studies by comparative genomic hybridisation and spectral karyotyping or multicolour FISH. Subtelomeric FISH made it possible to resolve several highly complex chromosome rearrangements, many of which had not been detected or were incompletely characterised by the other methods. In particular, previously undetected terminal imbalances were found in the two cell lines not showing microsatellite instability.     

Spectral karyotyping refines cytogenetic diagnostics of constitutional chromosomal abnormalities

Karyotype analysis by chromosome banding is the standard method for identifying numerical and structural chromosomal aberrations in pre- and postnatal cytogenetics laboratories. However, the chromosomal origins of markers, subtle translocations, or complex chromosomal rearrangements are often difficult to identify with certainty. We have developed a novel karyotyping technique, termed spectral karyotyping (SKY), which is based on the simultaneous hybridization of 24 chromosome-specific painting probes labeled with different fluorochromes or fluorochrome combinations. The measurement of defined emission spectra by means of interferometer-based spectral imaging allows for the definitive discernment of all human chromosomes in different colors. Here, we report the comprehensive karyotype analysis of 16 samples from different cytogenetic laboratories by merging conventional cytogenetic methodology and spectral karyotyping. This approach could become a powerful tool for the cytogeneticists, because it results in a considerable improvement of karyotype analysis by identifying chromosomal aberrations not previously detected by G-banding alone. Advantages, limitations, and future directions of spectral karyotyping are discussed. Received: 4 August 1997 / Accepted: 8 September 1997     

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.     

A First Generation Comparative Chromosome Map between Guinea Pig (Cavia porcellus) and Humans

The domesticated guinea pig, Cavia porcellus (Hystricomorpha, Rodentia), is an important laboratory species and a model for a number of human diseases. Nevertheless, genomic tools for this species are lacking; even its karyotype is poorly characterized. The guinea pig belongs to Hystricomorpha, a widespread and important group of rodents; so far the chromosomes of guinea pigs have not been compared with that of other hystricomorph species or with any other mammals. We generated full sets of chromosome-specific painting probes for the guinea pig by flow sorting and microdissection, and for the first time, mapped the chromosomal homologies between guinea pig and human by reciprocal chromosome painting. Our data demonstrate that the guinea pig karyotype has undergone extensive rearrangements: 78 synteny-conserved human autosomal segments were delimited in the guinea pig genome. The high rate of genome evolution in the guinea pig may explain why the HSA7/16 and HSA16/19 associations presumed ancestral for eutherians and the three syntenic associations (HSA1/10, 3/19, and 9/11) considered ancestral for rodents were not found in C. porcellus. The comparative chromosome map presented here is a starting point for further development of physical and genetic maps of the guinea pig as well as an aid for genome assembly assignment to specific chromosomes. Furthermore, the comparative mapping will allow a transfer of gene map data from other species. The probes developed here provide a genomic toolkit, which will make the guinea pig a key species to unravel the evolutionary biology of the Hystricomorph rodents.     

The combination of SKY and specific loci detection with FISH or immunostaining

Spectral karyotyping (SKY) represents an effective tool to detect individual chromosomes and analyze major karyotype abnormalities within an entire genome. We have tested the feasibility of combining SKY and FISH/protein detection in order to combine SKY's unique abilities with specific loci detection. Our experimental results demonstrate that various combined protocols involving SKY, FISH and immunostaining work well when proper procedures are used. This combined approach allows the tracking of key genes or targeted chromosome regions while monitoring changes throughout the whole genome. It is particularly useful when simultaneously monitoring the behavior of both protein complexes and DNA loci within the genome. The details of this methodology are described and systematically tested in this communication.     

SKY and FISH analysis of radiation-induced chromosome aberrations: a comparison of whole and partial genome analysis

For a retrospective dose estimation of human exposure to ionising radiation, a partial genome analysis is routinely used to quantify radiation-induced chromosome aberrations. For this purpose, fluorescence in situ hybridisation (FISH) with whole chromosome painting probes for selected chromosomes is usually applied covering about 20% of the whole genome. Since genome-wide screening techniques like spectral karyotyping (SKY) and multiplex FISH (mFISH) have been developed the detection of radiation-induced aberrations within the whole genome has now become feasible. To determine the correspondence between partial and whole genome analysis of radiation-induced chromosome aberrations, they were measured comprehensively in this study using in vitro irradiated blood samples from three donors. We were able to demonstrate that comparable results can be detected with both approaches. However, complex aberrations might be misinterpreted by partial genome analysis. We therefore conclude that whole genome analysis by SKY is useful especially in the high dose range to correct aberration data for complex exchange aberrations.     

Classical and molecular cytogenetics of the zebrafish, Danio rerio (Cyprinidae, Cypriniformes): an overview

The zebrafish, Danio rerio, has recently become the model system for the genetic analysis of vertebrate development. This paper reviews the advances in zebrafish cytogenetics, obtained through classical and molecular techniques, which will lead to the assignment of specific linkage groups to specific chromosome pairs in the zebrafish genome project. Several chromosome pairs of the 50-chromosome karyotype of D. rerio were differentially stained by classical staining techniques and additional information has been obtained by molecular cytogenetics. Indeed, the analysis of constitutive heterochromatin by C-banding and base-specific fluorochrome staining had suggested a differential composition of peri- and paracentromeric constitutive heterochromatin. The chromosome mapping of distinct AT- and GC-rich zebrafish satellite DNAs by means of PRINS (Primed in situ) and multicolor FISH (Fluorescence in situ Hybridization) has confirmed this hypothesis, which therefore provided the chromosome localization of 10% of the zebrafish genome. The analysis of nucleolus organizer regions (NORs) by silver staining and by FISH with 18S rDNA has also revealed the existence of variable and inactive NORs, in addition to those on the terminal regions of the long arms of the three NOR-bearing chromosome pairs. Other multicopy genes, such as minor ribosomal genes, or multicopy repeats, such as telomere specific sequences, have now been mapped on zebrafish chromosomes. The latest advancement in zebrafish molecular cytogenetics is the chromosome mapping of single locus genes. Single-copy genes from each of the 25 genetic linkage groups are now being mapped on zebrafish chromosomes by using PAC clones.     

Molecular cytogenetics of forest trees

The economic and ecological importance of forest trees, as well as their unique biological features, has recently raised the level of interest in studies on their genomes, including sequencing of the entire poplar genome. However, cytogenetic studies have not moved in parallel with developments in genomics. This is especially true for hardwood species characterized by small genomes and relatively high numbers of small chromosomes. Molecular cytogenetic studies have mainly been focused on coniferous species, owing to the larger size of their chromosomes, and have been applied exclusively for chromosome identification and comparative karyotyping in an attempt to understand genome evolution and phylogenetic relationships. In this context, rRNA genes physical mapped by FISH reveal particularly useful chromosomal landmarks with variable distribution patterns between species. Here we present a contribution of DNA markers used for chromosome analysis, which already allowed a deeper characterization and understanding of the processes underlying genome diversity of forest trees. The use of advanced cytogenetic techniques and other potential important methods for genome analysis of forest trees is also discussed.