Exon mapping by fiber-FISH or LR-PCR

Non-random mtDNA segregation patterns indicate a metastable heteroplasmic segregation unit in m.3243A>G cybrid cells

Many pathogenic mitochondrial DNA mutations are heteroplasmic, with a mixture of mutated and wild-type mtDNA present within individual cells. The severity and extent of the clinical phenotype is largely due to the distribution of mutated molecules between cells in different tissues, but mechanisms underpinning segregation are not fully understood. To facilitate mtDNA segregation studies we developed assays that measure m.3243A>G point mutation loads directly in hundreds of individual cells to determine the mechanisms of segregation over time. In the first study of this size, we observed a number of discrete shifts in cellular heteroplasmy between periods of stable heteroplasmy. The observed patterns could not be parsimoniously explained by random mitotic drift of individual mtDNAs. Instead, a genetically metastable, heteroplasmic mtDNA segregation unit provides the likely explanation, where stable heteroplasmy is maintained through the faithful replication of segregating units with a fixed wild-type/m.3243A>G mutant ratio, and shifts occur through the temporary disruption and re-organization of the segregation units. While the nature of the physical equivalent of the segregation unit remains uncertain, the factors regulating its organization are of major importance for the pathogenesis of mtDNA diseases.

A sugar beet (Beta vulgaris L.) reference FISH karyotype for chromosome and chromosome-arm identification, integration of genetic linkage groups and analysis of major repeat family distribution

We developed a reference karyotype for B. vulgaris which is applicable to all beet cultivars and provides a consistent numbering of chromosomes and genetic linkage groups. Linkage groups of sugar beet were assigned to physical chromosome arms by FISH (fluorescent in situ hybridization) using a set of 18 genetically anchored BAC (bacterial artificial chromosome) markers. Genetic maps of sugar beet were correlated to chromosome arms, and North-South orientation of linkage groups was established. The FISH karyotype provides a technical platform for genome studies and can be applied for numbering and identification of chromosomes in related wild beet species. The discrimination of all nine chromosomes by BAC probes enabled the study of chromosome-specific distribution of the major repetitive components of sugar beet genome comprising pericentromeric, intercalary and subtelomeric satellites and 18S-5.8S-25S and 5S rRNA gene arrays. We developed a multicolor FISH procedure allowing the identification of all nine sugar beet chromosome pairs in a single hybridization using a pool of satellite DNA probes. Fiber-FISH was applied to analyse five chromosome arms in which the furthermost genetic marker of the linkage group was mapped adjacently to terminal repetitive sequences on pachytene chromosomes. Only on two arms telomere arrays and the markers are physically linked, hence these linkage groups can be considered as terminally closed making the further identification of distal informative markers difficult. The results support genetic mapping by marker localization, the anchoring of contigs and scaffolds for the annotation of the sugar beet genome sequence and the analysis of the chromosomal distribution patterns of major families of repetitive DNA.

Genomic analysis of a 1 Mb region near the telomere of Hessian fly chromosome X2 and avirulence gene vH13

BACKGROUND

To have an insight into the Mayetiola destructor (Hessian fly) genome, we performed an in silico comparative genomic analysis utilizing genetic mapping, genomic sequence and EST sequence data along with data available from public databases.

RESULTS

Chromosome walking and FISH were utilized to identify a contig of 50 BAC clones near the telomere of the short arm of Hessian fly chromosome X2 and near the avirulence gene vH13. These clones enabled us to correlate physical and genetic distance in this region of the Hessian fly genome. Sequence data from these BAC ends encompassing a 760 kb region, and a fully sequenced and assembled 42.6 kb BAC clone, was utilized to perform a comparative genomic study. In silico gene prediction combined with BLAST analyses was used to determine putative orthology to the sequenced dipteran genomes of the fruit fly, Drosophila melanogaster, and the malaria mosquito, Anopheles gambiae, and to infer evolutionary relationships.

CONCLUSION

This initial effort enables us to advance our understanding of the structure, composition and evolution of the genome of this important agricultural pest and is an invaluable tool for a whole genome sequencing effort.

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.

Physical mapping of plasmid and cosmid clones in filamentous fungi by fiber-FISH

Fluorescence in situ hybridization to extended DNA fibers (fiber-FISH) serves as a powerful tool for direct physical mapping in plants and animals. Here, we show that fiber-FISH is useful for contig mapping as well as for estimating the physical distance between genetic markers in fungi. A five-cosmid contig from a chromosome of Nectria haematococca and four cloned genetic markers from a linkage map of Cochliobolus heterostrophus were chosen as models for the application of this technology. In N. haematococca, overlapping and non-overlapping clones were visually mapped on individual DNA fibers, confirming the results from conventional physical mapping perfectly. Fiber-FISH concomitantly indicated the gap size or the extent of overlap between two clones. In C. heterostrophus, the physical distance between the two pairs of genetic markers could be estimated from the microscopic measurements of the intervals. Chromosomal DNA isolated from a pulsed field gel was suitable for preparing the DNA fibers.

Combined use of PRINS and FISH in the study of the dystrophin gene

The efficacy of fluorescence in situ hybridization (FISH) may be limited in specific applications by low-resolution sensitivity. Primed in situ labeling (PRINS) is based on specific hybridization of an unlabeled oligonucleotide with a denatured template and synthesis of a single-strand DNA in situ. This method may represent a powerful alternative to FISH for gene mapping because of its ability to generate multiple independent signals within the same gene segment. We investigated the specificity of signals produced by a modified PRINS protocol combining a centromeric probe for the X-chromosome with specific primers for 3'- and 5'-terminal regions of the dystrophin gene. In approximately 70% of nuclei from male and female subjects, we detected one or two large signals (X-chromosome centromere) and two or four smaller signals (the two regions of the dystrophin gene). Specific hybridization of the oligonucleotides on Xp was demonstrated by localization of the smaller (dystrophin) and larger (X-centromere) signals on the same chromosome. Simultaneous hybridization with a centromeric probe and gene-specific oligonucleotides allowed localization of PRINS signals, and assessment of the specificity of the primers used for hybridization. This approach could facilitate identification of female carriers of small intragenic deletions in the dystrophin gene.

Copy-number fluctuation by unequal crossing-over in the chicken avidin gene family

The chicken avidin gene (AVD) forms a closely clustered gene family together with several avidin-related genes (AVRs). In this study, we used fluorescence in situ hybridization on extended DNA fibers (fiber-FISH) to show that the number of the AVD and AVR genes differs between individuals. Furthermore, the gene copy-number showed wide somatic variation in white blood cells of the individuals. The molecular mechanism underlying the fluctuation is most probably unequal crossing-over and/or unequal sister chromatid exchange, as judged by the Gaussian distribution of the gene counts. By definition, an increase in gene number on one locus should be accompanied by a decrease on the other locus in unequal sequence exchange. The results suggest that copy-number lability may be more common among gene families than previously thought. The chicken avidin gene family also provides an excellent model for studying the mechanisms of recombination and gene conversion.

Fluorescence in situ hybridization analysis of transcript dynamics in cells

Since the first description of in situ hybridization in 1969 the technique has advanced to allow sensitive detection of DNA and mRNA molecules at the cellular and subcellular levels. In particular fluorescence in situ hybridization (FISH) has become a frequently used tool in basic and applied biomedical research since detection is sensitive and allows discrimination of multiple targets in the same sample. By using RNA-FISH we have been able to detect primary transcripts of the human embryonic, fetal, and adult globins in erythroid cells to study the competitive transcription mechanism or variegated expression patterns of the human beta-globin locus. We have correlated such expression patterns with other parameters such as cell type, cell cycle, replication, and stage of differentiation by simultaneous detection of, e.g., incorporated BrdUTPs, proteins (e.g., cyclins A and E, PCNA, histones), and globin (primary) transcripts and/or locus integration sites. Thus a combination of FISH and immunofluorescence methods allow the visualization of different processes taking place in the nucleus relative to each other in terms of three-dimensional space and structure and time (development, cell cycle).

DNA fiber mapping techniques for the assembly of high-resolution physical maps

High-resolution physical maps are indispensable for directed sequencing projects or the finishing stages of shotgun sequencing projects. These maps are also critical for the positional cloning of disease genes and genetic elements that regulate gene expression. Typically, physical maps are based on ordered sets of large insert DNA clones from cosmid, P1/PAC/BAC, or yeast artificial chromosome (YAC) libraries. Recent technical developments provide detailed information about overlaps or gaps between clones and precisely locate the position of sequence tagged sites or expressed sequences, and thus support efforts to determine the complete sequence of the human genome and model organisms. Assembly of physical maps is greatly facilitated by hybridization of non-isotopically labeled DNA probes onto DNA molecules that were released from interphase cell nuclei or recombinant DNA clones, stretched to some extent and then immobilized on a solid support. The bound DNA, collectively called "DNA fibers," may consist of single DNA molecules in some experiments or bundles of chromatin fibers in others. Once released from the interphase nuclei, the DNA fibers become more accessible to probes and detection reagents. Hybridization efficiency is therefore increased, allowing the detection of DNA targets as small as a few hundred base pairs. This review summarizes different approaches to DNA fiber mapping and discusses the detection sensitivity and mapping accuracy as well as recent achievements in mapping expressed sequence tags and DNA replication sites.

Effective generation of very low density lipoprotein receptor transgenic mice by overlapping genomic DNA fragments: high testis expression and disturbed spermatogenesis

The generation of functional transgenes via microinjection of overlapping DNA fragments has previously been reported to be successful, but it is still not a widely applied approach. Here we show that the method is very reliable, and should be considered, in case a single large insert clone of the desired gene is not available. In the present study, two large DNA fragments consisting of overlapping cosmids, together constituting the human very low density lipoprotein receptor (VLDLR) gene (35 kb), were used to generate VLDLR transgenic (VLDLR-Tg) mice. Three transgenic founders were born, of which two (strain #2 and #3) generated transgenic offspring. Using Fiber-FISH analysis, the integration site was shown to contain at least 44 and 64 DNA fragments in mouse strains #2 and #3, respectively. This copy number resulted in integration sites of 1.5 and 2.5 megabase in size. Notably, over 90% of the fragments in both mouse strains #2 and #3 were flanked by their complementary fragment. In line with this observation, Southern blot analysis demonstrated that the correct recombination between fragments predominated in the transgenic insertion. Human VLDLR expression was detected in testis, kidney and brain of both mouse strains. Since this pattern did not parallel the endogenous VLDLR expression, some crucial regulatory elements were probably not present in the cosmid clones. Human VLDLR expression in testis was detected in germ cells up to the meiotic stage by in situ mRNA analysis. Remarkably, in the F1 generation of both VLDLR-Tg mouse strains the testis was atrophic and giant cells were detected in the semineferous tubuli. Furthermore, male VLDLR-Tg mice transmitted the transgene to their progeny with low frequencies. This could imply that VLDLR overexpression in the germ cells disturbed spermatogenesis.

Overview of fluorescence in situ hybridization techniques for molecular cytogenetics

This unit presents an overview of the FISH methodology. It covers such topics as direct versus indirect methods, sensitivity, multiplicity, resolution, and applications.

DNA fiber-FISH staining mechanism

Fluorescence in situ hybridization to DNA fibers (Fiber-FISH) is a high-resolution, wide-ranging physical DNA mapping method that finds increasing application in the study of pathological gene rearrangements. Here we present experiments designed to understand the nature of the discontinuous FISH signal patterns seen after Fiber-FISH. Use of a novel cisplatin-based chemical labeling method enabled us to produce intact biotin-labeled cosmid target DNA molecules. We monitored by immunofluorescence the fate of such cosmid targets during denaturation and hybridization. The same cosmid DNA labeled with digoxigenin by nick-translation was used to analyze the FISH probe signal distribution in a different color. The probe signals proved to be a subset of the target signals remaining after denaturation and hybridization. We argue that the discontinuity of probe signals in Fiber-FISH is mainly caused by loss of target DNA and limited accessibility due to in situ renaturation and attachment. Furthermore, we conclude that FISH sensitivity is determined by hybridization efficiency and not the ability to generate sufficient signal from small probes. (J Histochem Cytochem 48:743-745, 2000)

Bone disorders in the dog: a review of modern genetic strategies to find the underlying causes

In man, the genetic defects of more than 600 inherited diseases, of which at least 150 skeletal diseases, have been identified as is the chromosomal location for approximately 7000 genes. This rapid progress has been made possible by the generation of a genetical and physical map of the human genome. There is no reason to believe that for the dog not a similar development may occur. This review is therefore focussed on the use of novel tools now available for comparative molecular genetic studies of skeletal dysplasias in the dog. Because the genomes of mammals at the subchromosomal level are very well conserved, likely candidate disease genes known from other species might be considered. In this review, formation of the bones and the most important canine disorders of the skeleton influencing locomotion will be discussed first. The canine disorders discussed are canine hip dysplasia, the three different forms of elbow dysplasia (fragmented coronoid process, ununited anconeal process, osteochondrosis dissecans and incongruency) and dwarfism. Where possible a link is made with similar diseases in man or mouse. Then, the molecular biological tools available to analyse the genetic defect will be reviewed and some examples discussed.

Imaging of single DNA molecule: applications to high-resolution genomic studies

Single molecule analysis of DNA has revealed new insights into its structural and physical properties. The application of new methods for manipulating and visualizing DNA has resulted in important advances in high-resolution physical mapping of the genome and quantitative cytogenetic studies of genomic abnormalities (Lichter 1997). Studies of single molecules of DNA have employed a variety of approaches including electron microscopy, atomic force microscopy, scanning-tunneling microscopy and fluorescence microscopy. A number of new technologies have recently been developed to exploit fluorescence microscopy's full potential for genomic analysis and the fine mapping of subtle genetic alterations. In the case of the latter application, particular emphasis has been placed on developing new methods for stretching DNA for high-resolution fluorescence in-situ hybridization studies. We have recently described a process called molecular combing according to which single DNA molecules bound by their extremities to a solid surface are uniformly stretched and aligned by a receding air/water interface (Bensimon et al. 1994). In the following, we will review recent developments concerning molecular combing and discuss its current and potential applications for the high-resolution mapping of the human genome, the detection and quantification of subtle genomic imbalances and the positional cloning of disease-related genes.

High resolution FISH in plants - techniques and applications

Fluorescence in situ hybridization (FISH) is an effective and accurate cytogenetic tool for mapping single copy and repetitive DNA sequences on chromosomes. Attempts to increase the detection sensitivity of very small chromosomal targets, and to improve the spatial resolution of signals derived from flanking sequences, have led to the development of a variety of novel techniques: it is now possible to perform in situ hybridizations on interphase nuclei, meiotic pachytene chromosomes and isolated chromatin (DNA fibres). The recent application of these techniques has indicated that a spatial resolution of 1 kb between adjacent targets and a sensitivity of targets smaller than 1 kb is now feasible. Here, we describe the benefits of these novel chromosome analysis techniques and discuss their relevance for the study of plant genomes.

Fiber-FISH analysis of the 3'-terminal region of the human L-type Ca2+ channel alpha 1C subunit gene

Human L-type Ca2+ channel alpha 1C subunit gene (CACNL1A1) maps to the distal region of chromosome 12p13, and is composed of approximately 50 exons spanning over 150 kb of the human genome as estimated by restriction map analysis. However, the structure and the total length of the 3'-end of the gene is not clear because the size of several big introns remains unknown. Here the fiber-FISH technique was used to determine the relative order and size of eight partial genomic DNA clones from the central and 3'-terminal regions of CACNL1A1. The total physical distance of this region, including the size and gap distances between the clones were re-estimated. The results show that the physical order of the tested clones was 5'-g14-5 > g12-2 > g10-8 > g4-5 > g16-7 > g8-3 > g12-5 > g6-20-3'. Their individual sizes vary between 6.7 and 21.9 kb. Clones g6-20 and g12-5, both containing repetitive exon 45/46-like element, were found to be located within 59.1 kb downstream of g8-3 containing earlier identified polyadenylation site, i.e. 229.5 kb away from clone g14-5 (exons 10, 11). The possible implications of this structural complexity is discussed.

Mapping ESTs by Fiber–FISH

A visual transcript map of six genes was constructed on the chromosome 21q22.3 by high resolution fluorescence in situ hybridization (FISH). Expressed sequence tags (ESTs) from six genes—PWP2, KNP1, AIRE, C21orf3,SMT3A, and C21orf1—were successfully localized by fiber–FISH by use of sensitive tyramide-based detection. The sizes of the ESTs varied between 315 to 956 bp and most of them map within the 3′-untranslated region. The ESTs were assigned to and subsequently ordered within cosmid, PAC, and BAC clones hybridized on DNA fibers. Physical distances between ESTs and known markers were determined. Our results demonstrate the feasibility and accuracy of visual mapping EST sequences in relation to known markers. The main advantage of this approach is that it can be applied to finely map any of the database ESTs for positional cloning efforts. The sensitivity, specificity, and reproducibility of this high-resolution EST mapping technique is evaluated.

Advances in fluorescence in situ hybridization

The techniques of in situ hybridization (ISH) are widely applied for analyzing the genetic make-up and RNA expression patterns of individual cells. This review focusses on a number of advances made over the last 5 years in the fluorescence ISH (FISH) field, i.e., Fiber-FISH, Multi-colour chromosome painting, Comparative Genomic Hybridization, Tyramide Signal Amplification and FISH with Polypeptide Nucleic Acid and Padlock probes.

Advances in fluorescent in situ hybridisation

Recent advances in fluorescent in situ hybridisation included the generation of allele-specific probes, bar-coded chromosomes, and the visualisation of chromosome territories and genes within the nucleus. One major advance has been our ability to visualise and make precise and reproducible measurements from stretched DNA molecules prepared directly from human cells.