Mapping and chromosome analysis: the potential of fluorescence in situ hybridization

Determination of the ruminant origin of bone particles using fluorescence in situ hybridization (FISH)

Molecular biology techniques such as PCR constitute powerful tools for the determination of the taxonomic origin of bones. DNA degradation and contamination by exogenous DNA, however, jeopardise bone identification. Despite the vast array of techniques used to decontaminate bone fragments, the isolation and determination of bone DNA content are still problematic. Within the framework of the eradication of transmissible spongiform encephalopathies (including BSE, commonly known as "mad cow disease"), a fluorescence in situ hybridization (FISH) protocol was developed. Results from the described study showed that this method can be applied directly to bones without a demineralisation step and that it allows the identification of bovine and ruminant bones even after severe processing. The results also showed that the method is independent of exogenous contamination and that it is therefore entirely appropriate for this application.

Fluorescence in situ hybridization and optical mapping to correct scaffold arrangement in the tomato genome

The order and orientation (arrangement) of all 91 sequenced scaffolds in the 12 pseudomolecules of the recently published tomato (Solanum lycopersicum, 2n = 2x = 24) genome sequence were positioned based on marker order in a high-density linkage map. Here, we report the arrangement of these scaffolds determined by two independent physical methods, bacterial artificial chromosome–fluorescence in situ hybridization (BAC-FISH) and optical mapping. By localizing BACs at the ends of scaffolds to spreads of tomato synaptonemal complexes (pachytene chromosomes), we showed that 45 scaffolds, representing one-third of the tomato genome, were arranged differently than predicted by the linkage map. These scaffolds occur mostly in pericentric heterochromatin where 77% of the tomato genome is located and where linkage mapping is less accurate due to reduced crossing over. Although useful for only part of the genome, optical mapping results were in complete agreement with scaffold arrangement by FISH but often disagreed with scaffold arrangement based on the linkage map. The scaffold arrangement based on FISH and optical mapping changes the positions of hundreds of markers in the linkage map, especially in heterochromatin. These results suggest that similar errors exist in pseudomolecules from other large genomes that have been assembled using only linkage maps to predict scaffold arrangement, and these errors can be corrected using FISH and/or optical mapping. Of note, BAC-FISH also permits estimates of the sizes of gaps between scaffolds, and unanchored BACs are often visualized by FISH in gaps between scaffolds and thus represent starting points for filling these gaps.

Developments in Using Scanning Probe Microscopy To Study Molecules on Surfaces — From Thin Films and Single-Molecule Conductivity to Drug–Living Cell Interactions

Scanning probe microscopy (SPM) techniques, including atomic force microscopy (AFM) and scanning tunnelling microscopy (STM), have revolutionized our understanding of molecule–surface interactions. The high resolution and versatility of SPM techniques have helped elucidate the morphology of adsorbed surfactant layers, facilitated the study of electronically conductive single molecules and biomolecules connected to metal substrates, and allowed direct observation of real-time processes such as in situ DNA hybridization and drug–cell interactions. These examples illustrate the power that SPM possesses to study (bio)molecules on surfaces and will be discussed in depth in this review.

Preparation of Samples for Comparative Studies of Arthropod Chromosomes: Visualization, In Situ Hybridization, and Genome Size Estimation

The ability to obtain large amounts of genomic sequence for organisms and high throughput technology has led to a change in the thrust of research at the level of chromosomes in animals. In the past chromosomal analysis of animals was focused on gross changes such as inversions, translocations, and deletions for both genetic and evolutionary studies. The advent of in situ hybridization technology and the ability to measure genome content size changed both the precision and the scale of studies addressing chromosomal change as a tool in evolutionary biology. This chapter addresses two of the major areas of change that have occurred in chromosomal studies in the past decade -- examination of more refined and genome enabled structural changes in chromosomes and genome size measure. This chapter describes some of the chromosome structure approaches such as fluorescent in situ hybridization (FISH), comparative genomic hybridization (CGH) and other techniques. As well, advances in Genome size measurement and theory are described herein.

Integrated and sequence-ordered BAC- and YAC-based physical maps for the rat genome

As part of the effort to sequence the genome of Rattus norvegicus, we constructed a physical map comprised of fingerprinted bacterial artificial chromosome (BAC) clones from the CHORI-230 BAC library. These BAC clones provide approximately 13-fold redundant coverage of the genome and have been assembled into 376 fingerprint contigs. A yeast artificial chromosome (YAC) map was also constructed and aligned with the BAC map via fingerprinted BAC and P1 artificial chromosome clones (PACs) sharing interspersed repetitive sequence markers with the YAC-based physical map. We have annotated 95% of the fingerprint map clones in contigs with coordinates on the version 3.1 rat genome sequence assembly, using BAC-end sequences and in silico mapping methods. These coordinates have allowed anchoring 358 of the 376 fingerprint map contigs onto the sequence assembly. Of these, 324 contigs are anchored to rat genome sequences localized to chromosomes, and 34 contigs are anchored to unlocalized portions of the rat sequence assembly. The remaining 18 contigs, containing 54 clones, still require placement. The fingerprint map is a high-resolution integrative data resource that provides genome-ordered associations among BAC, YAC, and PAC clones and the assembled sequence of the rat genome.

FISH to mitotic chromosomes and extended DNA fibres of Beta procumbens in a series of monosomic additions to beet (B. vulgaris)

The physical localization and organization of a Procumbentes-specific repetitive DNA sequence, PB6-4, on the chromosomes of Beta procumbens (2n = 18) were studied, using FISH (fluorescence in situ hybridization) to mitotic chromosomes and extended DNA fibres. The chromosomes of B. procumbens were studied in metaphase complements of the species itself, as well as in preparations of a series of eight different B. procumbens-derived monosomic additions to B. vulgaris (2n = 18). FISH to chromosome spreads of B. procumbens revealed that PB6-4 hybridizes to all chromosomes, predominantly in the pericentromeric regions, but with differences in size and brightness of the signals. Hybridization of PB6-4 to metaphase complements of B. vulgaris revealed no signals, indicating that cross-hybridization with the genome of this species was negligible. Consequently, hybridization of PB6-4 to metaphase complements of the monosomic additions yielded fluorescent signals on the alien chromosomes only. The previously observed differences in size and brightness of the fluorescent spots were confirmed using the single alien chromosomes. FISH of PB6-4 to extended DNA fibres of the monosomic additions indicated differences in the fluorescent track lengths between the alien chromosomes. Measurements of the fluorescent tracts allowed classification into discrete groups, varying from one to three groups per B. procumbens chromosome. The data revealed that the brightness or size of the signal at mitotic metaphase and the length of the fluorescent tracks on the DNA fibres were correlated.

An efficient method for the physical mapping of transgenes in barley using in situ hybridization

The genetic transformation of crops by particle bombardment and Agrobacterium tumefaciens systems have the potential to complement conventional plant breeding programmes. However, before deployment, transgenic plants need to be characterized in detail, and physical mapping is an integral part of this process. Therefore, it is important to have a highly efficient method for transgene detection by fluorescence in situ hybridization (FISH). This study describes a new approach, which provides efficient control of probe length and labelling, both of which play an important role in in situ hybridization of transgenes. The approach is based on reducing the size of the plasmid prior to labelling by nick translation, rather than using the whole or linearized plasmid, or varying the amounts of DNaseI in the nick translation mixture. This provided much more efficient labelling of the probe, which yielded optimal hybridization, minimal fluorescent background, and accurate physical location of the transgene.Key words: barley, transformation, FISH, transgene detection, probe design.

Biomass quantification by image analysis

Microbiologists have always rely on microscopy to examine microorganisms. When microscopy, either optical or electron-based, is coupled to quantitative image analysis, the spectrum of potential applications is widened: counting, sizing, shape characterization, physiology assessment, analysis of visual texture, motility studies are now easily available for obtaining information on biomass. In this chapter the main tools used for cell visualization as well as the basic steps of image treatment are presented. General shape descriptors can be used to characterize the cell morphology, but special descriptors have been defined for filamentous microorganisms. Physiology assessment is often based on the use of fluorescent dyes. The quantitative analysis of visual texture is still limited in bioengineering but the characterization of the surface of microbial colonies may open new prospects, especially for cultures on solid substrates. In many occasions, the number of parameters extracted from images is so large that data-mining tools, such as Principal Components Analysis, are useful for summarizing the key pieces of information.

Optimization and automation of fluorescence-based DNA hybridization for high-throughput clone mapping

Large-scale hybridization-based genome mapping projects, such as the production of sequence-ready physical clone maps, call for robust and cheap DNA labeling techniques that are amenable to automation. We routinely use a high-throughput protocol based on fluorescence detection. DNA probes are labeled via polymerase chain reaction (PCR) amplification with primers that are digoxigenin-modified at their 5' ends. Alternatively, digoxigenin-labeled dUTP is incorporated in a random hexamer priming reaction. Hybridization takes place in small volumes by sandwiching the probe between filters and plastic sheets. A fluorescence signal is produced by the activity of alkaline phosphatase attached to an anti-digoxigenin antibody upon the addition of AttoPhos substrate. Signals are directly detected with a charge-coupled device (CCD) camera and scored by an image data analysis system. DNA filters can be reused at least 40 times without loss of data quality. Significant advantages compared to radioactive techniques are the reduced health risk, enabling highly parallel processing; the production of spot signals uniform in size and intensity, which is essential for efficient image analysis; and a cost reduction of about 70%.

Nonradioactive In Situ Hybridization: Recent Techniques and Applications

In situ hybridization (ISH) has become a standard method for the localization of nucleic acid sequences in chromosomes, single cells, and tissue sections. Nonradioactive ISH has not only eliminated the problems associated with radioactive probes but has also achieved a higher degree of resolution. Advances in probe preparation and labeling methods have facilitated the general application of ISH. In combination with immunohistochemistry, ISH can provide histological information on gene activity at the DNA, mRNA, and protein levels. Some nonradioactive ISH can simultaneously detect nucleic acid sequences in the same tissue or in a chromosome spread. Advances in ISH technology, including use of the polymerase chain reaction offer both a high sensitivity allowing detection of low levels of gene expression and the cytological localization of gene sequences.

Molecular pathology in the diagnosis of hematologic neoplasia. Review article

Over the past decade molecular genetic methods have played an increasingly important role in the diagnosis of hematologic malignancies. Moreover, they have provided a tool to analyze many of the non-random cytogenetic anomalies associated with hematologic neoplasias, contributing considerably to our understanding of several of those diseases, and to improving diagnostic accuracy. The rapid development of molecular genetics progressively allows the replacement of time-consuming and technically demanding procedures. Even more relevant are the new clinical applications that already include the search for valuable prognostic information and ways of evaluating minimal residual disease or recognizing early relapsing disease. This paper is a critical but necessarily simplified overview of the main contributions of molecular genetics to the field of hematopathology. We discuss the information provided by several molecular methods within different clinical contexts, covering common problems in diagnostic pathology as well as prognostic evaluation and therapy monitoring.

Mapping elasticity of rehydrated metaphase chromosomes by scanning force microscopy

Scanning force microscopy was used for mapping the viscoelastic properties of metaphase chromosomes. These properties were probed by scanning with various imaging forces and subsequent calculation of the difference image. The procedure allows a mapping of the viscoelastic behavior expressed as force-dependent indentation of the local surface feature and results in an image with material contrast. The approach is demonstrated on rehydrated metaphase chromosomes, which were spread and air-dried before rehydration in aqueous buffer. The rehydration resulted in a swelling of the chromosome structure and was accompanied by drastic changes in the viscoelastic properties. For comparisons, force-distance curves on metaphase chromosomes were accumulated; these curves were also used for the calculation of the stiffness curve. The demonstrated approach of mapping viscoelasticity by differential scanning force microscopy allows the detection of domains with varying mechanical properties in biomolecules such as chromosomes.

Sensitive multicolor fluorescence in situ hybridization using catalyzed reporter deposition (CARD) amplification

We describe the simultaneous localization of DNA sequences in cell and chromosome preparations by means of differently fluorochrome-labeled (AMCA, FITC, TRITC) tyramides using the catalyzed reporter deposition (CARD) procedure. For this purpose, repeated as well as single-copy DNA probes were labeled with biotin, digoxigenin, and FITC, hybridized, and visualized with three different cytochemical detection systems based on horseradish peroxidase conjugates. These were sequentially applied to interphase nuclei and metaphase chromosomes at low concentrations to prevent crossreaction and nonspecific background. In situ localized peroxidase activity was visualized by the deposition of fluorochrome-labeled tyramide molecules. To allow specific deposition of a second and a third tyramide conjugate for multiple-target fluorescence in situ hybridization (FISH), remaining peroxidase activity was always completely inactivated by a mild acid treatment before application of the next peroxidase conjugate. The CARD reactions were optimized for maximal signal-to-noise ratio and discrete localization by tuning reaction time, H2O2, and tyramide concentrations. For both repeated and single-copy DNA targets, high FISH signal intensities were obtained, providing improvement of sensitivity over conventional indirect detection systems. In addition, the fluorescence CARD detection system proved to be highly efficient and easy to implement in multiple-labeling studies, such as reported here for FISH.

On the role of DNA double-strand breaks in toxicity and carcinogenesis

DNA double-strand breaks are associated with various endogenous processes, such as transcription, recombination, replication, and with the process of active cell death, which aims to eliminate cells. In addition, DNA double-strand breaks can be induced by irradiation, exposure to chemicals, increased formation of reactive oxygen species, and, indirectly, during repair of other types of DNA damage or as a consequence of extranuclear lesions. In addition to the neutral filter elution of DNA, the recently introduced pulsed-field gel electrophoresis is capable of determining DNA double-strand breaks with higher accuracy and sensitivity and is expected to increase our knowledge on the frequency and the role of DNA breakage. Parallel determination of parameters for cytotoxicity is necessary to elucidate the causal primary lesion. Although the repair of DNA double-strand breaks is a complex task, cells are capable of repairing--with or without errors and up to a certain extent--and surviving this DNA lesion. Gene translocations, rearrangements, amplifications, and deletions arising during repair and misrepair of double-strand breaks may contribute to cell transformation and tumor development.

Comparison of immunologic amplification vs enzymatic deposition of fluorochrome-conjugated tyramide as detection systems for FISH

Using various sizes and dilutions of hapten-conjugated DNA probes, we compared catalyzed reporter deposition (CARD) to fluorochrome-conjugated antibody layering (immunological method) for amplifying FISH signals. Cosmid and phage probes that contained human DNA inserts of 40 KB and 15 KB, respectively, and were mapped to chromosome 15q11.2 were used to evaluate these amplification methods. The probes were used either at standard concentrations (10 ng/microliter) or at dilutions up to 1:40 (0.25 ng/microliter). Detection of FISH signals using either immunological (three antibody layers) or CARD methods were comparable when the undiluted (10 ng/microliter) or 1:4 dilution (2.5 ng/microliter) of the cosmid probe was used. Use of a single fluorochrome-conjugated antibody layer produced very weak FISH signals. However, addition of an unlabeled secondary antibody followed by a third antibody conjugated to the same fluorochrome (i.e., two rounds of amplification) produced a strong signal that was detected at a 1:4 probe dilution but was not successfully detected at probe dilutions of 1:10 or greater. In contrast, intense probe signals were produced with the CARD method at all probe dilutions, particularly when coupled to extended hapten-antibody incubation times. The 15-KB phage probe was difficult to detect at a 1:4 dilution with the standard immunologic amplification methods but was readily detected with the CARD method. These data suggest that CARD may be useful for FISH in that (a) less probe may be needed and therefore valuable probe reagents may be conserved, and (b) smaller targets may be detected, thus extending the range of this technique.

Use of meiotic FISH for identification of a new monosome in Gossypium hirsutum L

The extensive use of molecular cytogenetics in human genetics and clinical diagnostics indicates that analogous applications in plants are highly feasible. One sort of application would be the identification of new aneuploids, which traditionally involves either direct karyotypic identification, which is feasible in only a few plant species, or tests with markers (cytogenetic, genetic, or molecular), which require sexual hybridization and at least one subsequent seed or plant generation. We have used meiotic fluorescence in situ hybridization (FISH) to analyze a new monosome of cotton (Gossypium hirsutum L., 2n = 4x = 52, 2(AD)1) that had a phenotype which seemed to be distinct from monosomes in the Cotton Cytogenetic Collection. Painting with A2-genome DNA revealed the monosome's D-subgenome origin. DAPI-PI staining showed that the monosome carries a major NOR, delimiting it to the major NOR-bearing chromosomes of the D-subgenome, i.e., 16 or 23. Dual-color FISH with 5S and 18S-28S rDNAs indicated that the monosome contains separate major clusters of each of these two tandemly repeated rDNA elements, thus delimiting the monosome to chromosome 23, for which the Cotton Cytogenetic Collection has previously been devoid of any sort of deficiency. Of the 26 chromosomes in the cotton genome, the Collection now provides coverage for 16 (70%) in the form of monosomy, and 20 (77%) in the form of monosomy and (or) telosomy. Use of molecular cytogenetic methods to identify a new plant aneuploid in cotton exemplifies the fact that a physicochemical karyotypic chromosome identification system is not required a priori for application of new molecular cytogenetic methods, thus indicating their potential applicability to nearly all plant species.

Utilization of FISH in positional cloning: an example on 13q22

In positional cloning the initial assignment of a gene to a specific chromosomal locus is followed by physical mapping of the critical region. The construction of a high-resolution physical map still involves considerable effort. However, new high-resolution fluorescence in situ hybridization (FISH) techniques have facilitated this process substantially. Here we summarize a strategy that combines a spectrum of FISH techniques [metaphase, interphase, mechanically stretched chromosomes (MSCs), and fiber-FISH on free chromatin] for the construction and characterization of a high-resolution physical map for a positional cloning project. The chromosomal region 13q22, containing the locus of the variant form of the neuronal ceroid lipofuscinosis (vLINCL, CLN5) disease, serves here as an example for this process. We used metaphase FISH to exclude positionally a candidate gene, to refine the locus to 13q22, and to analyze the possible chimerism of the YACs in the region. Both metaphase and interphase FISH techniques were applied to determine the low-resolution distances between the restricting markers. FISH using MSCs confirmed the centromeric-telomeric order of the clones and facilitated the estimation of the size of the gaps between the clones. Finally, fiber-FISH was found to be the method of choice for the construction of an accurate high-resolution map of the contig established over the restricted region. Thus, FISH techniques in combination with genetic mapping data enabled the refinement of the initial 4-cM region to a high-resolution map of only 400 kb in length. Here the FISH strategy replaced the need for many laborious traditional physical mapping methods, e.g., pulsed-field gel electrophoresis.

Applications of image analysis in cell technology

Image analysis is now a well established complement to optical microscopy, allowing routine quantification of microscopic observations. Recent method developments include location and enumeration of bacteria in solid foods, in situ microscopy and image analysis for on-line monitoring of yeast fermentations, and texture analysis of fungal colonies for subsequent transfer. Notable recent applications include studies on the pulsatile growth of hyphal apices, biochemical differentiation of fungal colonies, and simple structural differentiation of mycelia from submerged fungal cultures.

Preparation of tomato meiotic pachytene and mitotic metaphase chromosomes suitable for fluorescence in situ hybridization (FISH)

Fluorescence in situ hybridization (FISH) is an increasingly powerful tool with a variety of applications in both basic and applied research. With excellent genetic, cytogenetic and molecular maps available, the tomato genome provides a good model to benefit from the full potential of FISH. Tomato chromosomes at mitotic metaphase are small and not particularly suitable for high-resolution FISH. In contrast, chromosomes at meiotic pachytene are about 15 times longer, and easier to identify by their differences in chromosome arm lengths and chromomere pattern. We have developed a technique for preparing chromosomal spreads of young pollen mother cells at mid-prophase I which is suitable for FISH. In a first series of experiments, the hybridization patterns of three classes of repetitive DNA sequences were studied in single and multicolour FISH.

Near-IR dyes in three-color volumetric capillary cytometry: cell analysis with 633- and 785-nm laser excitation

Several fluorescent dyes that absorb in the near-infrared are described. The photostability and aggregation properties of the dyes were examined. Two of the dyes, BHMP and BHDMAP, emit at 805 nm and were useful dyes for protein labeling. A dual-laser, three-color scanning instrument was constructed. CD3+CD4+ and CD3+CD8+ populations were enumerated in undiluted, whole blood based on the fluorescence of Cy5, Cy5.5 and BHMP.