Identification of flow-sorted chromosomes by G-banding and in situ hybridization

The identification of flow-sorted chromosomes is a very important tool for checking the purity of the fractions obtained. An easy and reproducible method for obtaining G-banded chromosomes with good resolution of bands is described. Also, we are able to show that the percentage of chromosomes which can be clearly distinguished by this procedure depends to a large extent on the duration of mitotic arrest. In particular when sorting chromosomes from human-rodent hybrid cell lines, the possibility of using in situ hybridization in addition to conventional staining techniques to characterize the chromosomes can help overcome the problem of highly condensed chromosomes and chromosomal fragments of unknown origin, which cannot be identified otherwise. Thus, we have developed an in situ hybridization technique, based on biotin-labelled human genomic DNA, which allows a clear distinction between human and rodent chromosomal material to be made.     

Identification of the rice D-genome chromosomes by genomic in situ hybridisation

 The 24 rice D-genome chromosomes were identified among the 48 chromosomes of O. latifolia, which comprise the C- and D-genomes, using genomic in situ hybridisation (GISH). The B-genome chromosomes were also discriminated from the C-genome chromosomes in O. minuta (BBCC) by GISH. A comparison of the differences in the fluorescence intensity between the C and D genomes within O. latifolia (CCDD), and between the B and C genomes within O. minuta, indicated that the overall nucleotide-sequence homology between the B and C genomes is less than that between the C and D genomes. The origin of the D genome and the phylogenetic relationship of the D genome among the rice genomes are discussed, based on the results obtained. Received: 5 June 1997 / Accepted: 19 June 1997     

C-banding and fluorescence in situ hybridization studies of the wheat-alien hybrid 'Agrotana'.

'Agrotana', a wheat-alien hybrid (2n = 56), is a potential source of resistance to common root rot, stem rust, wheat streak mosaic virus, and the wheat curl mite. However, the origin of 'Agrotana', reported to be durum wheat x Agropyron trichophorum (pubescent wheatgrass), is uncertain. The objective of this investigation was to determine the chromosome constitution of 'Agrotana' using C-banding and fluorescence in situ hybridization techniques. The F1 hybrid of 'Agrotana' x 'Chinese Spring' wheat showed 7 I + 21 II in 14.9% of the pollen mother cells, evidence of the presence of the A, B, and D genomes in 'Agrotana'. The hybrid had 16 heavily C-banded chromosomes, namely 4A, and 1-7B of wheat, and a translocation that probably involved wheat chromosomes 2A and 2D. In situ hybridization using biotinylated genomic DNA of Ag. trichophorum cv. Greenleaf blocked with CS DNA failed to identify the alien chromosomes in 'Agrotana', indicating that the alien chromosomes were not likely derived from pubescent wheatgrass. In situ hybridization using labelled wheat genomic DNA blocked with 'Agrotana' DNA revealed that 'Agrotana' had 40 wheat, 14 alien, and 2 (a pair) wheat-alien translocated chromosomes. There was no homology between wheat and the alien chromosomes or chromosome segments involved in the wheat-alien recombinant. Two of the seven pairs of alien chromosomes were homoeologous to each other. The ability to identify alien chromatin in wheat using labelled wheat DNA instead of labelled alien DNA will be particularly useful in chromosome engineering of wheat germplasms having alien chromatin of unknown origin.     

Identification of Haynaldia villosa chromosomes added to wheat using a sequential C-banding and genomic in situ hybridization technique

Genomic in situ hybridization (GISH) offers a convenient and effective method for cytological detection, but can not determine the identity of the chromosomes involved. We integrated C-banding with GISH to identify Haynaldia villosa chromosomes in a wheat background. All chromosomes of H. villosa showed C-bands, either in telomeric regions or in both telomeric and centromeric regions, which allowed unequivocal identification of each H. villosa chromosome. The seven pairs of H. villosa chromosomes were differentiated as 1–7 according to their characteristic C-bands. Using a sequential C-banding and GISH technique, we have analyzed somatic cells of F₃ plants from the amphiploid Triticum aestivum-H. villosa x Yangmai 158 hybrids. Three plants (94009/5-4,94009/5-8 and 94009/5-9) were shown to contain H. villosa chromosome(s). 94009/5-4 (2n = 45) had three H. villosa chromosomes (2, 3 and 4); 94009/5-8 (2n = 45) possessed one chromosome 4 and a pair of chromosome 5, and 94009/5-9 (2n = 43) was found to have one chromosome 6 of H. villosa. The combination of GISH with C-banding described here provides a direct comparison of the cytological and molecular landmarks. Such a technique is particularly useful for identifying and localizing alien chromatin and DNA sequences in plants.     

Primer-induced in situ hybridization to plant chromosomes.

Primer-induced in situ hybridization of high copy sequences was used successfully on rye mitotic chromosome spreads. Nucleolus organizer sequences were detected in rye, and the pattern obtained was in full agreement with previously reported results by conventional in situ hybridization. The future potential of the primer-induced in situ hybridization technique is briefly discussed.     

Evidence for integrity of parental genomes in the diploid hybridogenetic water frog Pelophylax esculentus by genomic in situ hybridization

The Western Palearctic water frogs Pelophylax ridibundus and P. lessonae were identified as parental (sexual) species and P. esculentus as their interspecific, hybridogenetically reproducing hybrid with hemiclonal heredity. We used genomic in situ hybridization (GISH) to identify parental chromosomes of P.lessonae and P.ridibundus in diploid P. esculentus karyotypes (2n = 26). GISH probes were made by fluorochrome labeling of total genomic DNA extracted from the sexual progenitors. The labeled probe from one species was hybridized to chromosomes of P. esculentus in the presence of excess of unlabeled genomic DNA from the other species. Thus, the P. lessonae probe was blocked by P. ridibundus unlabeled DNA, and vice versa. We successfully discriminated each of the 13 respective parental chromosomes in metaphase complements of the hybrids according to species-specific hybridization signals. GISH enabled us to confirm additional differences between parental chromosomes in size (smaller chromosomes belong to P. lessonae) and in the presence of DAPI-positive centromeric heterochromatin (detected in chromosomes of P. ridibundus, but not in P. lessonae). The fact that no visible intergenomic exchanges were found in metaphase chromosomes of diploid P. esculentus provides important information on the genomic integrity of hemiclonal transmission and supports hybridogenesis as a reproductive mode at the chromosome level for the specimens examined.     

DNA, chromosomes, and in situ hybridization.

In situ hybridization is a powerful and unique technique that correlates molecular information of a DNA sequence with its physical location along chromosomes and genomes. It thus provides valuable information about physical map position of sequences and often is the only means to determine abundance and distribution of repetitive sequences making up the majority of most genomes. Repeated DNA sequences, composed of units of a few to a thousand base pairs in size, occur in blocks (tandem or satellite repeats) or are dispersed (including transposable elements) throughout the genome. They are often the most variable components of a genome, often being species and, occasionally, chromosome specific. Their variability arises through amplification, diversification and dispersion, as well as homogenization and loss; there is a remarkable correlation of molecular sequence features with chromosomal organization including the length of repeat units, their higher order structures, chromosomal locations, and dispersion mechanisms. Our understanding of the structure, function, organization, and evolution of genomes and their evolving repetitive components enabled many new cytogenetic applications to both medicine and agriculture, particularly in diagnosis and plant breeding.     

Analysis of genes and chromosomes by nonisotopic in situ hybridization

Nonisotopic in situ hybridization is a powerful tool to analyze the organization of complex genomes. Current approaches utilizing this technique for the analysis of linear and spatial genome organizations are presented. Clinical applications of these approaches, which open new avenues for diagnosis of disease-related chromosomal changes, are also discussed.     

Molecular differentiation of sex chromosomes probed by comparative genomic hybridization

Comparative genomic hybridization (CGH) was used to identify and probe sex chromosomes in several XY and WZ systems. Chromosomes were hybridized simultaneously with FluorX-labelled DNA of females and Cy3-labelled DNA of males in the presence of an excess of Cot-1 DNA or unlabelled DNA of the homogametic sex. CGH visualized the molecular differentiation of the X and Y in the house mouse, Mus musculus, and in Drosophila melanogaster: while autosomes were stained equally by both probes, the X and Y chromosomes were stained preferentially by the female-derived or the male-derived probe, respectively. There was no differential staining of the X and Y chromosomes in the fly Megaselia scalaris, indicating an early stage of sex chromosome differentiation in this species. In the human and the house mouse, labelled DNA of males in the presence of unlabelled DNA of females was sufficient to highlight Y chromosomes in mitosis and interphase. In WZ sex chromosome systems, the silkworm Bombyx mori, the flour moth Ephestia kuehniella, and the wax moth Galleria mellonella, the W chromosomes were identified by CGH in mitosis and meiosis. They were conspicuously stained by both female- and male-derived probes, unlike the Z chromosomes, which were preferentially stained by the male-derived probe in E. kuehniella only but were otherwise inconspicuous. The ratio of female:male staining and the pattern of staining along the W chromosomes was species specific. CGH shows that W chromosomes in these species are molecularly well differentiated from the Z chromosomes. The conspicuous binding of the male-derived probe to the W chromosomes is presumably due to an accumulation of common interspersed repetitive sequences. Received: 6 January 1999; in revised form: 28 January 1999 / Accepted: 11 February 1999     

Gene mapping on maize pachytene chromosomes by in situ hybridization

A sensitive in situ hybridization technique which was effective for mapping genes of low copy number on human metaphase chromosomes was used for gene mapping on maize pachytene chromosomes. A cloned genomic EcoR1 fragment of 10.8 kb, containing most or all of the sequence encoding the Waxy locus mRNA, was used as the probe. Southern DNA blotting analyses performed by Shure et al. (1983) indicated that the Waxy locus was a single copy sequence. In our in situ hybridization experiment, the probe hybridized to a specific site on chromosome 9. Labeling at this site was detected in 48.6% of 154 randomly selected copies of chromosome 9. To test the sensitivity of the method, subclones of the fragment with insert sizes of 6.6, 4.7, 3.5, 2.3, 1.9 and 0.8 kb were used for in situ hybridizations. Labeling efficiency for each probe was determined. The data showed that a single copy probe of 1.9 kb could be detected at the correct position in 18% of 183 randomly selected number 9 chromosomes.     

Fluorescent in situ hybridization to ascidian chromosomes

The draft genome of the ascidian Ciona intestinalis has been sequenced. Mapping of the genome sequence to the Ciona 14 haploid chromosomes is essential for future studies of the genome-wide control of gene expression in this basal chordate. Here we describe an efficient protocol for fluorescent in situ hybridization for mapping genes to the Ciona chromosomes. We demonstrate how the locations of two BAC clones can be mapped relative to each other. We also show that this method is efficient for coupling two so-far independent scaffolds into one longer scaffold when two BAC clones represent sequences located at either end of the two scaffolds.     

Digital mapping of bacterial artificial chromosomes by fluorescence in situ hybridization

The bacterial artificial chromosome (BAC) has become the most popular tool for cloning large DNA fragments. The inserts of most BAC clones average 100-200 kilobases (kb) and molecular characterization of such large DNA fragments is a major challenge. Here we report a simple and expedient technique for physical mapping of BAC inserts. Individual BAC molecules were immobilized on glass slides coated with Poly-L-lysine. The intact circular BAC molecules were visualized by fluorescence in situ hybridization using BAC DNA as a probe. The 7.4 kb BAC vector was extended to approximately 2.44 kb per micrometer. Digitally measured linear distances can be transformed into kilobases of DNA using the extension of BAC vector as a standard calibration. We mapped DNA fragments as small as 2 kb directly on circular BAC molecules. A rice BAC clone containing both tandem and dispersed repeats was analyzed using this technique. The distribution and organization of the different repeats within the BAC insert were efficiently determined. The results showed that this technique will be especially valuable for characterizing BAC clones that contain complex repetitive DNA sequences.     

Chromosomal in situ hybridization using yeast artificial chromosomes

Large DNA fragment cloning methods using yeast artificial chromosomes (YACs) have vastly improved the strategies for constructing physical maps of regions of complex genomes, as well as for isolating and cloning genes important for human disease. We present here a simple and rapid method for carrying out in situ hybridization to metaphase chromosomes using isolated YAC clones by labeling DNA directly in agarose gel slices. Nonisotopic labeling and chromosomal in situ hybridization can be used to determine the chromosomal localization of individual YAC clones on human metaphase chromosomes. This method can also be used to characterize YAC clones consisting of single fragments from those that contain concatamerized, and thus artifactual, inserts. This technique also offers a valuable tool to study consistent translocations in neoplastic diseases by identifying YACs that span a specific chromosomal breakpoint.     

Identification of intergenomic recombinations in unisexual salamanders of the genus Ambystoma by genomic in situ hybridization (GISH)

Unisexual salamanders in the genus Ambystoma (Amphibia, Caudata) are endemic to eastern North America and are mostly all-female polyploids. Two to four of the bisexual species, A. laterale, A. jeffersonianum, A. texanum and A. tigrinum, contribute to the nuclear genome of unisexuals and more than 20 combinations that range from diploid to pentaploid have been identified in this complex. Because the karyotypes of the four bisexual species are similar, homologous and homoeologous chromosomes in the unisexuals can not be distinguished by conventional or banded karyotypes. We chose two widespread unisexual genomic combinations (A.laterale-2 jeffersonianum [or LJJ] and A. 2 laterale-jeffersonianum [or LLJ]) and employed genomic in situ hybridization (GISH) to identify the genomes in these unisexuals. Under optimum conditions, GISH reliably distinguishes the respective chromosomes attributed to both A.laterale and A. jeffersonianum. Of four populations examined, two were found to have independently evolved homoeologous recombinants that persist in both LJJ and LLJ individuals. Our results refute the previous hypothesis of clonal integrity and independent evolution of the genome combinations in these unisexuals. Our data provide evidence for intergenomic interactions between maternal chromosomes during meiosis in unisexuals and help to explain previously observed non-homologous bivalents and/or quadrivalents among lampbrush chromosomes that were possibly initiated by partial homosequential pairing among the homo(eo)logues. To explore the utility of GISH in other members of the complex, probes developed from A. laterale were also applied to unisexuals that contained A. tigrinum and A. texanum genomes. GISH is an effective tool that can be used to identify and to quantify genomic constituents and to investigate intergenomic interactions in unisexual salamanders. GISH also has potential application to examine possible genomic evolution in other unisexuals.     

Localizing DNA and RNA within nuclei and chromosomes by fluorescence in situ hybridization.

The enormous potential of in situ hybridization derives from the unique ability of this approach to directly couple cytological and molecular information. In recent years, there has been a surge of success in powerful new applications, resulting from methodologic advances that bring the practical capabilities of this technology closer to its theoretical potential. A major advance has been improvements that enable, with a high degree of reproducibility and efficiency, precise visualization of single sequences within individual metaphase and interphase cells. This has implications for gene mapping, the analysis of nuclear organization, clinical cytogenetics, virology, and studies of gene expression. This article discusses the current state of the art of fluorescence in situ hybridization, with emphasis on applications to human genetics, but including brief discussions on studies of nuclear DNA and RNA organization, and on applications to clinical genetics and virology. Although a review of all of the literature in this field is not possible here, many of the major contributions are summarized along with recent work from our laboratory.     

Localization of Agrobacterium rhizogenes T-DNA in plant chromosomes by in situ hybridization

We have used in situ hybridization to determine the sites of insertion of Agrobacterium rhizogenes Ri T-DNA in the chromosomes of Crepis capillaris (2n = 6) transformed roots. Four transformed root lines were obtained by infecting Crepis stem segments with A. rhizogenes. Southern hybridization analysis indicated that each root line was the result of one or more independent T-DNA insertion events. In two root lines, one copy of T-DNA was present; the other two root lines each contained two copies of T-DNA. To localize these T-DNA inserts on Crepis chromosomes, metaphase spreads were perpared from each root line, and hybridized in situ to a biotinlabeled T-DNA probe. The results indicated that T-DNA was present in a different chromosomal location in each root line, and that each chromosome had been a target for T-DNA insertion at least once. In the root lines containing two T-DNA inserts, two patterns of integration were observed: in one case the T-DNAs were present on separate chromosomes; in the other case the two T-DNAs were close together (but not tandemly arranged) on a single chromosome. A comparison of these results and those obtained previously for a fifth Crepis-transformed root line demostrated that Ri T-DNA does not insert preferentially into a particlar chromosomal location.     

Constitutive heterochromatin polymorphisms in human chromosomes identified by whole comparative genomic hybridization

Whole comparative genomic hybridization (W-CGH) is a new technique that reveals cryptic differences in highly repetitive DNA sequences, when different genomes are compared using metaphase or interphase chromosomes. W-CGH provides a quick approach to identify differential expansion of these DNA sequences at the single-chromosome level in the whole genome. In this study, we have determined the frequency of constitutive chromatin polymorphisms in the centromeric regions of human chromosomes using a whole-genome in situ cross-hybridization method to compare the whole genome of five different unrelated individuals. Results showed that the pericentromeric constitutive heterochromatin of chromosome 6 exhibited a high incidence of polymorphisms in repetitive DNA families located in pericentromeric regions. The constitutive heterochromatin of chromosomes 5 and 9 was also identified as highly polymorphic. Although further studies are necessary to corroborate and assess the overall incidence of these polymorphisms in human populations, the use of W-CGH could be pertinent and of clinical relevance to assess rapidly, from a chromosomal viewpoint, genome similarities and differences in closely related genomes such as those of relatives, or in more specific situations such as bone marrow transplantation where chimerism is produced in the recipient.     

Fluorescentin situ hybridization to soybean metaphase chromosomes

Repetitive DNA sequences were detected directly on somatic metaphase chromosome spreads from soybean root tips using fluorescentin situ hybridization. Methods to spread the forty small metaphase chromosomes substantially free of cellular material were developed using protoplasts. The specific DNA probe was a 1.05 kb internal fragment of a soybean gene encoding the 18S ribosomal RNA subunit. Two methods of incorporating biotin residues into the probe were compared and detection was accomplished with fluorescein-labeled avidin. The rDNA probe exhibits distinct yellow fluorescent signals on only two of the forty metaphase chromosomes that have been counterstained with propidium iodide. This result agrees with our previous analyses of soybean pachytene chromosome [27] showing that only chromosome 13 is closely associated with the nucleolus organizer region. Fluorescentin situ hybridization with the rDNA probe was detected on three of the forty-one metaphase chromosomes in plants that are trisomic for chromosome 13.