Induction of chromosome banding by trypsin/EDTA for gene mapping by in situ hybridization

We describe an easy and reproducible procedure that utilizes trypsin/EDTA for the induction of chromosome banding in conjunction with in situ hybridization. The high quality banding resolution required for grain localization is obtained on both elongated and contracted chromosomes derived from synchronized or nonsynchronized human lymphocytes or fibroblasts. This procedure can also be useful for gene localization on chromosomes from cancer cells.     

原位杂交技术在植物遗传育种上的应用

本文在简要介绍原位杂交技术的基础之上,重点介绍了该技术在植物遗传育种领域,即在(1)异源染色质及染色体畸变检测;(2)植物基因工程及基因表达研究;(3)构建植物基因物理图谱;(4)染色体RNA研究等方面的应用现状,并对原位杂交技术在提高检出率,与染色体显带技术结合,PCR-原位杂交等方面提了一些见解。     

原位杂交技术在植物遗传育种上的应用

本文在简要介绍原位杂交技术的基础之上 ,重点介绍了该技术在植物遗传育种领域 ,即在 (1 )异源染色质及染色体畸变检测 ;(2 )植物基因工程及基因表达研究 ;(3)构建植物基因物理图谱 ;(4)染色体RNA研究等方面的应用现状 ,并对原位杂交技术在提高检出率 ,与染色体显带技术结合 ,PCR 原位杂交等方面提了一些见解。     

Distribution of CT-rich tracts is conserved in vertebrate chromosomes

The distribution of d(CT)-rich pyrimidine tracts in the karyotypes of a variety of vertebrates was studied by in situ hybridization. The probe for these studies was a 56 bp homopyrimidine/homopurine sequence obtained from a mouse genomic library constructed with DNA prepared from a restriction enzyme digestion of metaphase chromosomes. Single-stranded DNA nuclease digestions and two-dimensional gel analysis of topoisomers of this sequence indicated that it is capable of adopting a triplex conformation in vitro. In situ hybridization with this probe to the karyotypes of ten different vertebrate species revealed a highly conserved chromosomal distribution of d(CT)-rich tracts. These tracts are found throughout the chromosomal arms and in some karyotypes they are clustered, producing a banding pattern. However, at the resolution of the light microscope these tracts appeared to be absent from the centromeric regions of all chromosomes examined except those of chicken. The non-random distribution of these tracts to the chromosomal arm regions implies an organizational or functional role for this repeat class. It is unlikely that the 56 bp sequence type contributed to the formation of the triplex DNA structure previously detected in centromeric domains of mouse.     

Chromosomal in situ suppression hybridization after Giemsa banding

Summary We report the successive application of classical Giemsa banding and chromosomal in situ suppression hybridization in clinical cytogenetics. The use of both techniques within one protocol requires an additional fixation of the chromosome preparations and an improved suppression of the labelled repetitive sequences. The combination of these two cytological techniques allows the high resolution mapping of translocated Y-chromosomal sequences in the chromosome set of an XX-male.     

In situ hybridization and chromosome banding in mammalian species

Chromosome banding is often required in conjunction with fluorescent in situ hybridization of labelled probes for chromosome painting, satellite DNA and low-copy sequences to allow identification of chromosomes and simultaneous probe localization. Here, we present a method that reveals both patterns with only one observation step. The band pattern is produced by restriction-enzyme digestion of chromosomes, followed by fixation with paraformaldehyde in PBS, a short chromosome denaturation step in hybridization solution, and then standard in situ hybridization, washing and detection protocols. Using a range of different mammalian species, chromosome-banding patterns were immediately recognizable, although synchronisation procedures normally required for high- resolution G-banding were not needed. Unlike other methods available, only one round of observation is required using a conventional fluorescence microscope, the method works without modification in many species, and in situ hybridization is not used for chromosome identification (allowing multiple targets and minimizing background). The banding pattern is probably generated by a combination of DNA dissolution and heterochromatin reorganisation after enzyme digestion, followed by paraformaldehyde fixation of the new chromatin structure and incomplete denaturation. The method is of widespread utility in comparative genomics and genome organization programmes.     

Three cases with rare interstitial rearrangements of chromosome 1 characterized by multicolor banding

In this report, we describe three unrelated patients with similar symptoms such as mental retardation, growth delay and multiple phenotypic abnormalities. GTG-banding analysis revealed karyotypes with add(1p) in two cases and an add(1q) in the third. Fluorescence in situ hybridization (FISH) analysis using high resolution multicolor banding (MCB) characterized the aberrations of the abnormal chromosomes 1 as a (sub)terminal duplication and inverted duplications, respectively. Although three different chromosomal regions i.e. 1p36.1, 1p36.2-->1p31.3 and 1q41-->1q44 were involved, all three patients had similar patterns of dysmorphic findings. These cases demonstrate the power of MCB in the characterization of small interstitial chromosomal aberrations and resulted in the characterization of three previously unreported congenital chromosome 1 rearrangements.     

Cytogenetics and fluorescence in situ hybridization assessment of sex-chromosome mosaicism in Klinefelter's syndrome

A retrospective study was carried out in 152 infertile men to determine the prevalence of sex chromosome abnormalities among non-obstructive azoospermic and severe oligospermic men (n = 51) and to evaluate the feasibility of fluorescence in situ hybridization (FISH) techniques to assess mosaicism in Klinefelter's patients in comparison with conventional cytogenetics. Cytogenetic analysis were performed for 51 infertile men and among 14 chromosomal abnormalities found, nine were compatible with Klinefelter's syndrome. FISH staining with a CEP X/CEP Y probes were performed for Klinefelter's patients and for five of them; testes were biopsied for histopathologic examination. Six Klinefelter's patients showed a non-mosaic 47,XXY and three showed a 47,XXY/46,XY mosaic by G or R banding analysis of 20 cells with a ratio of 17%, 20% and 33%, respectively. FISH analysis confirmed mosaicism in only one patient (the first) in whom a third cells population was found. There was no relationship between the ratios of mosaicism by banding and FISH analysis. Conventional histopathologic findings in five non-mosaic Klinefelter's patients confirm the diagnosis of Sertoli Only Cells syndrome. FISH is recommended in Klinefelter's syndrome to define exactly the cytogenetic statute as mosaic or non-mosaic and then discussing prognosis and decision regarding fertility counseling.     

Genetic analysis of transgenome structure and size of chromosome-mediated gene transfer lines

The TK-selected chromosome-mediate gene transferlines were analysed using DNA dot blot method,G-11banding and in situ hybridization.The results showedthat CMGT can provide a wide variety of intermediatesize of the transgenome from greater than 80,000kb toless than 2,000kb.Some of transfectants are intergratedinto mouse chromosome which can be detected by G-11banding and in situ hybridization     

Chromosomal localization of transfected genes by a combination of hot banding and fluorescence in situ hybridization.

We describe the combination of hot banding with fluorescence in situ hybridization as a rapid and efficient method to identify integration sites of transfected DNA sequences in chromosomes. As a test system we used SW480 EJ2, a clonal cell line obtained after transfection of SW480 with pSV2neoEJ, a plasmid containing a point-mutated, c-Ha-RAS oncogene. Nick-translated probes were compared with random primed-labeled probes to evaluate their relative efficiency in fluorescence in situ hybridization. The fluorescence signals were quantified in interphase nuclei by confocal scanning laser microscopy. Nick-translated probes were found to yield better results. Hot banding followed by fluorescence in situ hybridization localized the integration site of pSV2neoEJ in SW480 EJ2 at the site of a translocation on a marker chromosome Xp+. The combination of fluorescence in situ hybridization and hot banding can be used to (a) rapidly and efficiently analyze integration sites in large numbers of transfectants, (b) assess the clonality of transfected cell lines, and (c) localize the site of integration of transfected genes in the recipient genome.     

Combined RxFISH/G-banding allows refined karyotyping of solid tumors

Chromosome banding analysis of solid tumors often yields incomplete karyotypes because of the complex rearrangements encountered. The addition of fluorescence in situ hybridization (FISH) methods has helped improve the accuracy of solid tumor cytogenetics, but the absence of screening qualities from standard FISH approaches has proved a severe limitation. We describe the cytogenetic analysis of ten solid tumors using G-banding followed by cross-species color banding (RxFISH), a FISH-based screening technique giving a chromosome-specific banding pattern based on the genomic homologies between humans and gibbons. The addition of RxFISH analysis in all cases led to the identification of previously unidentified intra- as well as interchromosomal rearrangements, thus giving a much more certain and detailed karyotype. In two gastric stromal sarcomas, a tumor type for which no cytogenetic data were hitherto available, numerical chromosomal aberrations dominated, but one of the tumors also carried an unbalanced 7;17-translocation with the same breakpoint in chromosome 17 as that seen in endometrial stromal sarcomas. Received: 15 January 1999 / Accepted: 5 March 1999     

In situ localization of a mammalian protamine gene: parameters affecting specificity of hybridization

Southern hybridization analysis of Indian muntjac genomic DNA with the Eco-Taq bovine genomic protamine probe revealed a simple banding pattern. The pattern of hybridization was identical with that previously observed in the genus Bos. This suggested that the bovine probe specifically hybridized to the Indian muntjac protamine gene. The opportunity was thus provided to assign the chromosomal location of the protamine gene in a comparatively simple system. Accordingly, this probe and the corresponding cDNA probe were used for in situ chromosome hybridization and localization. Various parameters affecting specificity and the resolution of hybridization were examined. Subsequent to optimization, the Indian muntjac gene was shown to be autosomal and distally located in the telomeric region of the p arm of chromosome 1.     

Toward a multicolor chromosome bar code for the entire human karyotype by fluorescence in situ hybridization

A colored banding pattern for human chromosomes is described that distinguishes each chromosome in a single fluorescence in situ hybridization with a set of subregional DNA probes. Alu/polymerase chain reaction products of various human/rodent somatic cell hybrids (fragment hybrids) were pooled into two probe sets that were labeled differentially and detected by red and green fluorescence. Chromosome regions hybridized by DNA present in both pools appeared yellow. The result was a multi-color set of 110 distinct signals per haploid chromosome set for the human karyotype. Each individual chromosome showed a unique sequence of signals, a result termed the “chromosome bar code”. The reproducibility of the hybridization pattern in various labeling and hybridization experiments was analyzed by computer densitometry. We have applied the chromosome bar code both in diagnostic cytogenetics and in genome studies. The approach allows the rapid identification of chromosomes and chromosome rearrangements. Although not yet showing the resolution of classical banding patterns, the present experiments demonstrate various applications in which the present multi-color bar code can significantly add to the spectrum of cytogenetic techniques. Received: 18 December 1996 / Accepted: 10 February 1997     

Tools and methodologies for cytogenetic studies of plant chromosomes

A brief overview is presented in advances in cytogenetic methodology and the development of aneuploid stocks since the 1920s. The methodologies range from first reports of chromosome numbers of major organisms, the development of chromosome karyotypes, then aneuploid stocks in major crop plants. Molecular inputs include chromosome banding techniques, molecular marker maps, and in situ hybridization methodologies. All of the new techniques have greatly increased the degree of resolution obtained from cytogenetic studies. The text was submitted by the authors in English.     

Tools and methodologies for cytogenetic studies of plant chromosomes

A brief overview is presented in advances in cytogenetic methodology and development of aneuploid stocks since the 1920s. The methodologies range from first reports of chromosome numbers of major organisms, the development of chromosome karyotypes, then aneuploid stocks in the major crop plants. Molecular inputs included chromosome banding techniques, molecular marker maps and in situ hybridization methodologies. All of the new techniques greatly increased the degree of resolution obtained from cytogenetic studies.     

Rapid physical mapping of cloned DNA on banded mouse chromosomes by fluorescence in situ hybridization.

Physical mapping of DNA clones by nonisotopic in situ hybridization has greatly facilitated the human genome mapping effort. Here we combine a variety of in situ hybridization techniques that make the physical mapping of DNA clones to mouse chromosomes much easier. Hybridization of probes containing the mouse long interspersed repetitive element to metaphase chromosomes produces a Giemsa-like banding pattern which can be used to identify individual Mus musculus, Mus spretus, and Mus castaneus chromosomes. The DNA binding fluorophore, DAPI, gives quinacrine-like bands that can complement the hybridization banding data. Simultaneous hybridization of a differentially labeled clone of interest with the banding probe allows the assignment of a mouse clone to a specific cytogenetic band. These methods were validated by first mapping four known genes, Cpa, Ly-2, Cck, and Igh-6, on banded chromosomes. Twenty-seven additional clones, including twenty anonymous cosmids, were then mapped in a similar fashion. Known marker clones and fractional length measurements can also provide information about chromosome assignment and clone order without the necessity of recognizing banding patterns. Clones hybridizing to each murine chromosome have been identified, thus providing a panel of marker probes to assist in chromosome identification.     

Physical mapping of the Esterase-6 locus of Drosophila melanogaster

The Esterase-6 gene locus of Drosophila melanogaster although well-characterized, has not been definitly mapped by in situ hybridization. In this paper, a high resolution in situ hybridization protocol using an avidin/biotinylated-horseradish peroxidase/diaminobenzidine system was adopted to refine the physical map position of the Esterase-6 locus. Clarity of signal, detail of banding pattern and absence of background allowed the assignment of a 1.8 kb cDNA encoding Esterase-6 to three bands within subsections 69 A1–A3 on the left arm of polytene chromosome 3. These data refine earlier deletion mapping and low resolution in situ hybridization results, which assigned Esterase-6 to 69 A1–A5. The potential use of this high resolution in situ hybridization technique in the analysis of the physical organization of the Esterase-6 gene duplication and surrounding region is discussed.     

Multicolor chromosome banding (MCB) with YAC/BAC-based probes and region-specific microdissection DNA libraries

Multicolor chromosome banding (MCB) allows the delineation of chromosomal regions with a resolution of a few megabasepairs, i.e., slightly below the size of most visible chromosome bands. Based on the hybridization of overlapping region-specific probe libraries, chromosomal subregions are hybridized with probes that fluoresce in distinct wavelength intervals, so they can be assigned predefined pseudo-colors during the digital imaging and visualization process. The present study demonstrates how MCB patterns can be produced by region-specific microdissection derived (mcd) libraries as well as collections of yeast or bacterial artificial chromosomes (YACs and BACs, respectively). We compared the efficiency of an mcd library based approach with the hybridization of collections of locus-specific probes (LSP) for fluorescent banding of three rather differently sized human chromosomes, i.e., chromosomes 2, 13, and 22. The LSP sets were comprised of 107 probes specific for chromosome 2, 82 probes for chromosome 13, and 31 probes for chromosome 22. The results demonstrated a more homogeneous coverage of chromosomes and thus, more desirable banding patterns using the microdissection library-based MCB. This may be related to the observation that chromosomes are difficult to cover completely with YAC and/or BAC clones as single-color fluorescence in situ hybridization (FISH) experiments showed. Mcd libraries, on the other hand, provide high complexity probes that work well as region-specific paints, but do not readily allow positioning of breakpoints on genetic or physical maps as required for the positional cloning of genes. Thus, combinations of mcd libraries and locus-specific large insert DNA probes appear to be the most efficient tools for high-resolution cytogenetic analyses.     

Sequential chromosome banding and in situ hybridization analysis.

Different combinations of chromosome N- or C-banding with in situ hybridization (ISH) or genomic in situ hybridization (GISH) were sequentially performed on metaphase chromosomes of wheat. A modified N-banding-ISH/GISH sequential procedure gave best results. Similarly, a modified C-banding - ISH/GISH procedure also gave satisfactory results. The variation of the hot acid treatment in the standard chromosome N- or C-banding procedures was the major factor affecting the resolution of the subsequent ISH and GISH. By the sequential chromosome banding - ISH/GISH analysis, multicopy DNA sequences and the breakpoints of wheat-alien translocations were directly allocated to specific chromosomes of wheat. The sequential chromosome banding- ISH/GISH technique should be widely applicable in genome mapping, especially in cytogenetic and molecular mapping of heterochromatic and euchromatic regions of plant and animal chromosomes.     

Karyotyping of Brassica napus L. Based on C0t-1 DNA Banding by Fluorescence In Situ Hybridization

In order to precisely recognize and karyotype Brassica napus L. chromosomes, C0t-1 DNA was extracted from its genomic DNA, labeled with biotin-1 1-dUTP and in situ hybridized. The hybridized locations were detected by Cy3-conjugated streptavidin. Specific fluorescence in situ hybridization （FISH） signal bands were detected on all individual chromosome pairs. Each chromosome pair showed specific banding patterns. The B. napus karyotype has been constructed, for the first time, on the basis of both Cot-1 DNA FISH banding patterns and chromosome morphology.