Improvements in cytogenetic slide preparation: controlled chromosome spreading, chemical aging and gradual denaturing

BACKGROUND: Metaphase spreading is an essential technique for clinical and molecular cytogenetics. Results of classical banding techniques as well as complex fluorescent in situ hybridization (FISH) applications, such as comparative genomic hybridization (CGH) or multiplex FISH (M-FISH), are greatly influenced by the quality of chromosome spreading and pretreatment of the slide prior to hybridization. Materials and Methods Using hot steam and a metal plate with a temperature gradient across its surface, a reproducible protocol for slide preparation, aging, and hybridization was developed. RESULTS: This protocol yields good chromosome spreads from even the most difficult cell suspensions and is unaffected by the environmental conditions. Chromosome spreads were suitable for both banding and FISH techniques common to the cytogenetic laboratory. Chemical aging is a rapid slide pretreatment procedure for FISH applications, which allows freshly prepared cytogenetic slides to be used for in situ hybridization within 30 min, thus increasing analytical throughput and reducing benchwork. Furthermore, the gradually denaturing process described allows the use of fresh biologic material with optimal FISH results while protecting chromosomal integrity during denaturing. CONCLUSION: The slide preparation and slide pretreatment protocols can be performed in any laboratory, do not require specialized equipment, and provide robust results.     

Identification of de novo chromosomal markers and derivatives by spectral karyotyping

Despite major advances in molecular cytogenetics during the past decade and the important diagnostic role that fluorescence in situ hybridization (FISH) plays in the characterization of chromosomal abnormalities, the usefulness of this technique remains limited by the number of spectrally distinguishable fluorochromes or fluorochrome combinations. Overcoming this major limitation would allow one to use FISH to screen the whole human genome for chromosomal aberrations which, until recently, was possible only through conventional karyotyping. A recently described molecular cytogenetics technology, 24-color FISH using spectral karyotyping (SKY), permits the simultaneous visualization of all human chromosomes in 24 different colors. Most chromosomal aberrations detected during cytogenetic evaluation can be resolved using routine cytogenetic techniques alone or in combination with single- or dual-color FISH. However, some cases remain unresolved, in particular de novo supernumerary marker chromosomes and de novo unbalanced structural rearrangements. These findings cause particular diagnostic and counseling concerns when detected during prenatal diagnosis. The purpose of this report is to demonstrate the application of SKY in the characterization of these de novo structural chromosomal abnormalities. Eight cases are described in this report. SKY has considerable diagnostic applications in prenatal diagnosis because of its reliability and speed. The identification of the chromosomal origin of markers and unbalanced translocations provides the patient, physician, and genetic counselor with better predictive information on the phenotype of the carrier. Received: 2 June 1998 / Accepted: 16 June 1998     

Spectral karyotyping analysis of human and mouse chromosomes

Classical banding methods provide basic information about the identities and structures of chromosomes on the basis of their unique banding patterns. Spectral karyotyping (SKY), and the related multiplex fluorescence in situ hybridization (M-FISH), are chromosome-specific multicolor FISH techniques that augment cytogenetic evaluations of malignant disease by providing additional information and improved characterization of aberrant chromosomes that contain DNA sequences not identifiable using conventional banding methods. SKY is based on cohybridization of combinatorially labeled chromosome-painting probes with unique fluorochrome signatures onto human or mouse metaphase chromosome preparations. Image acquisition and analysis use a specialized imaging system, combining Sagnac interferometer and CCD camera images to reconstruct spectral information at each pixel. Here we present a protocol for SKY analysis using commercially available SkyPaint probes, including procedures for metaphase chromosome preparation, slide pretreatment and probe hybridization and detection. SKY analysis requires approximately 6 d.     

A micro-spreading improvement for spermatogenic chromosomes from Triatominae (Hemiptera-Reduviidae)

Cytogenetics of triatomines have been a valuable biological tool for the study of evolution, taxonomy, and epidemiology of these vectors of Trypanosoma cruzi. Here we present a single microtube protocol that combines micro-centrifugation and micro-spreading, allowing high quality cytogenetic preparations from male gonadal material of Rhodnius prolixus and Triatoma lecticularia. The amount of cellular scattering can be modulated, which can be useful if small aggregates of synchronous cells are desired. Moreover, a higher number of slides per gonad can be obtained with fully flattened clean chromosomal spreads with minimum overlaps, optimal for classical and modern molecular cytogenetic analyses.     

Multicolor banding technique, spectral color banding (SCAN): new development and applications

Conventional banding techniques can characterize chromosomal aberrations associated with tumors and congenital diseases with considerable precision. However, chromosomal aberrations that have been overlooked or are difficult to analyze even by skilled cytogeneticists were also often noted. Following the introduction of multicolor karyotyping such as spectral karyotyping (SKY) and multiplex-fluorescence in situ hybridization (M-FISH), it is possible to identify this kind of cryptic or complex aberration comprehensively by a single analysis. To date, multicolor karyotyping techniques have been established as useful tools for cytogenetic analysis. However, since this technique depends on whole chromosome painting probes, it involves limitations in that the origin of aberrant segments can be identified only in units of chromosomes. To overcome these limitations, we have recently developed spectral color banding (SCAN) as a new multicolor banding technique based on the SKY methodology. This new technique may be deemed as an ideal chromosome banding technique since it allows representation of a multicolor banding pattern matching the corresponding G-banding pattern. We applied this technique to the analysis of chromosomal aberrations in tumors that had not been fully characterized by G-banding or SKY and found it capable of (1) detecting intrachromosomal aberrations; (2) identifying the origin of aberrant segments in units of bands; and (3) precisely determining the breakpoints of complex rearrangements. We also demonstrated that SCAN is expected to allow cytogenetic analysis with a constant adequate resolution close to the 400-band level regardless of the degree of chromosome condensation. As compared to the conventional SKY analysis, SCAN has remarkably higher accuracy for a particular chromosome, allowing analysis in units of bands instead of in units of chromosomes and is hence promising as a means of cytogenetic analysis.     

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     

Spectral karyotyping, a 24-colour FISH technique for the identification of chromosomal rearrangements

 Spectral karyotyping (SKY) is a new fluorescence in situ hybridisation (FISH) technique that refers to the molecular cytogenetic analysis of metaphase preparations by means of spectral microscopy. For SKY of human metaphase chromosomes, 24 chromosome-specific painting probes are used in just one FISH experiment. The probes are labelled by degenerate oligonucleotide-primed PCR using three fluorochromes and two haptens. Each probe is differentially labelled with one, two, three or four fluorescent dyes, resulting in a unique spectral signature for every chromosome. After in situ hybridisation and immunodetection, a spectral image is acquired using a conventional fluorescence light microscope equipped with a custom-designed triple-bandpass filter and the SpectraCube, which is able to retrieve spectral information for every pixel in a digital CCD image. The 24-colour display and chromosome classification are based on the unique emission spectra of the chromosomes. Together with chromosome banding information from an inverted DAPI or a G-banded metaphase, a comprehensive overview of chromosomal aberrations is presented. Accepted: 3 July 1997     

In situ hybridization of biotinylated DNA probes to cotton meiotic chromosomes

A modified procedure for in situ hybridization of biotinylated probes to meiotic chromosomes of cotton has been developed with high retention of squashed cells on slides, preservation of acid-fixed chromosome morphology, exceptionally low levels of background precipitate at nonspecific hybridization sites and improved photomicrographic recording. Salient features of the techniques include pretreatment of slides before squashing, cold storage of squash preparations, and use of interference filters for distinguishing precipitate from chromatin. A cloned 18S/28S ribosomal DNA fragment from soybean was biotinylated via nick-translation and hybridized to microsporocyte meiotic chromosomes of cotton (Gossypium hirsutum L. and G. hirsutum L. X G. barbadense L.). Enzymatically formed precipitate from streptavidin-bound peroxidase marked the in situ hybridization. In situ hybridization of biotinylated probes to cotton meiotic chromosomes adds the specificity and resoltion of in situ hybridization to the chromosomal and genomic perspectives provided by meiotic cytogenetic analyses. Molecular cytogenetic analyses of meiotic cells offer certain inherent analytical advantages over analyses of somatic cells, e.g., in terms of mapping, and for studying fundamental biological and genetic problems, particularly for organisms that are not amenable to somatic karyotypic analysis.     

多色-FISH技术的进展及其在分子生物医学上的应用

传统显带分析技术以每条染色体独特的显带带型为依据,提供染色体形态结构的基本信息,用于染色体核型的初步分析。然而有些染色体重排由于涉及的片断太小或具有相似的带型,用该方法难以探测或准确描绘。多元荧光原位杂交(M-FISH),光谱核型分析(SKY),FISH-显带分析技术是染色体特异的多色荧光原位杂交技术(mFISH)。它们能够探测出传统显带分析不能发现的染色体异常,提供更准确的核型。M-FISH和SKY均以组合标记的染色体涂染探针共杂交为基础,二者的不同在于观察仪器和分析方法上。它们可对中期染色体涂片进行快速准确分析,描绘复杂核型,确认标记染色体,主要用于恶性疾病的细胞遗传学诊断分析。FISH-显带分析技术以FISH技术为基础,能同时检测多条比染色体臂短的染色体亚区域。符合该定义的FISH-显带分析技术各有特点,其共同特点是都能产生DNA特异的染色体条带。这些条带有更多色彩,能提供更多信息。FISH-显带分析技术已经成功地被用于进化生物学、放射生物学以及核结构的研究,同时也被用于产前、产后以及肿瘤细胞遗传学诊断,是很有潜力的工具。     

Cytogenetic characterization of the TM4 mouse Sertoli cell line. I. Conventional banding techniques, FISH and SKY.

Permanent Sertoli cell lines provide an ideal system for the in vitro analysis of function and responsiveness to biochemical/hormonal factors of this particular cell type. In general, cytogenetic analyses of cell lines often reveal remarkable chromosomal changes that may be associated with functional characteristics. In the present study we investigated the mouse Sertoli cell line TM4 by C-banding, silver staining, FISH and spectral karyotyping (SKY). A highly increased chromosome number (average 85-95) as well as five stable marker chromosomes were detected by the conventional staining techniques. SKY identified the markers as a translocation chromosome T(1;3), isochromosomes 11 and 18 and two different-sized microchromosomes. The results show the usefulness of combining SKY and conventional banding methods for the evaluation of chromosome alterations in widely used cell lines.     

Spectral Karyotyping to Study Chromosome Abnormalities in Humans and Mice with Polycystic Kidney Disease

Conventional method to identify and classify individual chromosomes depends on the unique banding pattern of each chromosome in a specific species being analyzed ^{1, 2}. This classical banding technique, however, is not reliable in identifying complex chromosomal aberrations such as those associated with cancer. To overcome the limitations of the banding technique, Spectral Karyotyping (SKY) is introduced to provide much reliable information on chromosome abnormalities.SKY is a multicolor fluorescence in-situ hybridization (FISH) technique to detect metaphase chromosomes with spectral microscope ^{3, 4}. SKY has been proven to be a valuable tool for the cytogenetic analysis of a broad range of chromosome abnormalities associated with a large number of genetic diseases and malignancies ^{5, 6}. SKY involves the use of multicolor fluorescently-labelled DNA probes prepared from the degenerate oligonucleotide primers by PCR. Thus, every chromosome has a unique spectral color after in-situ hybridization with probes, which are differentially labelled with a mixture of fluorescent dyes (Rhodamine, Texas Red, Cy5, FITC and Cy5.5). The probes used for SKY consist of up to 55 chromosome specific probes ^7-10.The procedure for SKY involves several steps (Figure 1). SKY requires the availability of cells with high mitotic index from normal or diseased tissue or blood. The chromosomes of a single cell from either a freshly isolated primary cell or a cell line are spread on a glass slide. This chromosome spread is labeled with a different combination of fluorescent dyes specific for each chromosome. For probe detection and image acquisition,the spectral imaging system consists of sagnac interferometer and a CCD camera. This allows measurement of the visible light spectrum emitted from the sample and to acquire a spectral image from individual chromosomes. HiSKY, the software used to analyze the results of the captured images, provides an easy identification of chromosome anomalies. The end result is a metaphase and a karyotype classification image, in which each pair of chromosomes has a distinct color (Figure 2). This allows easy identification of chromosome identities and translocations. For more details, please visit Applied Spectral Imaging website (http://www.spectral-imaging.com/).SKY was recently used for an identification of chromosome segregation defects and chromosome abnormalities in humans and mice with Autosomal Dominant Polycystic Kidney Disease (ADPKD), a genetic disease characterized by dysfunction in primary cilia ^11-13. Using this technique, we demonstrated the presence of abnormal chromosome segregation and chromosomal defects in ADPKD patients and mouse models ¹⁴. Further analyses using SKY not only allowed us to identify chromosomal number and identity, but also to accurately detect very complex chromosomal aberrations such as chromosome deletions and translocations (Figure 2).     

In Situ Hybridization of Biotinylated Dna Probes to Cotton Meiotic Chromosomes

A modified procedure for in situ hybridization of biotinylated probes to meiotic chromosomes of cotton has been developed with high retention of squashed cells on slides, preservation of acid-fixed chromosome morphology, exceptionally low levels of background precipitate at nonspecific hybridization sites and improved photomicrographic recording. Salient features of the techniques include pretreatment of slides before squashing, cold storage of squash preparations, and use of interference Biters for distinguishing precipitate from chromatin. A cloned 18S/28S ribosomal DNA fragment from soybean was biotinylated via nick-translation and hybridized to microsporocyte meiotic chromosomes 6f cotton (Gostypium hirsutum L. and G. hirsutum L. X G. barbadense L.). Enzymatically formed precipitate from streptavidin-bound peroxidase marked the in situ hybridization.

In situ hybridization of biotinylated probes to cotton meiotic chromosomes adds the specificity and resolution of in situ hybridization to the chromosomal and genomic perspectives provided by meiotic cytogenetic analyses. Molecular cytogenetic analyses of meiotic cells offer certain inherent analytical advantages over analyses of somatic cells, e.g., in terms of mapping, and for studying fundamental biological and genetic problems, particularly for organisms that are not amenable to somatic karyotypic analysis.     

Rapid localization of transgenes in mouse chromosomes with a combined Spectral Karyotyping/FISH technique

We explored the feasibility of combined Spectral Karyotyping (SKY) and Fluorescence In Situ Hybridization (FISH) as means to rapidly map a chromosomally integrated renin/green fluorescent protein (GFP) fusion gene construct (Ren-GFP) in the transgenic mouse, Tg(Ren-GFP)1Kwg. A sequential hybridization with SKY probes followed by FISH gave consistently satisfactory results, demonstrating that multiple copies of the Ren-GFP transgene in this transgenic mouse line are integrated into a single chromosomal site of Chromosome (Chr) 4, most probably in the juxta-centromeric euchromatic region consisting of the A2-A3 domain. Chr 4 as a sole carrier of the transgene also was confirmed by co-hybridization to p1 BAC clone DNA containing telomeric sequences specific for mouse Chr 4 and the Ren-GFP construct in pGEM4Z vector. The hemizygosity of the Ren-GFP transgene is maintained not only in bone marrow cells, but also in lung cells proliferating in vitro, indicating that stable integration of the Ren-GFP transgene into chromosomal DNA was established at a very early embryonic stage. We conclude that the SKY/FISH technique is a reliable and facile method for establishing the integration site of a transgene. As such, this protocol has obvious advantages over traditional backcross methods in terms of time, cost and labor for determining the chromosomal location of transgenes.     

De novostructural chromosomal imbalances: molecular cytogenetic characterization of partial trisomies

De novo structural chromosomal imbalances represent a major challenge in modern cytogenetic diagnostics. Based solely on conventional cytogenetic techniques it may be impossible to identify the chromosomal origin of additional chromosomal material. In these cases molecular cytogenetic investigations including multicolor-FISH (M-FISH), spectral karyotyping (SKY), multicolor banding (MCB) and cenM-FISH combined with appropriate single-locus FISH probes are highly suitable for the determination of the chromosomal origin and fine characterization of derivative chromosomes. Here we report on four patients with de novo chromosomal imbalances and distinct chromosomal phenotypes, three of them harboring pure partial trisomies: a mildly affected boy with pure partial trisomy 10q22.2-->q22.3 approximately 23.1 due to an interstitial duplication, a girl with pure trisomy 12p11.21-->pter and atypically moderate phenotype as the consequence of an X;autosome translocation, and a girl with multiple congenital abnormalities and severe developmental delay and a 46,XX,15p+ karyotype hiding a trisomy 17pter-->17q11.1. The fourth patient is a girl with minor phenotypic features and mental retardation with an inverted duplication 18q10-->p11.31 combined with a terminal deletion of 18p32. The clinical pictures are compared with previously described patients with focus on long term outcome.     

Genetic susceptibility to adverse effects of drugs and environmental toxicants. The role of the CYP family of enzymes

DNA loss by the process of micronucleation is associated with aging, cancer and environmental exposure. The primary aim of this study was to identify the chromosomal origin of the DNA excluded into micronuclei (MN). This was achieved using a novel application of SKY and FISH technologies. Cytochalasin B (Cyt B)-treated lymphocyte cultures from three females (aged 28, 42 and 72) were analyzed. SKY revealed that the majority of MN (89.8, 82.9, and 97.6% in the 28-, 42- and 72-year-old (y.o.), respectively) had a uniform, single color, suggesting that they were comprised of DNA from a single chromosome. Using a pancentromeric probe, most of the MN (82% in 28 y.o., 69% in 42 y.o. and 80% in 72 y.o.) had one centromere signal present. Overall, the confirmation studies (using FISH with chromosome-specific WCP) were in agreement with the SKY chromosomal assignments for 71.1% of the MN. Although the SKY analysis showed that all of the 23 chromosomes (22 autosomes and the X chromosome) could be present in the MN, overall, the X chromosome was seen most frequently. DNA from the X chromosome was seen in 50.6% of MN in the 42 y.o. individual, whereas in the 28 and 72 y.o. it was seen in 12.2 and 7.1% of MN, respectively. This difference (P<0.0001) in the frequencies of X chromosome exclusion into MN among individuals was independently confirmed using a single whole chromosome painting probe (WCP) for the X chromosome. SKY also showed variation in the frequency of autosomal exclusion into MN between chromosomes and between females. Collectively, this study supports the hypothesis that the majority of MN contain DNA from a single, monocentric chromosome. The use of SKY technology for the identification of the chromosomal content(s) of MN provides an opportunity for expansion of our knowledge of the chromosomal changes that accompany MN formation.     

Genetic Characteristics of the Human Hepatic Stellate Cell Line LX-2

The human hepatic cell line LX-2 has been described as tool to study mechanisms of hepatic fibrogenesis and the testing of antifibrotic compounds. It was originally generated by immortalisation with the Simian Vacuolating Virus 40 (SV40) transforming (T) antigen and subsequent propagation in low serum conditions. Although this immortalized line is used in an increasing number of studies, detailed genetic characterisation has been lacking. We here have performed genetic characterisation of the LX-2 cell line and established a single-locus short tandem repeat (STR) profile for the cell line and characterized the LX-2 karyotype by several cytogenetic and molecular cytogenetic techniques. Spectral karyotyping (SKY) revealed a complex karyotype with a set of aberrations consistently present in the metaphases analyses which might serve as cytogenetic markers. In addition, various subclonal and single cell aberrations were detected. Our study provides criteria for genetic authentication of LX-2 and offers insights into the genotype changes which might underlie part of its phenotypic features.     

Simultaneous identification and banding of human chromosome material in somatic cell hybrids

We have developed a method that identifies human chromosomes in human x hamster somatic cell hybrids and simultaneously bands these same metaphases. Other methods generally require separate slides for banding and detection of human chromosome material, making the precise characterization of human material difficult. Our procedure involves denaturing metaphase chromosomes, followed by in situ hybridization of biotinylated whole human DNA. Fluoresceinated avidin is then bound to the biotinylated DNA, staining the human chromosomes yellow-green when excited with UV light. Chromosome banding is achieved by staining the slides with DAPI and actinomycin D. The fluorescein and DAPI excite maximally at 488 and 355 nm and emit at 520 and 450 nm, respectively. This permits identification of the human material at one excitation wavelength and visualization of the banding patterns at another wavelength. With this procedure, we have successfully identified both intact and broken human chromosomes, as well as human material involved in human x hamster translocations. The results indicate that this procedure is more accurate and considerably more rapid than previous methods and can be routinely employed for the cytogenetic analysis of human x rodent hybrids.     

Human cells in suspension 2

Summary When PHA stimulated human lymphoid cells are allowed to proliferate in vitro and chromosomal slides are prepared from the culture after 48,72, 96,120, and 144h of growth, gradual changes in chromosome morphology can be observed after traditional Giemsa staining of the slides. Keeping culture conditions, colcemid exposure, and fixation procedure constant for all samples, it is found that average chromosome length decreases with increasing culture time. A shift from high frequencies of subbanded chromosomes (sample 48 h and sample 72 h) to high frequencies of unbanded and G banded chromosomes (sample 120 h and sample 144 h) takes place simultaneously with the general compaction of the chromosomes. Examination of trypsin-induced G bands as well as examination of untreated G banded chromosomes from all samples clearly indicate that the basic G band pattern is not altered during proliferation and differentiation, although the progressive compaction of the chromosome observed with increasing culture time results in a phenomenon similar to that observed during mitosis, where the compact late metaphase chromosome after trypsin treatment exhibits fewer but more prominent bands than the prophase/prometaphase chromosomes. Thus the progressive compaction of metaphase chromosomes observed during in vitro aging seems to resemble the condensation processes during the G₂ phase and mitosis.It has been suggested that the chromomeres serve as centers for chromosome condensation during mitosis, probably mediated by a sulphydryl-disulphide transition in chromosomal proteins. The data presented here further suggest that the chromomeres may also serve as centers for chromosomal differentiation, presumable by a mechanism similar to that acting during chromosome condensation in mitosis.     

A method for generating selective DNA probes for the analysis of C-negative regions in human chromosomes

Linker-adapter polymerase chain reaction (LA-PCR) is among the most efficient techniques for whole genome DNA amplification. The key stage in LA-PCR is the hydrolysis of a DNA sample with restriction endonucleases, and the choice of a restriction endonuclease (or several endonucleases) determines the composition of DNA probes generated in LA-PCR. Computer analysis of the localization of the restriction sites in human genome has allowed us to propose an efficient technique for generating DNA probes by LA-PCR using the restriction endonucleases HaeIII and RsaI. In silico hydrolysis of human genomic DNA with endonucleases HaeIII and RsaI demonstrate that 100- to 1,000-bp DNA fragments are more abundant in the gene-rich regions. Applying in situ hybridization to metaphase chromosomes, we demonstrated that the produced DNA probes predominantly hybridized to the C-negative chromosomal regions, whereas the FISH signal was almost absent in the C-positive regions. The described protocol for generating DNA probes may be successfully used in subsequent cytogenetic analysis of the C-negative chromosomal regions.