肿瘤染色体畸变分析方法新进展

摘要: 肿瘤的发生多与染色体畸变有关, 确定染色体畸变与肿瘤的关系, 必然离不开染色体畸变的检测分析。文章简要综述几种常用染色体畸变的检测方法及其新进展, 包括G显带、荧光原位杂交(FISH )、光谱核型分析(SKY)、多色荧光原位杂交(M-FISH)、多色显带分析技术(Rx-FISH)、比较基因组杂交(CGH)和微阵列比较基因组杂交(Array CGH), 以及这些方法在肿瘤诊断和研究方面的应用。     

白菜rDNA及C-(0)t-1DNA的荧光原位杂交及其核型分析

以早熟白菜苔为实验材料,从其基因组DNA中分离出C0t-1 DNA并用生物素标记作探针,25S rDNA用地高辛标记作探针,对有丝分裂中期相染色体进行双色荧光原位杂交。每对染色体上均显示出了特定的C0t-1 DNA荧光原位杂交带型,5对染色体上显示出了25S rDNA荧光原位杂交带型。双色荧光原位杂交证实了C0t-1 DNA与25S rDNA二者具有一致的染色体位置特征,表明基于rDNA及C0t-1 DNA的荧光原位杂交核型分析技术,优于目前普遍采用的只基于rDNA的荧光原位杂交核型分析方法。结合C0t-1 DNA与25S rDNA的荧光原位杂交带型和传统的染色体的形态学标记分析方法及白菜已公布的基于rDNA分布的核型分析结果,创建了一个精确的白菜核型。     

白菜rDNA及C0t-1DNA的荧光原位杂交及其核型分析

以早熟白菜苔为实验材料,从其基因组DNA中分离出C0t-1DNA并用生物素标记作探针,25SrDNA用地高辛标记作探针,对有丝分裂中期相染色体进行双色荧光原位杂交。每对染色体上均显示出了特定的C0t-1DNA荧光原位杂交带型,5对染色体上显示出了25SrDNA荧光原位杂交带型。双色荧光原位杂交证实了C0t-1DNA与25SrDNA二者具有一致的染色体位置特征,表明基于rDNA及C0t-1 DNA的荧光原位杂交核型分析技术,优于目前普遍采用的只基于rDNA的荧光原位杂交核型分析方法。结合C0t-1 DNA与25SrDNA的荧光原位杂交带型和传统的染色体的形态学标记分析方法及白菜已公布的基于rDNA分布的核型分析结果,创建了一个精确的白菜核型。     

应用G显带染色体荧光原位杂交（FISH）技术研究复杂的染色体易位

建立常规Ｇ显带染色体标本的荧光原位杂交（ＦＩＳＨ）技术,用于分析患者复杂的染色体易位。原位杂交前,用甲醛固定Ｇ显带标本,是获得良好显带和荧光杂交效果的关键步骤。仅用常规细胞遗传学方法分析,显示一例习惯性流产患者的核型为４６,ＸＸ,ｔ（１;５;１２）（１ｐｔｅｒ→１ｑ２５：：１２ｑ２４→１２ｑｔｅｒ;５ｑｔｅｒ→５ｐ１１：：１ｑ２５→１ｑｔｅｒ,１２ｐｔｅｒ→１２ｑ２４：．５ｐ１１→５ｐｔｅｒ）,而采用本方法确定患者的核型实际为４６,ＸＸ,ｔ（１;５,１２）（１ｐｔｅｒ→１ｑ２３：：１２ｑ２２→１２ｑｔｅｒ,５ｑｔｅｒ→５ｐ１１：：１ｑ２５→１ｑｔｅｒ;１２ｐｔｅｒ→１２ｑ２２：：１ｑ２３→１ｑ２５：５ｐ１１→５ｐｔｅｒ）。结果表明,新建立的Ｇ显带染色体荧光原位杂交（ＦＩＳＨ）技术能更有效地检测患者复杂的染色体易位。     

一例特殊inv(Y)形成机理的研究

应用双色荧光原位杂交的方法,国内首次报道一例特殊inv(Y)异常的性质,探讨Y染色体倒位结构异常的形成机理以及与习惯性流产临床表型的关系。应用 Biotin-11-dUTP标记的Y染色体短臂断裂点Yp11.3探针（编号889）和CY3标记的Y染色体长臂断裂点Yq12远端异染色质区探针(编号PY3.4),对1例G显带核型分析为[46, XY(90%) / 46, X, inv(Y)(p11.3;q12)]的平衡易位携带者进行双色荧光原位杂交研究。双色FISH结果显示,该易位携带者异常核型比例为22%,稍高于G显带分析中确定的比例。而且,除G显带检测出的倒位类型外,又有两种类型的倒位,其中涉及到常规显带技术难以检测出的染色单体型倒位。3种倒位类型的存在说明该患者inv(Y)断裂点呈不均一性。FISH技术是一种能准确可靠检测出染色体倒位形成的重要手段。      

中国人体细胞染色体高分辨G带模式图

本工作应用高分辨染色体技术,分析了31名健康汉族人外周血的高分辨G带,制作了中国人体细胞染色体的高分辨G带核型图。并经镜下比较和照片剪贴配对分析,认为中国人体细胞高分辨G带的带纹顺序与宽窄基本与人类细胞遗传学高分辨显带命名的国际体制(ISCN,1981)中高分辨G带模式图一致,但在850条带阶段,1、2、8和Y染色体的某些区带与ISCN(1981)的模式图有些差别,故重新描绘了这四个染色体的模式图。     

FISH技术的临床应用研究

荧光原位杂交（FISH）是染色体显带技术的补充和发展,以人类精子,早期胚胎等间期核及中期染色体为材料,用FISH技术检测染色体的数目异常和微小的结构异常。结果快速准确,显示它较之传统的细胞遗传学技术诊断具有明显的优越性,在临床应用中有广泛的前景。     

应用G显色带染色体荧光原位杂交（FISH）技术研究复杂的染色体易位

建立常规Ｇ显带染色体标的荧光原位杂交（ＦＩＳＨ）技术,用于分析患者复杂的染色体易位,原位杂交前,用甲醛固定Ｇ显带标本,是获得良好显带和荧光杂交效果的关键步聚,仅用常细胞遗学方法分析,显示一例习惯性流产患者的核型为４６,ＸＸ,ｔ（１;５;１２）（１ｐｔｅｒ→１ｑ２５：：１２ｑ２４→１２ｑｔｅｒ;５ｑｔｅｒ→５ｑ１１：：１ｑ２５→１ｑｔｅｒ;１２ｐｔｅｒ→１２ｑ２４;：５ｐ１１→５ｐｔｅｒ）而采用本方     

基因组原位杂交技术及其在园艺植物基因组研究中的应用

基因组原位杂交(GISH)技术可以鉴定植物多倍体物种起源、杂种亲本染色体来源和组成,分析栽培种与其近缘野生种的亲缘关系,研究减数分裂染色体行为等。基因组原位杂交包括多色基因组原位杂交、比较基因组原位杂交和自身基因组原位杂交等。基因组原位杂交技术的关键步骤是染色体制片、探针制备及长度优化、探针与封阻的浓度比例和杂交后洗脱强度。该文对近年来国内外有关基因组原位杂交技术的发展及其在园艺植物基因组研究中的应用现状进行了综述,并指出随着多种园艺植物全基因组的测定,未来应从基因组信息中寻找更多的染色体特异性标记,结合荧光显带及荧光原位杂交技术,为深入研究园艺植物的起源以及遗传关系鉴定等提供技术支持。     

一例t（Y;15）并t（14;21）复合易位的细胞与分子遗传学研究

本文对一便生育过先天愚型儿的个体刊进行了细胞与分子遗传学研究。发现先证者拥有ｔ（１４;２１）用一个短臂增大变异为１５号标记染色体。通过Ｇ－显带、Ｃ－显带、Ｑ－显带、硝酸银染色及Ｙ染色体长臂异染色质区特异控针ｐＹ３．４对先证者基因组ＤＮＡ的斑点杂交和中期染色体的原位杂交,证实变异部分由Ｙ染色体长臂异染色质区易位所形成,从而排除了巨大随体的存在或其他染色体参与重排形成变的可能性,结果表明,常规显带与染     

Multicolor fluorescence in situ hybridization (FISH) applied to FISH-banding

During the last decade not only multicolor fluorescence in situ hybridization (FISH) using whole chromosome paints as probes, but also numerous chromosome banding techniques based on FISH have been developed for the human and for the murine genome. This review focuses on such FISH-banding techniques, which were recently defined as 'any kind of FISH technique, which provide the possibility to characterize simultaneously several chromosomal subregions smaller than a chromosome arm. FISH-banding methods fitting that definition may have quite different characteristics, but share the ability to produce a DNA-specific chromosomal banding'. While the standard chromosome banding techniques like GTG lead to a protein-related black and white banding pattern, FISH-banding techniques are DNA-specific, more colorful and, thus, more informative. For some, even high-resolution FISH-banding techniques the development is complete and they can be used for whole genome hybridizations in one step. Other FISH-banding methods are only available for selected chromosomes and/or are still under development. FISH-banding methods have successfully been applied in research in evolution- and radiation-biology, as well as in studies on the nuclear architecture. Moreover, their suitability for diagnostic purposes has been proven in prenatal, postnatal and tumor cytogenetics, indicating that they are an important tool with the potential to partly replace the conventional banding techniques in the future.     

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.     

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     

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.     

Structural unbalanced chromosome rearrangements resolved by comparative genomic hybridization.

The identification of unbalanced structural chromosome rearrangements using conventional cytogenetic techniques depends on recognition of the unknown material from its banding pattern. Even with optimally banded chromosomes, when large chromosome segments are involved, cytogeneticists may not always be able to determine the origin of extrachromosomal material and supernumerary chromosomes. We report here on the application of comparative genomic hybridization (CGH), a new molecular-cytogenetic assay capable of detecting chromosomal gains and losses, to six clinical samples suspected of harboring unbalanced structural chromosome abnormalities. CGH provided essential information on the nature of the unbalanced aberration investigated in five of the six samples. This approach has proved its ability to resolve complex karyotypes and to provide information when metaphase chromosomes are not available. In cases where metaphase chromosome spreads were available, confirmation of CGH results was easily obtained by fluorescence in situ hybridization (FISH) using specific probes. Thus the combined use of CGH and FISH provided an efficient method for resolving the origin of aberrant chromosomal material unidentified by conventional cytogenetic analysis.     

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).     

mBAND: a high resolution multicolor banding technique for the detection of complex intrachromosomal aberrations

Precise breakpoint definition of chromosomal rearrangements using conventional banding techniques often fails, especially when more than two breakpoints are involved. The classic banding procedure results in a pattern of alternating light and dark bands. Hence, in banded chromosomes a specific chromosomal band is rather identified by the surrounding banding pattern than by its own specific morphology. In chromosomal rearrangements the original pattern is altered and therefore the unequivocal determination of breakpoints is not obvious. The multicolor banding technique (mBAND, see Chudoba et al., 1999) is able to identify breakpoints unambiguously, even in highly complex chromosomal aberrations. The mBAND technique is presented and illustrated in a case of intrachromosomal rearrangement with seven breakpoints all having occurred on one chromosome 16, emphasizing the unique analyzing power of mBAND as compared to conventional banding techniques.     

Characterization of chromosomal aberrations in diffuse large B-cell lymphoma (DLBL) by G-banding and spectral karyotyping (SKY)

Cytogenetic chromosome analysis by classical G-banding was supplemented by spectral karyotyping (SKY) in 12 cases of diffuse large B-cell lymphoma (DLBL). SKY is a fluorescence in-situ-based, genome-wide screening technique allowing identification of genetic material even in highly condensed metaphase chromosomes of poor morphology. By simultaneous hybridization of whole chromosome painting probes onto tumor chromosome spreads genetic rearrangements are visualized permitting the clarification of even complex karyotype alterations and the identification of genetic material of previously unknown origin, so-called marker chromosomes. Taking the SKY results into account, we reevaluated the G-banding karyotypes initially carried out, thus generating a more precise karyotype in ten of twelve (83%) cases investigated. In particular, thirteen chromosomal rearrangements not correctly recognized by classical cytogenetics were identified, the genetic origin of seven marker chromosomes was elucidated and three structural genetic rearrangements were redefined. We found SKY to be a valuable technique to establish a definite karyotype in addition to classical cytogenetics.