G-显带技术、荧光原位杂交和比较基因组杂交技术在产前诊断中的应用

目的 探讨G显带、荧光原位杂交(fluorescencein situ hybridization,FISH)和比较基因组杂交(comparative genomic hybridization,CGH)技术在产前诊断中应用的程序及意义.方法 采集102例妊娠16周～24周胎儿的羊水,采用G显带、G显带/FISH和G显带/FISH/CGH三阶梯的核型诊断程序,并分析其在产前诊断中的意义.结果 102例胎儿中,经第1阶梯诊断核型98例,诊断困难2例,失败2例;第2阶梯诊断核型2例,诊断困难1例,失败1例;第3阶梯诊断核型2例.经3阶梯诊断程序核型的诊断率达100%(102/102例),异常核型7例(7/102例,6.68 0A),其中第1、第2和第3阶梯分别诊断异常核型4例(4/7例,57.1 oA)、1例(1/7例,14.3%)和2例(2/7例,28.5%).结论 在产前诊断中实施3阶梯诊断程序有助于提高核型的确诊率,规范染色体诊断流程.     

Comparative genomic hybridization as a tool in tumour cytogenetics

The quality of cytogenetic analysis of solid tumours has greatly improved in the past decade, but a number of technical difficulties remain which limit the characterization of solid tumour chromosomes by conventional cytogenetics alone. The identification of regions of chromosomal abnormality has been aided by the introduction of molecular cytogenetic techniques such as fluorescence in situ hybridization (FISH). Of these, a recently developed approach, comparative genomic hybridization (CGH), has had a particular impact on the cytogenetic analysis of solid tumours. It incorporates the sensitivity of in situ techniques and overcomes many of the drawbacks of conventional cytogenetic analysis. This review first outlines the CGH method, giving details for the preparation of DNA probes and target human metaphase chromosomes together with information on the in situ technique and data handling criteria used in our laboratory. It then presents an overview of some of the current applications of CGH, together with a discussion of future directions in the field. Copyright © 1999 John Wiley & Sons, Ltd.     

Microarray-based comparative genomic hybridization and its applications in human genetics

Through the years, several techniques capable of detecting DNA copy number changes have been developed. A number of those, such as karyotyping and fluorescence in situ hybridization (FISH), have proven to be valuable tools in both research and diagnostics. Recently, a new technique, called microarray-based comparative genomic hybridization (array CGH), has been introduced. Array CGH has proven to be a specific, sensitive, and fast technique, with considerable advantages compared to other methods used for the analysis of DNA copy number changes. Array CGH enables analysis of the whole genome in a single experiment. Until now, its applications have been mainly directed at detecting genomic abnormalities in cancer. However, array CGH is also suitable for the analysis of DNA copy number aberrations that cause human genetic disorders. This review gives an overview of array CGH and its applications in human genetics. Advantages, limitations, and future perspectives of array CGH are discussed.     

A cytogeneticist's perspective on genomic microarrays

The identification of cytogenetic imbalance is an important component of clinical genetics. About 1 in 154 newborns has a chromosome abnormality. Conventional cytogenetic analysis has enabled the identification of microscopic alterations of the chromosomes. The development of fluorescence in situ hybridization (FISH) and other molecular methodologies has made possible the identification of submicroscopic aberrations. An additional development was comparative genomic hybridization (CGH), a method that directly compares two genomes for DNA copy differences. As first developed, the substrate for CGH analysis is normal metaphase chromosomes. Recently, CGH has been applied to microarrays (array CGH) constructed from large insert clones to identify chromosome imbalance. Array CGH has many advantages over conventional cytogenetic and molecular cytogenetic techniques. Array CGH can be comprehensive (genome-wide), high resolution, amenable to automation, rapid, and sensitive. We anticipate that array CGH will be employed in the clinical cytogenetics laboratory in the near future and will lead to the identification of the chromosomal basis of new syndromes and existing genetic conditions.     

软组织肿瘤的比较基因组杂交研究进展

比较基因组杂交(comparative genomic hybridization,CGH) 是1992年建立起来的重大分子细胞遗传学分析技术,它在对整个基因组DNA拷贝数变异的检测方面是一种有效的方法。通过CGH检测,可找出染色体DNA拷贝数的变异特点,即基因拷贝数的扩增或丢失,从而确定相关的癌基因和抑癌基因所在的区域,为探讨肿瘤的发病机制提供依据。在过去的十几年中,用CGH对各种软组织肿瘤进行研究,已探测到了各种各样的有不同程度特异性的基因组的不平衡性,不仅开辟了探测各种癌症相关基因的新途径,并且找到了一些与临床相关的基因改变,可用于肿瘤的发生、发展、鉴别诊断、预后以及治疗等研究。     

Array-based comparative genomic hybridization of ductal carcinoma in situ and synchronous invasive lobular cancer

It has been increasingly recognized that ductal carcinoma in situ (DCIS), lobular carcinoma in situ (LCIS) and invasive cancer of the breast are often closely associated with one another. However, the genomic relationship between these histologically distinct entities has not been well characterized. Refinements in high-resolution comparative genomic hybridization (CGH) techniques allow for a detailed comparison of genomic alterations in synchronously occurring tumors. The following case illustrates how array CGH may be used to better understand whether synchronous neoplasms share a common origin.     

Comparative genomic hybridization analysis of human oocytes and polar bodies

BACKGROUND: Classical cytogenetic methods and fluorescent in situ hybridization (FISH) have been employed for the analysis of chromosomal abnormalities in human oocytes. However, these methods are limited by the need to spread the sample on a microscope slide, a process that risks artefactual chromosome loss. Comparative genomic hybridization (CGH) is a DNA-based method that enables the investigation of the entire chromosome complement. We optimized and evaluated a CGH protocol for the chromosomal analysis of first polar bodies (PBs) and oocytes. The protocol was then employed to obtain a detailed picture of meiosis I errors in human oogenesis. METHODS: 107 MII oocyte-PB complexes were examined using whole genome amplification (WGA) and CGH. RESULTS: Data was obtained for 100 complexes, donated from 46 patients of average age 32.5 (range 18-42). 22 complexes from 15 patients were abnormal, giving an aneuploidy rate of 22%. CONCLUSIONS: The results presented in this study more than double the quantity of CGH data from female gametes currently available. Abnormalities caused by whole chromosome non-disjunction, unbalanced chromatid predivision and chromosome breakage were reliably identified using the CGH protocol. Analysis of the data revealed a preferential participation of chromosome X and the smaller autosomes in aneuploidy and provided further evidence for the existence of age-independent factors in female aneuploidy.     

髓母细胞瘤比较基因组杂交分析及ERBB-2异常表达的意义

目的研究髓母细胞瘤全基因组的遗传学异常,探讨癌基因的异常表达在髓母细胞瘤发病机制中的作用以及与预后的关系。方法应用比较基因组杂交（comparative genomic hybridization,CGH）技术检测14例髓母细胞瘤全基因组的遗传学改变;同时,在扩大系列的29例髓母细胞瘤中,应用荧光原位杂交（fluorescence in situ hybridization,FISH）和免疫组化染色分别检测ERBB-2在基因水平和蛋白水平的表达。结果（1）CGH结果显示,在所有14例髓母细胞瘤标本中,每一条染色体臂上都检测到了染色体的失衡（获得或丢失）,最常见的染色体异常为17q（85．7％）和7q（35．7％）的获得,以及8p（50％）、16q（28．6％）和17p（35．7％）的丢失;（2）FISH检测中,44．5％（13／29例）的肿瘤细胞有ERBB-2基因的异常表达;（3）免疫组化结果显示,37．9％（11／29例）的病例有抗体c-erbB-2的阳性表达;（4）在预后较差的16例患者中,56％（9／16例）的病例有ERBB-2的过度表达。结论CGH研究发现了髓母细胞瘤全基因组的染色体失衡。在染色体17q特异性位点上ERBB-2基因的异常改变很可能在髓母细胞瘤的发病机制中起着重要的作用,其过度表达与患者的预后密切相关。     

The Art and Applications of Fluorescence In Situ Hybridization in Endocrine Pathology

Fluorescence in situ hybridization (FISH) or molecular cytogenetics is currently recognized as a reliable, sensitive, and reproducible technique for identifying the copy number and structure of chromosomes. FISH combines molecular genetics with classic cytogenetics and allows simultaneous morphologic evaluation on a single slide. Centromeric DNA probes are used to detect specific chromosomes and telomeric probes to demonstrate all chromosomes. Sequence-specific probes can localize in situ a single gene copy on a specific chromosome locus. FISH allows cytogenetic investigation of metaphase spreads and interphase nuclei. Several protocols have been proposed to analyze preparations from fresh samples or archival material. Comparative genomic hybridization (CGH) is a novel cytogenetic technique, which combines FISH with automatic digital image analysis. Comparative analysis of the hybridization products of tumor DNA and reference DNA with normal metaphase chromosomes, each labeled with color different fluorochrome, can retrieve chromosomal imbalances of the entire genome in a single experiment. FISH and CGH are powerful morphologic tools in understanding physiologic mechanisms and in resolving problems of the pathogenesis of several diseases. These techniques shed light on the cytogenetic background in many endocrinological disorders, providing a better understanding of the activities and alterations of endocrine cell function.     

胚胎植入前非整倍体筛查研究进展

非整倍体是最常见的染色体数目异常,发生于卵母细胞或胚胎可导致胚胎种植失败、自发性流产和新生儿出生缺陷.胚胎植入前非整倍体筛查主要利用极体,卵裂球和囊胚检测非整倍体.荧光原位杂交技术为目前常规技术,正广泛应用于临床.比较基因组杂交是在染色体荧光原位杂交技术的基础上发展起来的一种新的分子细胞遗传学技术.随着微阵列技术的引进...     

A CGH study of 27 patients with CHARGE association

CHARGE association is a non-random occurrence of congenital malformations including coloboma, heart disease, choanal atresia, retarded growth and/or retarded development, genital hypoplasia, ear anomalies and/or deafness. The cause of this association remains unknown. Various genetic mechanisms have been proposed, including a contiguous gene syndrome but, so far, no recurrent locus has been identified. To address this question, we decided to perform a comparative genomic hybridization (CGH) study on a cohort of 27 patients with CHARGE association and a normal standard karyotype. We found two chromosomal anomalies: a der(9)t(9;13) derived from a paternal translocation and a der(6)t(4;6) of unknown origin. This suggests that chromosome imbalances may well mimic CHARGE association. Therefore patients with CHARGE association must be carefully tested with classical and molecular cytogenetic techniques to detect a potential chromosome imbalance. It is expected that more stringent diagnostic criteria of CHARGE association could define a more homogeneous group of patients where a single genetic cause might be identified.     

联合应用多种细胞及分子细胞遗传学技术确诊额外标记染色体

目的应用比较基因组杂交技术（comparative genomic hybridization，CGH）、荧光原位杂交（fluorescence in situ hybridization，FISH）和传统细胞遗传学技术分析1例额外标记染色体（supernumerary marker chromosome，SMC），探讨这些技术的联合使用在识别新发生的标记染色体方面的临床应用。方法1例智力低下患儿，通过常规G显带技术分析其染色体核型。针对发现的SMC，通过CGH分析其起源，通过FISH技术证实。同时应用N带和C带技术分析SMC的随体组成和着丝粒组成。结合已有的文献报道，分析该SMC的表型效应。结果染色体G带分析显示患者为携带SMC的嵌合体，核型描述为mos．47，XX，＋may[31]／48，XX，＋2mar[29]。CGH分析显示患儿基因组中有15q11→q14片段重复，以15q探针与患者中期分裂相进行FISH检测证实SMC来源于15号染色体。应用检测缺失型Prader-wiUi综合征／Angelman综合征的UBE3A探针与患者中期分裂相检测显示SMC有两个UBE3A杂交信号，对照的PML位点没有信号。N带显示SMC携带双随体，c带分析SMC为双着丝粒。综合上述结果，患者核型为：mos．47，xx，＋der（15）（pter＋q14：：q14→pter）[31]／48，XX，＋2der（15）（pter→q14：：q14→pter）[29]．ish der（15）（WCPl5＋，UBE3A＋＋，PML-）。结论CGH对于检测出不平衡染色体结构重排具有提示作用，结合FISH和传统的细胞遗传学技术，为确定SMC的结构组成提供了可信的技术平台，为分析这类异常核型个体的表型、预后和复发风险提供了依据。     

鼻咽癌的比较基因组杂交研究

目的：研究鼻咽癌的遗传变异特性。方法：采用激光微切割技术分离鼻咽癌细胞DNA，用比较基因组杂交检测6例鼻咽癌组织。结果：6q12-22、8q染色体区域的扩增，染色体11q23-24、13q基因缺失。结论：鼻咽癌具有染色体变异，其中6q12-22、8q、11q23-24和13q区域可能存在一些与鼻咽癌相关的未知基因。     

Reliability of comparative genomic hybridization to detect chromosome abnormalities in first polar bodies and metaphase II oocytes

BACKGROUND: Preimplantation Genetic Diagnosis (PGD) using FISH to analyze up to nine chromosomes to discard chromosomally abnormal embryos has resulted in an increase of pregnancy rates in certain groups of patients. However, the number of chromosomes that can be analyzed is a clear limitation. We evaluate the reliability of using comparative genomic hybridization (CGH) to detect the whole set of chromosomes, as an alternative to PGD using FISH. METHODS AND RESULTS: We have analysed by CGH both, first polar bodies (1PBs) and metaphase II (MII) oocytes from 30 oocytes donated by 24 women. The aneuploidy rate was 48%. Considering two maternal age groups, a higher number of chromosome abnormalities were detected in the older group of oocytes (23% versus 75%, P < 0.02). About 33% of the 1PB-MII oocyte doublets diagnosed as aneuploid by CGH would have been misdiagnosed as normal if FISH with nine chromosome probes had been used. CONCLUSION: We demonstrate the reliability of 1PB analysis by CGH, to detect almost any chromosome abnormality in oocytes as well as unbalanced segregations of maternal translocations in a time frame compatible with regular in vitro fertilization (IVF). The selection of euploid oocytes could help to increase implantation and pregnancy rates of patients undergoing IVF treatment.     

人食管鳞癌细胞系EC9706的建立及其比较基因组杂交分析

目的 以中国男性食管鳞癌为来源，建立一个可良好传代的细胞系，从而提价七个有用的体外模式用于食管癌的研究。方法 采用组织块培养法，以新鲜的食管癌组织细胞系EC9706，做了初步的生物学特性观察，并采用比较基因组杂交的方法进行细胞遗传学的检测。结果 食管癌细胞系EC9706生长曲线显示其生长良好，易于培养。传代时间为26h，平皿集落形成率为91．9％，且能够在软琼脂中形成集落。经异种接种到裸鼠中均形成移植性肿瘤，肿瘤的病理诊断为中－低分化鳞状细胞癌。比较基因组杂交结果得出染色体1p1,q2-4,2p1,5p,7p14,7q21,11q1,11q2,20q扩增，其中5p表现出高水平的扩增。而染色体2p2,2q2,3p,4,9p,14,18,Xq缺失。结论 建立的细胞系EC9706可用于研究食管癌的癌变过程。     

Comparative genomic hybridization and karyotyping of human embryonic stem cells reveals the occurrence of an isodicentric X chromosome after long-term cultivation

Human embryonic stem (hES) cells are important research toolsin studies of the physiology of early tissue differentiation.In addition, prospects are high regarding the use of these cellsfor successful cell transplantation. However, one concern hasbeen that cultivation of these cells over many passages mightinduce chromosomal changes. It is thus important to investigatethese cell lines, and check that a normal chromosomal contentis retained even during long-term in vitro culture. Comparativegenomic hybridization (CGH) was used to analyse three hES celllines derived in our laboratory and cultured continuously for30–42 weeks, comprising 35–39 cell passages. CGHcould be successfully performed in 48 out of a total of 50 isolatedsingle cells (96%). All three lines (HS181, HS235 and HS237)were shown to have a normal chromosomal content when analysedby both single cell CGH and by karyotyping up to passages 39,39 and 35 respectively. No aneuploidies or larger deletionsor amplifications were detected, and they were female (46,XX).However, HS237 was reanalysed at passage 61, and at that pointan aberrant X chromosome was detected by karyotyping. The aberrationwas confirmed and characterized by single cell CGH and fluorescencein situ hybridization analysis, 46,X,idic(X)(q21). Thus, chromosomalaberrations may occur over time in stem cell lines, and continuousanalysis of these cells during cultivation is crucial. Singlecell CGH is a method that can be used for continuous analysisof the hES cell lines during cultivation, in order to detectchromosome imbalance.     

Identification and characterization of a de novo partial trisomy 10p by comparative genomic hybridization (CGH)

We report the characterization of a de novo unbalanced chromosome rearrangement by comparative genomic hybridization (CGH) in a 15-day-old child with hypotonia and dysmorphia. We describe the combined use of CGH and fluorescence in situ hybridization (FISH) to identify the origin of the additional chromosomal material on the short arm of chromosome 6. Investigation with FISH revealed that the excess material was not derived from chromosome 6. Identification of unknown unbalanced aberrations that could not be identified by traditional cytogenetics procedures is possible by CGH analysis. Visual analysis of digital images from CGH-metaphase spreads revealed a predominantly green signal on the telomeric region of chromosome 10p. After quantitative digital ratio imaging of 10 CGH-metaphase spreads, a region of gain was found in the chromosome band 10p14-pter. The CGH finding was confirmed by FISH analysis, using a whole chromosome 10 paint probe. These results show the usefulness of CGH for a rapid characterization of de novo unbalanced translocation, unidentifiable by karyotype alone.     

比较基因组杂交技术的应用

肿瘤发生和发育畸形与染色体的不平衡有关,包括染色体的扩增和缺失.常规的比较基因组杂交技术(conventional comparative genomic hybridization)由于能在一次试验中掌握整个基因组DNA拷贝数的变化并可以将此改变准确的定位于染色体,因而在探讨肿瘤的发生和生长发育畸形机理的研究方面得到了广泛的应用.在此基础上发展起来的微阵列比较基因组杂交技术(microarray CGH/ array-based CGH),为精确、定量地研究人类基因组微缺失和微扩增及其定位提供了有力工具.本文综述了CGH和CGHa 技术的原理及应用.     

用比较基因组杂交技术(CGH)检测肾癌染色体畸变

目的应用比较基因组杂交技术(CGH)分析原发性肾癌肿瘤组织中染色体异常变化,探讨肾癌细胞遗传物质的改变,揭示肾癌发生发展的内在本质及其与临床特征之间的关系。方法采用CGH技术对12例肾癌组织提取的全基因组DNA进行检测,以了解肾癌全基因组的变化。结果CGH技术检测的12例肾癌标本中均有染色体的畸变(扩增和/或缺失),常见的扩增区是1p、4p、5q、7p、9p、16p,常见的缺失区是3q、4q、6q、9q、14q、18q。结论原发性肾癌存在广泛的遗传物质不平衡现象,肾癌细胞染色体扩增和/或缺失可能是肾癌发生发展的基础。     

Microarray comparative genomic hybridization (CGH)-based prenatal diagnosis for chromosome abnormalities using cell-free fetal DNA in amniotic fluid

Cell-free fetal DNA (cffDNA) in the supernatant of amniotic fluid, which is usually discarded, can be used as a sample for prenatal diagnosis. For rapid prenatal diagnosis of frequent chromosome abnormalities, for example trisomies 13, 18, and 21, and monosomy X, using cffDNA, we have developed a targeted microarray-based comparative genomic hybridization (CGH) panel on which BAC clones from chromosomes 13, 18, 21, X, and Y were spotted. Microarray-CGH analysis was performed for a total of 13 fetuses with congenital anomalies using cffDNA from their uncultured amniotic fluid. Microarray CGH with cffDNA led to successful molecular karyotyping for 12 of 13 fetuses within 5 days. Karyotypes of the 12 fetuses (one case of trisomy 13, two of trisomy 18, two of trisomy 21, one of monosomy X, and six of normal karyotype) were later confirmed by conventional chromosome analysis using cultured amniocytes. The one fetus whose molecular-karyotype was indicated as normal by microarray CGH actually had a balanced translocation, 45,XY,der(14;21)(q10;q10). The results indicated that microarray CGH with cffDNA is a useful rapid prenatal diagnostic method at late gestation for chromosome abnormalities with copy-number changes, especially when combined with conventional karyotyping of cultured amniocytes.