Comparative genomic hybridization reveals non-random chromosomal aberrations in early preinvasive cervical lesions.

We performed CGH analysis on 34 cervical lesions, which included 8 cases of koilocytosis, 6 mild dysplasias and 20 moderate dysplasias. Chromosome aberrations were detected in 11 cases of which 9 were moderate dysplasias. A total of 55 chromosome arms were involved. The most frequent aberrations were losses of 5p and Xq, each of which was present in 5/34 cases. Gain of 3q was detected in two moderate dysplasias. This aberration is the most frequent copy number change in advanced-stage cervical carcinoma. A considerable number of the aberrations found in the preinvasive cases of this study are frequently present in invasive cervical tumors. The presence of apparently non-random chromosome aberrations in early preinvasive cervical lesions has not previously been described.

High resolution comparative genomic hybridisation analysis reveals imbalances in dyschromosomal patients with normal or apparently balanced conventional karyotypes.

A sensitive technique is needed for screening whole genome imbalances in dyschromosomal patients when G-banding shows normal karyotypes or apparently balanced translocations. In this study we performed highly sensitive comparative genomic hybridisation analysis on a number of such cases and revealed chromosomal imbalances in all.

Deletions below 10 megabasepairs are detected in comparative genomic hybridization by standard reference intervals.

Comparative genomic hybridization (CGH) is a widely used technique for studying chromosomal imbalances. The sensitivity of the technique is, however, relatively low. Deletions down to a size of 10-12 Mbp have been detected by the use of fixed diagnostic thresholds. In this study, we applied standard reference intervals as detection criteria on a number of deletions in the range of 3 Mbp to 14-18 Mbp. All deletions were detected. Thus, detection by standard reference intervals confers a considerably higher sensitivity to CGH analysis compared to fixed diagnostic thresholds. Genes Chromosomes Cancer 25:410-413, 1999.

Comparative genomic hybridization reveals a recurrent pattern of chromosomal aberrations in severe dysplasia/carcinoma in situ of the cervix and in advanced-stage cervical carcinoma.

We analyzed 17 cases of dysplasia/carcinoma in situ (CIS) of the cervix and 29 advanced-stage cervical squamous cell carcinomas by comparative genomic hybridization (CGH). A comparable recurrent pattern of aberrations was detected in both preinvasive and invasive cases, although the total number of aberrations was much higher in the latter category. The most consistent chromosomal gain was mapped to chromosome arm 3q in 35% of preinvasive cases and in 72% of invasive cases. Chromosome aberrations were detected in 13/17 preinvasive cases with a total of 61 involved chromosome arms. In the invasive cases, frequent gains also occurred on 1q (45%), 8q (41%), 15q (41%), 5p (34%), and Xq (34%), and frequent losses were mapped to chromosome arms 3p (52%), 11q (48%), 13q (38%), 6q (38%), and 4p (34%). A recurrent pattern of aberrations has not previously been described in preinvasive lesions of the cervix. Our finding is surprising considering that only few preinvasive lesions are expected to progress to invasive cancer.

Improved sensitivity in comparative genomic hybridization analysis of DNA heteroploid cell mixtures after pre-enrichment of subpopulations by fluorescence activated cell sorting.

Cytogenetic analysis of solid tumors with comparative genomic hybridization (CGH) is hampered by the dilution of DNA from individual tumor subpopulations with DNA from other cells. We investigated to what extent this dilution effect can be alleviated using fluorescence activated cell sorting (flow sorting) of experimental DNA heteroploid cell mixtures prior to CGH. From mixtures of normal lymphocytes with triploid K-562 cells the individual components were sorted according to stemline DNA content and processed by CGH in comparison with pure K-562 samples and the original mixtures. Compared with 30 autosome copy number imbalances found in pure K-562 samples, a mixture with 32% K-562 cells showed 16 imbalances, and none were detected in mixtures with 13% or 5% K-562 cells. In contrast, 29, 22 and 23 imbalances were detected in K-562 nuclei sorted from the 32%, 13% and 5% mixtures, respectively. This indicate that CGH analysis of flow sorted DNA aneuploid subpopulations enables a specific cytogenetic analysis of the individual subclones in a DNA heteroploid cell population.

Detection of chromosomal gains and losses in comparative genomic hybridization analysis based on standard reference intervals.

Criteria for detection of chromosome aberrations by Comparative Genomic Hybridization (CGH) are not standardized and improvement of this part of the analysis is of paramount importance to the applicability of the technique. The aim of this work was to suggest CGH detection criteria that increase the specificity and sensitivity and at the same time include chromosome regions previously excluded from CGH analysis. We analyzed 33 hybridizations with normal DNA and modified our CGH software in order to use a selection of these normal analyses as a model for interpretation of analyses of unknown samples. This approach was successfully tested on 14 samples with known aberrations.

Detection of chromosomal aberrations in seminomatous germ cell tumours using comparative genomic hybridization.

Comparative genomic hybridization (CGH) was used to evaluate tissue specimens from 16 seminomas in order to elucidate the pathogenesis of germ cell tumours in males. A characteristic pattern of losses and gains within the entire genomes was detected in 94% of the seminomas by comparing the ratio profiles of the tumours with a standard of cytogenetically normal genomic DNA. Losses represented 43% of the total number of alterations often affecting chromosomes and chromosome arms 4, 5, 11, 13q, and 18q. Gains amounted to 57% and were often observed on 1q, 7, 8, 12, 14q, 15q, 21q, and 22q. Aberrations of 12p and 21q appeared most consistently. Results from CGH analysis displayed no relationship to the clinical stages of the malignancy. Some rare aberrations appeared, however, only in clinical stage II and in tumours showing relapse in the contralateral testis following orchiectomy, although the alterations were not present in all of the tumours in question. Losses of 16q13-21 and gains of 9q22.1-22.2 were demonstrated in both groups, while loss of 16p12 and gains of 6p21 and 6q23.3-24 were detected in the latter group as well. In conclusion, a specific pattern of chromosomal alterations was demonstrated in the seminomas by improved detection criteria, which increased specificity and sensitivity. The rare aberrations, which appeared only in tumours in improved detection criteria, which increased specificity and sensitivity. The rare aberrations, which appeared only in tumours in clinical stage II and relapsed tumours, may be linked to tumour progression, invasiveness, and bilateral disease.

Automatic correction of the interfering effect of unsuppressed interspersed repetitive sequences in comparative genomic hybridization analysis.

Comparative genomic hybridization (CGH) is a relatively new technique whose application is increasing. The method has mostly been employed for detection of chromosome aberrations in cancers, and a large amount of data in this field is accumulating. At the same time, efforts are made to improve the technique in order to increase the sensitivity and the generation of reliable results. Based on experimental data, we have developed a computer algorithm for eliminating some of the interfering effects of unsuppressed repetitive sequences in CGH analysis, and thereby improved our CGH analysis system.

Comparative genomic hybridization in clinical cytogenetics.

We report the results of applying comparative genomic hybridization (CGH) in a cytogenetic service laboratory for (1) determination of the origin of extra and missing chromosomal material in intricate cases of unbalanced aberrations and (2) detection of common prenatal numerical chromosome aberrations. A total of 11 fetal samples were analyzed. Seven cases of complex unbalanced aberrations that could not be identified reliably by conventional cytogenetics were successfully resolved by CGH analysis. CGH results were validated by using FISH with chromosome-specific probes. Four cases representing common prenatal numerical aberrations (trisomy 21, 18, and 13 and monosomy X) were also successfully diagnosed by CGH. We conclude that CGH is a powerful adjunct to traditional cytogenetic techniques that makes it possible to solve clinical cases of intricate unbalanced aberrations in a single hybridization. CGH may also be a useful adjunct to screen for euchromatic involvement in marker chromosomes. Further technical development may render CGH applicable for routine aberration screening.

Image analysis in comparative genomic hybridization.

Comparative genomic hybridization (CGH) is a new technique by which genomic imbalances can be detected by combining in situ suppression hybridization of whole genomic DNA and image analysis. We have developed software for rapid, quantitative CGH image analysis by a modification and extension of the standard software used for routine karyotyping of G-banded metaphase spreads in the Magiscan chromosome analysis system. The DAPI-counterstained metaphase spread is karyotyped interactively. Corrections for image shifts between the DAPI, FITC, and TRITC images are done manually by moving the three images relative to each other. The fluorescence background is subtracted. A mean filter is applied to smooth the FITC and TRITC images before the fluorescence ratio between the individual FITC- and TRITC-stained chromosomes is computed pixel by pixel inside the area of the chromosomes determined by the DAPI boundaries. Fluorescence intensity ratio profiles are generated, and peaks and valleys indicating possible gains and losses of test DNA are marked if they exceed ratios below 0.75 and above 1.25. By combining the analysis of several metaphase spreads, consistent findings of gains and losses in all or almost all spreads indicate chromosomal imbalance. Chromosomal imbalances are detected either by visual inspection of fluorescence ratio (FR) profiles or by a statistical approach that compares FR measurements of the individual case with measurements of normal chromosomes. The complete analysis of one metaphase can be carried out in approximately 10 minutes.

Metaphase quality can be monitored by automatic counting of bands.

A high quality of cytogenetic preparations is important for maintaining a high standard in the cytogenetic laboratory. In the past, quality has been assessed by visual counting or estimation of the number of bands on chromosomes. In this paper we have counted bands automatically during karyotyping by using the Magiscan chromosome analysis system. A high correlation between automatic and visual counting was found, the automatic counting was reproducible and count figures were comparable when the karyotyping machines were operated by different technicians. The automatic counting procedure has now been included in our routine for 1 year. The highest numbers of bands were counted on slides from peripheral blood, with fewer bands for amniotic fluid and the lowest number for cells from chorionic villi. All three cell types showed significant variations in band number over time, which may be due to changes in weather conditions and/or the reagents used for cell culture, harvest and staining. It is concluded that the automatic counting procedure may be used to monitor the quality of metaphases over time and to set limits for band number on routine preparations acceptable for analysis.

Automatic assessment of the quality of G-banded metaphases. A preliminary study.

Assessment of the quality of cytogenetic preparations is important for 1) a general quality control of the cytogenetic laboratory and 2) for determining the quality of individual cytogenetic analyses. It is generally accepted that good preparations allow a more detailed search for structural abnormalities than poor preparations. As part of a comprehensive study on automated assessment of slide quality we have developed a simple algorithm for automated measurement of metaphase resolution. During semi-automated karyotyping with the Magiscan chromosome analysis system (Joyce-Loebl) three measurements related to resolution are automatically extracted 1) the total number of dark bands of the chromosomes of the metaphase (TB), 2) the normalized average length of the chromosomes (NL), and 3) the average "thickness" of the chromosomes (T). The algorithm TB x NL/T has been tested on 35 metaphases of various quality and compared with visual assessment of the same 35 metaphases. The results indicate that the automatic assessment of metaphase resolution is superior to the visual.

Automated multiple-cell karyotyping: a clinical feasibility study.

In order to increase the efficiency of the Magiscan metaphase location and karyotyping system, its software and mode of operation have been changed. In the new multiple-cell karyotyping method, interactions by the operator are only required for relocation and counting of metaphases, but not for karyotyping. Metaphases are located and their coordinates recorded automatically as before. The first metaphase in the list is relocated, displayed on the screen, and counted by the operator. It is then karyotyped automatically while the operator relocates and counts the next metaphase in the list. This procedure continues until an appropriate number of metaphases have been counted and karyotyped. Finally a composite karyotype is printed out. Each karyotype is represented by a column of 23 chromosome pairs (1-22 and XX or XY) and all columns are lined up next to each other. Most chromosomes are correctly classified into the composite karyotype. Minor structural abnormalities are detected by comparing pairs of homologues. Overlapped, close touching, and grossly abnormal chromosomes are often misclassified or rejected and shown beneath the classified chromosomes. A trained cytotechnician can easily detect even small chromosome abnormalities on the composite karyotype. A clinical feasibility study indicates that the procedure can be used for routine cytogenetic analysis.

Clinical performance of a system for semiautomated chromosome analysis.

Until recently equipment for automated chromosome analysis has not been used for routine purposes in clinical cytogenetic laboratories. During a 3 1/2-year period the chromosome laboratory of Rigshospitalet has tested the Magiscan chromosome system under routine conditions and performed the first evaluation of its clinical performance. The system consists of an image processor with a light pen for manual interaction connected to a hard-copy printer and a microscope with a TV camera and a motorized scanning stage for eight slides. Automated metaphase finding takes place without operator assistance. An operator is involved in the analysis after the metaphases are located. Using two of these complete systems, we have performed a total of 4,691 chromosome analyses comprising a count of 10 metaphases, of which three were "eyeball" karyotyped and one was "machine" karyotyped. Presently, two-thirds of our prenatal analyses (amniotic-cell cultures) are carried out with these two machines. A third Magiscan system without scanning stage is used as a "karyotyping-only" system to produce hard-copy karyograms in those cases in which metaphases are manually located and counted in the microscope. Since the end of 1984, 4,773 additional machine karyograms have been produced with this system. With a complete system, a prenatal analysis can be carried out in an average of 35 min. The average time for a machine karyotype is 7 min. Since 1984 the productivity of the laboratory has increased 17%-20% without enlarging the staff.

Automatic classification of chromosomes as part of a routine system for clinical analysis.

A procedure for automatic classification of G-banded human chromosomes has been implemented on a semiautomated system for routine clinical analysis. Chromosomes represented by their density profiles are described by so-called weighted density distributions (WDDs) by application of a number of weighting functions and classified by a parametric discriminant analysis. During 16 mo of routine use of the system, 2,794 metaphases (127,925 chromosomes) from amniotic fluid have been karyotyped by the system with an error rate of 8-9%. This corresponds to 4-5 errors per metaphase. These errors can immediately be corrected by the operator on a displayed karyogram with a light pen.