Relationship between cytogenetic aberrations by CGH coupled with tissue microdissection and DNA ploidy by laser scanning cytometry in head and neck squamous cell carcinoma

Chromosome 20 aberrations at the diploid-aneuploid transition in sporadic colorectal cancer

DNA aneuploid sublines in sporadic colorectal cancers (CRCs) are quite frequent (about 85%) and likely the consequence of chromosomal instability and DNA copy number aberrations (CNAs). In order to gain insight into the mechanisms of the diploid-aneuploid transition in CRCs, we compared the CNA status in both diploid and aneuploid sublines. We used fresh/frozen material from 17 aneuploid CRCs, which was separated into 17 DNA diploid and 17 aneuploid sublines using enrichment of the epithelial component by multiparameter flow cytometry and sorting. CNA status of both sublines was obtained by array comparative genomic hybridization. The DNA diploid sublines from the aneuploid CRCs showed already CNAs, in particular, gains at 20 p and 20 q. The same aberrations were detected at increased frequencies in the corresponding DNA aneuploid sublines. Moreover, the very frequent gains/losses of chromosomes 4, 7, 8, 13, 15, and 18 in the DNA aneuploid sublines were absent or rare in the DNA diploid sublines from the same sporadic aneuploid CRCs. The comparison of the DNA diploid and aneuploid sublines from aneuploid CRCs suggests that 20 p and 20 q gains may play a role in the diploid-aneuploid transition. The 20 q chromosomal arm appears of particular interest since it harbors several genes implicated in chromosomal instability.

Laser scanning cytometry: principles and applications-an update

Laser scanning cytometer (LSC) is the microscope-based cytofluorometer that offers a plethora of unique analytical capabilities, not provided by flow cytometry (FCM). This review describes attributes of LSC and covers its numerous applications derived from plentitude of the parameters that can be measured. Among many LSC applications the following are emphasized: (a) assessment of chromatin condensation to identify mitotic, apoptotic cells, or senescent cells; (b) detection of nuclear or mitochondrial translocation of critical factors such as NF-κB, p53, or Bax; (c) semi-automatic scoring of micronuclei in mutagenicity assays; (d) analysis of fluorescence in situ hybridization (FISH) and use of the FISH analysis attribute to measure other punctuate fluorescence patterns such as γH2AX foci or receptor clustering; (e) enumeration and morphometry of nucleoli and other cell organelles; (f) analysis of progeny of individual cells in clonogenicity assay; (g) cell immunophenotyping; (h) imaging, visual examination, or sequential analysis using different probes of the same cells upon their relocation; (i) in situ enzyme kinetics, drug uptake, and other time-resolved processes; (j) analysis of tissue section architecture using fluorescent and chromogenic probes; (k) application for hypocellular samples (needle aspirate, spinal fluid, etc.); and (l) other clinical applications. Advantages and limitations of LSC are discussed and compared with FCM.

Comprehensive MicroRNA profiling for head and neck squamous cell carcinomas

PURPOSE

The objective of this study is to investigate the significance of microRNAs (miRNA) in patients with locally advanced head and neck squamous cell carcinoma (HNSCC).

EXPERIMENTAL DESIGN

A global miRNA profiling was done on 51 formalin-fixed archival HNSCC samples using quantitative reverse transcription-PCR approach, correlated with patients' clinical parameters. Functional characterization of HNSCC-associated miRNAs was conducted on three HNSCC cell lines. Cell viability and proliferation were investigated using MTS and clonogenic assays, respectively; cell cycle analyses were assessed using flow cytometry.

RESULTS

Thirty-eight of the 117 (33%) consistently detected miRNAs were significantly differentially expressed between malignant versus normal tissues. Concordant with previous reports, overexpression of miR-21, miR-155, let-7i, and miR-142-3p and underexpression of miR-125b and miR-375 were detected. Upregulation of miR-423, miR-106b, miR-20a, and miR-16 as well as downregulation of miR-10a were newly observed. Exogenous overexpression of miR-375 in HNSCC cell lines reduced proliferation and clonogenicity and increased cells in sub-G(1). Similar cellular effects were observed in knockdown studies of the miR-106b-25 cluster but with accumulation of cells in G(1) arrest. No major difference was detected in miRNA profiles among laryngeal, oropharyngeal, or hypopharyngeal cancers. miR-451 was found to be the only significantly overexpressed miRNA by 4.7-fold between nonrelapsed and relapsed patients.

CONCLUSION

We have identified a group of aberrantly expressed miRNAs in HNSCC and showed that underexpression of miR-375 and overexpression of miR-106b-25 cluster might play oncogenic roles in this disease. Further detailed examinations of miRNAs will provide opportunities to dissect the complex molecular abnormalities driving HNSCC progression.

Breast cancer cell lines carry cell line-specific genomic alterations that are distinct from aberrations in breast cancer tissues: comparison of the CGH profiles between cancer cell lines and primary cancer tissues

Background

Cell lines are commonly used in various kinds of biomedical research in the world. However, it remains uncertain whether genomic alterations existing in primary tumor tissues are represented in cell lines and whether cell lines carry cell line-specific genomic alterations. This study was performed to answer these questions.

Methods

Array-based comparative genomic hybridization (CGH) was employed with 4030 bacterial artificial chromosomes (BACs) that cover the genome at 1.0 megabase resolution to analyze DNA copy number aberrations (DCNAs) in 35 primary breast tumors and 24 breast cancer cell lines. DCNAs were compared between these two groups. A tissue microdissection technique was applied to primary tumor tissues to reduce the contamination of samples by normal tissue components.

Results

The average number of BAC clones with DCNAs was 1832 (45.3% of spotted clones) and 971 (24.9%) for cell lines and primary tumor tissues, respectively. Gains of 1q and 8q and losses of 8p, 11q, 16q and 17p were detected in >50% of primary cancer tissues. These aberrations were also frequently detected in cell lines. In addition to these alterations, the cell lines showed recurrent genomic alterations including gains of 5p14-15, 20q11 and 20q13 and losses of 4p13-p16, 18q12, 18q21, Xq21.1 and Xq26-q28 that were barely detected in tumor tissue specimens. These are considered to be cell line-specific DCNAs. The frequency of the HER2 amplification was high in both cell lines and tumor tissues, but it was statistically different between cell lines and primary tumors (P = 0.012); 41.3 ± 29.9% for the cell lines and 15.9 ± 18.6% for the tissue specimens.

Conclusions

Established cell lines carry cell lines-specific DCNAs together with recurrent aberrations detected in primary tumor tissues. It must therefore be emphasized that cell lines do not always represent the genotypes of parental tumor tissues.

The development of a mini-array for estimating the disease state of gastric adenocarcinoma by array CGH

BACKGROUND

The treatment strategy usually depends on the disease state in the individual patient. However, it is difficult to estimate the disease state before treatment in many patients. The purpose of this study was to develop a BAC (bacterial artificial chromosome) mini-array allowing for the estimation of node metastasis, liver metastasis, peritoneal dissemination and the depth of tumor invasion in gastric cancers.

METHODS

Initially, the DNA copy number aberrations (DCNAs) were analyzed by array-based comparative genomic hybridization (aCGH) in 83 gastric adenocarcinomas as a training-sample set. Next, two independent analytical methods were applied to the aCGH data to identify the BAC clones with DNA copy number aberrations that were linked with the disease states. One of the methods, a decision-tree model classifier, identified 6, 4, 4, 4, and 7 clones for estimating lymph node metastasis, liver metastasis, peritoneal dissemination, depth of tumor invasion, and histological type, respectively. In the other method, a clone-by-clone comparison of the frequency of the DNA copy number aberrations selected 26 clones to estimate the disease states.

RESULTS

By spotting these 50 clones together with 26 frequently or rarely involved clones and 62 reference clones, a mini-array was made to estimate the above parameters, and the diagnostic performance of the mini-array was evaluated for an independent set of 30 gastric cancers (blinded - sample set). In comparison to the clinicopathological features, the overall accuracy was 66.7% for node metastasis, 86.7% for liver metastasis, 86.7% for peritoneal dissemination, and 96.7% for depth of tumor invasion. The intratumoral heterogeneity barely affected the diagnostic performance of the mini-array.

CONCLUSION

These results suggest that the mini-array makes it possible to determine an optimal treatment for each of the patients with gastric adenocarcinoma.

Losses of 3p14 and 9p21 as shown by fluorescence in situ hybridization are early events in tumorigenesis of oral squamous cell carcinoma and already occur in simple keratosis

Tumorigenesis of oral squamous cell carcinoma (OSCC) has been postulated to represent a multistep process driven by the accumulation of carcinogen-induced genetic changes. Alterations of the 3p14 fragile site containing the fragile histidine triade gene and of the 9p21 tumor suppressor locus containing methylthioadenosine phosphorylase, p16 and p15 characteristically occur in oral leukoplakia, a known precursor of OSCC, and are at present considered to indicate the transition from simple keratosis (hyperplasia) to dysplasia. The aim of the study was to evaluate the occurrence of losses of 3p14 and 9p21 and to evaluate polysomies 3 and 9 in leukoplakias using highly sensitive fluorescence in situ hybridization (FISH) probes. Examining 67 leukoplakias (24 hyperplasias, 33 dysplasias, 10 in situ carcinomas), control tissues of oral mucosa from infants and adults as well as invasive carcinomas and normal epithelia of tumor patients with locus specific FISH probes targeting 3p14 and 9p21, and centromeric probes for chromosomes 3 and 9 we could demonstrate that losses of these sites appeared very early in the tumorigenesis of OSCC and were already present in the great majority of simple keratoses. Polysomy 3 occurring more frequently than polysomy 9 was characteristic of dysplasia and in situ carcinomas and thus seems to follow losses of 3p14 and 9p21 during oral squamous cell carcinogenesis.

DNA ploidy, proliferative capacity and intratumoral heterogeneity in primary and recurrent head and neck squamous cell carcinomas (HNSCC) – Potential implications for clinical management and treatment decisions

Despite new diagnostic and therapeutic strategies (combined radiochemotherapy, EGFR antibody Cetuximab), the prognosis of head and neck squamous cell carcinoma (HNSCC) is still poor and more information regarding prognosis is essential to establish earlier and better treatment options. To elucidate the role of DNA ploidy and cellular proliferation, resected tumors of 48 patients with primary or recurrent HNSCC were analyzed by flow cytometry and in vitro-5-bromodeoxyuridine incorporation (BrdU). The results were compared with histopathological findings such as tumor size, lymph node involvement and tumor differentiation. To assess the influence of intratumoral heterogeneity of these biological parameters, multiple biopsies (>3) were analyzed by flow cytometry and BrdU-incorporation in 12 larger (>4 cm diameter) tumors. BrdU-labeling index (LI%) was significantly higher in aneuploid HNSCC and correlated significantly with poor histologic differentiation of the analyzed tumor tissues (P<0.001). Furthermore, a trend for higher LI% in nodal positive tumors was observed. Aneuploid HNSCC showed significantly more often tissue dedifferentiation (P=0.049) and in most cases an advanced tumor stage, especially in tumors with biclonal cell lines. Lymph node involvement was also seen more often in aneuploid and undifferentiated tumors. As in aneuploid tumors recurrent HNSCC showed in most cases a higher LI% and poor tissue differentiation, but as a result of the small collection of samples there was no correlation between aneuploidy and tumor recurrence. To proof the robustness of the acquired data and to estimate the influence of intratumoral heterogeneity to ploidy and LI% multiple biopsies were analyzed in larger tumors. Using a specific statistical algorithm a secure estimation of ploidy and LI% was possible by a single biopsy in these tumors. These findings indicate aneuploidy and proliferative activity as important findings for malignant progression in HNSCC. An estimation of these biological parameters may be useful for identification of patients with high risk for lymph node involvement or tumor recurrence and pre-treatment can be performed by a single biopsy. As a conclusion, these patients may benefit from more aggressive treatment.

Molecular cytogenetic analysis of oral squamous cell carcinomas by comparative genomic hybridization, spectral karyotyping, and fluorescence in situ hybridization

We investigated relationships between DNA copy number aberrations and chromosomal structural rearrangements in 11 different cell lines derived from oral squamous cell carcinoma (OSCC) by comparative genomic hybridization (CGH), spectral karyotyping (SKY), and fluorescence in situ hybridization (FISH). CGH frequently showed recurrent chromosomal gains of 5p, 20q12, 8q23 approximately qter, 20p11 approximately p12, 7p15, 11p13 approximately p14, and 14q21, as well as losses of 4q, 18q, 4p11 approximately p15, 19p13, 8p21 approximately pter, and 16p11 approximately p12. SKY identified the following recurrent chromosomal abnormalities: i(5)(p10), i(5)(q10), i(8)(q10), der(X;1)(q10;p10), der(3;5)(p10;p10), and der(3;18)(q10;p10). In addition, breakpoints detected by SKY were clustered in 11q13 and around centromeric regions, including 5p10/q10, 3p10/q10, 8p10/q10 14q10, 1p10/1q10, and 16p10/16q10. Cell lines with i(5)(p10) and i(8)(q10) showed gains of the entire chromosome arms of 5p and 8q by CGH. Moreover, breakages near the centromeres of chromosomes 5 and 8 may be associated with 5p gain, 8q gain, and 8p loss in OSCC. FISH with a DNA probe from a BAC clone mapping to 5p15 showed a significant correlation between the average numbers of i(5)(p10) and 5p15 (R(2) = 0.8693, P< 0.01) in these cell lines, indicating that DNA copy number of 5p depends upon isochromosome formation in OSCC.

Laser scanning cytometry in human brain slices

BACKGROUND

The Laser Scanning Cytometry (LSC) offers quantitative fluorescence analysis of cell suspensions and tissue sections.

METHODS

We adapted this technique to immunohistochemical labelled human brain slices.

RESULTS

We were able to identify neurons according to their labelling and to display morphological structures such as the lamination of the entorhinal cortex. Further, we were able to distinguish between neurons with and without cyclin B1 expression and we could assign the expression of cyclin B1 to the cell islands of layer II and the pyramidal neurons of layer V of the entorhinal cortex in Alzheimer's disease effected brain. In addition, we developed a method depicting the three-dimensional distribution of the cells in intact tissue sections.

CONCLUSIONS

In this pilot experiments we could demonstrate the power of the LSC for the analysis of human brain sections.

Comparative genomic hybridization reveals genetic progression of oral squamous cell carcinoma from dysplasia via two different tumourigenic pathways

To clarify the genetic pathway(s) involved in the development and progression of oral squamous cell carcinoma (OSCC), as well as the relationship between genetic aberrations and biological characteristics of OSCC tumours, comparative genomic hybridization was used to analyse genetic alterations in both primary OSCCs and adjacent dysplastic lesions of the same biopsy specimens from 35 patients. Gain of 8q22-23 was the most frequent alteration in both OSCC and mild dysplasia, and was considered the earliest event in the process of oral tumourigenesis. The average number of DNA sequence copy number aberrations (DSCNAs) increased with progression from mild dysplasia to invasive carcinoma (r = 0.737, n = 70, p < 0.001). OSCC samples were classified as having a large or small number of DSCNAs (OSCC-L, 21.4 +/- 4.7 DSCNAs or OSCC-S, 10.0 +/- 1.7 DSCNAs, respectively; p < 0.0001). Gains of 3q26-qter, 8q, 11q13, 14q, and 20q and losses of 4q, 5q12-22, 6q, 8p, 13q, and 18q22-qter were common to OSCC-L and OSCC-S. Gains of 5p15, 7p, 17q11-22, and 18p and losses of 3p14-21, 4p, and 9p were detected exclusively in OSCC-L. The average number of DSCNAs depended on whether the samples showed OSCC- L or dysplasia plus OSCC-L, or showed OSCC-S or dysplasia plus OSCC-S (p = 0.001). Gain of 5p15 and losses of 4p and 9p were detected even in dysplastic lesions adjacent to OSCC-L samples. Loss of 4p was associated with node metastasis by multivariate analysis (p = 0.013). OSCC-L tumours were more often T3-T4 stage tumours than T1-T2 stage tumours (p = 0.03). These findings suggest that two different types of OSCC, OSCC-L associated with high-stage cancer and OSCC-S associated with low-stage cancer, arise from different types of dysplasia via different genetic pathways.

Laser scanning cytometry: principles and applications

The laser scanning cytometer (LSC) is the microscope-based cytofluorometer that offers a plethora of analytical capabilities. Multilaser-excited fluorescence emitted from individual cells is measured at several wavelength ranges, rapidly (up to 5000 cells/min), with high sensitivity and accuracy. The following applications of LSC are reviewed: (1) identification of cells that differ in degree of chromatin condensation (e.g., mitotic or apoptotic cells or lymphocytes vs granulocytes vs monocytes); (2) detection of translocation between cytoplasm vs nucleus or nucleoplasm vs nucleolus of regulatory molecules such as NF-kappaB, p53, or Bax; (3) semiautomatic scoring of micronuclei in mutagenicity assays; (4) analysis of fluorescence in situ hybridization; (5) enumeration and morphometry of nucleoli; (6) analysis of phenotype of progeny of individual cells in clonogenicity assay; (7) cell immunophenotyping; (8) visual examination, imaging, or sequential analysis of the cells measured earlier upon their relocation, using different probes; (9) in situ enzyme kinetics and other time-resolved processes; (10) analysis of tissue section architecture; (11) application for hypocellular samples (needle aspirate, spinal fluid, etc.); (12) other clinical applications. Advantages and limitations of LSC are discussed and compared with flow cytometry.

Identification of candidate genes associated with salivary adenoid cystic carcinomas using combined comparative genomic hybridization and oligonucleotide microarray analyses

Adenoid cystic carcinoma (ACC) of the salivary gland often has a variable clinical course with a poor prognosis. To investigate DNA copy number aberrations associated with ACCs, we compared comparative genome hybridization data from ACCs (n = 6) with other types of salivary gland tumors such as adenocarcinomas (n = 3) and pleomorphic adenomas (n = 6). While 15 gain loci (1q32, 6p25, 6q21-q24, 7q11.2, 7q31, 10q11.2, 11p12-q12, 12q13, 12q14, 13q24, 16p13.3-13.2, 18p11.3, 18q23, 19q13.4, and Xq28) were detected, no DNA loss locus was evident. To examine the expression status of genes on the ACC-associated loci, transcriptional measurements of approximately 38000 human genes then were monitored using Affymetrix U133 Plus 2.0 GeneChips. A total of 4431 genes were found differentially expressed by at least two-fold between ACCs and normal salivary glands. Of them, 3162 genes were up-regulated and 1269 genes were down-regulated in ACCs. After obtaining locus information about the RNA transcripts from the Affymetrix database, we found 262 ACC-associated genes with increased expression on ACC-associated loci. To investigate functional network and gene ontology, the 262 genes were analyzed using Ingenuity Pathway Analysis Tool. The function with the highest P value was a cancer-related function (P = 2.52e-4 to 4.71e-2). In addition, we identified pituitary tumor-transforming gene 1 and transformation related protein 63 genes that were up-regulated by increasing DNA copy number and modulated expression of oncogenes. These results suggested that the combination of copy number and gene expression profiling provides an improved strategy for gene identification in salivary gland ACCs.

Frequent deletion and down-regulation of ING4, a candidate tumor suppressor gene at 12p13, in head and neck squamous cell carcinomas

We previously showed two members of the ING family, ING1 and ING3 as a tumor suppressor gene in head and neck cancer. Progress in human genome sequencing provided additional information of the new members of the ING family genes. ING4 is localized to chromosome 12p13.31 region and harbors the PHD domain highly homologous among ING family proteins. We analyzed loss of heterozygosity at 12p12-13 region in 50 head and neck squamous cell carcinomas by using six highly polymorphic microsatellite markers and found allelic loss in 66% (33/50) of the informative cases. To clarify the role of ING4 in head and neck carcinogenesis, we first checked mutation status in tumor samples. As mutation of the ING4 gene was not found in head and neck cancers, we examined the mRNA expression level. Quantitative real-time RT-PCR analysis demonstrated decreased expression of ING4 mRNA in 76% of primary tumors as compared with that of matched normal samples. Since p53 dependent pathways of other ING family members have been shown, we examined p53 mutation status and compared with ING4 mRNA expression in tumor samples. However, no such direct relationship has been detected. In conclusion, frequent deletion and decreased mRNA expression of ING4 suggested it as a class two tumor suppressor gene and may play an important role in head and neck cancer.

Advanced molecular cytogenetics in human and mouse

Fluorescence in situ hybridization, spectral karyotyping, multiplex fluorescence in situ hybridization, comparative genomic hybridization, and more recently array comparative genomic hybridization, represent advancements in the field of molecular cytogenetics. The application of these techniques for the analysis of specimens from humans, or mouse models of human diseases, enables one to reliably identify and characterize complex chromosomal rearrangements resulting in alterations of the genome. As each of these techniques has advantages and limitations, a comprehensive analysis of cytogenetic aberrations can be accomplished through the utilization of a combination approach. As such, analyses of specific tumor types have proven invaluable in the identification of new tumor-specific chromosomal aberrations and imbalances (aneuploidy), as well as regions containing tumor-specific gene targets. Application of these techniques has already improved the classification of tumors into distinct categories, with the hope that this will lead to more tailored treatment strategies. These techniques, in particular the application of tumor-specific fluorescence in situ hybridization probes to interphase nuclei, are also powerful tools for the early identification of premalignant lesions.

Genomic gain of the epidermal growth factor receptor harboring band 7p12 is part of a complex pattern of genomic imbalances in oral squamous cell carcinomas

BACKGROUND

To determine the association between changes of genomic gene dose and clinical parameters in squamous cell carcinomas of the oral cavity, comparative genomic hybridization seemed suited not only to detect genomic imbalances in these tumors, but also particularly to examine the role of gain of 7p12, the band harboring the epidermal growth factor receptor (EGFR) in this context.

METHODS

Total genomic DNA obtained from 35 oral squamous cell carcinomas was subjected to comparative genomic hybridization (CGH) and detected patterns of genomic imbalances were associated with various clinical parameters.

RESULTS

The examined tumors exhibited five and up to 47 DNA copy number alterations (CNAs). Nineteen of these showed a gain of chromosome band 7p12. A highly complex but strikingly consistent pattern of genomic imbalances (average, 32 CNAs per tumor) was associated with this alteration, among which gains clearly dominated over losses of genomic material. Comparable patterns, however, could also be found in a few tumors with a high number of CNAs (average, 26) but without the 7p gain. Low numbers of imbalances always were accompanied by low consistency of CNA patterns and none of these cases showed enh(7p12). No significant differences with respect to pT class or grade of tumors were found between enh(7p)-positive and -negative tumors. Stage IV and lymph node affection were slightly more frequent among enh(7p12)-positive than in -negative cases. Relapse occurred in 63% in 7p12-positive vs. 25% in the negative group. Average disease-free survival of tumors without 7p gain clearly exceeded that of tumors with gain of 7p (36.8 vs. 21.3). However, some of these associations could also be found if comparison was based on number of CNAs. By means of hierarchical cluster analysis, we were able to show that different patterns of CNAs can be separated from each other in tumors with or without 7p alterations, and that these patterns predict short- or long-term survival of patients.

CONCLUSIONS

Previously described associations of gains of 7p12, the chromosomal band harboring the EGFR gene with clinical parameters can reasonably be estimated only within the context of the pattern and complexity of the genomic imbalances accompanying this chromosomal loss in examined tumors.

Laser scanning cytometry for the detection of neoplasia in urologic cytology specimens

BACKGROUND

The objective of the current pilot project was to assess the efficacy of laser scanning cytometry (LSC) for DNA ploidy analysis of atypical urologic cytology specimens to enhance the distinction between benign and malignant changes.

METHODS

Forty selected urologic cytology specimens that previously had been categorized as normal, atypical, or malignant were studied. Nuclear propidium iodide and fluorescence intensity measurements were converted to pixel values, which were used to create scattergrams that excluded debris and cell clusters from ploidy analysis, creating a gated (isolated) region of predominantly single cells for LSC ploidy analysis. Integral histograms then were created to show the number of cells present in diploid, tetraploid, and aneuploid peaks; these histograms also were used to assess DNA ploidy.

RESULTS

Ten normal specimens, 10 malignant specimens, and 20 atypical specimens were examined to assess the efficacy of LSC ploidy analysis. Normal and malignant specimens generated reference histograms for comparison with the atypical specimens and exhibited 90% specificity and 100% sensitivity. Ten atypical aneuploid specimens had histogram and scattergram patterns similar to those produced by malignant specimens and, using the cytometer's relocation feature, the presence of atypical cells was confirmed in the aneuploid regions.

CONCLUSIONS

The authors determined that DNA ploidy analysis of atypical urologic cytology specimens using LSC is a useful adjunct tool for identifying malignant specimens that lack sufficient cytologic criteria for diagnosis by light microscopy alone. However, LSC is time consuming and requires expensive equipment.

Loss of 9p21 is embedded in a complex but consistent pattern of genomic imbalances in oral squamous cell carcinomas

35 oral squamous cell carcinomas examined previously by comparative genomic hybridization (CGH) exhibited 5 up to 47 copy number alterations (CNAs). 13 of those cases showed a loss of parts of the short arm of chromosome 9, band p21 being affected in all of these cases. A highly complex but strikingly consistent pattern of genomic imbalances with an average 31.5 CNAs per tumor was associated with this deletion, and gains clearly dominated over losses of genomic material. Comparable patterns, however, could also be found in tumors with a high number of CNAs (24 CNAs) but without the deletion. Low numbers of imbalances were accompanied by low consistency of the CNA patterns. None of these latter cases showed the deletion 9p21. 66.7% of the dim(9p21)-positive tumors were of class pT4 (vs. 22% in dim(9p21)-negative cases), 77% of stage III or IV (vs. 47% in the group without the deletion), but only 8% of the dim(9p21)-positive tumors were classified as grade 3 (vs. 41% in the negative group). Other clinicopathologic features like prevalence of relapse, or survival time could not be as clearly associated with the deletion. For instance, short relapse-free survival was clearly associated with a high number of CNAs, rather independent of presence or absence of dim(9p21) in the affected tumor. From these findings it is concluded that previously found associations of 9p21 deletion with clinical parameters can reasonably be estimated only in the context of the pattern and complexity of the genomic imbalances accompanying this chromosomal loss in the examined tumors.

DNA gains at 8q23.2: a potential early marker in head and neck carcinomas

Gains or amplifications involving chromosome arm 8q are one of the most recurrent chromosomal alterations in head and neck tumors. To characterize previously reported gains, we performed fluorescence in situ hybridization (FISH) using the sequences BAC RP1179E1 and 8-centromere PMJ 128 as probes. Gains and/or amplifications were detected in all 19 cases evaluated by FISH. The FISH analysis, but not G-banding, revealed homogeneously staining region in three cases. We conclude that gains of one or more genes on chromosome arm 8q may be important for the early stages of head and neck carcinomas.

Detection of amplified oncogenes by genome DNA microarrays in human primary esophageal squamous cell carcinoma: comparison with conventional comparative genomic hybridization analysis

Oncogene amplification in 20 surgically resected esophageal squamous cell carcinomas (ESCC) was examined with DNA microarrays that detected 57 oncogenes and two reference DNA. Alterations in DNA copy numbers detected by microarrays were compared to those obtained by conventional comparative genomic hybridization (CGH). Amplification of eight oncogenes (CCND1, FGF3/FGF4, EMS1, SAS, ERBB2, PDGFRA, MYC, and BCL2) was detected by DNA microarrays in 9 of 20 tumors. Although ERBB2 was 23.2 times higher than the control level in one case, the average magnitude of gene amplification was approximately two to four times that of the control level. EMS1, CCND1, and FGF3/FGF4, which are all located on 11q13, were amplified in 7, 5, and 4 of 20 ESCC, respectively, and they were coamplified in 3 tumors. A comparison of genome DNA microarrays and CGH data revealed that although most amplified oncogenes were included in chromosomal regions for which DNA copy number gains were detected by conventional CGH, not all amplified genes on microarrays showed concomitant DNA copy number gains on CGH. In conclusion, microarrays of oncogenes are useful for the comprehensive identification of amplified oncogenes and for analysis of areas of specific amplification within chromosomal regions with DNA copy number increases detected by CGH analysis.

Molecular cytogenetic analysis of solid tumors

Molecular cytogenetic methods including fluorescence in situ hybridization (FISH) and comparative genomic hybridization (CGH) can be used for surgically removed solid tumors to obtain information valuable for both biomedical research and clinical oncology. FISH allows cytogenetic analysis even of cells in interphase. In addition, because CGH analysis permits comprehensive analysis of alterations in DNA copy number in a single experiment, it is possible to estimate not only the genetic pathways of carcinogenesis but also the biological characteristics, such as metastatic potential and patient prognosis at the time of diagnosing the solid tumor. The number of DNA copy number aberrations increases with tumor progression, leading to the concept of genetic staging of malignant tumors. Molecular cytogenetic analysis aids in realizing individualized, tailored medicine in cancer patients; therapeutic strategies are constructed for individual patients based on specific genetic alterations.

Detection of gene amplification and deletion in high-grade gliomas using a genome DNA microarray (GenoSensor Array 300)

Glioblastoma is a rapidly growing tumor that accounts for more than 50% of all primary gliomas. Amplification of oncogenes and deletion of tumor suppressor genes frequently affects tumor progression. Thus, the goal of this study was to conduct a comprehensive analysis of gene aberrations of individual glioblastomas. A genome DNA microarray (GenoSensor Array 300), spotted with 287 target genes, was used to analyze resected tissue from 11 different high-grade gliomas. The average number of gene aberrations was 9.0 per case (WHO grade III) and 13.3 per case (WHO grade IV). EGFR was the most frequent amplified gene in this series (4 of 11 cases), and high-level amplification was also detected for EGFR, SAS/CDK4, and AKT1. A high frequency of deleted genes was observed in 6 of 11 cases (54.5%), including FGFR2, MTAP, and DMBT1. The detected gene aberrations were matched to the classical primary glioblastoma pathway in five of nine cases. We conclude that the GenoSensor Array 300 genomic DNA microarray is a useful method for the comprehensive identification of amplified and deleted genes in glioblastoma.

Recurrent genetic alterations in 26 colorectal carcinomas and 21 adenomas from Chinese patients

Colorectal cancer (CRC) is one of the most common malignancies worldwide. The incidence of CRC in the Chinese population has increased dramatically during the last two decades; however, nonrandom chromosomal alterations in Chinese patients have not been described. In the present study, comparative genomic hybridization (CGH) was applied to detect recurrent chromosome alterations in 26 primary colorectal carcinomas and 21 colorectal adenomas from Chinese patients. In CRC, several recurrent chromosomal changes were found, including gains of 8q (14/26 cases, 54%), 20q (54%), 3q (50%), 13q (50%), 5p (46%), 7p (42%), 7q (42%), and 12p (38%) and losses of 18q (65%) and 17p (42%). From comparison with previous CGH studies, the frequent gains of 3q and 12p might be distinctive occurrences in Chinese patients. The distribution of frequently found chromosomal alterations in different locations was studied. The gain of 20q was more frequently found in colon cancer (P<0.01) and the gain of 12p was more frequently found in rectal cancer. Chromosomal alterations were found in 19/21 of adenomas; the most frequent chromosomal alteration was the loss of 18q (9/21 cases, 43%). These recurrent alterations provide several starting points for the isolation of candidate oncogenes and tumor suppressor genes.

Comparative genomic hybridization analysis detected frequent overrepresentation of chromosome 3q in squamous cell carcinoma of the lung

The aim of this study was to provide cytogenetic data about squamous cell carcinomas of the lung and to evaluate their characteristic alterations and histogenetic relations. We analyzed 41 squamous cell lung carcinomas by comparative genomic hybridization (CGH) technique. CGH was performed using directly fluorochrome-conjugated DNA. Chromosomal regions where the mean ratio fell below 0.75 were therefore considered to reflect DNA copy number loss (underrepresentation), whereas regions where the mean ratio exceeded 1.25 were considered gains (overrepresentations) in the tumor genome. Overrepresentations were considered to be high-level amplification when the fluorescence ratio exceeded 1.5. Chromosomal imbalances were observed in every case. Copy number gains frequently were detected at 3q, 5p, 8q, 12p, and Xq. Losses were found at 16p, 4q, 5q, 3p, 17p, and 16q. DNA amplifications were observed at 12 regions: 3q26.1-27, 8q13-23.1, 12p12.3-pter, 12q15, 2p14-16, 4q28-31.2, 5p13.1-pter, 6q21-22.3, 7p11.2-13, 13q21.2-32, 18p11.2-pter, and 20p11.2-pter. Gains on 3q were frequently detected not only in the more than 3 cm group (79%) but also in the 3 cm or less group (77%). The mean frequency of gained or lost chromosomal regions was 7.2+/-4.7 in the 3 cm or less group (n=13) and 10.2+/-6.3 in the more than 3 cm group (n=28) (P=0.4503). The mean frequency of gained or lost chromosomal regions was significantly higher in the carcinoma with lymph node metastasis group (12.5+/-7.6 regions) (n=12) than in the carcinoma without lymph node metastasis group (7.9+/-4.6) (n=29) (P=0.0251). In conclusion, an increased copy number at 3q may contribute to the development of squamous cell carcinoma of the lung.

Microdissection of histologic sections: past, present, and future

Histologic and cytologic changes are central to the diagnosis and classification of many disease processes, particularly neoplasms. The correlation of these changes with genomics, proteomics, and molecular pathways entails refined microdissection techniques that are frequently used to procure a pure population of cells from complex tissue. Here we review the past, present, and future of some of these new advances in microdissection techniques including manual techniques, laser microdissection, laser capture microdissection, and laser catapulting.

Detection of genetic alterations in pancreatic cancers by comparative genomic hybridization coupled with tissue microdissection and degenerate oligonucleotide primed polymerase chain reaction

The aim of this study was to elucidate cytogenetic changes in pancreatic cancers (PCs) and to examine their clinical implications. We screened for genetic alterations in 32 primary PCs including 4 cases with distant organ metastasis using comparative genomic hybridization coupled with tissue microdissection and degenerate oligonucleotide primed polymerase chain reaction (DOP-PCR). The present study revealed frequent gains of chromosomes 13q and 15q and a loss of Xq in addition to a high prevalence of chromosomal imbalances. The average number of total genetic alterations and gains tended to be higher in N1 tumors (TNM classification) than in N0 tumors. The average number of amplifications was significantly higher in M1 tumors than in M0 tumors (p = 0.024). Gain/amplification of 20q was more frequently observed in M1 tumors than in M0 tumors (p = 0.016), and this change was also detected in all of 4 distant metastatic lesions. Losses of 6q, 8p, 9p, 17p, and 18q were recurrent in N0 and M0 tumors, and these alterations were also retained in N1 and M1 tumors. These observations suggest that these genetic losses contribute to the development of PCs and that increases in the DNA copy number confer an aggressive character on cancer cells. Especially, gain/amplification of 20q was associated with the potential of distant organ metastasis of tumor cells.

Clinical applications of laser scanning cytometry

This study reviews existing and potential clinical applications of laser scanning cytometry (LSC) and outlines possible future developments. LSC provides a technology for solid phase cytometry. Fluorochrome-labeled specimens are immobilized on microscopic slides that are placed on a conventional epifluorescence microscope and analyzed by one or two lasers. Data comparable to flow cytometry are generated. In addition, the position of each event is recorded, a feature that allows relocalization and visualization of each measured event. The major advantage of LSC compared with other cytometric methods is the combination of two features: (a) the minimal clinical sample volume needed and (b) the connection of fluorescence data and morphological information for the measured event. Since the introduction of LSC, numerous methods have been established for the analysis of cells, cellular compartments, and tissues. Although most cytometric methods use only two or three colors, the characterization of specimens with up to five fluorochromes is possible. Most clinical applications have been designed to determine ploidy and immunophenotype; other applications include analyses of tissue biopsies and sections, fluorescence in situ hybridization, and the combination of vital and nonvital information on a single-cell basis. With the currently available assays, LSC has proven its wide spectrum of clinical applicability in slide-based cytometry and can be introduced as a standard technology in multiple clinical settings.

Compilation of published comparative genomic hybridization studies

The power of comparative genomic hybridization (CGH) has been clearly proven since the first paper appeared in 1992 as a tool to characterize chromosomal imbalances in neoplasias. This review summarizes the chromosomal imbalances detected by CGH in solid tumors and in hemopathies. In May of 2001, we took a census of 430 articles providing information on 11,984 cases of human solid tumors or hematologic malignancies. Comparative generic hybridization has detected a number of recurrent regions of amplification or deletion that allows for identification of new chromosomal loci (oncogenes, tumor suppressor genes, or other genes) involved in the development, progression, and clonal evolution of tumors. When CGH data from different studies are combined, a pattern of nonrandom genetic aberrations appears. As expected, some of these gains and losses are common to different types of pathologies, while others are more tumor-specific.

High telomerase activity correlates with the stabilities of genome and DNA ploidy in renal cell carcinoma

Malignant tumors have telomerase activity, which is thought to play a critical role in tumor growth. However, the relation between telomerase activity and genomic DNA status in tumor cells is poorly understood. In the present study, we examined telomerase activity in 13 clear cell type renal cell carcinomas (CRCCs) with similar clinicopathologic features by telomeric repeat amplification protocol assay (TRAP). Based on TRAP assay results, we divided the CRCCs into two groups: a high telomerase activity group and a low/no telomerase activity group. We then analyzed genomic aberration, DNA ploidy, and telomere status in these two groups by comparative genomic hybridization (CGH), laser scanning cytometry (LSC), and telomere-specific fluorescence in situ hybridization (T-FISH), respectively. CGH showed the high telomerase activity group to have fewer genomic changes than the low/no telomerase activity group, which had many genomic aberrations. Moreover, with LSC, DNA diploid cells were found more frequently in the high telomerase activity group than in the low/no telomerase activity group. In addition, T-FISH revealed strong telomere signal intensity in the high telomerase activity group compared with that of the low/no telomerase activity group. These results suggest that telomerase activity is linked to genomic DNA status and that high telomerase activity is associated with genomic stability, DNA ploidy, and telomere length in CRCC.

DNA sequence copy number aberrations associated with histological subtypes and DNA ploidy in gastric carcinoma

We have analyzed DNA sequence copy number aberrations (DSCNAs) and DNA ploidy by using comparative genomic hybridization and laser scanning cytometer in gastric carcinomas (GCs) to elucidate the genomic aberrations in relation to clinicopathological parameters. Thirty-two out of 33 cases showed one or more DSCNAs with a mean number of 11.7 per tumor. High-level gains were detected at 2p, 3q, 6p, 7p, 7q, 8q, 12p, 13q, 19q, and 20q. Frequency of gross genomic abnormalities and chromosome regions that have genomic aberrations were similar in both intestinal- and diffuse-type GCs, except aberrations at 8p, 9p, 12q, and 20q. The overall number of DSCNAs was significantly greater in DNA aneuploid tumors than that in DNA diploid tumors. We detected genomic aberrations characterized by histological subtype, tumor location, and DNA ploidy status: gain of 20q and losses of 8p and 9p in intestinal-type GCs, gains of 8p and 12q in diffuse-type GCs, gain of 20q in the lower third GCs, and loss of 5q, 9p, 10q, 16q, and 18q in DNA aneuploid GCs. Furthermore, 5q loss is associated with DNA aneuploidy (P = 0.0001) or the total number of losses (P = 0.001), gain + losses (P = 0.004), and high-level gains (P = 0.001) in GCs. Among these loci, chromosome 8p was unique. Gain of 8p was more common in diffuse-type GC, whereas loss of 8p was more frequently detected in intestinal-type GC. In conclusion, we describe chromosomal regions of 5q, 8p, and 20q, which are of interest for further investigation of GCs.

Comparative genomic hybridization analysis reveals 3q gain resulting in genetic alteration in 3q in advanced oral squamous cell carcinoma

We analyzed DNA sequence copy number aberrations (DSCNAs) in 17 primary oral squamous cell carcinomas (OSCCs) by comparative genomic hybridization. DSCNAs were detected frequently at 3q25-qter (7/17), Xp21 (5/17), and Xq12-q23 and 8q23-q24 (4/17), and losses were detected frequently at 13q21-q22 (5/17), 3p21-pter, 4p15-pter and 17p13 (4/17), and 8p22-pter and 9p21-pter (3/17). Four tumors showed amplifications of seven loci: 3q11-qter, 3q13, 3q26, 7q21-q22, 8q23-qter, 9p22-pter, and 12p11. The total number of DSCNAs was significantly greater in stage III and stage IV tumors than in stage I and stage II tumors (P=.008). Furthermore, 3q gain was detected preferentially in stage III and stage IV tumors (6/8) rather than in stage I and stage II tumors (1/9, P=.013). In our study, all tumors with gain of 3q also contained one or more loss(es) in common regions. On the other hand, all tumors with gain of 9p did not contain 3q gains. These observations indicate that gain of 3q and accumulation of DSCNAs are strongly associated with tumor progression in OSCC. Furthermore, 3q gain and loss of one or more additional loci in common aberration regions appears to be a group of DSCNs associated with dominant genetic pathways of leading to advanced OSCCs.