Ritva Karhu

Molecular cytogenetics of primary breast cancer by CGH

Comparative genomic hybridization (CGH) reveals DNA sequence copy number changes that are shared among the different cell subpopulations present in a tumor and may help to delineate the average progression pathways of breast cancer. Previous CGH studies of breast cancer have concentrated on selected subgroups of breast cancer. Here, 55 unselected primary breast carcinomas were analyzed using optimized quality‐controlled CGH procedures. Gains of 1q (67%) and 8q (49%) were the most frequent aberrations. Other recurrent gains were found at 33 chromosomal regions, with 16p, 5p12–14, 19q, 11q13–14, 17q12, 17q22–24, 19p, and 20q13 being most often (>18%) involved. Losses found in >18% of the tumors involved 8p, 16q, 13q, 17p, 9p, Xq, 6q, 11q, and 18q. The total number of aberrations per tumor was highest in poorly differentiated (P = 0.01) and in DNA aneuploid (P = 0.05) tumors. The high frequency of 1q gains and presence of +1q as the sole abnormality suggest that it is an early genetic event. In contrast, gains of 8q were most common in genetically and phenotypically advanced breast cancers. The vast majority of breast cancers (80%) have gains of 1q, 8q, or both, and 3 changes (+1q, +8q, or −13q) account for 91% of the tumors. In conclusion, CGH results indicate that certain chromosomal imbalances are very often selected for, sometimes in a preferential order, during the progression of breast cancer. Further studies of such common changes may form the basis for a molecular cytogenetic classification of breast cancer. Genes Chromosomes Cancer 21:177–184, 1998.

Genome screening by comparative genomic hybridization

Comparative genomic hybridization (CGH) provides a molecular cytogenetic approach for genome-wide scanning of differences in DNA sequence copy number. The technique is now attracting wide-spread interest, especially among cancer researchers. The rapidly expanding database of CGH publications already covers about 1500 tumors and is beginning to reveal genetic abnormalities that are characteristic of certain tumor types or stages of tumor progression. Six novel gene amplifications, as well as a locus for a cancer-predisposition syndrome, have been discovered based on CGH data. CGH has now been established as a first-line screening technique for cancer researchers and will serve as a basis for ongoing efforts to develop high-resolution next-generation genome scanning, such as the microarray technology.

Optimizing DOP‐PCR for universal amplification of small DNA samples in comparative genomic hybridization

The standard comparative genomic hybridization (CGH) protocol relies on availability of macroscopic tumor samples, which do not contain too much interfering normal cells. Recently, CGH after universal amplification of genomic DNA with degenerate oligonucleotide primed PCR (DOP‐PCR) has been used to detect genetic aberrations in microdissected tumor specimens. However, owing to the technical difficulties, CGH results of only few microdissected samples have so far been published. We have developed an improved protocol for DOP‐PCR, which includes direct incorporation of fluorochrome‐conjugated nucleotides into the PCR product. Among the four polymerase enzymes tested, ThermoSequenase gave the best yield, with PCR products ranging from 100–4,000 bp. A two‐step PCR‐procedure was used, consisting of a preamplification with low stringency conditions followed by amplification in more stringent conditions. The method was first validated by hybridizing DOP‐PCR‐amplified normal DNA against nick‐translated reference DNA, which showed uniform and even hybridization result for all chromosomes. Comparison of DOP‐PCR CGH to conventional CGH in MCF‐7 breast cancer cell line further indicated that genetic aberrations can be reliably detected after DOP‐PCR amplification. The sensitivity of the DOP‐PCR‐CGH was tested by serial dilution of MCF‐7 DNA. Fifty picograms of sample DNA (corresponding roughly to two MCF‐7 cells) was sufficient for high quality CGH. Experiments with cells microdissected from intraductal breast cancer demonstrated that carcinoma cells from 1 to 2 ducts were sufficient for a successful DOP‐PCR CGH analysis. We conclude that the improved DOP‐PCR‐CGH protocol provides a powerful tool to study genetic aberrations in different histological subpopulations of malignant as well as precancerous lesions. DOP‐PCR also improves the success rate of conventional paraffin‐block CGH, because a poor quality or a too low yield of extracted DNA can be compensated by universal DNA amplification by DOP‐PCR. Genes Chromosom. Cancer 18:94–101, 1997.

Frequent amplification of 8q24, 11q, 17q, and 20q-specific genes in pancreatic cancer

Genetic changes involved in the development and progression of pancreatic cancer are still partly unknown, despite the progress in recent years. In this study, comparative genomic hybridization analysis in 31 pancreatic cancer cell lines showed that chromosome arms 8q, 11q, 17q, and 20q are frequently gained in this tumor type. Copy number analysis of selected genes from these chromosome arms by fluorescence in situ hybridization showed amplification of the MYC oncogene in 54% of the cell lines, whereas CCND1 was amplified in 28%. In the 17q arm, the ERBB2 oncogene was amplified in 20% of the cell lines, TBX2 in 50%, and BIRC5 in 58%, indicating increased involvement toward the q telomere of chromosome 17. In the 20q arm, the amplification frequencies varied from 32% to 83%, with the CTSZ gene at 20q13 being most frequently affected. These results illustrate that amplification of genes from the 8q, 11q, 17q, and 20q chromosome arms is common in pancreatic cancer.

High-resolution analysis of gene copy number alterations in human prostate cancer using CGH on cDNA microarrays: impact of copy number on gene expression.

Identification of target genes for genetic rearrangements in prostate cancer and the impact of copy number changes on gene expression are currently not well understood. Here, we applied high-resolution comparative genomic hybridization (CGH) on cDNA microarrays for analysis of prostate cancer cell lines. CGH microarrays identified most of the alterations detected by classic chromosomal CGH, as well as a number of previously unreported alterations. Specific recurrent regions of gain (28) and loss (18) were found, and their boundaries defined with sub-megabasepair accuracy. The most common changes included copy number decreases at 13q, and gains at 1q and 5p. Refined mapping identified several sites, such as at 13q (33-44, 49-51, and 74-76 Mbp from the p-telomere), which matched with minimal regions of loss seen in extensive loss of heterozygosity mapping studies of large numbers of tumors. Previously unreported recurrent changes were found at 2p, 2q, 3p, and 17q (losses), and at 3q, 5p, and 6p (gains). Integration of genomic and transcriptomic data revealed the role of individual candidate target genes for genomic alterations as well as a highly significant (P <.0001) overall association between copy number levels and the percentage of differentially expressed genes. Across the genome, the overall impact of copy number on gene expression levels was, to a large extent, attributable to low-level gains and losses of copy number, corresponding to common deletions and gains of often large chromosomal regions.

Comparative genomic hybridization reveals frequent gains of 20q, 8q, 11q, 12p, and 17q, and losses of 18q, 9p, and 15q in pancreatic cancer

Comparative genomic hybridization (CGH) was used to screen for genomic imbalances in 24 exocrine pancreatic carcinomas, including 11 low‐passage cell lines (4–8 subcultures) and 13 uncultured samples. Aberrations were found in all cell lines and in seven of the 13 biopsies. The most frequent changes in the cell lines were gains of 20q (91%), 11q (64%), 17q (64%), 19q (64%), 8q, 12p, 14q, and 20p (55%), and losses of 18q (100%), 9p (91%), 15q (73%), 21q (64%), 3p (55%), and 13q (55%). High‐level gains (tumor to normal ratio over 1.5) were detected at 3q, 6p, 7q, 8q, 12p, 19q, and 20q. Among the tumor biopsies, overrepresentations of 7p and 8q were most common (31%), followed by 5p, 5q, 11p, 11q, 12p, and 18q (23%), whereas the most frequent losses involved 18p and 18q (31%) and 6q and 17p (23%). The genetic changes in nine samples obtained from metastatic lesions did not differ significantly from those in 15 primary carcinomas. Most of the gains and losses detected in this CGH study correspond well to those identified in previous cytogenetic and molecular genetic investigations of pancreatic carcinomas. However, frequent gain of 12p and loss of 15q have not been previously reported. Molecular genetic analyses of these chromosome arms are warranted, and may lead to the discovery of novel genes important in pancreatic carcinogenesis. Genes Chromosomes Cancer 20:383–391, 1997.

Chromosomal Alterations in 15 Breast Cancer Cell Lines by Comparative Genomic Hybridization and Spectral Karyotyping

Breast cancer cell lines have been widely used as models in functional and therapeutical studies, but their chromosomal alterations are not well known. We characterized the chromosomal aberrations in 15 commonly used human breast carcinoma cell lines (BT‐474, BT‐549, CAMA‐1, DU4475, MCF7, MDA‐MB‐134, MDA‐MB‐157, MDA‐MB‐361, MDA‐MB‐436, MPE600, SK‐BR‐3, T‐47D, UACC‐812, UACC‐893, and ZR‐75‐1) by comparative genomic hybridization (CGH) and spectral karyotyping (SKY). By CGH the most frequent gains were detected at 1q, 8q, 20q, 7, 11q13, 17q, 9q, and 16p, whereas losses were most common at 8p, 11q14–qter, 18q, and Xq. SKY revealed a multitude of structural and numerical chromosomal aberrations. Simple translocations, typically consisting of entire translocated chromosome arms, were the most common structural aberrations. Complex marker chromosomes included material from up to seven different chromosomes. Evidence for a cytogenetic aberration not previously described in breast cancer, the isoderivative chromosome, was found in two cell lines. Translocations t(8;11), t(12;16), t(1;16), and t(15;17) were frequently found, although the resulting derivative chromosomes and their breakpoints were strikingly dissimilar. The chromosomes most frequently involved in translocations were 8, 1, 17, 16, and 20. An excellent correlation was found between the number of translocation events found by SKY in the individual cell lines, and the copy number gains and losses detected by CGH, indicating that the majority of translocations are unbalanced. Genes Chromosomes Cancer 28:308–317, 2000.

Comparative Genomic Hybridization Reveals Frequent Losses of Chromosomes 1p and 3q in Pheochromocytomas and Abdominal Paragangliomas, Suggesting a Common Genetic Etiology

Pheochromocytomas and abdominal paragangliomas are rare, catecholamine-producing tumors that arise from the chromaffin cells derived from the neural crest. We used comparative genomic hybridization (CGH) to screen for copy number changes in 23 pheochromocytomas and 11 abdominal paragangliomas. The pattern of copy number changes was similar between pheochromocytomas and paragangliomas, with the most consistent finding being loss of 1cen-p31, which was detected in 28/34 tumors (82%). Losses were also found on 3q22-25 (41%), 11p (26%), 3p13-14 (24%), 4q (21%), 2q (15%), and 11q22-23 (15%), and gains were detected on 19p (26%), 19q (24%), 17q24-qter (21%), 11cen-q13 (15%), and 16p (15%). Losses of 1p and 3q were detected in the majority of tumors, whereas gains of 19p and q, 17q, and 16p were seen only in tumors with six or more CGH alterations. This progression of genetic events did not correspond with the conversion to a malignant phenotype. CGH alterations involving chromosome 11 were more frequent in the malignant tumors, compared with the benign tumors (9/12 versus 3/16). In summary, we propose that pheochromocytomas and abdominal paragangliomas, which share many clinical features, also have a common genetic origin and that the loss of 1cen-p31 represents an early and important event in tumor development.

A comprehensive expression survey of bone morphogenetic proteins in breast cancer highlights the importance of BMP4 and BMP7

Bone morphogenetic proteins (BMPs) regulate diverse cellular processes, such as proliferation, differentiation, and apoptosis. The BMPs have been studied in several cancers, but thus far contradictory results have been obtained and, especially in breast cancer, information on BMPs is still limited. We performed a systematic expression survey of BMPs and their receptors in breast cancer. mRNA expression was studied of seven BMP ligands (BMP2-BMP8) and six receptors (ACVR1, BMPR1A, BMPR1B, BMPR2, ACVR2A, and ACVR2B) that specifically mediate BMP signals. Expression levels were determined in 22 breast cancer cell lines, 39 primary breast tumors, normal human mammary epithelial cell line, and normal mammary gland using semiquantitative RT-PCR. The expression frequencies and expression levels of different BMPs varied considerably in breast cancer with BMP4 and BMP7 being most frequently expressed and showing highest expression levels. The BMP specific receptors were more uniformly expressed and indicated that breast cancer is fully capable of transmitting BMP signals. Expression frequencies and levels for both the ligands and the receptors were in good concordance between the breast cancer cell lines and primary tumors. We can conclude that breast cancers possess functional BMP signaling machinery on the cell surface with distinct differences in the expression of various BMP ligands. Our survey focuses the attention particularly toward BMP4 and BMP7 and suggests their importance in breast cancer. Breast cancer cell lines and the data generated here serve as a good resource for further studies on BMP function in breast cancer.

Primary Cutaneous T-Cell Lymphomas Show a Deletion or Translocation Affecting NAV3, the Human UNC-53 Homologue

Multicolor fluorescent in situ hybridization (FISH) was used to identify acquired chromosomal aberrations in 12 patients with mycosis fungoides or Sézary syndrome, the most common forms of primary cutaneous T-cell lymphoma (CTCL). The most frequently affected chromosome was 12, which showed clonal deletions or translocations with a break point in 12q21 or 12q22 in five of seven consecutive Sézary syndrome patients and a clonal monosomy in the sixth patient. The break point of a balanced translocation t(12;18)(q21;q21.2), mapped in the minimal common region of two deletions, fine mapped to 12q2. By locus-specific FISH, the translocation disrupted one gene, NAV3 (POMFIL1), a human homologue of unc-53 in Caenorhabditis elegans. A missense mutation in the remaining NAV3 allele was found in one of six cases with a deletion or translocation. With locus-specific FISH, NAV3 deletions were found in the skin lesions of four of eight (50%) patients with early mycosis fungoides (stages IA-IIA) and in the skin or lymph node of 11 of 13 (85%) patients with advanced mycosis fungoides or Sézary syndrome. Preliminary functional studies with lentiviral small interfering RNA-based NAV3 silencing in Jurkat cells and in primary lymphocytes showed enhanced interleukin 2 expression (but not CD25 expression). Thus, NAV3 may contribute to the growth, differentiation, and apoptosis of CTCL cells as well as to the skewing from Th1-type to Th2-type phenotype during disease progression. NAV3, a novel putative haploinsufficient tumor suppressor gene, is disrupted in most cases of the commonest types of CTCL and may thus provide a new diagnostic tool.