Sandy DeVries

Breast tumor copy number aberration phenotypes and genomic instability

BackgroundGenomic DNA copy number aberrations are frequent in solid tumors, although the underlying causes of chromosomal instability in tumors remain obscure. Genes likely to have genomic instability phenotypes when mutated (e.g. those involved in mitosis, replication, repair, and telomeres) are rarely mutated in chromosomally unstable sporadic tumors, even though such mutations are associated with some heritable cancer prone syndromes.MethodsWe applied array comparative genomic hybridization (CGH) to the analysis of breast tumors. The variation in the levels of genomic instability amongst tumors prompted us to investigate whether alterations in processes/genes involved in maintenance and/or manipulation of the genome were associated with particular types of genomic instability.ResultsWe discriminated three breast tumor subtypes based on genomic DNA copy number alterations. The subtypes varied with respect to level of genomic instability. We find that shorter telomeres and altered telomere related gene expression are associated with amplification, implicating telomere attrition as a promoter of this type of aberration in breast cancer. On the other hand, the numbers of chromosomal alterations, particularly low level changes, are associated with altered expression of genes in other functional classes (mitosis, cell cycle, DNA replication and repair). Further, although loss of function instability phenotypes have been demonstrated for many of the genes in model systems, we observed enhanced expression of most genes in tumors, indicating that over expression, rather than deficiency underlies instability.ConclusionMany of the genes associated with higher frequency of copy number aberrations are direct targets of E2F, supporting the hypothesis that deregulation of the Rb pathway is a major contributor to chromosomal instability in breast tumors. These observations are consistent with failure to find mutations in sporadic tumors in genes that have roles in maintenance or manipulation of the genome.

Bladder Cancer Outcome and Subtype Classification by Gene Expression

Models of bladder tumor progression have suggested that genetic alterations may determine both phenotype and clinical course. We have applied expression microarray analysis to a divergent set of bladder tumors to further elucidate the course of disease progression and to classify tumors into more homogeneous and clinically relevant subgroups. cDNA microarrays containing 10,368 human gene elements were used to characterize the global gene expression patterns in 80 bladder tumors, 9 bladder cancer cell lines, and 3 normal bladder samples. Robust statistical approaches accounting for the multiple testing problem were used to identify differentially expressed genes. Unsupervised hierarchical clustering successfully separated the samples into two subgroups containing superficial (pTa and pT1) versus muscle-invasive (pT2-pT4) tumors. Supervised classification had a 90.5% success rate separating superficial from muscle-invasive tumors based on a limited subset of genes. Tumors could also be classified into transitional versus squamous subtypes (89% success rate) and good versus bad prognosis (78% success rate). The performance of our stage classifiers was confirmed in silico using data from an independent tumor set. Validation of differential expression was done using immunohistochemistry on tissue microarrays for cathepsin E, cyclin A2, and parathyroid hormone–related protein. Genes driving the separation between tumor subsets may prove to be important biomarkers for bladder cancer development and progression and eventually candidates for therapeutic targeting.

Genetic alterations in primary breast cancers and their metastases: direct comparison using modified comparative genomic hybridization.

Breast tumor development and progression are thought to be driven by an accumulation of genetic alterations, but little is known about the specific changes that occur during the metastatic process. We analyzed pairs of primary breast cancers and their matched lymph node metastases from 11 patients, pairs of primaries and distant metastases from three patients, and pairs of primaries, and local recurrences from two patients by using comparative genomic hybridization (CGH). Simultaneous hybridization analysis of primary versus matched lesion DNAs from 11 patients was also performed (modified CGH). This modified approach was useful not only for confirming CGH results but also for demonstrating quantitative differences between aberrations present at both sites. Frequent chromosomal changes present at both sites (>35% of 16 cases) were 1q, 8q, and 17q gains and 6q, 8p, 9q, 13q, 16q, 17p, and Xp losses. The total number of aberrations detected exclusively in the lymph nodes or distant metastases was higher than that in the primary tumors (2.5 vs. 0.7, P< 0.05). We found high‐level amplifications in four metastases (two lymph nodes and two distant metastases), but none in any primary tumor. These findings suggest that progression from primary breast cancer to metastasis may be associated with the acquisition of further genetic changes. Although further investigations are required, it was of interest that 3 of 11 patients (27%) showed 18q loss solely in their lymph node metastases. Genes Chromosom. Cancer 19:267–272, 1997.

Clonality of lobular carcinoma in situ and synchronous invasive lobular carcinoma

Lobular carcinoma in situ (LCIS) of the breast is considered a marker for an increased risk of carcinoma in both breasts. However, the frequent association of LCIS with invasive lobular carcinoma (ILC) suggests a precursor‐product relation. The possible genomic relation between synchronous LCIS and ILC was analyzed using the technique of array‐based comparative genomic hybridization (CGH).

Bladder cancer stage and outcome by array-based comparative genomic hybridization.

Purpose: Bladder carcinogenesis is believed to follow alternative pathways of disease progression driven by an accumulation of genetic alterations. The purpose of this study was to evaluate associations between measures of genomic instability and bladder cancer clinical phenotype. Experimental Design: Genome-wide copy number profiles were obtained for 98 bladder tumors of diverse stages (29 pTa, 14 pT1, 55 pT2-4) and grades (21 low-grade and 8 high-grade superficial tumors) by array-based comparative genomic hybridization (CGH). Each array contained 2,464 bacterial artificial chromosome and P1 clones, providing an average resolution of 1.5 Mb across the genome. A total of 54 muscle-invasive cases had follow-up information available. Overall outcome analysis was done for patients with muscle-invasive tumors having “good” (alive >2 years) versus “bad” (dead in <2 years) prognosis. Results: Array CGH analysis showed significant increases in copy number alterations and genomic instability with increasing stage and with outcome. The fraction of genome altered (FGA) was significantly different between tumors of different stages (pTa versus pT1, P = 0.0003; pTa versus pT2-4, P = 0.02; and pT1 versus pT2-4, P = 0.03). Individual clones that differed significantly between different tumor stages were identified after adjustment for multiple comparisons (false discovery rate < 0.05). For muscle-invasive tumors, the FGA was associated with patient outcome (bad versus good prognosis patients, P = 0.002) and was identified as the only independent predictor of overall outcome based on a multivariate Cox proportional hazards method. Unsupervised hierarchical clustering separated “good” and “bad” prognosis muscle-invasive tumors into clusters that showed significant association with FGA and survival (Kaplan-Meier, P = 0.019). Supervised tumor classification (prediction analysis for microarrays) had a 71% classification success rate based on 102 unique clones. Conclusions: Array-based CGH identified quantitative and qualitative differences in DNA copy number alterations at high resolution according to tumor stage and grade. Fraction genome altered was associated with worse outcome in muscle-invasive tumors, independent of other clinicopathologic parameters. Measures of genomic instability add independent power to outcome prediction of bladder tumors.

20q gain associates with immortalization : 20q13.2 amplification correlates with genome instability in human papillomavirus 16 E7 transformed human uroepithelial cells

Breast, bladder, colon, and ovarian carcinomas show frequent low level 20q gain and less frequently high level 20q13.2 amplification, but the significance of these 20q amplifications in transformation has not been defined. Using karyotypic and comparative genomic hybridization (CGH) analyses, chromosome losses and gains were analysed in six newly immortalized human uroepithelial cell (HUC) lines transformed by Human Papillomavirus 16 (HPV16) E7. Results showed clonal chromosomes with 20q11->qter gain in all six lines. CGH revealed a peak of 20q13.2 amplification in two cell lines. FISH with whole chromosome 20 paint showed expanded chromosome regions (ECRs) and double minute chromosomes (DMs) that contained chromosome 20 material in cell lines with 20q13.2 amplification. FISH with probes from the center of the 20q13.2 human breast cancer amplicon showed as many as 24 signals in cells with 20q13.2 amplification. The acquisition of genome instability in these E7-HUCs did not correlate with TP53 mutation, as all E7-HUCs contained only wildtype TP53. These results suggest that low level 20q gain is associated with overcoming cellular senescence in E7 transformed cells (P-value=2×10−7), but does not confer genome instability, while high level 20q13.2 amplification is associated with chromosome instability. Loss of 10p (P-value=3×10−5) was also important in immortalization of E7-transformed HUCs. Thus, these results have profound implications for interpreting the significance of high versus low level 20q gains in human cancers.

Patterns of Chromosomal Alterations in Breast Ductal Carcinoma In situ

Purpose: Ductal carcinoma in situ (DCIS) is thought to be a nonobligate precursor of invasive cancer. Genomic changes specific to pure DCIS versus invasive cancer, as well as alterations unique to individual DCIS subtypes, have not been fully defined. Experimental Design: Chromosomal copy number alterations were examined by comparative genomic hybridization in 34 cases of pure DCIS and compared with 12 cases of paired synchronous DCIS and invasive ductal cancer, as well as to 146 additional cases of invasive breast cancer of ductal or lobular histology. Genomic differences between high-grade and low/intermediate-grade DCIS, as well as between pure DCIS and invasive cancer, were identified. Results: Pure DCIS showed almost the same degree of chromosomal instability as invasive ductal cancers. A higher proportion of low/intermediate-grade versus high-grade DCIS had loss of 16q (65 versus 12%, respectively; P = 0.002). When compared with lower grade DCIS, high-grade DCIS exhibited more frequent gain of 17q (65 versus 41%; P = 0.15) and higher frequency loss of 8p (77 versus 41%; P = 0.04). Chromosomal alterations in those cases with synchronous DCIS and invasive ductal cancer showed a high degree of shared changes within the two components. Conclusions: DCIS is genetically advanced, showing a similar degree of chromosomal alterations as invasive ductal cancer. The pattern of alterations differed between high- and low/intermediate-grade DCIS, supporting a model in which different histological grades of DCIS are associated with distinct genomic changes. These regions of chromosomal alterations may be potential targets for treatment and/or markers of prognosis.

Genetic and phenotypic characteristics of pleomorphic lobular carcinoma in situ of the breast.

The clinical, pathologic, and molecular features of pleomorphic lobular carcinoma in situ (PLCIS) and the relationship of PLCIS to classic LCIS (CLCIS) are poorly defined. In this study, we analyzed 31 cases of PLCIS (13 apocrine and 18 nonapocrine subtypes) and compared the clinical, pathologic, immunophenotypic, and genetic characteristics of these cases with those of 24 cases of CLCIS. Biomarker expression was examined using immunostaining for E-cadherin, gross cystic disease fluid protein-15, estrogen, progesterone, androgen receptor, human epidermal growth factor receptor2, CK5/6, and Ki67. Array-based comparative genomic hybridization to assess the genomic alterations was performed using microdissected formalin-fixed paraffin-embedded samples. Patients with PLCIS presented with mammographic abnormalities. Histologically, the tumor cells were dyshesive and showed pleomorphic nuclei, and there was often associated necrosis and microcalcifications. All lesions were E-cadherin negative. Compared with CLCIS, PLCIS showed significantly higher Ki67 index, lower estrogen receptor and progesterone receptor expression, and higher incidence of HER2 gene amplification. The majority of PLCIS and CLCIS demonstrated loss of 16q and gain of 1q. Apocrine PLCIS had significantly more genomic alterations than CLCIS and nonapocrine PLCIS. Although lack of E-cadherin expression and the 16q loss and 1q gain-array-based comparative genomic hybridization pattern support a relationship to CLCIS, PLCIS has clinical, mammographic, histologic, immunophenotypic, and genetic features that distinguish it from CLCIS. The histologic features, biomarker profile, and genomic instability observed in PLCIS suggest a more aggressive phenotype than CLCIS. However, clinical follow-up studies will be required to define the natural history and most appropriate management of these lesions.

Protein acetylation and histone deacetylase expression associated with malignant breast cancer progression

Purpose: Excess histone deacetylase (HDAC) activity can induce hypoacetylation of histone and nonhistone protein substrates, altering gene expression patterns and cell behavior potentially associated with malignant transformation. However, HDAC expression and protein acetylation have not been studied in the context of breast cancer progression. Experimental Design: We assessed expression levels of acetylated histone H4 (ac-H4), ac-H4K12, ac-tubulin, HDAC1, HDAC2, and HDAC6 in 22 reduction mammoplasties and in 58 specimens with synchronous normal epithelium, ductal carcinoma in situ (DCIS), and invasive ductal carcinoma (IDC) components. Differences among groups were tested for significance using nonparametric tests. Results: From normal epithelium to DCIS, there was a marked reduction in histone acetylation (P < 0.0001). Most cases showed similar levels of acetylation in DCIS and IDC, although some showed further reduction of ac-H4 and ac-H4K12 from DCIS to IDC. Expression of HDAC1, HDAC2, and HDAC6 was also significantly reduced but by a smaller magnitude. Greater reductions of H4 acetylation and HDAC1 levels were observed from normal to DCIS in estrogen receptor–negative compared with estrogen receptor–positive, and in high-grade compared with non–high-grade tumors. Conclusion: Overall, there was a global pattern of hypoacetylation associated with progression from normal to DCIS to IDC. These findings suggest that the reversal of this hypoacetylation in DCIS and IDC could be an early measure of HDAC inhibitor activity.

Array-based comparative genomic hybridization from formalin-fixed, paraffin-embedded breast tumors.

Identification of prognostic and predictive genomic markers requires long-term clinical follow-up of patients. Extraction of high-quality DNA from archived formalin-fixed, paraffin-embedded material is essential for such studies. Of particular importance is a robust reproducible method of whole genome amplification for small tissue samples. This is especially true for high-resolution analytical approaches because different genomic regions and sequences may amplify differentially. We have tested a number of protocols for DNA amplification for array-based comparative genomic hybridization (CGH), in which relative copy number of the entire genome is measured at 1 to 2 mb resolution. Both random-primed amplification and degenerate oligonucleotide-primed amplification approaches were tested using varying amounts of fresh and paraffin-extracted normal and breast tumor input DNAs. We found that random-primed amplification was clearly superior to degenerate oligonucleotide-primed amplification for array-based CGH. The best quality and reproducibility strongly depended on accurate determination of the amount of input DNA using a quantitative polymerase chain reaction-based method. Reproducible and high-quality results were attained using 50 ng of input DNA, and some samples yielded quality results with as little as 5 ng input DNA. We conclude that random-primed amplification of DNA isolated from paraffin sections is a robust and reproducible approach for array-based CGH analysis of archival tumor samples.