Recurrent copy number alterations in prostate cancer: an in silico meta-analysis of publicly available genomic data.

We present a meta-analysis of somatic copy number alterations (CNAs) from 11 publications that examined 662 prostate cancer patient samples, which were derived from 546 primary and 116 advanced tumors. Normalization, segmentation, and identification of corresponding CNAs for meta-analysis was achieved using established commercial software. Unsupervised analysis identified five genomic subgroups in which approximately 90% of the samples were characterized by abnormal profiles with gains of 8q. The most common loss was 8p (NKX3.1). The CNA distribution in other genomic subgroups was characterized by losses at 2q, 3p, 5q, 6q, 13q, 16q, 17p, 18q, and PTEN (10q), and acquisition of 21q deletions associated with the TMPRSS2-ERG fusion rearrangement. Parallel analysis of advanced and primary tumors in the cohort indicated that genomic deletions of PTEN and the gene fusion were enriched in advanced disease. A supervised analysis of the PTEN deletion and the fusion gene showed that PTEN deletion was sufficient to impose higher levels of CNA. Moreover, the overall percentage of the genome altered was significantly higher when PTEN was deleted, suggesting that this important genomic subgroup was likely characterized by intrinsic chromosomal instability. Predicted alterations in expression levels of candidate genes in each of the recurrent CNA regions characteristic of each subgroup showed that signaling networks associated with cancer progression and genome stability were likely to be perturbed at the highest level in the PTEN deleted genomic subgroup.

Flavopiridol synergizes with sorafenib to induce cytotoxicity and potentiate antitumorigenic activity in EGFR/HER-2 and mutant RAS/RAF breast cancer model systems.

Oncogenic receptor tyrosine kinase (RTK) signaling through the Ras-Raf-Mek-Erk (Ras-MAPK) pathway is implicated in a wide array of carcinomas, including those of the breast. The cyclin-dependent kinases (CDKs) are implicated in regulating proliferative and survival signaling downstream of this pathway. Here, we show that CDK inhibitors exhibit an order of magnitude greater cytotoxic potency than a suite of inhibitors targeting RTK and Ras-MAPK signaling in cell lines representative of clinically recognized breast cancer (BC) subtypes. Drug combination studies show that the pan-CDK inhibitor, flavopiridol (FPD), synergistically potentiated cytotoxicity induced by the Raf inhibitor, sorafenib (SFN). This synergy was most pronounced at sub-EC50 SFN concentrations in MDA-MB-231 (KRAS-G13D and BRAF-G464V mutations), MDA-MB-468 [epidermal growth factor receptor (EGFR) overexpression], and SKBR3 [ErbB2/EGFR2 (HER-2) overexpression] cells but not in hormone-dependent MCF-7 and T47D cells. Potentiation of SFN cytotoxicity by FPD correlated with enhanced apoptosis, suppression of retinoblastoma (Rb) signaling, and reduced Mcl-1 expression. SFN and FPD were also tested in an MDA-MB-231 mammary fat pad engraftment model of tumorigenesis. Mice treated with both drugs exhibited reduced primary tumor growth rates and metastatic tumor load in the lungs compared to treatment with either drug alone, and this correlated with greater reductions in Rb signaling and Mcl-1 expression in resected tumors. These findings support the development of CDK and Raf co-targeting strategies in EGFR/HER-2-overexpressing or RAS/RAF mutant BCs.

PTEN genomic deletions that characterize aggressive prostate cancer originate close to segmental duplications.

Deletion of PTEN at 10q23.3 occurs in ∼40% of human prostate cancers and is associated with aggressive metastatic potential, poor prognosis, and androgen-independence. This high frequency of recurrent PTEN deletions in prostate cancer suggests there may be unusual genomic features close to this locus that facilitate DNA alteration at 10q23.3. To explore possible mechanisms for deletions in the PTEN region, a meta-analysis of 311 published human genome array datasets was conducted and determined that the minimal prostate cancer-associated deletion at 10q23.3 corresponds to ∼2.06 MB region flanked by BMPR1A and FAS. On a separate cohort comprising an additional 330 tumors, four-color fluorescence in situ hybridization analysis using probes for BMPR1A, FAS, cen(10), and PTEN showed that 132 of 330 (40%) tumors had PTEN loss, 50 (15%) of which were homozygous losses (comprising in total 100 deletion events). Breakpoints between PTEN and BMPR1A or FAS were subsequently mapped in 100 homozygous and 82 hemizygous PTEN losses, revealing that 125/182 PTEN microdeletions occurred within the 940 kB interval between BMPR1A and PTEN. Furthermore, this breakpoint interval coincides with a repeat-rich region of 414 kB containing the SD17 and SD18 segmental duplications, which contain at least 13 homologous inverted repeat sequences. Together, these data suggest that a strong selective growth advantage for loss of PTEN and upregulation of PI3K/AKT, combined with the close proximity of PTEN to a large unstable segment of repeated DNA comprising SD17 and SD18, can lead to recurrent microdeletions of the PTEN gene in prostate cancer. © 2011 Wiley Periodicals, Inc.

Prostate cancer as a model system for genetic diversity in tumors.

This chapter will summarize novel understandings of the early molecular events in prostatic carcinogenesis that may underlie both the genetic and clinical heterogeneity. Areas covered include preneoplasia, stem cell concepts, telomere abnormalities, and the nature of tumor-stromal interactions. The oncogenomics of prostate cancer is reviewed with emphasis on androgen signaling, ETS gene family aberrations, and PTEN deletion. The notion that "field cancerization," coupled with genomic instability may explain both the occurrence of multifocal disease, and the recent observations of genetic diversity of ERG alteration in individual tumors are discussed. Collectively, genomic studies are rapidly moving human prostate cancer closer to the promise of personalized medicine, so that specific genetic profiles of individual tumors will determine the best therapeutic approaches.

Thymic involution and proliferative T-cell responses in multiple sclerosis.

We investigated naïve CD4 T-cell homeostasis in relapsing-remitting multiple sclerosis (RRMS). Quantification of signal joint T-cell receptor excision circles in FACS-isolated CD31hi cells, which correspond closely to CD4 recent thymic emigrants (RTEs), indicates that young patients have reduced generation of CD4 RTEs compared to age-matched controls. In RRMS, compared to controls, CXCR4 analyses indicate age-associated thymic output of progressively immature CD4 RTEs, and Ki-67 data demonstrate altered T-cell proliferative responses that fail to maintain naïve CD4 T-cell numbers with age. Thus, RRMS patients have early thymic involution with compensatory homeostatic peripheral T-cell proliferative responses that may predispose patients to autoreactivity.