Showing papers by "Gary K. Scott published in 2006"

Optimized high-throughput microRNA expression profiling provides novel biomarker assessment of clinical prostate and breast cancer biopsies

Abstract: Recent studies indicate that microRNAs (miRNAs) are mechanistically involved in the development of various human malignancies, suggesting that they represent a promising new class of cancer biomarkers. However, previously reported methods for measuring miRNA expression consume large amounts of tissue, prohibiting high-throughput miRNA profiling from typically small clinical samples such as excision or core needle biopsies of breast or prostate cancer. Here we describe a novel combination of linear amplification and labeling of miRNA for highly sensitive expression microarray profiling requiring only picogram quantities of purified microRNA. Comparison of microarray and qRT-PCR measured miRNA levels from two different prostate cancer cell lines showed concordance between the two platforms (Pearson correlation R2 = 0.81); and extension of the amplification, labeling and microarray platform was successfully demonstrated using clinical core and excision biopsy samples from breast and prostate cancer patients. Unsupervised clustering analysis of the prostate biopsy microarrays separated advanced and metastatic prostate cancers from pooled normal prostatic samples and from a non-malignant precursor lesion. Unsupervised clustering of the breast cancer microarrays significantly distinguished ErbB2-positive/ER-negative, ErbB2-positive/ER-positive, and ErbB2-negative/ER-positive breast cancer phenotypes (Fisher exact test, p = 0.03); as well, supervised analysis of these microarray profiles identified distinct miRNA subsets distinguishing ErbB2-positive from ErbB2-negative and ER-positive from ER-negative breast cancers, independent of other clinically important parameters (patient age; tumor size, node status and proliferation index). In sum, these findings demonstrate that optimized high-throughput microRNA expression profiling offers novel biomarker identification from typically small clinical samples such as breast and prostate cancer biopsies.

Rapid alteration of MicroRNA levels by histone deacetylase inhibition

Abstract: Improved understanding of the molecular mechanisms by which small-molecule inhibitors of histone deacetylases (HDAC) induce programs, such as cellular differentiation and apoptosis, would undoubtedly assist their clinical development as anticancer agents. As modulators of gene transcript levels, HDAC inhibitors (HDACi) typically affect only 5% to 10% of actively transcribed genes with approximately as many mRNA transcripts being up-regulated as down-regulated. Using microRNA (miRNA) array analysis, we report rapid alteration of miRNA levels in response to the potent hydroxamic acid HDACi LAQ824 in the breast cancer cell line SKBr3. Within 5 hours of exposure to a proapoptotic dose of LAQ824, significant changes were measured in 40% of the >60 different miRNA species expressed in SKBr3 cells with 22 miRNA species down-regulated and 5 miRNAs up-regulated. To explore a potential functional link between HDACi induced mRNA up-regulation and miRNA down-regulation, antisense experiments were done against miR-27a and miR-27b, both abundantly expressed and down-regulated in SKBr3 cells by LAQ824. Correlating a set of genes previously determined by cDNA array analysis to be rapidly up-regulated by LAQ824 in SKBr3 with a database of potential 3' untranslated region miRNA binding elements, two genes containing putative miR-27 anchor elements were identified as transcriptionally up-regulated following miR-27 antisense transfection, ZBTB10/RINZF, a Sp1 repressor, and RYBP/DEDAF, an apoptotic facilitator. These findings emphasize the importance of post-transcriptional mRNA regulation by HDACi in addition to their established effects on promoter-driven gene expression.

Novel pathways associated with quinone-induced stress in breast cancer cells.

Abstract: Hormone-dependent breast cancers that overexpress the ligand-binding nuclear transcription factor, estrogen receptor (ER), represent the most common form of breast epithelial malignancy. Exposure of breast epithelial cells to a redox-cycling and arylating quinone induces mitogen-activated protein kinase phosphorylation of the cytoskeletal filament protein, cytokeratin-8, along with thiol arylation of H3 nuclear histones. Exogenous or endogenous quinones can also induce ligand-independent nuclear translocation and phosphorylation of ER; with excess exposure, these quinones can arylate ER zinc fingers, impairing ER DNA-binding and altering ER-inducible gene expression. Immunoaffinity enrichment for low abundance proteins such as ER, coupled with modern mass spectrometry techniques, promises to improve understanding of the protein-modifications produced by endogenous and exogenous quinone exposure and their role in the development or progression of epithelial malignancies such as breast cancer.

Validated High-Throughput Screening of Drug-Like Small Molecules for Inhibitors of ErbB2 Transcription

Abstract: A whole cell high-throughput screening assay was developed and tested against >2,000 structurally and functionally diverse drug-like small molecules to identify lead compounds capable of cell permeability and selective silencing of ErbB2 transcription. Screening employed reporter sublines clonally selected from ErbB2-negative MCF7 breast cancer cells after stable genomic integration of the ErbB2 proximal promoter driving a luciferase reporter; anti-ErbB2 activities (50% inhibitory concentration values) were compared to inhibition of control MCF7 sublines bearing integrated reporters driven by either a mutated ErbB2 promoter or the cyclin D1 promoter. Of the seven resulting lead compounds, four emerged from the National Cancer Institute (NCI)/ Developmental Therapeutics Program (DTP) Structural Diversity Set (NSC-131547, NSC-176328, NSC-259968, and NSC-321237); three others emerged from a panel of anticancer compounds with known mechanistic actions and included a minor groove DNA-binding antibiotic (NSC-58...

Altered promoter usage characterizes monoallelic transcription arising with ERBB2 amplification in human breast cancers.

Abstract: Analysis of a collection of human breast cancers (n = 150), enriched in ERBB2-positive cases (n = 57) and involving tumor genotyping relative to population-matched blood genotyping (n = 749) for a common ERBB2 single nucleotide polymorphism Ala(G)1170Pro(C), revealed that ERBB2 amplification in breast cancer is invariably monoallelic. Analysis of paired breast cancer and blood samples from informative (G1170C heterozygotic) ERBB2-positive (n = 12) and ERBB2-negative (n = 17) cases not only confirmed monoallelic amplification and ERBB2 transcriptional overexpression but also revealed that most low ERBB2 expressing breast cancers (12/17) exhibit unbalanced allelic transcription, showing 3-fold to nearly 5,000-fold preferential expression from one of two inherited alleles. To explore cis-acting transcriptional mechanisms potentially selected during ERBB2 amplification, levels of four different ERBB2 transcript variants (5.2, 4.7, 2.1, and 1.4 kb) were correlated with total (4.6 kb) ERBB2 mRNA levels in ERBB2-positive (n = 14) versus ERBB2-negative (n = 43) primary breast cancers. Relative expression of only the 2.1 kb extracellular domain-encoding splice variant and a 4.7 kb mRNA variant that uses an alternative start site were significantly increased in association with ERBB2-positivity, implicating altered promoter usage and selective transcript regulation within the ERBB2 amplicon. Altogether, these findings provide new mechanistic insights into the development of ERBB2-positive breast cancer and strong rationale for delineating candidate cis-acting regulatory elements that may link allele-specific ERBB2 transcription in premalignant breast epithelia with subsequent development of breast cancers bearing monoallelic ERBB2 amplicons.

Therapeutic destabilization of ErbB2 transcripts mediated by U-rich mRNA binding proteins and microRNAs.

Abstract: Proc Amer Assoc Cancer Res, Volume 47, 2006 5616 A screen for small molecule inhibitors of ErbB2 transcription identified two drug classes, histone deacetylase (HDAC) and proteasome inhibitors that, relative to Actinomycin D, accelerate decay of mature ErbB2 transcripts. Elements regulating ErbB2 transcript stability have been mapped to a conserved U-rich region within its endogenous 3' UTR, thought to bind to either the stabilizing protein, HuR, or the destabilizing protein AUF1. Additionally, this U-rich region contains several putative microRNA (miRNA) binding elements which may modulate mature transcript stability by recruitment of cognate miRNAs. To assess ErbB2 mRNA stabilizing mechanisms dependent on miRNAs, AUF1 or HuR proteins that may be sensitive to HDAC and/or proteasome inhibition, SKBr3 cells were pretreated (72 h) with siRNAs targeting Dicer (required for mature miRNA processing), HuR or AUF1 prior to culture treatment (5 h) with either HDAC (LAQ824) or proteasome (PS341) inhibitors. ErbB2 mRNA levels of untreated SKBr3 were increased by Dicer siRNA, which also partially prevented the ErbB2 mRNA decline induced by HDAC inhibition. In contrast, AUF1 siRNA pretreatment partially prevented the ErbB2 mRNA decline induced by proteasome inhibition. Consistent with Dicer siRNA results indicating that miRNAs negatively regulate ErbB2 transcript levels, a novel microarray platform for profiling ∼200 miRNAs demonstrated that HDAC inhibition of SKBr3 cells results in upregulation of three miRNAs that putatively bind to the 3’ UTR of ErbB2: miR125a, miR125b, and miR320. Altogether, these findings point to the potential therapeutic importance of mRNA stability as regulated by miRNAs and U-rich mRNA binding proteins, and suggest that HDAC and proteasome inhibitors accelerate ErbB2 transcript decay by fundamentally different mechanisms.