Sarah E. Aiyar

Cofactor of BRCA1: A Novel Transcription Factor Regulator in Upper Gastrointestinal Adenocarcinomas

Cofactor of BRCA1 (COBRA1) is a newly characterized member of the negative elongation factor (NELF) complex. In this work, we show that COBRA1 is overexpressed in the majority of primary upper gastrointestinal adenocarcinomas (UGC), and its overexpression correlates with down-regulation of TFF1. We have detected overexpression of COBRA1 mRNA using quantitative real-time reverse transcription-PCR in 28 (79%) primary UGCs. Immunohistochemical analysis of UGC tissue arrays that contained 70 tumor samples showed moderate-strong staining for COBRA1 in 60 (84%) tumors. Interestingly, the tumor samples showed absent-weak staining for TFF1 in 45 (65%) of the tumors. Simultaneous loss of TFF1 expression and overexpression of COBRA1 was observed in 42 of 70 (60%) tumors. Using small interfering RNA technology with gastric cancer cells, we have shown that COBRA1 inhibition leads to increased TFF1 promoter activity and gene expression. Promoter analysis of TFF1 indicated that regulation of TFF1 by COBRA1 is estrogen independent in contrast to breast cancer. Moreover, COBRA1 regulation of TFF1 in gastric cancer cells was independent of NELF-E. Using several truncated mutants and site mutants of the TFF1 promoter, we have shown that COBRA1 can negatively regulate the activator protein-1 (AP-1) complex at the TFF1 promoter and thus down-regulate TFF1 expression in gastric cancer cell lines. Electrophoretic mobility shift assay showed that COBRA1 attenuates AP-1 binding to DNA. Our results suggest COBRA1 as a novel oncogene in UGCs that regulate AP-1 binding and the expression of TFF1 in upper gastric epithelia.

Cofactor of BRCA1 modulates androgen-dependent transcription and alternative splicing.

Transcriptional activity of nuclear receptors (NRs) is influenced by a large number of coregulators that exert their actions predominantly at the transcription initiation step. Unlike most well-characterized NR coregulators, cofactor of BRCA1 (COBRA1), a subunit of the negative elongation factor (NELF), binds to estrogen receptor alpha (ERalpha) and modulates estrogen-dependent transcription by impeding the movement of RNA polymerase II (RNAPII) during the transcription elongation stage. Here we show that, in addition to ERalpha, COBRA1 also displays various degrees of affinity for several other NRs. In particular, COBRA1 binds strongly to androgen receptor (AR) via its ligand-binding domain (LBD). Small hairpin RNA (shRNA)-mediated reduction of endogenous COBRA1 enhances androgen-mediated transcription. The effect of COBRA1 knockdown can be rescued by a silent mutant COBRA1 that is refractory to the shRNA action. Using a reporter assay for alternative splicing, we also provide evidence for a role of COBRA1 in influencing the exon skipping/inclusion of nascent transcripts produced from an androgen-dependent promoter. These findings suggest that COBRA1 may coordinate multiple steps in ligand-dependent gene expression, which in turn ensures both the quantity and quality of hormone-stimulated gene products.

Regulation of clustered gene expression by cofactor of BRCA1 (COBRA1) in breast cancer cells

Eucaryotic genes that are coordinately expressed tend to be clustered. Furthermore, gene clusters across chromosomal regions are often upregulated in various tumors. However, relatively little is known about how gene clusters are coordinately expressed in physiological or pathological conditions. Cofactor of BRCA1 (COBRA1), a subunit of the human negative elongation factor, has been shown to repress estrogen-stimulated transcription of trefoil factor 1 (TFF1 or pS2) by stalling RNA polymerase II. Here, we carried out a genome-wide study to identify additional physiological target genes of COBRA1 in breast cancer cells. The study identified a total of 134 genes that were either activated or repressed upon small hairpin RNA-mediated reduction of COBRA1. Interestingly, many COBRA1-regulated genes reside as clusters on the chromosomes and have been previously implicated in cancer development. Detailed examination of two such clusters on chromosome 21 (21q22) and chromosome X (Xp11) reveals that COBRA1 is physically associated with a subset of its regulated genes in each cluster. In addition, COBRA1 was shown to regulate both estrogen-dependent and -independent transcription of the gene cluster at 21q22, which encompasses the previously identified COBRA1-regulated TFF1 (pS2) locus. Thus, COBRA1 plays a critical role in the regulation of clustered gene expression at preferred chromosomal domains in breast cancer cells.

Tetra-methoxystilbene modulates ductal growth of the developing murine mammary gland

Extensive data suggest that estradiol contributes to the development of breast cancer by acting as a mitogen and exerting direct genotoxic effects after enzymatic conversion to 4-hydroxyestradiol (4-OHE2) via cytochrome P450 1B1 (CYP1B1). The mammary gland, ovary, and uterus all express CYP1B1. Overexpression of this enzyme has been associated with an increased risk of breast cancer and blockade might reduce this carcinogenic effect. For this reason, we conducted systematic in vitro and in vivo studies of a CYP1B1 inhibitor, TMS (2,3′,4,5′-tetramethoxystilbene). We found that TMS blocked the enzymatic conversion of radiolabeled estradiol to both 2-hydroxyestradiol (2-OHE2) and 4-OHE2, but did not inhibit Cyp1b1 message formation. In vivo studies using mass spectrometry showed that TMS inhibited formation of 2-OHE2 and 4-OHE2 and the resulting estrogen-DNA adducts. To examine its biologic actions in vivo, we investigated whether TMS could block the hyperplastic changes that occur in the developing breast of aromatase-transfected mice. We found that TMS induced a significant reduction of ductal structures in mice less than 6 months in age. In older mice, no reduction in breast morphology occurred. These latter studies uncovered unexpected estrogen agonistic actions of TMS at high doses, including a paradoxical stimulation of breast ductal structures and the endometrium. These studies suggest that the enzyme inhibitory properties of TMS, as well as the effects on developing breast, could implicate a role for TMS in breast cancer prevention, but only in low doses and on developing breast.

BRCA1: A locus‐specific “liaison” in gene expression and genetic integrity

Mutations in BRCA1 predominantly lead to elevated risks of breast and ovarian cancers. In contrast to the tissue‐specific nature of BRCA1tumors, the normal BRCA1 gene product functions in diverse nuclear events including transcription, DNA repair, and DNA damage checkpoint. Recent findings of physical and functional associations between BRCA1 and the RNA polymerase II (RNAPII)‐dependent transcription machinery may shed some light on this longstanding paradox of BRCA1 biology. Eukaryotic gene expression is now known to be a continuous process, whereby each step is physically and functionally connected to the next. In particular, RNAPII plays a pivotal role in coordinating transcription with various pre‐mRNA processing events and stress response. Interestingly, BRCA1 preferentially interacts with the processive form of RNAPII and proteins that regulate RNAPII activity and movement during transcription elongation. In response to DNA damage, BRCA1 dissociates from RNAPII and localizes to DNA damage sites. We propose that BRCA1 may coordinate multiple steps in gene expression, including transcription initiation, elongation, and pre‐mRNA processing via its interactions with the transcription machinery at selected gene loci. The same BRCA1‐associated transcription apparatus may serve as a sensor for stress signals and facilitate the transition from a transcription state to checkpoint/DNA repair state. Such a coordinating role of BRCA1 in gene expression may ensure the appropriate quantity and quality of the mature transcripts for certain breast and ovarian cancer‐related genes, as well as the genetic integrity of the breast and ovary tissues.

Development of a high sensitivity, nested Q-PCR assay for mouse and human aromatase

Measurement of breast tissue estradiol levels could provide a powerful method to predict the risk of developing breast cancer but obtaining sufficient amounts of tissue from women is difficult from a practical standpoint. Assessment of aromatase in ductal lavage fluid or fine needle aspirates from breast might provide a surrogate marker for tissue estrogen levels but highly sensitive methods would be required. These considerations prompted us to develop an ultra-sensitive, “nested” PCR assay for aromatase which is up to one million fold more sensitive than standard PCR methods. We initially validated this assay using multiple tissues from the aromatase transgenic mouse and found that coefficients of variation for measurement of replicate samples averaged less than 5%. We demonstrated a 60-fold enhancement in aromatase message in the transgenic versus the wild type mouse breast but surprisingly, levels in the transgenic animals were highly variable, ranging from 0.4 to 27 relative units. The variability of aromatase expression in the transgenic breast did not correlate with the degree of breast development and did not appear to relate to hormonal manipulation of the MMTV promoter but probably related to lack of exhaustive inbreeding and mixed zygocity of transgenic animals. Extensive validation in mouse tissues provided confidence regarding the assay in human tissues, since nearly identical methods were used. The human assay was sufficiently sensitive to detect aromatase in a single human JAR (choriocarcinoma) cell, in all breast biopsies measured, and in 7/23 ductal lavage fluids.

Anticancer effect of (E)-2-hydroxy-3′,4,5′-trimethoxystilbene on breast cancer cells by mitochondrial depolarization

BackgroundTMS (2,3′,4,5′-tetramethoxystilbene), a stilbene analog derived from rhapontigenin, was previously demonstrated to induce apoptosis in hormone-resistant breast cancer cells. Therefore, this study investigated the anticancer effect of a new stilbene analog, HTMS ((E)-2-hydroxy-3′,4,5′-trimethoxystilbene), and its mechanism in various breast cancer cell lines.Materials and methodsThe effect of HTMS on cell proliferation of MDA-MB-231, MCF-7, and LTED cells was evaluated using MTT assays. Cell apoptosis was detected by FITC-annexin V staining and flow cytometry analysis, changes in mitochondrial potential were determined by fluorescence microscopy using TMRE staining, and the expression of cleaved PARP and release of cytochrome c were assessed by Western blot analysis.ResultsHTMS significantly decreased the cell viability of various types of breast cancer cells in a dose- and time-dependent manner, characterized by G2/M arrest of the cell cycle and the induction of apoptosis. In particular, HTMS disturbed the mitochondrial membrane potential, causing a release of cytochrome c during apoptosis. Furthermore, HTMS was superior to TMS in inhibiting cancer cell growth in a pilot comparison study.ConclusionHTMS is an effective apoptotic agent for breast cancer cells, making it a candidate therapeutic agent for the treatment of breast cancer.

Abstract 131: Mechanisms by which 2,3’, 4,5’ tetramethoxystilbene (TMS), a resveratrol derivative, induces death in breast cancer cells

Proceedings: AACR 101st Annual Meeting 2010‐‐ Apr 17‐21, 2010; Washington, DC We have examined a non-toxic pro-apoptotic agent, TMS (2, 3’,4, 5’ tetramethoxystilbene), which belongs to the Resveratrol family of stilbenes. To learn about the mechanism by which TMS achieved its effects we carried out microarray analysis and found that TMS treatment increased tubulin genes as well as stress response and pro-apoptotic genes. Fractionation studies uncovered that TMS treatment causes cleavage of Bax from the p21 form to a truncated p18 form. Co-localization analysis of immunofluorescent studies showed that Bax moved from the cytosol to the mitochondria. In addition, the pro-apoptotic proteins Noxa and Bim (EL, L, and S) were increased upon TMS treatment. Breast cancer cell lines reduced for Bax, Bim and Noxa are compromised for TMS-mediated cell death. Transmission electron microscopy revealed evidence of nuclear condensation, formation of apoptotic bodies and DAPI staining showed evidence of DNA fragmentation. TMS treatment was able to induce both caspase-independent and caspase-dependent death via the intrinsic death pathway. Citation Format: {Authors}. {Abstract title} [abstract]. In: Proceedings of the 101st Annual Meeting of the American Association for Cancer Research; 2010 Apr 17-21; Washington, DC. Philadelphia (PA): AACR; Cancer Res 2010;70(8 Suppl):Abstract nr 131.