Discovery and Mechanistic Study of a Class of Protein Arginine Methylation Inhibitors

Xenoestrogens regulate the activity of arginine methyltransferases

Arginine methylation is a common post-translational modification that has been strongly implicated in transcriptional regulation. The arginine methyltransferases (PRMTs) were first reported as transcriptional coactivators for the estrogen and androgen receptors. Compounds that inhibit these enzymes will provide us with valuable tools for dissecting the roles of these enzymes in cells, and will possibly also have therapeutic applications. In order to identify such inhibitors of the PRMTs, we have previously performed a high-throughput screen using a small molecule library. These compounds were named arginine methyltransferase inhibitors (AMIs). The majority of these inhibitors were polyphenols, and one in particular (AMI-18) shared additional features with a group of known xenoestrogens. We, thus, tested a panel of xenoestrogens and found that a number of them possess the ability to inhibit PRMT activity, in vitro. These inhibitors primarily target CARM1, and include licochalcone A, kepone, benzyl 4-hydroxybenzoate, and tamoxifen. We developed a cell-based reporter system for CARM1 activity, and showed that tamoxifen (IC(50) =30 μM) inhibits this PRMT. The ability of these compounds to regulate the activity of transcriptional coactivators may be an unappreciated mechanism of action for xenoestrogens, and might also explain the efficacy of high-dose tamoxifen treatment on estrogen receptor negative cancers.

Epigenetics of prostate cancer and the prospect of identification of novel drug targets by RNAi screening of epigenetic enzymes

Alterations in epigenetic processes probably underlie most human malignancies. Novel genome-wide techniques, such as chromatin immunoprecipitation and high-throughput sequencing, have become state-of-the-art methods to map the epigenomic landscape of development and disease, such as in cancers. Despite these advances, the functional significance of epigenetic enzymes in cancer progression, such as prostate cancer, remain incompletely understood. A comprehensive mapping and functional understanding of the cancer epigenome will hopefully help to facilitate development of novel cancer therapy targets and improve future diagnostics. The authors have developed a novel cell microarray-based high-content siRNA screening technique suitable to address the putative functional role and impact of all known putative and novel epigenetic enzymes in cancer, including prostate cancer.

Small molecule modulators of histone acetylation and methylation: a disease perspective

Chromatin modifications have gained immense significance in the past few decades as key regulators of gene expression. The enzymes responsible for these modifications along with the other non-histone proteins, remodeling factors and small RNAs modulate the chromatin dynamicity, which in turn directs the chromatin function. A concerted action of different modifying enzymes catalyzes these modifications, which are read by effector modules and converted to functional outcomes by various protein complexes. Several small molecules in the physiological system such as acetyl CoA, NAD(+), and ATP are actively involved in regulating these functional outcomes. Recent understanding in the field of epigenetics indicate the possibility of the existence of a network, 'the epigenetic language' involving cross talk among different modifications that could regulate cellular processes like transcription, replication and repair. Hence, these modifications are essential for the cellular homeostasis, and any alteration in this balance leads to a pathophysiological condition or disease manifestation. Therefore, it is becoming more evident that modulators of these modifying enzymes could be an attractive therapeutic strategy, popularly referred to as 'Epigenetic therapy.' Although this field is currently monopolized by DNA methylation and histone deacetylase inhibitors, this review highlights the modulators of the other modifications namely histone acetylation, lysine methylation and arginine methylation and argues in favor of their therapeutic potential.