Investigating the Role of Protein Arginine Methyltransferases in Breast Cancer Etiology

Morettin, Alan James

January 2015

Breast cancer is the most commonly diagnosed cancer amongst Canadian women. Though numerous treatments are available, in many instances tumours become refractory or recur. Therefore, understanding the biological events that lead to the progression and therapeutic resistance of breast cancer is essential for the development of novel treatment options for this disease. Numerous members of the protein arginine methyltransferase (PRMT) family, which are the enzymes responsible for catalyzing methylation on arginine residues are aberrantly regulated in breast cancer. Hence, understanding the precise contribution of PRMTs to the development and progression of breast cancer is important. This Thesis will present my findings on the alternatively spliced PRMT1 isoform, PRMT1v2, previously identified to be overexpressed in breast cancer cell lines and here shown to promote breast cancer cell survival and invasion. Second, a novel role is ascribed to PRMT6, another PRMT aberrantly expressed in breast cancer. PRMT6 promotes chemoresistance to the drug bortezomib by mediating stress granule formation through down-regulation of eIF4E. Increased stress granule formation in bortezomib-resistant cancer cells promotes cell survival. Third, DDX3, a prototypical PRMT substrate which is overexpressed in breast cancer cell lines and stimulates transformation of mammary epithelial cells is a novel substrate of PRMT1, CARM1, and PRMT6. Lastly, TDRD3, a reader/effector of arginine methylation also overexpressed in breast tumours regulates breast cancer cell proliferation, anchorage-independent growth and cell motility and invasion.

Arginine Methylation

PRMTs

Breast Cancer

Étude structurale des protéine arginine méthyltransférases : reconnaissance des substrats et conception rationnelle de modulateurs / Structural study of protein arginine methyltransferases : substrate recognition and structure-based design of modulators

Marechal, Nils

14 September 2018

Les protéine arginine méthyltransférases (PRMT) sont impliquées dans de nombreux processus cellulaires, incluant la régulation de l’expression des gènes, le contrôle de l’épissage, le maintien de l’intégrité du génome et la transduction du signal. De nombreuses études montrent que la dérégulation de l’activité des PRMT est associée au développement de pathologies, et en particulier de cancers. Les PRMT constituent ainsi une des nouvelles cibles potentielles en chimiothérapie. Les travaux présentés dans ce manuscrit portent sur trois cibles : PRMT2, PRMT3 et PRMT4/CARM1. Combinant des approches biochimiques, biophysiques et structurales (cristallographie et cryo- microscopie électronique), ces travaux comportent deux aspects : (I) comprendre au niveau atomique la régulation de la réaction de méthylation des protéines (reconnaissance protéines-protéines et interactions entre modifications post-traductionnelles) ; (II) découvrir des inhibiteurs spécifiques et puissants de plusieurs PRMT cibles. / Protein arginine methyltransferases (PRMT) are involved in many cellular processes, including gene expression regulation, splicing control, maintenance of genome integrity and signal transduction.Since deregulation of those biological processes appears to be implicated in the pathogenesis of different diseases, PRMTs have emerged as potential new targets for the development of novel therapeutic modulators. Despite the large amount of biological and structural data on PRMTs, two challenges remain to be solved by structural biology ; (I) understanding how PRMTs recognize and bind their full-length substrates ; (II) revealing how PRMTs achieve specific arginine methylation on different target sites. The works presented here focused on 3 targets: PRMT2, PRMT3 and PRMT4/ CARM1. We used biochemical, biophysical and structural methods (bio-crystallography and cryo- electron microscopy) to decipher structural clues that drive PRMT-substrate recognition. We developed new chemical probes that can be used in early drug discovery for the conception of PRMT inhibitors.

PRMT

Epigénétique

Méthylation des arginines

Analogues SAM-peptides

Inhibiteurs

Structure biologique

PRMTs

Epigenetic

Arginine methylation

PRMTs ; SAM-peptides analogs

Inhibitors

Structural biology

572.8

Development of Novel Methods and their Utilization in the Analysis of the Effect of the N-terminus of Human Protein Arginine Methyltransferase 1 Variant 1 on Enzymatic Activity, Protein-protein Interactions, and Substrate Specificity

Suh-Lailam, Brenda Bienka

01 May 2010

Protein arginine methyltransferases (PRMTs) are enzymes that catalyze the methylation of protein arginine residues, resulting in the formation of monomethylarginine, and/or asymmetric or symmetric dimethylarginines. Although understanding of the PRMTs has grown rapidly over the last few years, several challenges still remain in the PRMT field. Here, we describe the development of two techniques that will be very useful in investigating PRMT regulation, small molecule inhibition, oligomerization, protein-protein interaction, and substrate specificity, which will ultimately lead to the advancement of the PRMT field. Studies have shown that having an N-terminal tag can influence enzyme activity and substrate specificity. The first protocol tackles this problem by developing a way to obtain active untagged recombinant PRMT proteins. The second protocol describes a fast and efficient method for quantitative measurement of AdoMet-dependent methyltranseferase activity with protein substrates. In addition to being very sensitive, this method decreases the processing time for the analysis of PRMT activity to a few minutes compared to weeks by traditional methods, and generates 3000-fold less radioactive waste. We then used these methods to investigate the effect of truncating the NT of human PRMT1 variant 1 (hPRMT1-V1) on enzyme activity, protein-protein interactions, and substrate specificity. Our studies show that the NT of hPRMT1-V1 influences enzymatic activity and protein-protein interactions. In particular, methylation of a variety of protein substrates was more efficient when the first 10 amino acids of hPRMT1v1 were removed, suggesting an autoinhibitory role for this small section of the N-terminus. Likewise, as portions of the NT were removed, the altered hPRMT1v1 constructs were able to interact with more proteins. Overall, my studies suggest the the sequence and length of the NT of hPRMT1v1 is capable of enforcing specific protein interactions.

enzyme activity measurement

Methylation

protein-protein interactions

substrate specificity

Biochemistry