Type I PRMTs and PRMT5 Independently Regulate Both snRNP Arginine Methylation and Post-Transcriptional Splicing

Protein arginine methyltransferases (PRMTs) methylate histones, splicing factors, and many other nuclear proteins. Type I enzymes (PRMT1-4,6,8) catalyze mono- (Rme1/MMA) and asymmetric (Rme2a/ADMA) dimethylation; Type II enzymes (PRMT5,9) catalyze mono- and symmetric (Rme2s/SDMA) dimethylation. Misregulation of PRMTs in multiple types of cancers is associated with aberrant gene expression and RNA splicing. To understand the specific mechanisms of PRMT activity in splicing regulation, we treated cells with the PRMT5 inhibitor GSK591 and the Type I inhibitor MS023 and probed their transcriptomic consequences. We discovered that Type I PRMTs and PRMT5 inversely regulate core spliceosomal Sm protein Rme2s and intron retention. Loss of Sm Rme2s is associated with the accumulation of polyadenylated RNA containing retained introns and snRNPs on chromatin. Conversely, increased Sm Rme2s correlates with decreased intron retention and chromatin-association of intron-containing polyadenylated RNA. Using the newly developed SKaTER-seq model, comprehensive and quantitative analysis of co-transcriptional splicing revealed that either Type I PRMT or PRMT5 inhibition resulted in slower splicing rates. Surprisingly, altered co-transcriptional splicing kinetics correlated poorly with ultimate changes in alternatively spliced mRNA. Quantitation of retained intron decay following inhibition of nascent transcription revealed that Type I PRMTs and PRMT5 reciprocally regulate post-transcriptional splicing efficiency.

A beginner’s guide to RT-PCR, qPCR and RT-qPCR

The development of the polymerase chain reaction (PCR), for which Kary Mullis received the 1992 Novel Prize in Chemistry, revolutionized molecular biology. At around the time that prize was awarded, research was being carried out by Russel Higuchi which led to the discovery that PCR can be monitored using fluorescent probes, facilitating quantitative real-time PCR (qPCR). In addition, the earlier discovery of reverse transcriptase (in 1970) laid the groundwork for the development of RT-PCR (used in molecular cloning). The latter can be coupled to qPCR, termed RT-qPCR, allowing analysis of gene expression through messenger RNA (mRNA) quantitation. These techniques and their applications have transformed life science research and clinical diagnosis.

Identification of differentially regulated genes in human patent ductus arteriosus

In order to identify differentially expressed genes that are specific to the ductus arteriosus, 18 candidate genes were evaluated in matched ductus arteriosus and aortic samples from infants with coarctation of the aorta. The cell specificity of the gene's promoters was assessed by performing transient transfection studies in primary cells derived from several patients. Segments of ductus arteriosus and aorta were isolated from infants requiring repair for coarctation of the aorta and used for mRNA quantitation and culturing of cells. Differences in expression were determined by quantitative PCR using the ΔΔCt method. Promoter regions of six of these genes were cloned into luciferase reporter plasmids for transient transfection studies in matched human ductus arteriosus and aorta cells. Transcription factor AP-2b and phospholipase A2 were significantly up-regulated in ductus arteriosus compared to aorta in whole tissues and cultured cells, respectively. In transient transfection experiments, Angiotensin II type 1 receptor and Prostaglandin E receptor 4 promoters consistently gave higher expression in matched ductus arteriosus versus aorta cells from multiple patients. Taken together, these results demonstrate that several genes are differentially expressed in ductus arteriosus and that their promoters may be used to drive ductus arteriosus-enriched transgene expression.