Epitranscriptomics: new players in an old game.

Ageing is a conserved and unavoidable biological process characterized by progressive decline of physiological functions with time. Despite constituting the greatest risk factor for most human diseases, little is known about the molecular mechanisms driving the ageing process. More than 170 chemical RNA modifications, also known as the epitranscriptome, decorate eukaryotic coding and non-coding RNAs and have emerged as novel regulators of RNA metabolism, modulating RNA stability, translation, splicing or non-coding RNA processing. Studies on short-lived organisms such as yeast or worms connect mutations on RNA modifying enzymes with lifespan changes, and dysregulation of the epitranscriptome has been linked to age-related diseases and ageing hallmarks themselves in mammals. Moreover, transcriptome-wide analyses are starting to reveal changes in messenger RNA modifications in neurodegenerative diseases and in the expression of some RNA modifiers with age. These studies are starting to put the focus on the epitranscriptome as a potential novel regulator of ageing and lifespan, and open new avenues for the identification of targets to treat age-related diseases. In this review, we discuss the connection between RNA modifications and the enzymatic machinery regulating their deposition in coding and non-coding RNAs, and ageing and hypothesize about the potential role of RNA modifications in the regulation of other ncRNAs playing a key role in ageing, such as transposable elements and tRNA fragments. Finally, we reanalyze available datasets of mouse tissues during ageing and report a wide transcriptional dysregulation of proteins involved in the deposition, removal or decoding of several of the best-known RNA modifications.

A Simple, Rapid, and Cost-Effective Method for Loss-of-Function Assays in Pluripotent Cells.

Embryonic stem cells (ESCs) are derived from the inner cell mass of the preimplantation blastocyst and can be maintained indefinitely in vitro without losing their properties. Given their self-renewal and pluripotency, ESCs not only represent a key tool to study early embryonic development in a dish, but also an unlimited source of material for tissue replacement in regenerative medicine. Loss-of-function assays using RNA interference are a powerful tool to understand the roles of specific genes and are facilitated by lentiviral-mediated delivery of vector-encoded shRNAs which allows long-term silencing of single or multiple genes. Here, we describe the steps for rapid and cost-effective production and testing of lentiviral particles with vector-encoded shRNAs for gene silencing in ESCs. This protocol can be easily adapted for loss-of-function assays in other pluripotent cells or culture conditions of interest.

The comprehensive interactomes of human adenosine RNA methyltransferases and demethylases reveal distinct functional and regulatory features.

N6-methyladenosine (m6A) and N6,2'-O-dimethyladenosine (m6Am) are two abundant modifications found in mRNAs and ncRNAs that can regulate multiple aspects of RNA biology. They function mainly by regulating interactions with specific RNA-binding proteins. Both modifications are linked to development, disease and stress response. To date, three methyltransferases and two demethylases have been identified that modify adenosines in mammalian mRNAs. Here, we present a comprehensive analysis of the interactomes of these enzymes. PCIF1 protein network comprises mostly factors involved in nascent RNA synthesis by RNA polymerase II, whereas ALKBH5 is closely linked with most aspects of pre-mRNA processing and mRNA export to the cytoplasm. METTL16 resides in subcellular compartments co-inhabited by several other RNA modifiers and processing factors. FTO interactome positions this demethylase at a crossroad between RNA transcription, RNA processing and DNA replication and repair. Altogether, these enzymes share limited spatial interactomes, pointing to specific molecular mechanisms of their regulation.

RNA methylation in nuclear pre-mRNA processing.

Eukaryotic RNA can carry more than 100 different types of chemical modifications. Early studies have been focused on modifications of highly abundant RNA, such as ribosomal RNA and transfer RNA, but recent technical advances have made it possible to also study messenger RNA (mRNA). Subsequently, mRNA modifications, namely methylation, have emerged as key players in eukaryotic gene expression regulation. The most abundant and widely studied internal mRNA modification is N6 -methyladenosine (m6 A), but the list of mRNA chemical modifications continues to grow as fast as interest in this field. Over the past decade, transcriptome-wide studies combined with advanced biochemistry and the discovery of methylation writers, readers, and erasers revealed roles for mRNA methylation in the regulation of nearly every aspect of the mRNA life cycle and in diverse cellular, developmental, and disease processes. Although large parts of mRNA function are linked to its cytoplasmic stability and regulation of its translation, a number of studies have begun to provide evidence for methylation-regulated nuclear processes. In this review, we summarize the recent advances in RNA methylation research and highlight how these new findings have contributed to our understanding of methylation-dependent RNA processing in the nucleus. This article is categorized under: RNA Processing > RNA Editing and Modification RNA Processing > Splicing Regulation/Alternative Splicing RNA Interactions with Proteins and Other Molecules > Protein-RNA Interactions: Functional Implications.