Curated Optogenetic Publication Database

Abstract: RNA is the cornerstone of biology's central dogma, which was initially thought to serve only as an intermediate between DNA and protein. Decades of research, in particular the discovery of new classes of non-coding RNAs (ncRNAs), have unveiled a plethora of activities that RNAs can fulfil besides coding for proteins, ranging from catalysis over scaffolding to regulatory functions. These ncRNAs not only play important roles in healthy individuals, but also are implicated in a wide range of diseases, including cancers, cardiovascular and neurological diseases, which have been demonstrated in several clinical studies.1 For this reason, the study of RNA metabolism, including transcription, pre-mRNA processing, mRNA export, RNA trafficking and translation, represents a crucial milestone for understanding the biology of cells and molecular pathology of disease. However, when compared to our knowledge of proteins and genomes, our understanding of RNA's diverse biological roles is significantly lacking, in part because of the transient and complex dynamics of RNA and the challenges associated with precisely manipulating RNA metabolism from synthesis to degradation. While methods so far developed have made a significant impact in shedding light on the mysteries of RNA, tools that allow precise spatiotemporal control of RNA metabolism are still urgently needed for deeper insight into the diverse physiological functions of RNA.