Abstract
Non-coding RNAs (ncRNAs) are functional RNA molecules that comprise about 80% of both mammals and prokaryotes genomes. Recent studies have identified a large number of small regulatory RNAs in Escherichia coli and other bacteria. In prokaryotes, RNA regulators are a diverse group of molecules that modulate a wide range of physiological responses through a variety of mechanisms. Similar to eukaryotes, bacterial microRNAs are an important class of ncRNAs that play an important role in the development and secretion of proteins and in the regulation of gene expression. Similarly, riboswitches are cis-regulatory structured RNA elements capable of directly controlling the expression of downstream genes in response to small molecule ligands. As a result, riboswitches detect and respond to the availability of various metabolic changes within cells. The most extensive and most widely studied set of small RNA regulators act through base pairing with RNAs. These types of RNAs are vital for prokaryotic life, activating or suppressing important physiological processes by modifying transcription or translation. The majority of these small RNAs control responses to changes in environmental conditions. Finally, clustered regularly interspaced short palindromic repeat (CRISPR) RNAs, a newly discovered RNA regulator group, contains short regions of homology to bacteriophage and plasmid sequences that bacteria use to splice phage DNA as a defense mechanism. The detailed mechanism is still unknown but devoted to target homologous foreign DNAs. Here, we review the known mechanisms and roles of non-coding regulatory RNAs, with particular attention to riboswitches and their functions, briefly introducing translational applications of CRISPR RNAs in mammals.
Highlights
The cell regulatory network is a complex set of molecular factors that interact with each other and genes, controlling gene expression
Riboswitches are usually classified as metabolite-sensing RNAs, which are embedded within the 5 -untranslated region (UTR) of their mRNAs, and they respond to different environmental changes by altering gene expression and by binding to small molecules [4]
Hundreds of RNAs have been identified, each playing a specific role in regulating cellular processes and gene expression
Summary
The cell regulatory network is a complex set of molecular factors that interact with each other and genes, controlling gene expression. Researches in the last decade have confirmed the role of these ncRNAs in various processes [6] Based on their constitutive pair base, ncRNAs are divided into two main groups: small and large non-coding RNAs (sncRNAs and lncRNAs, respectively). Riboswitches sense and respond to the availability of different nutrients in cells, modulating metabolic pathways [2] These RNAs were first described 10 years ago and recognized as essential factors in controlling gene expression in a wide range of bacteria. Riboswitches are usually classified as metabolite-sensing RNAs, which are embedded within the 5 -untranslated region (UTR) of their mRNAs, and they respond to different environmental changes by altering gene expression and by binding to small molecules [4]. This review will summarize the genetic structure of prokaryotes and bacterial regulatory RNAs, focusing on small RNAs and riboswitches
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