Creative Math of RNA Polymerase III Termination: Sense Plus Antisense Makes More Sense

Genome editing with programmable base editors in human cells

Genome editing has garnered significant attention over the last decade, resulting in a massive expansion of the genome engineering toolbox. Base editors encompass a class of tools that enable installing single-nucleotide changes in genomic DNA without the use of double-strand breaks. With the ever-increasing development of new and/or improved base editor systems, it is easy to be overwhelmed by the abundance of options. Here, we provide clear guidance to facilitate the selection of a base editor and to design guide RNAs (gRNAs) to suit various needs. Additionally, we describe in detail how to generate gRNA plasmids, transfect various mammalian cell types, and evaluate editing efficiencies. Finally, we give alternative methods and troubleshooting tips for some common pitfalls encountered during base editing.

A high density of cis-information terminates RNA Polymerase III on a 2-rail track

Transcription termination delineates the 3' ends of transcripts, prevents otherwise runaway RNA polymerase (RNAP) from intruding into downstream genes and regulatory elements, and enables release of the RNAP for recycling. While other eukaryotic RNAPs require complex cis-signals and/or accessory factors to achieve these activities, RNAP III does so autonomously with high efficiency and precision at a simple oligo(dT) stretch of 5-6 bp. A basis for this high density cis-information is that both template and nontemplate strands of the RNAP III terminator carry distinct signals for different stages of termination. High-density cis-information is a feature of the RNAP III system that is also reflected by dual functionalities of the tRNA promoters as both DNA and RNA elements. We review emerging developments in RNAP III termination and single strand nontemplate DNA use by other RNAPs. Use of nontemplate signals by RNAPs and associated transcription factors may be prevalent in gene regulation.