Structural and mechanistic basis of reiterative transcription initiation

Structural visualization of transcription initiation in action

Transcription initiation is a complex process, and its mechanism is incompletely understood. We determined the structures of de novo transcribing complexes TC2 to TC17 with RNA polymerase II halted on G-less promoters when nascent RNAs reach 2 to 17 nucleotides in length, respectively. Connecting these structures generated a movie and a working model. As initially synthesized RNA grows, general transcription factors (GTFs) remain bound to the promoter and the transcription bubble expands. Nucleoside triphosphate (NTP)-driven RNA-DNA translocation and template-strand accumulation in a nearly sealed channel may promote the transition from initially transcribing complexes (ITCs) (TC2 to TC9) to early elongation complexes (EECs) (TC10 to TC17). Our study shows dynamic processes of transcription initiation and reveals why ITCs require GTFs and bubble expansion for initial RNA synthesis, whereas EECs need GTF dissociation from the promoter and bubble collapse for promoter escape.

Predicting Corynebacterium glutamicum promoters based on novel feature descriptor and feature selection technique

The promoter is an important noncoding DNA regulatory element, which combines with RNA polymerase to activate the expression of downstream genes. In industry, artificial arginine is mainly synthesized by Corynebacterium glutamicum. Replication of specific promoter regions can increase arginine production. Therefore, it is necessary to accurately locate the promoter in C. glutamicum. In the wet experiment, promoter identification depends on sigma factors and DNA splicing technology, this is a laborious job. To quickly and conveniently identify the promoters in C. glutamicum, we have developed a method based on novel feature representation and feature selection to complete this task, describing the DNA sequences through statistical parameters of multiple physicochemical properties, filtering redundant features by combining analysis of variance and hierarchical clustering, the prediction accuracy of the which is as high as 91.6%, the sensitivity of 91.9% can effectively identify promoters, and the specificity of 91.2% can accurately identify non-promoters. In addition, our model can correctly identify 181 promoters and 174 non-promoters among 400 independent samples, which proves that the developed prediction model has excellent robustness.

Purification of synchronized E. coli transcription elongation complexes by reversible immobilization on magnetic beads

Synchronized transcription elongation complexes (TECs) are a fundamental tool for in vitro studies of transcription and RNA folding. Transcription elongation can be synchronized by omitting one or more nucleoside triphosphates (NTPs) from an in vitro transcription reaction so that RNA polymerase can only transcribe to the first occurrence of the omitted nucleotide(s) in the coding DNA strand. This approach was developed over four decades ago and has been applied extensively in biochemical investigations of RNA polymerase enzymes, but has not been optimized for RNA-centric assays. In this work, we describe the development of a system for isolating synchronized TECs from an in vitro transcription reaction. Our approach uses a custom 5' leader sequence, called C3-SC1, to reversibly capture synchronized TECs on magnetic beads. We first show using electrophoretic mobility shift and high-resolution in vitro transcription assays that complexes isolated by this procedure, called ^C3-SC1TECs, are >95% pure, >98% active, highly synchronous (94% of complexes chase in <15s upon addition of saturating NTPs), and compatible with solid-phase transcription; the yield of this purification is ∼8%. We then show that ^C3-SC1TECs perturb, but do not interfere with, the function of ZTP (5-aminoimidazole-4-carboxamide riboside 5'-triphosphate)-sensing and ppGpp (guanosine-3',5'-bisdiphosphate)-sensing transcriptional riboswitches. For both riboswitches, transcription using ^C3-SC1TECs improved the efficiency of transcription termination in the absence of ligand but did not inhibit ligand-induced transcription antitermination. Given these properties, ^C3-SC1TECs will likely be useful for developing biochemical and biophysical RNA assays that require high-performance, quantitative bacterial in vitro transcription.

Cotranscriptional RNA Chemical Probing

Cotranscriptional folding is a fundamental step in RNA biogenesis and the basis for many RNA-mediated gene regulation systems. Understanding how RNA folds as it is synthesized requires experimental methods that can systematically identify intermediate RNA structures that form during transcription. Cotranscriptional RNA chemical probing experiments achieve this by applying high-throughput RNA structure probing to an in vitro transcribed array of cotranscriptionally folded intermediate transcripts. In this chapter, we present guidelines and procedures for integrating single-round in vitro transcription using E. coli RNA polymerase with high-throughput RNA chemical probing workflows. We provide an overview of key concepts including DNA template design, transcription roadblocking strategies, single-round in vitro transcription with E. coli RNA polymerase, and RNA chemical probing and describe procedures for DNA template preparation, cotranscriptional RNA chemical probing, RNA purification, and 3' adapter ligation. The end result of these procedures is a purified RNA library that can be prepared for Illumina sequencing using established high-throughput RNA structure probing library construction strategies.