Density- and elongation speed-dependent error correction in RNA polymerization

Backtracking of RNA polymerase (RNAP) is an important pausing mechanism during DNA transcription that is part of the error correction process that enhances transcription fidelity. We model the backtracking mechanism of RNA polymerase, which usually happens when the polymerase tries to incorporate a noncognate or "mismatched" nucleotide triphosphate. Previous models have made simplifying assumptions such as neglecting the trailing polymerase behind the backtracking polymerase or assuming that the trailing polymerase is stationary. We derive exact analytic solutions of a stochastic model that includes locally interacting RNAPs by explicitly showing how a trailing RNAP influences the probability that an error is corrected or incorporated by the leading backtracking RNAP. We also provide two related methods for computing the mean times for error correction and incorporation given an initial local RNAP configuration. Using these results, we propose an effective interacting-RNAP lattice that can be readily simulated.

Theoretical analysis of RNA polymerase fidelity: a steady-state copolymerization approach

The fidelity of DNA transcription catalyzed by RNA polymerase (RNAP) has long been an important issue in biology. Experiments have revealed that RNAP can incorporate matched nucleotides selectively and proofread the incorporated mismatched nucleotides. However, systematic theoretical researches on RNAP fidelity are still lacking. In the last decade, several theories on RNA transcription have been proposed, but they only handled highly simplified models without considering the high-order neighbor effects and the oligonucleotides cleavage both of which are critical for the overall fidelity. In this paper, we regard RNA transcription as a binary copolymerization process and calculate the transcription fidelity by the steady-state copolymerization theory recently proposed by us for DNA replication. With this theory, the more realistic models considering higher-order neighbor effects, oligonucleotides cleavage, multi-step incorporation and multi-step cleavage can be rigorously handled.

Targeted knockdown of the PAF49 component of the PAF53/PAF49 heterodimer causes the degradation of PAF53

There are significant differences in the components of the ribosomal DNA transcription apparatuses of yeast and mammals. Moreover, the patterns of regulation between mammals and yeast are also different. To overcome, deficits in our understanding of mammalian rDNA transcription, we have developed a system to introduce an inducible degron into the endogenous genes of mammalian cells. This allows us to combine a knock out the endogenous gene product and replace it with mutant proteins in order to study their function in ribosomal DNA transcription. Using this system, we show that the knockout of PAF49, the mammalian ortholog of yeast A34, results in the relatively rapid degradation of PAF53, the ortholog of yeast A49. Interestingly, the steady-state levels of the core subunits of RNA polymerase I are unaffected.

Application of Fluorescent turn-on Aptamers in RNA Studies

RNA is an intermediate player between DNA transcription and protein translation. RNAs also interact with other macromolecules, metabolites and regulate their fate. The emerging number of RNA identification expanded new...