AI Article Synopsis
- Nucleotide selection plays a crucial role in ensuring accurate gene replication and transcription, with Tyr(639) identified as key to this process in T7 RNA polymerase.
- A molecular-dynamics simulation reveals that Tyr(639) stabilizes at the active site, blocking noncognate nucleotides and allowing only cognate ones to proceed with insertion.
- The study also highlights how water molecules aid in RNA nucleotide recognition and how a mutant form of the polymerase (Y639F) fails to effectively differentiate between RNA and DNA nucleotides during preinsertion.
Article Abstract
Nucleotide selection is essential for fidelity control in gene replication and transcription. Recent work on T7 RNA polymerase suggested that a small posttranslocation free energy bias stabilizes Tyr(639) in the active site to aid nucleotide selection. However, it was not clear exactly how Tyr(639) assists the selection. Here we report a molecular-dynamics simulation study revealing atomistic detail of this critical selectivity. The study shows first that Tyr(639) blocks the active site at posttranslocation by marginally stacking to the end basepair of the DNA-RNA hybrid. The study then demonstrates that at the nucleotide preinsertion state, a cognate RNA nucleotide does not affect the local Tyr(639) stabilization, whereas a noncognate nucleotide substantially stabilizes Tyr(639) so that Tyr(639) keeps blocking the active site. As a result, further nucleotide insertion into the active site, which requires moving Tyr(639) out of the site, would be hindered for the noncognate nucleotide, but not for the cognate nucleotide. In particular, we note that water molecules assist the ribose recognition in the RNA nucleotide preinsertion, and help Tyr(639) stacking to the end basepair in the case of a DNA nucleotide. It was also seen that a base-mismatched nucleotide at preinsertion directly grabs Tyr(639) for the active site stabilization. We also find that in a mutant polymerase Y639F the strong stabilization of residue 639 in the active site cannot establish upon the DNA nucleotide preinsertion. The finding explains the reduced differentiation between ribo- and deoxyribonucleotides that has been recorded experimentally for the mutant polymerase.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC4223216 | PMC |
| http://dx.doi.org/10.1016/j.bpj.2014.09.038 | DOI Listing |
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