The spliceosome, a protein-directed metallo-ribozyme, catalyzes premature mRNA splicing via two transesterification reactions. The atomic-level details of the splicing mechanism and the role of the entwined protein-RNA environment during catalysis remain unresolved. Here, quantum-classical molecular dynamics simulations along with thermodynamic integration unveil that the second catalytic (exon-ligation) step occurs via an associative two-Mg2+-ion mechanism, exclusively catalyzed by RNA, with the scissile phosphate mediating a proton transfer from the nucleophile to the leaving group. Our outcomes provide fundamental advances in understanding the splicing mechanism in eukaryotes disclosing how the catalytic core of spliceosome’s ancestors self-splicing ribozymes remained conserved during evolution.

J. Borišek and A. Magistrato. All-Atom Simulations Decrypt the Molecular Terms of RNA Catalysis in the Exon-Ligation Step of the Spliceosome. ACS Catal. 10, 9 (2020)

© 2020 American Chemical Society

https://doi.org/10.1021/acscatal.0c00390

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The spliceosome, a protein-directed metallo-ribozyme, catalyzes premature mRNA splicing via two transesterification reactions. The atomic-level details of the splicing mechanism and the role of the entwined protein-RNA environment during catalysis remain unresolved. Here, quantum-classical molecular dynamics simulations along with thermodynamic int https://pubs.acs.org/doi/abs/10.1021/acscatal.0c00390