TY - JOUR
T1 - Long-Distance Communication in the HDV Ribozyme
T2 - Insights from Molecular Dynamics and Experiments
AU - Veeraraghavan, Narayanan
AU - Bevilacqua, Philip C.
AU - Hammes-Schiffer, Sharon
N1 - Funding Information:
We thank Alexander Soudackov and Barbara Golden for helpful comments. This study was supported by National Institutes of Health Grants GM58709 (P.C.B.) and GM56207 (S.H.-S.). This work was also supported in part through instrumentation funded by the National Science Foundation through grant OCI-0821527.
PY - 2010/9
Y1 - 2010/9
N2 - The hepatitis delta virus ribozyme is a small, self-cleaving RNA with a compact tertiary structure and buried active site that is important in the life cycle of the virus. The ribozyme's function in nature is to cleave an internal phosphodiester bond and linearize concatemers during rolling circle replication. Crystal structures of the ribozyme have been solved in both pre-cleaved and post-cleaved (product) forms and reveal an intricate network of interactions that conspire to catalyze bond cleavage. In addition, extensive biochemical studies have been performed to work out a mechanism for bond cleavage in which C75 and a magnesium ion catalyze the reaction by general acid-base chemistry. One issue that has remained unclear in this ribozyme and in other ribozymes is the nature of long-distance communication between peripheral regions of the RNA and the buried active site. We performed molecular dynamics simulations on the hepatitis delta virus ribozyme in the product form and assessed communication between a distal structural portion of the ribozyme-the protonated C41 base triple-and the active site containing the critical C75. We varied the ionization state of C41 in both the wild type and a C41 double mutant variant and determined the impact on the active site. In all four cases, effects at the active site observed in the simulations agree with experimental studies on ribozyme activity. Overall, these studies indicate that small functional RNAs have the potential to communicate interactions over long distances and that wild-type RNAs may have evolved ways to prevent such interactions from interfering with catalysis.
AB - The hepatitis delta virus ribozyme is a small, self-cleaving RNA with a compact tertiary structure and buried active site that is important in the life cycle of the virus. The ribozyme's function in nature is to cleave an internal phosphodiester bond and linearize concatemers during rolling circle replication. Crystal structures of the ribozyme have been solved in both pre-cleaved and post-cleaved (product) forms and reveal an intricate network of interactions that conspire to catalyze bond cleavage. In addition, extensive biochemical studies have been performed to work out a mechanism for bond cleavage in which C75 and a magnesium ion catalyze the reaction by general acid-base chemistry. One issue that has remained unclear in this ribozyme and in other ribozymes is the nature of long-distance communication between peripheral regions of the RNA and the buried active site. We performed molecular dynamics simulations on the hepatitis delta virus ribozyme in the product form and assessed communication between a distal structural portion of the ribozyme-the protonated C41 base triple-and the active site containing the critical C75. We varied the ionization state of C41 in both the wild type and a C41 double mutant variant and determined the impact on the active site. In all four cases, effects at the active site observed in the simulations agree with experimental studies on ribozyme activity. Overall, these studies indicate that small functional RNAs have the potential to communicate interactions over long distances and that wild-type RNAs may have evolved ways to prevent such interactions from interfering with catalysis.
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U2 - 10.1016/j.jmb.2010.07.025
DO - 10.1016/j.jmb.2010.07.025
M3 - Article
C2 - 20643139
AN - SCOPUS:77956170803
SN - 0022-2836
VL - 402
SP - 278
EP - 291
JO - Journal of Molecular Biology
JF - Journal of Molecular Biology
IS - 1
ER -