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New tools provide a second look at HDV ribozyme structure, dynamics and cleavage

Nucleic Acids Research (2014) 42(20) 12833-12846
DOI: 10.1093/nar/gku992
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Abstract

The hepatitis delta virus (HDV) ribozyme is a selfcleaving RNA enzyme essential for processing viral transcripts during rolling circle viral replication. The first crystal structure of the cleaved ribozyme was solved in 1998, followed by structures of uncleaved, mutant-inhibited and ion-complexed forms. Recently, methods have been developed that make the task of modeling RNA structure and dynamics significantly easier and more reliable. We have used ERRASER and PHENIX to rebuild and re-refine the cleaved and cis-acting C75U-inhibited structures of the HDV ribozyme. The results correct local conformations and identify alternates for RNA residues, many in functionally important regions, leading to improved R values and model validation statistics for both structures. We compare the rebuilt structures to a higher resolution, trans-acting deoxy-inhibited structure of the ribozyme, and conclude that although both inhibited structures are consistent with the currently accepted hammerhead-like mechanism of cleavage, they do not add direct structural evidence to the biochemical and modeling data. However, the rebuilt structures (PDBs: 4PR6, 4PRF) provide a more robust starting point for research on the dynamics and catalytic mechanism of the HDV ribozyme and demonstrate the power of new techniques to make significant improvements in RNA structures that impact biologically relevant conclusions.

Figures

  • Figure 1. Superposition of the three crystal structures of the HDV ribozyme: rebuilt cis-acting C75U-inhibited (PDB ID: 4PRF in gold), rebuilt cleaved (PDB ID: 4PR6 in blue) and trans-acting deoxy-inhibited (PDB ID: 3NKB, ribozyme in green, substrate strand in light green). Active-site metal ions for the two inhibited structures are also shown in corresponding colors. The region surrounding the metal ions forms the active site.
  • Figure 2. Sequences of the three HDV ribozyme crystal structures, aligned with the full-length ribozyme. The colors of the PDB IDs correspond to the colors of the splines in Figure 1. Residues discussed individually in the paper are highlighted in cyan and are in bold. Part of the P4 stem-loop was replaced by residues shown in smaller italics (U1A hairpin sequence motif in 1CX0/4PR6 and 1VC7/4PRF, and GAAA loop in 3NKB) to aid crystallization. These residues (146–159 in 1CX0/4PR6 and 1VC7/4PRF, 50–53 in 3NKB) do not have a corresponding sequence number in the full-length HDV ribozyme.
  • Figure 3. U23 and Mg2+ of the cleaved structure with Fo-Fc difference density at 3.5σ contour level. Here and in later figures, the blue and orange mesh correspond to positive and negative difference density respectively, hydrogen bonds are shown as green dotted pillows, steric clashes as hotpink spikes, ribose pucker outliers as magenta crosses, and bond-length or bond-angle outliers as springs or fans (blue if too small, red if too large). (a) The base and backbone of U23 in the original structure (1CX0), with the modeling errors highlighted. (b) Alternate conformations of U23 in the rebuilt structure (4PR6), with the backbone (gold), base (orange) and metal ion (brown) for the new conformation. All the modeling errors are corrected, and the difference density peaks have disappeared.
  • Figure 4. G25 and U20 in the cleaved ribozyme structure with Fo-Fc difference density at 3.5σ contour level. The hydrogen-bonded heavy atoms of U20 and G25 are highlighted as atom-colored balls. (a) Original structure (1CX0) and original density. (b) Reverse GU wobble base pair in the rebuilt structure (4PR6). U20 now makes hydrogen bonds with G25, and the positive difference density peak has disappeared.
  • Table 1. MolProbity statistics for the original cleaved structure (PDB ID: 1CX0) and its rebuilt version (PDB ID: 4PR6)
  • Figure 5. Base and backbone of residue A16 for the C75U-inhibited structure, with 2Fo-Fc electron density at 1σ contour level. The hydrogen-bonded heavy atoms of the base of A16 are highlighted as atom-colored balls. Here and in later figures, hydrogen bonds are shown as green dotted pillows and clashes as hotpink spikes. (a) A16 in the original structure (1VC7) and original density. The base of A16 clashes with a water molecule (peach ball). (b) The two alternate conformations for A16 in the rebuilt structure (4PRF) and new density.
  • Figure 6. G25:U20 base pair and themetal ion (gray ball) in theC75U-inhibited structure in 2Fo-Fc electron densitymap at 1σ contour level. The hydrogenbonded heavy atoms of G25 and U20 are highlighted as atom-colored balls. Here and in later figures, ribose pucker outliers are shown as magenta crosses. (a) Hoogsteen-WC base pair in the original structure (1VC7) and original density. Both G25 and U20 are ribose pucker outliers. (b) Reverse wobble base pair in the rebuilt structure (4PRF) and new density. Both ribose pucker outliers are corrected.
  • Figure 7. The active site of the C75U-inhibited ribozyme, with the catalytic metal ion (gray ball). The gold balls highlight the oxygen atoms in the metal ion neighborhood, and the dotted lines indicate metal ion interactions. Here and in later figures, bond-length outliers are shown as red and blue spirals, and bond-angle outliers are shown as red and blue fans. (a) Original structure (1VC7). The active site has a number of modeling errors. (b) The rebuilt structure (4PRF) active site, with all modeling errors corrected.

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APA

Kapral, G. J., Jain, S., Noeske, J., Doudna, J. A., Richardson, D. C., & Richardson, J. S. (2014). New tools provide a second look at HDV ribozyme structure, dynamics and cleavage. Nucleic Acids Research, 42(20), 12833–12846. https://doi.org/10.1093/nar/gku992

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