Summary information and primary citation
- PDB-id
-
7l3r;
DSSR-derived features in text and
JSON formats
- Class
- RNA
- Method
- X-ray (1.01 Å)
- Summary
- 23s sarcin ricin loop with a 3-deazapurine a2670
- Reference
-
Bereiter R, Himmelstoss M, Renard E, Mairhofer E, Egger
M, Breuker K, Kreutz C, Ennifar E, Micura R (2021):
"Impact of
3-deazapurine nucleobases on RNA properties."
Nucleic Acids Res., 49,
4281-4293. doi: 10.1093/nar/gkab256.
- Abstract
- Deazapurine nucleosides such as 3-deazaadenosine (c3A)
are crucial for atomic mutagenesis studies of functional
RNAs. They were the key for our current mechanistic
understanding of ribosomal peptide bond formation and of
phosphodiester cleavage in recently discovered small
ribozymes, such as twister and pistol RNAs. Here, we
present a comprehensive study on the impact of c3A and the
thus far underinvestigated 3-deazaguanosine (c3G) on RNA
properties. We found that these nucleosides can decrease
thermodynamic stability of base pairing to a significant
extent. The effects are much more pronounced for
3-deazapurine nucleosides compared to their constitutional
isomers of 7-deazapurine nucleosides (c7G, c7A). We
furthermore investigated base pair opening dynamics by
solution NMR spectroscopy and revealed significantly
enhanced imino proton exchange rates. Additionally, we
solved the X-ray structure of a c3A-modified RNA and
visualized the hydration pattern of the minor groove.
Importantly, the characteristic water molecule that is
hydrogen-bonded to the purine N3 atom and always observed
in a natural double helix is lacking in the
3-deazapurine-modified counterpart. Both, the findings by
NMR and X-ray crystallographic methods hence provide a
rationale for the reduced pairing strength. Taken together,
our comparative study is a first major step towards a
comprehensive understanding of this important class of
nucleoside modifications.
