Abstract
The identification of four-stranded G-quadruplexes (G4s) has highlighted the fact that DNA has additional spatial organisations at its disposal other than double-stranded helices. Recently, it became clear that the formation of G4s is not limited to the traditional G3+NL1G3+NL2G3+NL3G3+ sequence motif. Instead, the G3 triplets can be interrupted by deoxythymidylate (DNA) or uridylate (RNA) where the base forms a bulge that loops out from the G-quadruplex core. Here, we report the first high-resolution X-ray structure of a unique unimolecular DNA G4 with a cytosine bulge. The G4 forms a dimer that is stacked via its 5′-tetrads. Analytical ultracentrifugation, static light scattering and small angle X-ray scattering confirmed that the G4 adapts a predominantly dimeric structure in solution. We provide a comprehensive comparison of previously published G4 structures containing bulges and report a special γ torsion angle range preferentially populated by the G4 core guanylates adjacent to bulges. Since the penalty for introducing bulges appears to be negligible, it should be possible to functionalize G4s by introducing artificial or modified nucleotides at such positions. The presence of the bulge alters the surface of the DNA, providing an opportunity to develop drugs that can specifically target individual G4s.
Highlights
Fit The top and residuals5 of (A) panel shows the c(s) species analysis2 with 2 species, (B) c(s) analysis4 and distribution and the bottom panel the c(s, *) distribution. sluce(ss,wfre) raencaolyrrseisc3teind to standard conditions. (E) Plot of frictional ratio fr versus uncorrected sedimentation coefficient s as obtained from c(s, fr) analysis. (F) Plot of molecular mass M versus uncorrected sedimentation coefficient s as obtained from c(s, fr) analysis
Residuals5 of (A) panel shows the c(s) species analysis2 with 2 species, (B) c(s) analysis4 and distribution and the bottom panel the c(s, *) distribution. sluce(ss,wfre) raencaolyrrseisc3teind to standard conditions. (E) Plot of frictional ratio fr versus uncorrected sedimentation coefficient s as obtained from c(s, fr) analysis. (F) Plot of molecular mass M versus uncorrected sedimentation coefficient s as obtained from c(s, fr) analysis
Residuals5 of (A) panel shows the c(s) species analysis2 with 2 species, (B) c(s) analysis4 and distribution and the bottom panel the c(s, *) distribution. s (C) c(s, values wfre) raencaolyrrseisc3teind to standard conditions. (E) Plot of frictional ratio fr versus uncorrected sedimentation coefficient s as obtained from c(s, fr) analysis. (F) Plot of molecular mass M versus uncorrected sedimentation coefficient s as obtained from c(s, fr) analysis
Summary
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