A modular approach to enzymatic ligation of peptides and proteins with oligonucleotides.

Joining peptides and oligonucleotides offers potential benefits, but current methods remain laborious. Here we present a novel approach towards enzymatic ligation of the two modalities through the development of tag phosphoramidites as adaptors that can be readily incorporated onto oligonucleotides. This simple and highly efficient approach paves the way towards streamlined development and production of peptide/protein-oligonucleotide conjugates.

Stapling a G-quadruplex specific peptide.

G-quadruplex (G4) is a non-canonical four-stranded nucleic acid structure and the RHAU helicase has been identified to have high specificity for recognition of parallel-stranded G4s. We have designed and synthesized two stapled peptide analogues of the G4-specfic motif of RHAU, which preserve the G4 binding ability. Characterization of these peptides identified the stapled variants to exhibit higher helical formation propensity in aqueous buffer in comparison to the native RHAU sequence. Moreover, the stapled peptides exhibit superior enzymatic stability towards α-chymotrypsin. Our stapled RHAU peptides can serve as a new tool for targeting G4 nucleic acid structures.

Recognition of different base tetrads by RHAU (DHX36): X-ray crystal structure of the G4 recognition motif bound to the 3'-end tetrad of a DNA G-quadruplex.

G-quadruplexes (G4) are secondary structures of nucleic acids that can form in cells and have diverse biological functions. Several biologically important proteins interact with G-quadruplexes, of which RHAU (or DHX36) - a helicase from the DEAH-box superfamily, was shown to bind and unwind G-quadruplexes efficiently. We report a X-ray co-crystal structure at 1.5 Šresolution of an N-terminal fragment of RHAU bound to an exposed tetrad of a parallel-stranded G-quadruplex. The RHAU peptide folds into an L-shaped α-helix, and binds to a G-quadruplex through π-stacking and electrostatic interactions. X-ray crystal structure of our complex identified key amino acid residues important for G-quadruplex-peptide binding interaction at the 3'-end G•G•G•G tetrad. Together with previous solution and crystal structures of RHAU bound to the 5'-end G•G•G•G and G•G•A•T tetrads, our crystal structure highlights the occurrence of a robust G-quadruplex recognition motif within RHAU that can adapt to different accessible tetrads.

Inverting the G-Tetrad Polarity of a G-Quadruplex by Using Xanthine and 8-Oxoguanine.

G-quadruplexes are four-stranded nucleic acid structures that are built from consecutively stacked guanine tetrad (G-tetrad) assemblies. The simultaneous incorporation of two guanine base lesions, xanthine (X) and 8-oxoguanine (O), within a single G-tetrad of a G-quadruplex was recently shown to lead to the formation of a stable G⋅G⋅X⋅O tetrad. Herein, a judicious introduction of X and O into a human telomeric G-quadruplex-forming sequence is shown to reverse the hydrogen-bond polarity of the modified G-tetrad while preserving the original folding topology. The control exerted over G-tetrad polarity by joint X⋅O modification will be valuable for the design and programming of G-quadruplex structures and their properties.

Xanthine and 8-oxoguanine in G-quadruplexes: formation of a G·G·X·O tetrad.

G-quadruplexes are four-stranded structures built from stacked G-tetrads (G·G·G·G), which are planar cyclical assemblies of four guanine bases interacting through Hoogsteen hydrogen bonds. A G-quadruplex containing a single guanine analog substitution, such as 8-oxoguanine (O) or xanthine (X), would suffer from a loss of a Hoogsteen hydrogen bond within a G-tetrad and/or potential steric hindrance. We show that a proper arrangement of O and X bases can reestablish the hydrogen-bond pattern within a G·G·X·O tetrad. Rational incorporation of G·G·X·O tetrads in a (3+1) G-quadruplex demonstrated a similar folding topology and thermal stability to that of the unmodified G-quadruplex. pH titration conducted on X·O-modified G-quadruplexes indicated a protonation-deprotonation equilibrium of X with a pKa ∼6.7. The solution structure of a G-quadruplex containing a G·G·X·O tetrad was determined, displaying the same folding topology in both the protonated and deprotonated states. A G-quadruplex containing a deprotonated X·O pair was shown to exhibit a more electronegative groove compared to that of the unmodified one. These differences are likely to manifest in the electronic properties of G-quadruplexes and may have important implications for drug targeting and DNA-protein interactions.

Insights into G-quadruplex specific recognition by the DEAH-box helicase RHAU: Solution structure of a peptide-quadruplex complex.

Four-stranded nucleic acid structures called G-quadruplexes have been associated with important cellular processes, which should require G-quadruplex-protein interaction. However, the structural basis for specific G-quadruplex recognition by proteins has not been understood. The DEAH (Asp-Glu-Ala-His) box RNA helicase associated with AU-rich element (RHAU) (also named DHX36 or G4R1) specifically binds to and resolves parallel-stranded G-quadruplexes. Here we identified an 18-amino acid G-quadruplex-binding domain of RHAU and determined the structure of this peptide bound to a parallel DNA G-quadruplex. Our structure explains how RHAU specifically recognizes parallel G-quadruplexes. The peptide covers a terminal guanine base tetrad (G-tetrad), and clamps the G-quadruplex using three-anchor-point electrostatic interactions between three positively charged amino acids and negatively charged phosphate groups. This binding mode is strikingly similar to that of most ligands selected for specific G-quadruplex targeting. Binding to an exposed G-tetrad represents a simple and efficient way to specifically target G-quadruplex structures.

Rapid chemical ligation of oligonucleotides by the Diels-Alder reaction.

Extremely fast and efficient Diels-Alder chemical ligation of furan and maleimide oligonucleotides has been carried out in aqueous buffer. It was possible to ligate three oligonucleotides simultaneously in a controlled manner with the aid of a complementary splint. The templated reactions proceeded within 1 min at room temperature whereas non-templated reactions were slow and incomplete. Rapid and clean methods of DNA ligation such as the one demonstrated here have potential uses in biology and nanotechnology.

A helix swapping study of two protein cages.

Protein cages have been the focus of studies across multiple scientific disciplines. They have been used to deliver drugs, as templates for nanostructured materials, as substrates in the development of bio-orthogonal chemistry, and to restrict diffusion to study spatially confined reactions. Although their monomers fold into four-helix bundle structures, two cage proteins, DPS and BFR, self-assemble to form a 12-mer with tetrahedral symmetry and an octahedrally symmetric 24-mer, respectively. These monomers share strong similarities of both sequence and tertiary structure. However, they differ in the presence of a short additional helix. In BFR, the fifth helix is at the C-terminus and is positioned along the 4-fold symmetry axis, whereas with DPS, an extra helix helps to define the 2-fold axis in the cage and is located between the second and third helices in the monomer bundle. In an attempt to investigate if these short helices govern protein assembly, mutants were designed and produced that delete and swap these minidomains. All mutants form highly helical structures that unfold cooperatively as evidenced by thermal melting followed by circular dichroism. Dynamic light scattering, size exclusion chromatography, and sedimentation equilibrium experiments demonstrated that although many of the BFR mutants do not self-assemble and form lower-order complexes, many DPS mutants could form cages despite their unnatural design. Taken together, our data indicate that the BC helix is less important than the E helix for overall cage self-assembly, suggesting that dimerization may not play a role in nanostructure formation that is as key as previously assumed. Additionally, we found that fusing the minidomain from BFR onto DPS results in a mutant that assembles into a homogeneous population of a novel protein oligomer. This assembled cage while still formed from 12 subunits is larger in overall shape than that of the native protein.