Qiuda Xu scite author profile

Switching of G-quadruplex (G4) structures between variant types of folding has been proved to be a versatile tool for regulation of genomic expression and development of nucleic acid-based constructs. Various specific ligands have been developed to target G4s in K+ solution with therapeutic prospects. Although G4 structures have been reported to be converted by sequence modification or a unimolecular ligand binding event in K+-deficient conditions, switching G4s towards non-G4 folding continues to be a great challenge due to the stability of G4 in physiological K+ conditions. Herein, we first observed the G4 switching towards parallel-stranded duplex (psDNA) by multimolecular ligand binding (namely ligand clustering) to overcome the switching barrier in K+. Purine-rich sequences (e.g. those from the KRAS promoter region) can be converted from G4 structures to dimeric psDNAs using molecular rotors (e.g. thioflavin T and thiazole orange) as initiators. The formed psDNAs provided multiple binding sites for molecular rotor clustering to favor subsequent structures with stability higher than the corresponding G4 folding. Our finding provides a clue to designing ligands with the competency of molecular rotor clustering to implement an efficient G4 switching.

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Selectively Identifying Exposed-over-Unexposed C–C⁺ Pairs in Human Telomeric i-Motif Structures with Length-Dependent Polymorphism

Yang

Chen

et al. 2022

Anal. Chem.

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The i-motif structure (iM) has attracted much attention, because of its in vivo bioactivity and wide in vitro applications such as DNA-based switches. Herein, the length-dependent folding of cytosine-rich repeats of the human telomeric 5′-(CCCTAA)n‑1CCC-3′ (iM-n, where n = 2–8) was fully explored. We found that iM-4, iM-5, and iM-8 mainly form the intramolecular monomer iM structures, while a tetramolecular structure populates only for iM-3. However, iM-6 and iM-7 have the potential to fold as well into the dimeric iM structures besides the monomer ones. The natural hypericin (Hyp) was used as the polymorphism-selective probe to recognize the iM structures. Interestingly, only iM-3, iM-6, and iM-7 can efficiently switch on the Hyp fluorescence by specifically binding with the outmost C–C+ base pairs that are exposed directly to solution. However, other iM structures that fold in a way with a coverage of the outmost C–C+ pairs by loop sequences are totally unavailable for the Hyp binding. Theoretical modeling indicates that adaptive π–π and cation-π interactions contribute to the Hyp recognition toward the exposed C–C+ pairs. This specific iM recognition can be boosted by a photocatalytic DNAzyme construct. Our work provides a reliable fluorescence method to selectively explore the polymorphism of iM structures.

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Qiuda Xu

Visible light-driven i-motif-based DNAzymes

A catalytic triplex DNAzyme for porphyrin metalation

Selectively recognizing extrahelical conformations of DNA trinucleotide repeats by a hydroxylated porphyrin ligand

Switching G-quadruplex to parallel duplex by molecular rotor clustering

Selectively Identifying Exposed-over-Unexposed C–C⁺ Pairs in Human Telomeric i-Motif Structures with Length-Dependent Polymorphism

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Qiuda Xu

Visible light-driven i-motif-based DNAzymes

A catalytic triplex DNAzyme for porphyrin metalation

Selectively recognizing extrahelical conformations of DNA trinucleotide repeats by a hydroxylated porphyrin ligand

Switching G-quadruplex to parallel duplex by molecular rotor clustering

Selectively Identifying Exposed-over-Unexposed C–C+ Pairs in Human Telomeric i-Motif Structures with Length-Dependent Polymorphism

Contact Info

Product

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Selectively Identifying Exposed-over-Unexposed C–C⁺ Pairs in Human Telomeric i-Motif Structures with Length-Dependent Polymorphism