Topological impact of noncanonical DNA structures on Klenow fragment of DNA polymerase

Takahashi, Shuntaro; Brazier, John A.; Sugimoto, Naoki

doi:10.1073/pnas.1704258114

Cited by 108 publications

(122 citation statements)

References 47 publications

(66 reference statements)

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“…From the therapeutic view point, we investigated whether the structural transformation by Fis influenced the replication reaction. Previously, we reported that the replication reaction can be affected by the formation of non-canonical structures on the template DNA and that the i-motif especially blocked the processivity of DNA polymerase efficiently 10 . For the replication analysis, a fluorescein-labelled primer and template DNA containing VEGF IM was designed as reported previously 10 .…”

Section: Effects Of Loop Sequence Of Vegf Im On Its Structural Transfmentioning

confidence: 99%

Preferential targeting cancer-related i-motif DNAs by the plant flavonol fisetin for theranostics applications

Takahashi

Bhattacharjee

Ghosh

et al. 2020

Sci Rep

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The relationship of i-motif DNAs with cancer has prompted the development of specific ligands to detect and regulate their formation. Some plant flavonols show unique fluorescence and anti-cancer properties, which suggest the utility of the theranostics approach to cancer therapy related to i-motif DNA. We investigated the effect of the plant flavonol, fisetin (Fis), on the physicochemical property of i-motif DNAs. Binding of Fis to the i-motif from the promoter region of the human vascular endothelial growth factor (VEGF) gene dramatically induced the excited state intramolecular proton transfer (ESIPT) reaction that significantly enhanced the intensity of the tautomer emission band of Fis. This unique response was due to the coincidence of the structural change from i-motif to the hairpin-like structure which is stabilized via putative Watson-Crick base pairs between some guanines within the loop region of the i-motif and cytosines in the structure. As a result, the VEGF i-motif did not act as a replication block in the presence of fis, which indicates the applicability of fis for the regulation of gene expression of VEGF. The fluorescence and biological properties of Fis may be utilised for theranostics applications for cancers related to a specific cancer-related gene, such as VEGF. Besides the canonical right-handed DNA double helix, DNA sequences can adopt non-canonical structures, including G-quadruplexes (G4s) and i-motifs, that are stabilised by non-Watson-Crick base pairing 1. G4 structures are formed from guanine (G)-rich sequences, whereas i-motifs are formed from the cytosine (C)-rich sequences. The i-motif structure consists of two parallel duplexes that intercalate with each other in an antiparallel orientation (Fig. 1A). The parallel duplexes are held together via hydrogen bonding between a neutral cytosine (C) and a protonated cytosine (C +) (Fig. 1B) 2. The formation of an i-motif structure occurs more readily in an acidic condition because protonation of cytosine is required to form a hemiprotonated CC + base pair. However, there is increasing evidence to suggest that the i-motif structures can also form at neutral pH 3,4 and even in the nuclei of living mammalian cells 5,6. The i-motif forming sequences are found in or near the promoter regions of >40% of all human genes, which can regulate the expressions of genes like Bcl2 7,8 and HRAS 9. Furthermore, the i-motif along the cancer-related DNA sequences strongly inhibits DNA replication 10. Therefore, i-motif DNAs are attractive targets for the diagnosis of cancer risk and to treat cancer by the modulation of gene transcription and replication. Considering the use of specific targeted therapy based on specific targeted test (i.e., theranostics) for both diagnosis and therapeutics, some ligands that both emit a fluorescent signal upon binding to a specific i-motif and regulate the transcription or replication of the target gene are required. Currently, no ligands have such dual functions for i-motif DNAs. Flavonols and other related compounds o...

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Section: Effects Of Loop Sequence Of Vegf Im On Its Structural Transfmentioning

confidence: 99%

Preferential targeting cancer-related i-motif DNAs by the plant flavonol fisetin for theranostics applications

Takahashi

Bhattacharjee

Ghosh

et al. 2020

Sci Rep

Self Cite

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“…Only recently,t he i-motifs in promoter and telomeric regions were proposed to be implicated in the regulation of transcription [3] and the integrity of telomeric DNA. [4] However,d espite all available indications of i-motif function in vivo,t he biological relevance of i-motifs has remained am atter of dispute for the following reasons:1 )The lack of direct experimental evidence for the existence of i-motifs in vivo and 2) the very strong dependence of i-motif stability on chemical and physical environmental factors such as pH that generally appear to be incompatible with the parameters of the intracellular space.W hile i-motifs are rather stable in acidic pH, low ionic strength, and dehydrating conditions,the propensity for i-motifs is generally lower under simulated physiological conditions comprising relatively high ionic strength (ca.…”

mentioning

confidence: 99%

“…[12] In biological terms,o ur results support the concept that i-motif structures may act as active regulators of genomic DNAa nd potential drug targets. [3,4,13] …”

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Evaluation of the Stability of DNA i‐Motifs in the Nuclei of Living Mammalian Cells

et al. 2018

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C-rich DNAh as the capacity to form at etrastranded structure knowna sa ni -motif.T he i-motifs within genomic DNAh ave been proposed to contribute to the regulation of DNAtranscription. However,direct experimental evidence for the existence of these structures in vivo has been missing. Whether i-motif structures form in complex environment of living cells is not currently known. Herein, using stateof-the-art in-cell NMR spectroscopy, we evaluate the stabilities of i-motif structures in the complex cellular environment. We show that i-motifs formed from naturally occurring C-rich sequences in the human genome are stable and persist in the nuclei of living human cells.O ur data show that i-motif stabilities in vivo are generally distinct from those in vitro.Our results are the first to interlink the stability of DNAi -motifs in vitro with their stability in vivo and provide essential information for the design and development of i-motif-based DNAbiosensors for intracellular applications.

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“…DNA i‐motifs are four‐stranded structures consisting of two parallel DNA duplexes zipped together by the intercalation of protonated cytosine–cytosine (C.CH + ) base pairs . These i‐motifs have recently been postulated to be actively involved in the regulation of DNA transcription . However, because i‐motif formation was never directly observed in vivo and because the formation of DNA i‐motifs is promoted by low ionic strength and acidic pH , that is, factors that are rather inconsistent with the physiological cellular environment, the existence of i‐motifs in vivo has been controversial.…”

Section: In‐cell Nmr Spectroscopymentioning

confidence: 99%

Advances in the cellular structural biology of nucleic acids

et al. 2018

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Conventional biophysical and chemical biology approaches for delineating relationships between the structure and biological function of nucleic acids (NAs) abstract NAs from their native biological context. However, cumulative experimental observations have revealed that the structure, dynamics and interactions of NAs might be strongly influenced by a broad spectrum of specific and nonspecific physical-chemical environmental factors. This consideration has recently sparked interest in the development of novel tools for structural characterization of NAs in the native cellular context. Here, we review the individual methods currently being employed for structural characterization of NA structure in a native cellular environment with a focus on recent advances and developments in the emerging fields of in-cell NMR and electron paramagnetic resonance spectroscopy and in-cell single-molecule FRET of NAs.

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Topological impact of noncanonical DNA structures on Klenow fragment of DNA polymerase

Cited by 108 publications

References 47 publications

Preferential targeting cancer-related i-motif DNAs by the plant flavonol fisetin for theranostics applications

Preferential targeting cancer-related i-motif DNAs by the plant flavonol fisetin for theranostics applications

Evaluation of the Stability of DNA i‐Motifs in the Nuclei of Living Mammalian Cells

Advances in the cellular structural biology of nucleic acids

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