2018
DOI: 10.1038/s41557-018-0046-3
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I-motif DNA structures are formed in the nuclei of human cells

Abstract: Human genome function is underpinned by the primary storage of genetic information in canonical B-form DNA, with a second layer of DNA structure providing regulatory control. I-motif structures are thought to form in cytosine-rich regions of the genome and to have regulatory functions; however, in vivo evidence for the existence of such structures has so far remained elusive. Here we report the generation and characterization of an antibody fragment (iMab) that recognizes i-motif structures with high selectivi… Show more

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Cited by 468 publications
(449 citation statements)
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“…The complementary sequence of a G4, thus enriched in cytosines, is known to form the i‐motif structure under acidic conditions in vitro, through the interaction of hemiprotonated cytosine–cytosine (C−C) base pairs (Scheme A and B) . Although this structure was first recognised in 1993, its biological functions are still poorly understood, partly because of the lack of selective and potent ligands . In the first study of a small molecule binding to i‐motif in 2000, the group of Hurley examined the interaction between the telomeric i‐motif and TMPyP4, which is a porphyrin‐type G4‐stabilising ligand .…”
Section: Methodsmentioning
confidence: 99%
“…The complementary sequence of a G4, thus enriched in cytosines, is known to form the i‐motif structure under acidic conditions in vitro, through the interaction of hemiprotonated cytosine–cytosine (C−C) base pairs (Scheme A and B) . Although this structure was first recognised in 1993, its biological functions are still poorly understood, partly because of the lack of selective and potent ligands . In the first study of a small molecule binding to i‐motif in 2000, the group of Hurley examined the interaction between the telomeric i‐motif and TMPyP4, which is a porphyrin‐type G4‐stabilising ligand .…”
Section: Methodsmentioning
confidence: 99%
“…Specifically cytosine‐ or guanine‐rich sequences form distinct and well‐defined higher‐order structures, which significantly differ from common helical B‐DNA conformations . A typical example are DNA i‐motifs with hemi‐protonated cytosine (C:H:C) + pairs (Figure ). In contrast to standard double‐stranded B‐DNA, cytosine pairs in i‐motifs at pH values around 4‐6 form a stabilizing third hydrogen bond due to the intercalation of a proton .…”
Section: Introductionmentioning
confidence: 99%
“…DNA strands with such capability are designated as DNA aptamers (Figure d) . Certain special structural motifs are reconfigurable as well, such as guanine‐ and cytosine‐rich sequences that can fold into stable quadruplexes in the presence of specific metal ions and low pH (Figure e) . Base stacking between blunt ends of DNA helices are ion‐ and temperature‐sensitive (Figure f), and are, therefore, able to reconfigure upon stimulation .…”
Section: Reconfigurable Elements For Constructing Dynamic Dna Structuresmentioning
confidence: 99%