2′-Fluoroarabinonucleic acid modification traps G-quadruplex and i-motif structures in human telomeric DNA

Assi, Hala Abou; El-Khoury, Roberto; González, Carlos; Damha, Masad J.

doi:10.1093/nar/gkx838

Cited by 32 publications

(32 citation statements)

References 63 publications

(57 reference statements)

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“…Thus, i-motif structures were observed at neutral pH and low temperatures under molecular crowding conditions ( 18 , 19 ), under negative superhelicity ( 20 ), in the presence of silver ( 21 ) or copper (I) cations ( 22 ), and inside silica nano-channels ( 23 ). Chemical modifications such as 2′-deoxy-2′-fluoro-arabinocytidine (2′F-araC, known as 2′F-ANA) also induce formation of DNA i-motif structures under neutral conditions ( 24 , 25 ).…”

Section: Dna I-motif-structural Featuresmentioning

confidence: 99%

i-Motif DNA: structural features and significance to cell biology

Assi

Garavís

González

et al. 2018

Nucleic Acids Research

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The i-motif represents a paradigmatic example of the wide structural versatility of nucleic acids. In remarkable contrast to duplex DNA, i-motifs are four-stranded DNA structures held together by hemi- protonated and intercalated cytosine base pairs (C:C+). First observed 25 years ago, and considered by many as a mere structural oddity, interest in and discussion on the biological role of i-motifs have grown dramatically in recent years. In this review we focus on structural aspects of i-motif formation, the factors leading to its stabilization and recent studies describing the possible role of i-motifs in fundamental biological processes.

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Section: Dna I-motif-structural Featuresmentioning

confidence: 99%

i-Motif DNA: structural features and significance to cell biology

Assi

Garavís

González

et al. 2018

Nucleic Acids Research

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327

292

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“…guanosines in the telomeric sequence AGGG(TTAGGG)3 with 2'F-araG leads to a 15°C 1 increase in Tm of the resulting intramolecular G4, and a shift from the usual antiparallel or 2 hybrid topology of this sequence (11,43) to a parallel conformation ( Figure 1a) (44). Here, we 3 demonstrate that G4 formed from the unmodified sequence (22G0) in KCl is a poor telomerase 4 substrate, leading to the previously-observed stuttering pattern (26) in a direct telomerase 5 extension assay involving incorporation of radiolabeled α 32 P-dGTP ( Figure 1b).…”

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confidence: 99%

“…It has previously been difficult to distinguish whether 22 it is the parallel or intermolecular nature of G4 structures that allows their recognition by 23 telomerase. Here, we overcome this difficulty by exploiting the stabilization of intramolecular 24 parallel G4 conferred by the modified nucleotide 2'F-araG (44), enabling the demonstration 1 that inter-and intramolecular parallel G4 are extended by telomerase using the same 3-step 2 mechanism. These data reveal human telomerase to be a parallel G4 resolvase.…”

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confidence: 99%

“…Oligonucleotides and G-quadruplex preparation 19 Most DNA oligonucleotides ( Supplementary Table 1) were purchased from Integrated DNA 20 Technologies and RNA oligonucleotides from Dharmacon, with purification by high 21 performance liquid chromatography (HPLC). Oligonucleotides 22G0, 22G3, and 22G0+tail 22 were synthesized as previously described (44). Synthesis of (C5-alkylamino)-dT-41G3 (the 23 equivalent of 22G3+tail prior to AlexaFluor 555 TM conjugation) was performed on an ABI 1 3400 DNA synthesizer (Applied Biosystems) at 1 μmol scale on Unylinker CPG solid support 2 (Chemgenes).…”

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confidence: 99%

“…Synthesis of (C5-alkylamino)-dT-41G3 (the 23 equivalent of 22G3+tail prior to AlexaFluor 555 TM conjugation) was performed on an ABI 1 3400 DNA synthesizer (Applied Biosystems) at 1 μmol scale on Unylinker CPG solid support 2 (Chemgenes). Conjugation of (C5-alkylamino)-dT-41G3 to AlexaFluor 555 TM NHS Ester to 3 produce the desired 22G3+tail oligonucleotide was achieved following the standard protocol product was purified by anion exchange HPLC as described (44). The peak of (C5- Table 1) under the same 23 folding conditions as given for 22G0.…”

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confidence: 99%

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A mechanism for the extension and unfolding of parallel telomeric G-quadruplexes by human telomerase at single-molecule resolution

Paudel

Moye

Assi

et al. 2020

Preprint

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1Telomeric G-quadruplexes (G4) were long believed to form a protective structure at telomeres, 2 preventing their extension by the ribonucleoprotein telomerase. Contrary to this belief, we have 3 previously demonstrated that parallel-stranded conformations of telomeric G4 can be extended 4 by human and ciliate telomerase. However, a mechanistic understanding of the interaction of 5 telomerase with structured DNA remained elusive. Here, we use single-molecule fluorescence 6 resonance energy transfer (smFRET) microscopy and bulk-phase enzymology to propose a 7 mechanism for the resolution and extension of parallel G4 by telomerase. Binding is initiated 8 by the RNA template of telomerase interacting with the G-quadruplex; nucleotide addition then 9 proceeds to the end of the RNA template. It is only through the large conformational change 10 of translocation following synthesis that the G-quadruplex structure is completely unfolded to 11 a linear product. Surprisingly, parallel G4 stabilization with either small molecule ligands or 12 by chemical modification does not always inhibit G4 unfolding and extension by telomerase. 13These data reveal that telomerase is a parallel G-quadruplex resolvase.14 Human chromosomes contain many guanine (G)-rich elements capable of forming four-1 stranded G-quadruplex (G4) structures (1-4). A planar G-quartet is formed when four Gs form 2 hydrogen bonds in a cyclical manner via their Hoogsteen faces; such G-quartets stack on top 3 of each other and form G-quadruplexes (5, 6). G-rich sequences are primarily located in 4 promoter regions, intron and exon boundaries, origins of replication and telomeres (1-4). 5Vertebrate telomeres consist of many tandem repeats of the sequence TTAGGG, comprising a 6 double-stranded region and a 3' G-rich overhang (7). Fluorescence microscopy studies have 7 reached, telomerase translocates downstream, resulting in re-alignment of the RNA template 1 with the new 3' end of the product DNA (19, 22). 2One function of telomeric G4 may be to act as a 'cap', protecting the telomere from DNA 3 degradation (24). It has been widely believed that G4 formation within the 3' telomeric 4 overhang blocks telomere extension by telomerase, since early in vitro studies had shown that 5 G4 structures inhibit telomerase extension of a telomeric DNA substrate (25,26). In addition, 6 stabilization of G4 with small-molecule ligands has been shown to more effectively inhibit 7 telomerase activity, suggesting that chemical stabilization of G4 structures may be a viable 8 anti-cancer therapeutic strategy (27)(28)(29). However, the above-mentioned studies did not 9 distinguish between G4 conformations, and used oligonucleotides that likely folded into anti-10 parallel or 'hybrid' G4 forms as a telomerase substrate. A variety of helicases, such as RECQ5, 11 WRN, BLM, FANC-J and RHAU, recognize and resolve G4 in a conformation-specific 12 manner (30)(31)(32)(33). Similarly, we have demonstrated that telomerase can bind and extend specific 13 conformations of telomeric G4 -those t...

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