Not all G-quadruplexes are created equally: an investigation of the structural polymorphism of the c-Myc G-quadruplex-forming sequence and its interaction with the porphyrin TMPyP4

Le, Huy T.; Miller, Michael C.; Buscaglia, Robert; Dean, William L.; Holt, Patrick A.; Chaires, Jonathan B.; Trent, John O.

doi:10.1039/c2ob26504d

Cited by 57 publications

(53 citation statements)

References 70 publications

(125 reference statements)

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“…A number of equilibrating G4s have been described in the MYC promoter (55), most famously two unique structures with loops of 1, 2 and 1 nucleotide in the 5′-3′ direction, and a few studies highlighting a less frequent 1–6–1 loop isomer (G4 1–5 ) (54). From linear DNA, this 1:2:1 loop isomer structure forms from the second through the fifth run of continuous guanines as demonstrated by both DMS and NMR (G4 2–5 ) (52,53).…”

Section: Discussionmentioning

confidence: 99%

Nucleic acid clamp-mediated recognition and stabilization of the physiologically relevant MYC promoter G-quadruplex

Hao

Gaerig

2016

Nucleic Acids Res

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The MYC proto-oncogene is upregulated, often at the transcriptional level, in ∼80% of all cancers. MYC's promoter is governed by a higher order G-quadruplex (G4) structure in the NHE III1 region. Under a variety of conditions, multiple isoforms have been described to form from the first four continuous guanine runs (G41–4) predominating under the physiologically relevant supercoiled conditions. In the current study, short oligonucleotides complementing the 5′- and 3′-regions flanking the G4 have been connected by an abasic linker to form G4 clamps, varying both linker length and G4 isoform being targeted. Clamp A with an 18 Å linker was found to have marked affinity for its target isomer (G41–4) over the other major structures (G42–5 and G41–5, recognized by clamps B and C, respectively), and to be able to shift equilibrating DNA to foster greater G4 formation. In addition, clamp A, but not B or C, is able to modulate MYC promoter activity with a significant and dose-dependent effect on transcription driven by the Del4 plasmid. This linked clamp-mediated approach to G4 recognition represents a novel therapeutic mechanism with specificity for an individual promoter structure, amenable to a large array of promoters.

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Section: Discussionmentioning

confidence: 99%

Nucleic acid clamp-mediated recognition and stabilization of the physiologically relevant MYC promoter G-quadruplex

Hao

Gaerig

2016

Nucleic Acids Res

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“…For long sequences it is essential to purchase gel purified material to minimize sample heterogeneity. In sample preparation, the annealing protocol used can play an important role in G-quadruplex formation (Le, et al, 2012). Samples at working concentrations of 2 – 10 μM (strand) are annealed by imersion into boiling water contained in a 1 L beaker for 5 minutes, after which the beaker is removed from the heat source and allowed to slow cool to room temperature overnight (12 – 24 hr).…”

Section: Experimental Determination By Analytical Ultracentrifugationmentioning

confidence: 99%

“…In contrast, an antiparallel basket quadruplex structure in Na + solution determined by NMR spectroscopy predicted hydrodynamic properties fully consistent with experimentally determined values. Recently we reported a more extensive validation of HYDROPRO predictions for a variety of quadruplex structures obtained by NMR (Le, Buscaglia, Dean, Chaires, & Trent, 2013; Le, Dean, Buscaglia, Chaires, & Trent, 2014; Le et al, 2012; Miller et al, 2011). We have also used this approach to access higher-order quadruplex structures (Petraccone, Garbett, Chaires, & Trent, 2010; Petraccone et al, 2011; Petraccone, Trent, & Chaires, 2008).…”

Section: Introductionmentioning

confidence: 99%

Hydrodynamic Models of G-Quadruplex Structures

Chaires

Dean

et al. 2015

Methods in Enzymology

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G-quadruplexes are noncannonical four-stranded DNA or RNA structures formed by guanine-rich repeating sequences. Guanines nucleotides can hydrogen bond to form a planar tetrad structure. Such tetrads can stack to form quadruplexes of various molecularities with a variety of types of single-stranded loops joining the tetrads. High-resolution structures may be obtained by X-ray crystallography or NMR spectroscopy for quadruplexes formed by short (≈25 nt) sequences but these methods have yet to succeed in characterizing higher-order quadruplex structures formed by longer sequences. An integrated computational and experimental approach was implemented in our laboratory to obtain structural models for higher-order quadruplexes that might form in longer telomeric or promoter sequences. In our approach atomic-level models are built using folding principles gleaned from available high-resolution structures and then optimized by molecular dynamics. The program HYDROPRO is then used to construct bead models of these structures to predict experimentally testable hydrodynamic properties. Models are validated by comparison of these properties with measured experimental values obtained by analytical ultracentrifugation or other biophysical tools. This chapter describes our approach and practical procedures.

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“…Similarly to native chloroperoxidase, CPO, or cytochrome P450, the hemin/G-quadruplex can also catalyze a two-electron oxidation processes that are characterized by an oxygen atom transfer to the substrate [46]. Examples of these reactions are outlined in Scheme 1, Equations 1-3, where H 2 O 2 stimulates the oxidation of thioanisole, (8), to thioanisole sulfoxide, (9), Equation 1, the epoxidation of styrene, (10), to styrene oxide, (11), (with the phenylacetaldehyde coproduct, (12)), Equation 2, and the oxygen transfer to indole, (13), followed by the C-C coupling of the oxo-indole radical cation, (14), intermediate to indigo, (15), Equation 3.…”

Section: Synthetic Applications Of Metal Porphyrinfunctionalized G-qumentioning

confidence: 99%

“…For instance, the cationic Mn(III)-tetramethylpyridinium porphyrin, Mn(III)-TMPyP4, (22), bound to the G-quadruplex nanostructure was found to catalyze oxygen transfer reactions to olefins using persulfate, (23), as an oxygen source, to yield epoxides [50], Scheme 3, Equation 12. Specifically, the epoxidation of carbamazepine, (24), to carbamazepine-10,11-oxide, (25), Equation 13, was examined using different Mn(III)-TMPyP4-functiona lized G-quadruplexes as catalysts [50], Fig.…”

Section: Synthetic Applications Of Metal Porphyrinfunctionalized G-qumentioning

confidence: 99%

Metalloporphyrin/G-quadruplexes: From basic properties to practical applications

Golub

Lü

Willner

2015

J. Porphyrins Phthalocyanines

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Guanine-rich nucleic acids stimulate the formation of planar, Hoogsteen hydrogen bonds-stabilized G-quartet (1), Fig. 1(a). The following p-p stacking of G-quartets, leads to the self-assembly of G-quadruplexes. These G-quadruplexes reveal cation-induced stabilization by means of coordination, mainly in the presence of monovalent ions, generally in the order of stabilization of K + > NH 4 + > Rb + > Na + > Cs + > Li + [1]. The resulting G-quadruplexes may adopt various topologies, such as parallel, anti-parallel or mixed strand configurations [2]. For example, Fig. 1(b) outlines various forms of four-layer guanine-quartets exhibiting different configurations: (i) edge-loop dimeric hairpin structure, (ii) diagonal-loop dimeric hairpin, (iii) unimolecular single strand with diagonal central loop, and (iv) unimolecular edge-type ABSTRACT: Guanine-rich single-stranded nucleic acids self-assemble into G-quadruplex nanostructures (predominately in the presence of K + -ions). Metalloporphyrins bind to the G-quadruplex nanostructures to form supramolecular assemblies exhibiting unique catalytic, electrocatalytic and photophysical properties. This paper addresses the advances in the characterization and the implementation of the metalloporphyrin/G-quadruplexes complexes for various applications. Out of the different complexes, the most extensively studied complexes are the hemin/G-quadruplex horseradish peroxidase-mimicking DNAzyme and the Zn(II)-protoporphyrin IX-functionalized G-quadruplex. Specifically, the hemin/Gquadruplex was found to act as a catalyst for driving different chemical transformations that mimic the native horseradish peroxidase enzyme, and, also, to function as an electrocatalyst for the reduction of H 2 O 2 . Also, the hemin/G-quadruplex stimulates interesting photophysical and photocatalytic processes such as the electron-transfer quenching of semiconductor quantum dots or the chemiluminescence resonance energy transfer to semiconductor quantum dots. Alternatively, Zn(II)-protoporphyrin IX associated with G-quadruplexes exhibit intensified fluorescence properties. Beyond the straight forward application of the metalloporphyrin/G-quadruplexes as catalysts that stimulate different chemical transformations, the specific catalytic, electrocatalytic and photocatalytic functions of hemin/G-quadruplexes are heavily implemented to develop sophisticated colorimetric, electrochemical, and optical sensing platforms. Also, the unique fluorescence properties of Zn(II)-protoporphyrin IX-functionalized G-quadruplexes are applied to develop fluorescence sensing platforms. The article exemplifies different sensing assays for analyzing DNA, ligand-aptamer complexes and telomerase activity using the metalloporphyrins/Gquadruplexes as transducing labels. Also, the use of the hemin/G-quadruplex as a probe to follow the operations of DNA machines is discussed.

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Not all G-quadruplexes are created equally: an investigation of the structural polymorphism of the c-Myc G-quadruplex-forming sequence and its interaction with the porphyrin TMPyP4

Cited by 57 publications

References 70 publications

Nucleic acid clamp-mediated recognition and stabilization of the physiologically relevant MYC promoter G-quadruplex

Nucleic acid clamp-mediated recognition and stabilization of the physiologically relevant MYC promoter G-quadruplex

Hydrodynamic Models of G-Quadruplex Structures

Metalloporphyrin/G-quadruplexes: From basic properties to practical applications

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