Recognition of human telomeric G-quadruplex DNA by 1,5-disubstituted diethyl-amido anthraquinone derivative in different ion environments causing thermal stabilization and apoptosis.

Ligand binding to G-quadruplex (G4) structures at human telomeric DNA ends promotes thermal stabilization, disrupting the interaction of the telomerase enzyme, which is found active in 80-85% of cancers and serves as a molecular marker. Anthraquinone compounds are well-known G-quadruplex (G4) binders that inhibit telomerase and induce apoptosis in cancer cells. Our current investigation is based on 1,5-bis[3-(diethylamino)propionamido]anthracene-9,10-dione, a derivative of anthraquinone and its binding characterization with two different human telomeric DNA structures, wHTel26 and HTel22, in the effect of K+ and Na+ by using an array of biophysical, calorimetry, molecular docking and cell viability assay techniques. Binding constants (Kb) in the range of ∼105-107 M-1 and stoichiometries of 1:1, 2:1 & 4:1 were obtained from the absorbance, fluorescence, and circular dichroism study. Remarkable hypochromism (55, 97%) and ∼17 nm shift in absorbance, fluorescence quenching (95, 97%), the unaltered value of fluorescence lifetime, restoration of Circular Dichroism bands, absence of ICD band, indicated the external groove binding/binding somewhere at loops. This is also evident in molecular docking results, the ligand binds to groove forming base (G4, G5, G24, T25) and in the vicinity to TTA loop (G14, G15, T17) bases of wHTel26 and HTel22, respectively. Thermal stabilization induced by ligand was found greater in Na+ ion (27.5 °C) than (19.1 °C) in K+ ion. Ligand caused cell toxicity in MCF-7 cancer cell lines with an IC50 value of ∼8.4 µM. The above findings suggest the ligand, 1,5-bis[3-(diethylamino)propionamido]anthracene-9,10-dione could be a potent anticancer drug candidate and has great therapeutic implications.Binding of disubstituted amido anthraquinone derivative, 1,5-bis[3-(diethylamino)propionamido]anthracene-9,10-dione to human telomere HTel22 antiparallel conformation induced thermal stabilization.Communicated by Ramaswamy H. Sarma.

MOSR and NDHA Genes Comprising G-Quadruplex as Promising Therapeutic Targets against Mycobacterium tuberculosis: Molecular Recognition by Mitoxantrone Suppresses Replication and Gene Regulation.

Occurrence of non-canonical G-quadruplex (G4) DNA structures in the genome have been recognized as key factors in gene regulation and several other cellular processes. The mosR and ndhA genes involved in pathways of oxidation sensing regulation and ATP generation, respectively, make Mycobacterium tuberculosis (Mtb) bacteria responsible for oxidative stress inside host macrophage cells. Circular Dichroism spectra demonstrate stable hybrid G4 DNA conformations of mosR/ndhA DNA sequences. Real-time binding of mitoxantrone to G4 DNA with an affinity constant ~105-107 M-1, leads to hypochromism with a red shift of ~18 nm, followed by hyperchromism in the absorption spectra. The corresponding fluorescence is quenched with a red shift ~15 nm followed by an increase in intensity. A change in conformation of the G4 DNA accompanies the formation of multiple stoichiometric complexes with a dual binding mode. The external binding of mitoxantrone with a partial stacking with G-quartets and/or groove binding induces significant thermal stabilization, ~20-29 °C in ndhA/mosR G4 DNA. The interaction leads to a two/four-fold downregulation of transcriptomes of mosR/ndhA genes apart from the suppression of DNA replication by Taq polymerase enzyme, establishing the role of mitoxantrone in targeting G4 DNA, as an alternate strategy for effective anti-tuberculosis action in view of deadly multi-drug resistant tuberculosis disease causing bacterial strains t that arise from existing therapeutic treatments.

Erratum: Binding characterization of anthraquinone derivatives by stabilizing G-quadruplex DNA leads to an anticancerous activity.

[This corrects the article DOI: 10.1016/j.omtn.2022.11.008.].

Binding characterization of anthraquinone derivatives by stabilizing G-quadruplex DNA leads to an anticancerous activity.

G-quadruplex is a non-canonical secondary structure identified in the telomeric region and the promoter of many oncogenes. Anthraquinone derivatives, a well-known inducer of telomere disruption in malignant cells and activate the apoptotic pathway. We used biophysical and biochemical studies to confirm the interaction of synthesized anthraquinone derivatives with the human telomeric G-quadruplex sequence. The binding affinity of N-2DEA and N-1DEA are K b = 4.8 × 106 M-1 and K b = 7.6 × 105 M-1, respectively, leading to hypochroism, fluorescence quenching with minor redshift and ellipticity variations indicating ligand binding in the external groove. We found that sodium ions induced stabilization more rather than potassium ions. Molecular docking of complex demonstrates a molecule's exterior binding to a quadruplex. The investigation of ROS activity indicated that the cell initiates mortality in response to the IC50 concentration. Cellular morphology, nuclear condensation, and fragmentation were altered in the treated cell, impairing cellular function. Finally, the transcriptional regulatory study paves the way for drug design as an anti-cancer agent because of the tremendous possibilities of changing substituent groups on anthraquinones to improve efficacy and selectivity for G-quartet DNA. Our research focused on how ligand binding to telomere sequences induces oxidative stress and inhibits the growth of malignant cells.

Molecular rec§ognition of telomere DNA sequence by 2, 6 anthraquinone derivatives leads to thermal stabilization and induces apoptosis in cancer cells.

According to current research, anti-cancer anthraquinones impact telomere disruption and may interact with G-quadruplex DNA that triggers signaling to apoptosis. The present study represents the biophysical investigation of oxidative stress, late apoptosis, and induced senescence among cancer cells after binding laboratory synthesized piperidine-based anthraquinone derivatives, 2, 6- Bis [(3-piperidino)acetamido)]anthracene-9,10-dione (N1P) and 2, 6-Bis [piperidino)propionamido]anthracene-9,10-dione (N2P), with G-quadruplex DNA. We employed biophysical approaches to explore the interaction of synthetic anthraquinone derivatives with quadruplex DNA sequences to influence biological activities in the presence of K+ and Na+ cations. The binding affinity for N2P and N1P are Kb = 5.8 × 106 M-1 and Kb = 1.0 × 106 M-1, respectively, leading to hypo-/hyper-chromism with 5-7 nm red shift and significant fluorescence quenching and changes in ellipticity resulting in external binding of both the ligands to G-quadruplex DNA. Ligand binding induced enhancement of thermostability of G4 DNA is greater in Na+ environment (ΔTm = 34 °C) as compared to that in K+ environment (ΔTm = 21 °C), thereby restricting telomerase binding access to telomeres. Microscopic images of treated cells indicated cellular shape, nuclear condensation, and fragmentation alterations. The findings pave the path for therapeutic research, given the great potential of modifying anthraquinone substituent groups towards improved efficacy, ROS generation, and G-quadruplex DNA selectivity.

Structural basis for stabilization of human telomeric G-quadruplex [d-(TTAGGGT)]4 by anticancer drug adriamycin.

Besides inhibiting DNA duplication, DNA dependent RNA synthesis and topoisomerase-II enzyme action, anticancer drug adriamycin is found to cause telomere dysfunction and shows multiple strategies of action on gene functioning. We present evidence of binding of adriamycin to parallel stranded intermolecular [d-(TTAGGGT)]4 G-quadruplex DNA comprising human telomeric DNA by proton and phosphorus-31 nuclear magnetic resonance spectroscopy. Diffusion ordered spectroscopy shows formation of complex between the two molecules. Changes in chemical shift and line broadening of DNA and adriamycin protons suggest participation of specific chemical groups/moieties in interaction. Presence of sequential nuclear Overhauser enhancements at all base quartet steps and absence of large downfield shifts in 31P resonances give clear proof of absence of intercalation of adriamycin chromophore between base quartets. Restrained molecular dynamics simulations using observed 15 short intermolecular inter proton distance contacts depict stacking of ring D of adriamycin with terminal G6 quartet by displacing T7 base and external groove binding close to T1-T2-A3 bases. The disappearance of imino protons monitored as a function of temperature and differential scanning calorimetry experiments yield thermal stabilization of 24 °C, which is likely to come in the way of telomerase association with telomeres. The findings pave the way for design of alternate anthracycline based drugs with specific modifications at ring D to enhance induced thermal stabilization and use alternate mechanism of binding to G-quadruplex DNA for interference in functional pathway of telomere maintenance by telomerase enzyme besides their well known action on duplex DNA. Communicated by Ramaswamy H. Sarma.

Structural basis for stabilization of human telomeric G-quadruplex [d-(TTAGGGT)]4 by anticancer drug epirubicin.

Anthracycline anticancer drugs show multiple strategies of action on gene functioning by regulation of telomerase enzyme by apoptotic factors, e.g. ceramide level, p53 activity, bcl-2 protein levels, besides inhibiting DNA/RNA synthesis and topoisomerase-II action. We report binding of epirubicin with G-quadruplex (G4) DNA, [d-(TTAGGGT)]4, comprising human telomeric DNA sequence TTAGGG, using 1H and 31P NMR spectroscopy. Diffusion ordered spectroscopy, sequence selective changes in chemical shift (~0.33 ppm) and line broadening in DNA signals suggest formation of a well-defined complex. Presence of sequential nuclear Overhauser enhancements at all base quartet steps and absence of large downfield shifts in 31P resonances preclude intercalative mode of interaction. Restrained molecular dynamics simulations using AMBER force field incorporating intermolecular drug to DNA interproton distances, involving ring D protons of epirubicin depict external binding close to T1-T2-A3 and G6pT7 sites. Binding induced thermal stabilization of G4 DNA (~36 °C), obtained from imino protons and differential scanning calorimetry, is likely to come in the way of telomerase association with telomeres. The findings pave the way for drug-designing with modifications at ring D and daunosamine sugar.

Binding of anticancer drug adriamycin to parallel G-quadruplex DNA [d-(TTAGGGT)]4 comprising human telomeric DNA leads to thermal stabilization: A multiple spectroscopy study.

Adriamycin is known to exert its anti cancer action by inhibiting DNA duplication, RNA transcription and topoisomerase-II enzyme action. Recent findings of its binding to G-quadruplex DNA resulting in telomere dysfunction indicated multiple strategies of its action. The interaction of anticancer drug adriamycin with parallel stranded inter molecular G-quadruplex DNA [d-(TTAGGGT)]4 comprising human telomeric DNA sequence TTAGGG was investigated by absorption, fluorescence, circular dichroism and nuclear magnetic resonance spectroscopy to understand mode of their interaction. The adriamycin binds as monomer to G-quadruplex DNA with affinity (Kb1 = 9.8x105 M-1 and Kb2 = 6.7x105 M-1 ) higher than that reported for daunomycin, at two independent sites, mainly in terminal stacking and groove binding modes. The bound complex formed as a result of specific interactions induces thermal stabilization of DNA by 12.5-28.1°C, which is likely to hinder telomere association with telomerase enzyme and contribute significantly to adriamycin-induced apoptosis in cancer cell lines. The findings have therapeutic potential towards drug designing by way of altering substituent groups on anthracyclines to enhance efficacy using additional mechanism of targeting pathway of telomere maintenance by disrupting telomerase association with telomeres.

Dual mode of binding of anti cancer drug epirubicin to G-quadruplex [d-(TTAGGGT)]4 containing human telomeric DNA sequence induces thermal stabilization.

Epirubicin exerts its anti cancer action by blocking DNA/RNA synthesis and inhibition of topoisomerase-II enzyme. Recent reports on its influence on telomere maintenance, suggest interaction with G-quadruplex DNA leading to multiple strategies of action. The binding of epirubicin with parallel stranded inter molecular G-quadruplex DNA [d-(TTAGGGT)]4 comprising human telomeric DNA sequence TTAGGG was investigated by absorption, fluorescence, circular dichroism and nuclear magnetic resonance spectroscopy. The epirubicin binds as monomer to G-quadruplex DNA with affinity, Kb1 = 3.8 × 106 M-1 and Kb2 = 2.7 × 106 M-1, at two independent sites externally. The specific interactions induce thermal stabilization of DNA by 13.2-26.3 °C, which is likely to come in the way of telomere association with telomerase enzyme and contribute to epirubicin-induced apoptosis in cancer cell lines. The findings pave the way for drug designing in view of the possibility of altering substituent groups on anthracyclines to enhance efficacy using alternate mechanism of its interaction with G4 DNA, causing interference in telomere maintenance pathway by inducing telomere dysfunction.

Molecular recognition of 3+1 hybrid human telomeric G-quadruplex DNA d-[AGGG(TTAGGG)3] by anticancer drugs epirubicin and adriamycin leads to thermal stabilization.

Recent reports suggest influence of anti-cancer anthracyclines on telomere dysfunction and their possible interaction with G-quadruplex (G4) DNA as an alternate pathway to apoptosis. We have investigated interaction of epirubicin and adriamycin with G4 DNA [d-AGGG(TTAGGG)3] comprising human telomeric DNA sequence by surface plasmon resonance, absorption, fluorescence, circular dichroism and thermal denaturation. Epirubicin and adriamycin bind with affinity, Kb, = 2.5×105 and 5.2×105M-1, respectively in monomeric form leading to decrease in absorbance, fluorescence quenching and ellipticity changes without any significant shift in absorption emission maxima with corresponding induced thermal stabilization by 13.0 and 11.6°C in K+ rich solution. Na+ ions did not induce any thermal stabilization. Molecular docking confirmed external binding at grooves and loops of G4 DNA involving 4OCH3 of ring D, 9COCH2OH of ring A, 4'OH/H and 3'NH3+ of daunosamine sugar. Thermal stabilization induced by specific interactions is likely to hamper telomere association with telomerase enzyme and contribute to drug-induced apoptosis in cancer cell lines besides causing damage to duplex DNA. The findings pave the way for drug designing in view of immense possibilities of altering substituent groups on anthracyclines for enhancement of efficacy, reduced cell toxicity as well as specificity towards G-quadruplex DNA.

Nuclear magnetic resonance based structure of the protoberberine alkaloid coralyne and its self-association by spectroscopy techniques.

Coralyne is an important alkaloid due to its anti-cancer and other medicinal properties. It targets DNA in cells and acts as human topoisomerase-I poison, telomerase inhibitor and nucleic acid intercalator. It has high tendency to undergo self-association, which is a matter of concern for therapeutic applications. The understanding of its interaction with DNA requires precise knowledge of chemical shifts in Nuclear Magnetic Resonance (NMR) spectra besides self-association. The present study is the first report of a complete assignment of all 1H/13C resonances in NMR spectra of coralyne in DMSO-d6 using one dimensional 1H/13C and two dimensional NMR experiments. The chemical shift of all proton and several 13C resonances have also been obtained in D2O and ethanol-d6. The same has been calculated using Density Functional Theory (DFT). NMR spectra of coralyne show upfield shift of 0.6-1.2 ppm in aromatic ring protons suggesting stacking interactions. Apart from 11 intra molecular NOE cross peaks in 2D 1H-1H ROESY spectra, 3 short distance NOE correlations, H6-10OCH3, H5-10OCH3 and H12-16CH3, give direct independent evidence of the formation of a stacked dimer. The absorbance, fluorescence, circular dichroism and fluorescence lifetime experiments conducted in the present investigations corroborate results obtained by NMR.

Binding of anticancer drug daunomycin to parallel G-quadruplex DNA [d-(TTGGGGT)]4 leads to thermal stabilization: A multispectroscopic investigation.

Guanine rich DNA sequences form four stranded G-quadruplex structures found in telomeric DNA and oncogene promoters. Small molecules binding and stabilizing the G-quadruplex disrupt telomere maintenance and gene regulation, thereby limiting the proliferation of cancer cells. The anti-cancer drug daunomycin binds to both G-quadruplex DNA and duplex DNA. We have undertaken a study of interaction of daunomycin to [d-(TTGGGGT)]4 comprising telomeric DNA sequence from Tetrahymena thermophilia to understand the mechanisms of its action. Absorbance, fluorescence and circular dicroism spectra show significant change on interaction with no change in wavelength maxima. The daunomycin dimers present in free state in solution are disrupted on binding. Presence of all sequential short inter proton distance contacts in nuclear magnetic resonance spectra confirm external binding. The observed inter molecular nuclear Overhauser enhancements, changes in chemical shift and molecular docking studies establish well defined binding of daunomycin at two different sites of G-quadruplex DNA. Thermal stabilization of [d-(TTGGGGT)]4 by 10-15 °C upon daunomycin binding is expected to reduce access of telomerase to its functional site at telomeres. The present studies on mode of action pave the way for alternate derivatives/analogues by chemical modification of anthracyclines to arrive at a more potent telomerase inhibitor.

Molecular Recognition of Parallel G-quadruplex [d-(TTGGGGT)]4 Containing Tetrahymena Telomeric DNA Sequence by Anticancer Drug Daunomycin: NMR-Based Structure and Thermal Stability.

The anticancer drug daunomycin exerts its influence by multiple strategies of action to interfere with gene functioning. Besides inhibiting DNA/RNA synthesis and topoisomerase-II, it affects the functional pathway of telomere maintenance by the telomerase enzyme. We present evidence of the binding of daunomycin to parallel-stranded tetramolecular [d-(TTGGGGT)]4 guanine (G)-quadruplex DNA comprising telomeric DNA from Tetrahymena thermophilia by surface plasmon resonance and Diffusion Ordered SpectroscopY (DOSY). Circular Dichroism (CD) spectra show the disruption of daunomycin dimers, suggesting the end-stacking and groove-binding of the daunomycin monomer. Proton and phosphorus-31 Nuclear Magnetic Resonance (NMR) spectroscopy show a sequence-specific interaction and a clear proof of absence of intercalation of the daunomycin chromophore between base quartets or stacking between G-quadruplexes. Restrained molecular dynamics simulations using observed short interproton distance contacts depict interaction at the molecular level. The interactions involving ring A and daunosamine protons, the stacking of an aromatic ring of daunomycin with a terminal G6 quartet by displacing the T7 base, and external groove-binding close to the T1⁻T2 bases lead to the thermal stabilization of 15 °C, which is likely to inhibit the association of telomerase with telomeres. The findings have implications in the structure-based designing of anthracycline drugs as potent telomerase inhibitors.

Structural and biophysical insight into dual site binding of the protoberberine alkaloid palmatine to parallel G-quadruplex DNA using NMR, fluorescence and Circular Dichroism spectroscopy.

Plant derived small molecules, which interact with and stabilize G-quadruplex DNA, act as inhibitors of telomere elongation and oncogene expression in humans. The inhibition of telomerase enzyme has immense potential since it is over expressed in most cancer cells. Interaction of palmatine, an antitumor alkaloid, to parallel G-quadruplex DNA, [d(TTGGGGT)]4 and [d(TTAGGGT)]4, has been investigated using Nuclear Magnetic Resonance (NMR), fluorescence and Circular Dichroism (CD) spectroscopy. Titrations were monitored by 1H and 31P NMR spectra and solution structure of palmatine-[d(TTGGGGT)]4 complex was obtained by restrained Molecular Dynamics (rMD) simulations using distance restraints from 2D NOESY spectra. Thermal stabilization of DNA was determined by CD, 1H NMR and Differential Scanning Calorimetry (DSC). Binding of palmatine induces 98% enhancement of fluorescence accompanied by blue shift ∼8 nm. CD spectral bands of DNA show minor changes. Diffusion NMR studies confirm formation of a stable complex. Proton NMR signals of palmatine shift upfield upon binding and NOE cross peaks of H10, H3, H28, 5OCH3 protons with T2, A3/G3, G6 and T7 residues reveal dual recognition sites in both G-quadruplex DNA sequences, resulting in thermal stabilization of G-quadruplex by ∼13-17 °C. Restrained molecular dynamics simulations using NOE distance restraints for 2:1 palmatine-[d(TTGGGGT)]4 complex reveal end-stacking of palmatine at G6pT7 step and groove binding along T2pG3 step. Binding to [d(TTAGGGT)]4 takes place at T2pA3pG4 and G6pT7 steps. Structural features of molecular recognition of two different G-quadruplex DNA sequences by palmatine have relevance in rational drug development for anti-cancer therapy.

WITHDRAWN: Structural and biophysical insight into dual site binding of the protoberberine alkaloid palmatine to parallel G-quadruplex DNA using NMR, fluorescence and circular dichroism spectroscopy.

The Publisher regrets that this article is an accidental duplication of an article that has already been published, http://dx.doi.org/10.1016/j.biochi.2018.02.002. The duplicate article has therefore been withdrawn. The full Elsevier Policy on Article Withdrawal can be found at https://www.elsevier.com/about/our-business/policies/article-withdrawal.

NMR based structure reveals groove binding of mitoxantrone to two sites of [d-(TTAGGGT)]4 having human telomeric DNA sequence leading to thermal stabilization of G-quadruplex.

Interaction of mitoxantrone (MTX) with G-quadruplex, leading to inhibition of telomerase enzyme and anticancer action, is not understood. Titrations of MTX with [d-(TTAGGGT)]4, comprising human telomere single repeat sequence, have been monitored by fluorescence and 1H/31P NMR spectroscopy. Binding induces chemical shift changes in GNH (~0.3ppm), T2/T7/A3 base protons and sequence specific shifts in 31P resonances. Absence of large downfield shifts in 31P signals and presence of all sequential NOEs show that classical intercalation of drug between base quartets does not occur. The upfield shift (~0.53ppm) in 2/3H, 1/4OH and minor shift in 6/7H aromatic protons of MTX in complex rule out end stacking as a possible mode of interaction. The 26 short inter molecular contacts of 1/4OH, 11NH, 6/7H and 12CH2 protons of MTX with T1, T2, G6, G7 protons in the structure of complex obtained by restrained Molecular Dynamics simulations show binding at grooves accompanied by 4 hydrogen bonds and partial stacking of MTX with base pairs. Interaction causes thermal stabilization, ΔTm=35°C, which may be attributed to telomerase inhibition. The present study is the first report on solution structure of mitoxantrone-[d-(TTAGGGT)]4 complex and is significant for structure based designing of anthraquinone derivatives as future drugs.

NMR based structural studies decipher stacking of the alkaloid coralyne to terminal guanines at two different sites in parallel G-quadruplex DNA, [d(TTGGGGT)]4 and [d(TTAGGGT)]4.

BACKGROUND: Telomere elongation by telomerase gets inhibited by G-quadruplex DNA found in its guanine rich region. Stabilization of G-quadruplex DNA upon ligand binding has evolved as a promising strategy to target cancer cells in which telomerase is over expressed. METHODS: Interaction of anti-leukemic alkaloid, coralyne, to tetrameric parallel [d(TTGGGGT)]4 (Ttel7), [d(TTAGGGT)]4 (Htel7) and monomeric anti-parallel [dGGGG(TTGGGG)3] (Ttel22) G-quadruplex DNA has been studied using Circular Dichroism (CD) spectroscopy. Titrations of coralyne with Ttel7 and Htel7 were monitored by 1H and 31P NMR spectroscopy. Solution structure of coralyne-Ttel7 complex was obtained by restrained Molecular Dynamics (rMD) simulations using distance restraints from 2D NOESY spectra. Thermal stabilization of DNA was determined by absorption, CD and 1H NMR. RESULTS AND CONCLUSIONS: Binding of coralyne to Ttel7/Htel7 induces negative CD band at 315/300nm. A significant upfield shift in all GNH, downfield shift in T2/T7 base protons and upfield shift (1.8ppm) in coralyne protons indicates stacking interactions. 31P chemical shifts and NOE contacts of G3, G6, T2, T7 protons with methoxy protons reveal proximity of coralyne to T2pG3 and G6pT7 sites. Solution structure reveals stacking of coralyne at G6pT7 and T2pG3 steps with two methoxy groups of coralyne located in the grooves along with formation of a hydrogen bond. Binding stabilizes Ttel7/Htel7 by ~25-35°C in 2:1 coralyne-Ttel7/Htel7 complex. GENERAL SIGNIFICANCE: The present study is the first report on solution structure of coralyne-Ttel7 complex showing stacking of coralyne with terminal guanine tetrads leading to significant thermal stabilization, which may be responsible for telomerase inhibition.

Binding of the alkaloid coralyne to parallel G-quadruplex DNA [d(TTGGGGT)]4 studied by multi-spectroscopic techniques.

Binding of coralyne to tetra-molecular parallel G-quadruplex DNA [d(TTGGGGT)]4 was evaluated for the first time using biophysical techniques. Absorbance titrations show hypo/hyper-chromism accompanied by 12nm red shift with binding constant Kb=0.2-4.0×106M-1. Binding induces a negative circular dichroism band of coralyne at 315nm. Quenching of fluorescence (~64%) along with 10nm blue shift in emission maxima indicates proximity of coralyne to guanine bases. Job plot indicates existence of multiple complexes. The observed two fluorescence life times, 6 and 12ns, with relative abundance 33% and 63%, respectively suggest two binding sites/conformations in complex. 1D 1H NMR spectra reveal significant broadening and upfield shift of G3NH, G6NH and G3H8 proton signals upon binding. The NOESY spectra reveal sequence specific non-intercalative interaction of coralyne in monomeric form at two sites close to A3/G3 and G6 bases of [d(TTGGGGT)]4 and [d(TTAGGGT)]4, which has implications in anti-cancer drug action.

Nuclear magnetic resonance studies reveal stabilization of parallel G-quadruplex DNA [d(T2G4T)]4 upon binding to protoberberine alkaloid coralyne.

Stabilization of G-quadruplex DNA structures in human telomeric and proto-oncogenic promoter regions upon ligand binding has evolved as a viable anti-cancer strategy. We have studied interaction of coralyne, a human telomerase inhibiting protoberberine alkaloid, with parallel stranded tetrameric G-quadruplex DNA [d(T2G4T)]4 using Circular Dichroism (CD) and nuclear magnetic resonance (NMR) spectroscopy. Appearance of induced CD band and the Diffusion Ordered NMR Spectroscopy (DOSY) experiments confirm the formation of well defined coralyne-DNA complex. 1H and 31P NMR studies reveal that coralyne specifically recognizes T2pG3 and G6pT7 steps in DNA. Guanine imino protons indicate that coralyne binding induces thermal stabilization of the G-quadruplex DNA by >20°C. The observed specific changes and thermal stabilization of DNA upon binding may be attributed to inhibition of telomerase by coralyne.

NMR structure of dual site binding of mitoxantrone dimer to opposite grooves of parallel stranded G-quadruplex [d-(TTGGGGT)]4.

The formation of complex between anti-cancer drug mitoxantrone (MTX) and tetra-molecular parallel G-quadruplex DNA [d-(TTGGGGT)]4 has been studied by solution state one and two dimensional NMR spectroscopy. Mitoxantrone forms a head-to-tail dimer and binds at two opposite grooves of the G-quadruplex. The Job's method of continuous variation and thermal melting studies independently ascertain binding stoichiometry of 4:1 in mitoxantrone:DNA complex. The existence of only four guanine NH peaks corresponding to the four G-quartets during the course of titration shows that C4 symmetry of G-quadruplex is intact upon binding of mitoxantrone. The specific inter molecular short distance contacts between protons of two mitoxantrone molecules of dimer, that is, ring A protons with ring C and side chain methylene protons, confirms the formation of mitoxantrone head-to-tail dimer. The observed 38 Nuclear Overhauser Enhancement (NOE) cross peaks between MTX and G-quadruplex DNA indicate formation of a well-defined complex. The three dimensional structure of 4:1 mitoxantrone:[d-(TTGGGGT)]4 complex computed by using experimental distance restraints followed by restrained Molecular Dynamics (rMD) simulations envisages the critical knowledge of specific molecular interactions within ligand-G-quadruplex complex. The findings are of direct interest in development of anti-cancer therapeutic drug based on G-quadruplex stabilization, resulting in telomerase inhibition.