Hole Migration in Telomere-Based Oligonucleotide Anions and G-Quadruplexes

Vacuum ultraviolet photoionization of a gas-phase oligonucleotide anion leads to the formation of a valence hole. This hole migrates towards an energetically favorable site where it can weaken bonds and ultimately lead to bond cleavage. We have studied Vacuum UV photoionization of deprotonated oligonucleotides containing the human telomere sequence dTTAGGG and G-quadruplex structures consisting of four dTGGGGT single strands, stabilized by NH₄⁺ counter ions. The oligonucleotide and G-quadruplex anions were confined in a radiofrequency ion trap, interfaced with a synchrotron beamline and the photofragmentation was studied using time-of-flight mass spectrometry. Oligonucleotide 12-mers containing the 5'-TTAGGG sequence were found to predominantly break in the GGG region, whereas no selective bond cleavage region was observed for the reversed 5'-GGGATT sequence. For G-quadruplex structures, fragmentation was quenched and mostly non-dissociative single and double electron removal was observed.     

G‐Tetraplex‐Induced FRET within Telomeric Repeat Sequences Using PyA‐PerA as Energy Donor–Acceptor Pair

G‐tetraplex induced fluorescence resonance energy transfer (FRET) within telomeric repeat sequences has been studied using a nucleoside‐tethered FRET pair embedded in the human telomeric G‐quadruplex forming sequence (5′‐A GGG TT ^Py A GGG TT ^Per A GGG TTA GGG‐3′, Py=pyrene, Per=perylene). Conformational change from a single strand to an anti‐parallel G‐quadruplex leads to FRET from energy donor ( ^Py A ) to acceptor ( ^Per A ). The distance between the FRET donor/acceptor partners was controlled by changing the number of G‐quartet spacer units. The FRET efficiency decreases with increase in G‐quartet units. Overall findings indicate that this could be further used for the development of FRET‐based sensing and measurement techniques.     

Signal modelization for improved precision of assessment of minimum and mean telomere lengths

Telomere length is an important measure of cell and tissue regenerative capacities. The mean telomere length is classically used as global indicator of a tissue telomere length. In skeletal muscle, which is made of postmitotic myonuclei and satellite cells (muscle stem cells), minimum telomere length is also used to assess the telomere length of satellite cells and newly incorporated myonuclei. At present, the estimation of the method reproducibility during the assessment of mean and minimum telomere length using Southern blot analysis has never been documented. The aim of this report is to describe a signal modelization for improved precision of assessment of minimum and mean telomere lengths and to document the method reproducibility. Telomeres are assessed using a Southern technique where the gel is directly hybridized with the specific probe without the membrane-transferring step in order to prevent telomeric low signal loss. We found that the improved signal analysis for determination of telomere length is associated with coefficients of variation ranging from 1.37 to 4.29% for the mean telomeric restriction fragment (TRF) length and from 2.04 to 4.95% for the minimum TRF length. Improved method reproducibility would allow saving time and biological material as duplicate and triplicate measurement of the same sample is no longer required.     

紫玉兰素A与人端粒G-四链体相互作用的光谱学研究,第一个木脂素类衍生物与G-四链体相互作用

人端粒G-四链体结构是指端粒末端富含鸟嘌呤(G)的DNA序列在一价阳离子(如K+和Na+)诱导下通过G碱基间Hoogsteen氢键连接形成的DNA二级结构.能够稳定端粒G-四链体的配体通常为端粒酶抑制剂,其可能成为抗肿瘤药物.应用CD,FRET,NMR光谱方法第一次较全面地研究了一种木脂素衍生物,紫玉兰素A (liliflorin A)与人端粒序列dGGG (TTAG(G)3G-四链体HTG21的相互作用,采用分子对接技术进一步研究紫玉兰素A与人端粒序列dTAGGG(TIAGC)3 G-四链体HTG23的结合位点.CD实验数据表明紫玉兰素A提高HTG21解链温度,FRET实验测得4.0μmol·L-1紫玉兰素A可以将HTG21稳定温度提高3.2℃.NMR实验结果表明,加入紫玉兰素A三小时后HTG21核磁谱图出现明显变化.分子对接结果表明紫玉兰素A结合到HTG23较宽沟槽上,结合位点为G9,G10,G16和G17.紫玉兰素A是第一个能够选择性稳定人端粒G四链体HTG21的木脂素类衍生物配体.实验结果为以人端粒G-四链体为靶点的抗肿瘤药物设计提供了新型候选化合物.     

Association of Chromosomal Telomere DNA With Nuclear Matrix in HeLa Cell

Using Electron Spectroscopic Imaging (ESI), we visualized the in situ binding of nucleic acids to nuclear matrix and 3H-thymidine incorporation which indicates that a small partial DNA bound to nuclear matrix tightly. Furthermore we found that chromosomal telomere DNA could bind to nuclear matrix specifically by the dot and Southern hybridization. The result of the Southwestern blot suggests that telomere DNA has high affinity to lamin B, vimentin and some nuclear matrix proteins. Therefore, the nuclear matrix and lamina of HeLa cell are possibly associated with spatial organization and action of chromosome.     

Tandem mass spectrometry of platinated quadruplex DNA

Quadruplexes are higher-order structures formed by G-rich DNA strands that are involved in various processes of cell cycle regulation, such as control of telomere length and participation in gene regulation. Because of these central biological functions, quadruplex DNA represents a promising target for cancer therapy, e.g. by applying organometallic drugs, such as cisplatin. High-resolution electrospray tandem mass spectrometry is evaluated as a technique for exploring structural features of unplatinated and platinated quadruplexes. Results of experiments on tetramolecular, bimolecular and monomolecular quadruplexes provide information about the extent of platination and the binding sites of the drug. The dissociation behavior of the different types of quadruplexes is compared. Tetramolecular quadruplexes were found to weave out a strand end in order to provide a platination site, and their fragmentation is characterized by the release of an unplatinated strand and the formation of a platinated triplex. Partial opening of the structure in combination with the loss of small fragments leads to truncated quadruplex ions. For the bimolecular quadruplexes studied, strand separation is the predominant dissociation pathway. Depending on the loop sequence, cross-linking of the loops by cisplatin is demonstrated. Distinct differences in the product ion spectra of unannealed and annealed monomolecular sequences provide proof of quadruplex formation and show that platination preferentially occurs at the terminal regions.     

Analysis of G‐quadruplex conformations using Raman and polarized Raman spectroscopy

G‐quadruplexes (G4s) are four‐stranded DNA structures formed within nucleic acid sequences that are rich in guanines. G4 formation within DNA strands is believed to have significant biological relevance for the control of cell replication and gene expression. Therefore, the development and validation of experimental techniques that can easily and reliably characterize G4 structures under biologically relevant measurement conditions, like Raman spectroscopy, are desirable for G4‐targeted structure based drug design. Here we report Raman and polarized Raman studies of solutions of three oligonucleotides, thrombin binding aptamer (TBA) 5′‐GGTTGGTGTGGTTGG‐3′, human telomeric (HT) 5′‐(TTAGGG)₄‐3′, and a modified c‐Myc NHE‐III₁ sequence (MycL1) 5′‐TGAGGGTGGGTAGGGTGGGTAA‐3′, which were previously reported to form four distinct intramolecular G4 structures in the presence of Na⁺ or K⁺, as determined by NMR. Our results support the previously proposed antiparallel (TBA), antiparallel and hybrid (HT), and parallel with double‐chain reversal (DCR) loop (MycL1) structures. Large sample‐dependent variations in the intensity of bands associated with deoxyribose backbone modes in the 840–930 cm⁻¹ and 1420–1460 cm⁻¹ spectral regions were observed. Most notably, a highly polarized deoxyribose ring symmetric stretch (~930 cm⁻¹) appeared strongly in the solution spectra for HT and TBA, but was very weak or absent in the solution spectrum for MycL1 and the drop deposition (dried sample) spectra for all three oligonucleotides. It is hypothesized that the intensity of this band is likely controlled by furanose ring structure uniformity and/or solvent accessibility to certain nucleotide binding sites. Raman depolarization ratios measured for the G4s in solution were generally very similar to those previously reported for canonical B DNA, with the possible exception of base ring modes that consistently yielded slightly lower depolarization ratios for G4s compared to B DNA. The results further underscore the utility of Raman and polarized Raman spectroscopy for G4 structure elucidation under biologically relevant solution conditions. Copyright © 2015 John Wiley & Sons, Ltd.     

溶液pH和阳离子对端粒G-四链体DNA形成和结构的影响

采用电喷雾质谱和圆二色谱研究了溶液pH和阳离子对人类端粒G-四链体DNA的影响. ESI-MS和CD谱图表明, pH可以引起G-四链体DNA的构象转变和离解, 而K^＋, NH₄^＋,阳离子对G-四链体DNA的形成有着重要的促进作用.     

Use of an automated capillary DNA sequencer to investigate the interaction of cisplatin with telomeric DNA sequences

The determination of the sequence selectivity of DNA-damaging agents is very important in elucidating the mechanism of action of anti-tumour drugs. The development of automated capillary DNA sequencers with fluorescent labelling has enabled a more precise method for DNA sequence specificity analysis. In this work we utilized the ABI 3730 capillary sequencer with laser-induced fluorescence to examine the sequence selectivity of cisplatin with purified DNA sequences. The use of this automated machine enabled a higher degree of precision of both position and intensity of cisplatin-DNA adducts than previously possible with manual and automated slab gel procedures. A problem with artefact bands was overcome by ethanol precipitation. It was found that cisplatin strongly formed adducts with telomeric DNA sequences.     

A Carbazole Derivative Synthesis for Stabilizing the Quadruplex Structure

A new molecule of 3,6‐Bis(1‐methyl‐4‐vinylpyridium iodine)carbazole ( BMVC ) was synthesized for stabilizing the quadruplex structure of human telomeric sequence of d(T₂AG₃)₄ in vitro. Mixing BMVC with the DNA can raise the melting temperature of the d(T₂AG₃)₄ by ～ 13 °C, implying that BMVC could be a useful telomerase inhibitor. In addition, the fluorescence of the BMVC increased significantly upon interacting with the d(T₂AG₃)₄ which may be useful as a G‐quadruplex specific marker.