基于BCNTs/GC电极的鸟嘌呤与腺嘌呤电化学行为及其同时检测

利用掺硼碳纳米管（BCNTs）/GC电极研究了鸟嘌呤（G）和腺嘌呤（A）的电化学氧化行为. 与GC和CNTs/GC电极相比,BCNTs/GC电极具有更强的电催化活性,且响应电流明显增加. 两混合样品在BCNTs/GC电极上的氧化峰间隔较大,可实现对A和G的同时检测.     

高选择性端粒G-四链体稳定性配体:9-O-多胺取代小檗碱衍生物的合成及活性评价

设计合成了3个多胺取代的小檗碱衍生物5a~5c, 并利用圆二色(CD)光谱、 荧光共振能量转移(FRET)熔点实验、 荧光光谱和聚合酶链反应(PCR)终止实验等手段研究了小檗碱衍生物5a~5c与端粒DNA的相互作用. 结果表明, 小檗碱衍生物5a~5c可以诱导端粒DNA序列形成反平行结构G-四链体, 显著地提高了端粒G-四链体的稳定性, 有效地抑制了端粒的扩增; 而与双链DNA的相互作用则很小, 是高选择性的端粒G-四链体配体.     

Stabilization of G‐Quadruplex DNA,Inhibition of Telomerase Activity and Live Cell Imaging Studies of Chiral Ruthenium(II) Complexes

Telomerase inhibition is an attractive strategy for cancer chemotherapy. In the current study, we have synthesized and characterized two chiral ruthenium(II) complexes, namely, Λ‐[Ru(phen)₂(p‐MOPIP)]²⁺ and Δ‐[Ru(phen)₂(p‐MOPIP)]²⁺, where phen is 1,10‐phenanthroline and p‐MOPIP is 2‐(4‐methoxyphenyl)‐imidazo[4,5f][1,10]phenanthroline. The chiral selectivity of the compounds and their ability to discriminate quadruplex DNA were investigated by using UV/Vis, fluorescence spectroscopy, circular dichroism spectroscopy, fluorescence resonance energy transfer melting assay, polymerase chain reaction stop assay and telomerase repeat amplification protocol. The results indicate that the two chiral compounds could induce and stabilize the formation of antiparallel G‐quadruplexes of telomeric DNA in the presence or absence of metal cations. We report the remarkable ability of the two complexes Λ‐[Ru(phen)₂(p‐MOPIP)]²⁺ and Δ‐[Ru(phen)₂(p‐MOPIP)]²⁺ to stabilize selectively G‐quadruplex DNA; the former is a better G‐quadruplex binder than the latter. The anticancer activities of these complexes were evaluated by using the MTT assay. Interestingly, the antiproliferative activity of Λ‐[Ru(phen)₂(p‐MOPIP)]²⁺ was higher than that of Δ‐[Ru(phen)₂(p‐MOPIP)]²⁺, and Λ‐[Ru(phen)₂(p‐MOPIP)]²⁺ showed a significant antitumor activity in HepG2 cells. The status of the nuclei in Λ/Δ‐[Ru(phen)₂(p‐MOPIP)]²⁺‐treated HepG2 cells was investigated by using real‐time living cell microscopy to determine the effects of Λ/Δ‐[Ru(phen)₂(p‐MOPIP)]²⁺ on intracellular accumulation. The results show that Λ/Δ‐[Ru(phen)₂(p‐MOPIP)]²⁺ can be taken up by HepG2 cells and can enter into the cytoplasm as well as accumulate in the nuclei; this suggests that the nuclei were the cellular targets of Λ/Δ‐[Ru(phen)₂(p‐MOPIP)]²⁺.     

DHP促进[Ru(bpy)_3]~(2+)介导鸟嘌呤的氧化

应用循环伏安法和微分脉冲伏安法研究了ITO电极上双十六烷基磷酸盐(DHP)和多壁碳纳米管(MWNTs)对[Ru(bpy)3]2+(bpy=2,2′-联吡啶)介导鸟嘌呤氧化的影响.结果表明,[Ru(bpy)3]2+能够介导鸟嘌呤氧化.在0.01至0.15 mmol.L-1DHP浓度范围内,[Ru(bpy)3]2+介导鸟嘌呤氧化峰电流随DHP浓度的增大而增大,阳离子表面活性剂HTAC则起抑制作用.讨论了DHP参与[Ru(bpy)3]2+介导鸟嘌呤氧化的可能电极过程机理.     

Regioisomers in Vorbrüggen''s guanine nucleoside synthesis; N9 selectivity with a glucosamine derivative and 2-N-acetyl-6-O-diphenylcarbamoylguanine

Vorbrüggen coupling of trimethylsilylated 2-N-acetylguanine with pentofuranose derivatives gives N7/N9 glycosyl mixtures. The N9 isomers can be obtained selectively with 2-N-acetyl-6-O-diphenylcarbamoylguanine, and even with a less reactive glucosamine derivative.     

Beyond guanine quartets: cation-induced formation of homogenous and chimeric DNA tetraplexes incorporating iso-guanine and guanine

Background:iso-Guanine (iso-G) is the purine component of an isomeric Watson-Crick base pair that may have existed prebiotically. By comparing the abiotic molecular recognition properties of iso-G and its complement, iso-cytosine (iso-C), with those of genomic nucleotide bases, it may be possible to explain the exclusion of the iso-G-iso-C base pair from modern genomes. Whether a nucleobase forms quartets may have a key role in determining its functionality. Biotically, nucleic acid tetraplexes have been implicated in cellular functions; prebiotically, tetraplexes would probably interfere with replication. Recently, in vitro selection has yielded receptors and catalysts that incorporate G quartets. The versatility of these structures could be enhanced by expanding the range of bases that can form the quartet motif.Results: Native polyacrylamide gel electrophoresis of oligonucleotides bearing runs of iso-G provides strong support for tetraplex formation via cation-promoted DNA strand association. In particular, when strands of different lengths bearing the same iso-G tetrad recognition element were combined, five bands were observed after electrophoresis, corresponding to all possible heterotetraplexes with parallel strand alignment. An analogous experiment with a mixture of strands bearing iso-G or G tetrad recognition domains supports the existence of mixed iso-G/G tetraplexes with antiparallel strand alignment at chimeric junctions. iso-G tetraplex and quartet structure has also been probed by a photo-crosslinking experiment, ultra-violet spectroscopy and theoretical calculations.Conclusions: As iso-G and G both have a marked tendency to form tetraplexes, their tandem inclusion in genetic material may be problematic, leading to double-stranded DNA half composed of bases that have a tendency to auto-associate. The resulting density of ‘selfish’ bases could undermine Watson-Crick pair formation, especially in a prebiotic context devoid of enzymes. Nevertheless, the ability of iso-G to form mixed quartets with G may provide a basis for altering the properties of tetraplexes in the domain of artificial receptors or catalysts from in vitro selections.     

Potential energy surface of the reaction of imidazole with peroxynitrite: Density functional theory study

This article presents a theoretical investigation of the reaction mechanism of imidazole nitration by peroxynitrite using density functional theory calculations. Understanding this reaction mechanism will help in elucidating the mechanism of guanine nitration by peroxynitrite, which is one of the assumed chemical pathways for damaging DNA in cells. This work focuses on the analysis of the potential energy surface (PES) for this reaction in the gas phase. Calculations were carried out using Hartree–Fock (HF) and density functional theory (DFT) Hamiltonians with double‐zeta basis sets ranging from 6‐31G(d) to 6‐31++G(d,p), and the triple‐zeta basis set 6‐311G(d). The computational results reveal that the reaction of imidazole with peroxynitrite in gas phase produces the following species: (i) hydroxide ion and 2‐nitroimidazole, (ii) hydrogen superoxide ion and 2‐nitrosoimidazole, and (iii) water and 2‐nitroimidazolide. The rate‐determining step is the formation of a short‐lived intermediate in which the imidazole C₂ carbon is covalently bonded to peroxynitrite nitrogen. Three short‐lived intermediates were found in the reaction path. These intermediates are involved in a proton‐hopping transport from C₂ carbon to the terminal oxygen of the ? O? O moiety of peroxynitrite via the nitroso (ON? ) oxygen. Both HF and DFT calculations (using the Becke3–Lee–Yang–Parr functional) lead to similar reaction paths for proton transport, but the landscape details of the PES for HF and DFT calculations differ. This investigation shows that the reaction of imidazole with peroxynitrite produces essentially the same types of products (nitro‐ and nitroso‐) as observed experimentally in the reaction of guanine with peroxynitrite, which makes the former reaction a good model to study by computation the essential characteristics of the latter reaction. Nevertheless, the computationally determined activation energy for imidazole nitration by peroxynitrite in the gas phase is 84.1 kcal/mol (calculated at the B3LYP/6‐31++G(d,p) level), too large for an enzymatic reaction. Exploratory calculations on imidazole nitration in solution, and on the reaction of 9‐methylguanine with peroxynitrite in the gas phase and solution, show that solvation increases the activation energy for both imidazole and guanine, and that the modest decrease (15 kcal mol^?1) in the activation energy, due to the adjacent six member ring of guanine, is counterbalanced by solvation. These results lead to the speculation that proton tunneling may be at the origin of experimentally observed high reaction rate of guanine nitration by peroxynitrite in solution. © 2005 Wiley Periodicals, Inc. Int J Quantum Chem, 2005