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Design of an N^7-Glycosylated Purine Nucleoside for Recognition of GC Base Pairs by Triple Helix Formation

机译：N ^ 7-糖基化嘌呤核苷的设计，用于通过三螺旋形成识别GC碱基对

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Pyrimidine oligodeoxyribonucleotides bind in the major groove of DNA parallel to the purine Watson-Crick strand by formation of specific hydrogen bonds between thymine and adenine (T•AT triplet) and protonated cytosine and guanine (C+GC triplet) on the Hoogsteen face of the purine base. Alternatively, purine oligodeoxyribonucleotides bind in an antiparallel orientation relative to the purine Watson-Crick strand by formation of G•GC and A•AT triplets. The prerequisite protonation of cytosine in C+GC triplets leads to a considerable pH dependence in the binding affinity of C-containing oligodeoxyribonucleotides (Figure 1). Substitution of 5-methylcytosine (^mC) for cytosine results in increased binding affinities near physiological pH. In an attempt to eliminate the necessity for protonation, recent efforts have been directed toward the synthesis of nonnatural nucleosides which display the hydrogen bonding functionality of protonated cytosine.

机译：嘧啶寡聚脱氧核糖核苷酸通过在胸腺嘧啶和腺嘌呤（T•AT三联体）与质子化胞嘧啶和鸟嘌呤（C + GC三联体）之间形成特定的氢键，在平行于嘌呤Watson-Crick链的DNA主沟中结合。嘌呤碱。或者，嘌呤寡脱氧核糖核苷酸通过形成G•GC和A•AT三联体而相对于嘌呤Watson-Crick链以反平行方向结合。 C + GC三胞胎中胞嘧啶的必要质子化导致含C的寡脱氧核糖核苷酸的结合亲和力对pH的依赖性很大（图1）。 5-甲基胞嘧啶（^ mC）替代胞嘧啶导致在生理pH附近增加结合亲和力。为了消除质子化的必要性，最近的努力是针对非天然核苷的合成，其显示出质子化胞嘧啶的氢键功能。

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Hunziker Jürg; Priestley E. Scott; Brunar Helmut; Dervan Peter B.;
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年度 1995
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1. Design of an N~7-Glycosylated Purine Nucleoside for Recognition of GC Base Pairs by Triple Helix Formation [J] . Juerg Hunziker, E. Scott Priestley, Helmut Brunar, Journal of the American Chemical Society . 1995,第9期

机译：用于三螺旋形成识别GC碱基对的N〜7-糖基化嘌呤核苷的设计
2. Design and synthesis of a new type of modified nucleoside for triple helix-mediated adenine-thymine base pair recognition: Formation of hydrogen bonds to the far-side adenine [J] . Saito A., Kuroda R. Tetrahedron letters: The International Journal for the Rapid Publication of Preliminary Communications in Organic Chemistry . 1999,第26期

机译：用于三螺旋介导的腺嘌呤-胸腺嘧啶碱基对识别的新型修饰核苷的设计与合成：与远端腺嘌呤形成氢键
3. Direct and Facile Syntheses of Heterocyclic Vinyl-C-Nucleosides for Recognition of Inverted Base Pairs by DNA Triple Helix Formation: First Report by Direct Wittig Route [J] . Jeffrey H. Rothman The Journal of Organic Chemistry . 2007,第10期

机译：杂环乙烯基-C-核苷的直接和简便合成，用于通过DNA三重螺旋形成识别反向碱基对：直接Wittig路线的首次报道
4. Emission Spectroscopy of Complex Formation between Escherichia coli Purine Nucleoside Phosphorylase (PNP) and Identified Tautomeric Species of Formycin Inhibitors Resolves Ambiguities Found in Crystallographic Studies [C] . B. Kierdaszuk Conference on Methods and Applications of Fluorescence: Spectroscopy, Imaging, and Probes . 2002

机译：大肠杆菌嘌呤核苷磷酸酶（PNP）之间复杂形成的发射光谱谱和鉴定的甲酰霉素抑制剂的互变异构体决定了晶体研究中发现的含糊不清
5. Recognition of double helical DNA by purine oligonucleotides via triple helix formation. [D] . Beal, Peter Andrew. 1993

机译：嘌呤寡核苷酸通过三重螺旋形成识别双螺旋DNA。
6. Elucidation of the sequence-specific third-strand recognition of four Watson-Crick base pairs in a pyrimidine triple-helix motif: T.AT C.GC T.CG and G.TA. [O] . K Yoon, C A Hobbs, J Koch, 1992

机译：阐明了嘧啶三螺旋基序中的四个Watson-Crick碱基对的序列特异性第三链识别：T.ATC.GCT.CG和G.TA.
7. Elucidation of the sequence-specific third-strand recognition of four Watson-Crick base pairs in a pyrimidine triple-helix motif: T.AT, C.GC, T.CG, and G.TA. [O] . Yoon, K, Hobbs, C A, Koch, J, 1992

机译：阐明了嘧啶三螺旋基序中的四个Watson-Crick碱基对的序列特异性第三链识别：T.AT，C.GC，T.CG和G.TA.
8. Design of Novel Bases on Recognition of GC Base Pairs of DNA by OligonucleotideDirected Triple Helix Formation [R] . Koh, J. S., Dervan, P. B. 1991

机译：利用寡核苷酸定向三螺旋形成识别GC碱基对DNa的新型基因设计

Design of an N^7-Glycosylated Purine Nucleoside for Recognition of GC Base Pairs by Triple Helix Formation

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