While sequence-selective dsDNA targeting by triplex forming oligonucleotides has been studied extensively, only very little is known about the properties of PNA–dsDNA triplexes—mainly due to the competing invasion process. Here we show that when appropriately modified using pseudoisocytosine substitution, in combination with (oligo)lysine or 9-aminoacridine conjugation, homopyrimidine PNA oligomers bind complementary dsDNA targets via triplex formation with (sub)nanomolar affinities (at pH 7.2, 150 mM Na+). Binding affinity can be modulated more than 1000-fold by changes in pH, PNA oligomer length, PNA net charge and/or by substitution of pseudoisocytosine for cytosine, and conjugation of the DNA intercalator 9-aminoacridine. Furthermore, 9-aminoacridine conjugation also strongly enhanced triplex invasion. Specificity for the fully matched target versus one containing single centrally located mismatches was more than 150-fold. Together the data support the use of homopyrimidine PNAs as efficient and sequence selective tools in triplex targeting strategies under physiological relevant conditions.
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机译:虽然已经广泛研究了通过三链体形成寡核苷酸靶向序列选择性dsDNA,但对PNA-dsDNA三链体的性质知之甚少-主要是由于竞争性入侵过程。在此我们显示,当使用伪异胞嘧啶取代进行适当修饰时,与(寡聚)赖氨酸或9-氨基ac啶共轭结合,高嘧啶PNA寡聚体通过(亚)纳摩尔亲和力(在pH 7.2、150 mM Na +下)的三链体形成结合互补dsDNA靶标。通过改变pH值,PNA低聚物长度,PNA净电荷和/或通过用伪异胞嘧啶替代胞嘧啶,以及结合DNA嵌入剂9-氨基ac啶,可以将结合亲和力调节超过1000倍。此外,9-氨基ac啶结合还强烈增强了三链体的侵袭。完全匹配的靶标与仅包含一个位于中心的错配靶标的特异性相差150倍以上。数据一起支持在生理相关条件下将高嘧啶PNA作为三重靶向策略中的有效和序列选择工具。
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