Chain stretching in brushes favors sequence recognition for nucleobase-functionalized flexible precise oligomers†

IF 2.9 3区 化学 Q3 CHEMISTRY, PHYSICAL Soft Matter Pub Date : 2024-10-07 DOI:10.1039/D4SM00866A
Kseniia Grafskaia, Qian Qin, Jie Li, Delphine Magnin, David Dellemme, Mathieu Surin, Karine Glinel and Alain M. Jonas
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Abstract

Six different flexible stereocontrolled oligo(triazole-urethane)s substituted by precise sequences of nucleobases or analogs are synthesized. Molecular dynamics simulations indicate that the flexibility of the backbone leads to unspecific complexation of pairs of oligomers, irrespective of the complementarity of their sequences. This is ascribed to the existence of other interactions between pairs of oligomers, as well as to the spatial blurring of the sequence order encoded in the chemical structure of the chain due to its flexibility. The same conclusions are drawn when investigating the irreversible adsorption of different probe oligomers onto a layer of target oligomers grafted by click chemistry in a mushroom configuration on a silicon substrate. In contrast, when the target oligomers are grafted in denser brush configurations, irreversible adsorption becomes more specific, with it being twice as probable that probe chains of complementary sequence would be irreversibly-bound to the layer of target chains than those of non-complementary sequence. This is ascribed to lateral excluded volume interactions between chains in the brush, leading to partial chain stretching and increased spatial preservation of the information contained in the monomer sequence of the chains. At even higher grafting densities, however, the penetration of the probe chains in the brush becomes increasingly difficult, resulting in a loss of binding efficiency. Our work thus demonstrates the adverse role of chain flexibility in the specificity of complexation between nucleobase-functionalized oligomers and provides directions for an improvement of specificity by tuning the grafting density of target chains on a substrate.

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电刷中的链伸展有利于核碱基功能化柔性精确低聚物的序列识别。
我们合成了六种不同的由精确的核碱基序列或类似物取代的柔性立体可控寡聚(三唑-氨基甲酸酯)。分子动力学模拟表明,骨架的柔性会导致成对寡聚物的非特异性复合,而与它们的序列互补性无关。这归因于成对的低聚物之间存在其他相互作用,也归因于链的柔性导致化学结构中编码的序列顺序在空间上变得模糊。在研究不同探针低聚物不可逆地吸附在硅基底上通过点击化学以蘑菇构型接枝的目标低聚物层上时,也得出了同样的结论。与此相反,当目标低聚物以更密集的刷状构型接枝时,不可逆吸附变得更具特异性,互补序列的探针链不可逆地结合到目标链层上的概率是非互补序列探针链的两倍。这归因于刷子中链条之间的横向排除体积相互作用,导致部分链条拉伸,增加了链条单体序列所含信息的空间保存。然而,在更高的接枝密度下,探针链在电刷中的穿透变得越来越困难,导致结合效率下降。因此,我们的工作证明了链的灵活性对核糖功能化低聚物之间复合的特异性的不利作用,并为通过调整底物上目标链的接枝密度来提高特异性提供了方向。
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来源期刊
Soft Matter
Soft Matter 工程技术-材料科学:综合
CiteScore
6.00
自引率
5.90%
发文量
891
审稿时长
1.9 months
期刊介绍: Where physics meets chemistry meets biology for fundamental soft matter research.
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