高温Cy5标记γ-PNAs的纯化和组装成三维DNA纳米笼。

Justin D Flory, Trey Johnson, Chad R Simmons, Su Lin, Giovanna Ghirlanda, Petra Fromme
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引用次数: 3

摘要

PNA是一种杂交分子,非常适合于连接多肽的功能景观和结构多样性,可以用DNA纳米结构进行工程设计。然而,由于PNA的疏水性,在水溶液中处理PNA更具挑战性。一种使用菌株促进的溶液相方法,开发了铜自由点击化学将荧光染料Cy5偶联到2双功能PNA链,作为构建环状PNA多肽的第一步,环状PNA多肽可以排列在3D DNA纳米支架内。设计了一个3D DNA纳米笼,将2条荧光标记的PNA链的结合位点靠近模拟蛋白质活性位点。变性聚丙烯酰胺凝胶电泳(PAGE)是一种从大量未反应的染料和未反应的中性PNA中纯化带电的、染料标记的PNA偶联物的有效方法。通过荧光监测凝胶在水中的洗脱,发现对更可溶性的PNA链更有效。原生页面显示,两个PNA链杂交到DNA纳米笼内的预期结合位点。Förster共振能量转移(FRET)与Cy3标记的DNA纳米笼被用来确定一个PNA-Cy5缀合物的解离温度接近50℃。稳态和时间分辨荧光被用来研究染料取向和各种配合物之间的相互作用。双功能、耐热的PNA分子是控制小DNA纳米笼内肽的组装和取向以模拟蛋白质催化位点的有趣候选者。
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Purification and assembly of thermostable Cy5 labeled γ-PNAs into a 3D DNA nanocage.

PNA is hybrid molecule ideally suited for bridging the functional landscape of polypeptides with the structural diversity that can be engineered with DNA nanostructures. However, PNA can be more challenging to work with in aqueous solvents due to its hydrophobic nature. A solution phase method using strain promoted, copper free click chemistry was developed to conjugate the fluorescent dye Cy5 to 2 bifunctional PNA strands as a first step toward building cyclic PNA-polypeptides that can be arranged within 3D DNA nanoscaffolds. A 3D DNA nanocage was designed with binding sites for the 2 fluorescently labeled PNA strands in close proximity to mimic protein active sites. Denaturing polyacrylamide gel electrophoresis (PAGE) is introduced as an efficient method for purifying charged, dye-labeled PNA conjugates from large excesses of unreacted dye and unreacted, neutral PNA. Elution from the gel in water was monitored by fluorescence and found to be more efficient for the more soluble PNA strand. Native PAGE shows that both PNA strands hybridize to their intended binding sites within the DNA nanocage. Förster resonance energy transfer (FRET) with a Cy3 labeled DNA nanocage was used to determine the dissociation temperature of one PNA-Cy5 conjugate to be near 50°C. Steady-state and time resolved fluorescence was used to investigate the dye orientation and interactions within the various complexes. Bifunctional, thermostable PNA molecules are intriguing candidates for controlling the assembly and orientation of peptides within small DNA nanocages for mimicking protein catalytic sites.

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