Tural Aksel, Erik J Navarro, Nicholas Fong, Shawn M Douglas
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引用次数: 0
Abstract
We describe design principles for accurate folding of three-dimensional DNA origami. To evaluate design rules, we reduced the problem of DNA strand routing to the known problem of shortest-path finding in a weighted graph. To score candidate DNA strand routes we used a thermodynamic model that accounts for enthalpic and entropic contributions of initial binding, hybridization, and DNA loop closure. We encoded and analyzed new and previously reported design heuristics. Using design principles emerging from this analysis, we redesigned and fabricated multiple shapes and compared their folding accuracy using electrophoretic mobility analysis and electron microscopy imaging. Redesigned shapes showed 6- to 30-fold improvements in yield compared to original designs. We demonstrate accurate folding can be achieved by optimizing staple routes using our model and provide a computational framework for applying our methodology to any design.
我们描述了精确折叠三维 DNA 折纸的设计原则。为了评估设计规则,我们将 DNA 链路由问题简化为已知的加权图中的最短路径查找问题。为了对候选 DNA 链路径进行评分,我们使用了一个热力学模型,该模型考虑了初始结合、杂交和 DNA 环闭合的焓和熵贡献。我们对新的和以前报道过的设计启发式方法进行了编码和分析。利用分析得出的设计原则,我们重新设计并制造了多种形状,并利用电泳迁移率分析和电子显微镜成像比较了它们的折叠精度。与原始设计相比,重新设计的形状在产量上提高了 6 到 30 倍。我们证明了利用我们的模型优化主食路线可以实现精确折叠,并提供了一个计算框架,可将我们的方法应用于任何设计。
期刊介绍:
The Proceedings of the National Academy of Sciences (PNAS), a peer-reviewed journal of the National Academy of Sciences (NAS), serves as an authoritative source for high-impact, original research across the biological, physical, and social sciences. With a global scope, the journal welcomes submissions from researchers worldwide, making it an inclusive platform for advancing scientific knowledge.