Engineering a custom-sized DNA scaffold for more efficient DNA origami-based nucleic acid data storage.

IF 2.6 Q2 BIOCHEMICAL RESEARCH METHODS

Synthetic biology (Oxford, England) Pub Date : 2025-04-07 eCollection Date: 2025-01-01 DOI:10.1093/synbio/ysaf008

Sarah E Kobernat, Maryna Lazouskaya, Benjamin C Balzer, Amanda Wolf, Golam M Mortuza, George D Dickinson, Tim Andersen, William L Hughes, Luca Piantanida, Eric J Hayden

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Abstract

DNA has emerged as a promising material to address growing data storage demands. We recently demonstrated a structure-based DNA data storage approach where DNA probes are spatially oriented on the surface of DNA origami and decoded using DNA-PAINT. In this approach, larger origami structures could improve the efficiency of reading and writing data. However, larger origami require long single-stranded DNA scaffolds that are not commonly available. Here, we report the engineering of a novel longer DNA scaffold designed to produce a larger rectangle origami needed to expand the origami-based digital nucleic acid memory (dNAM) approach. We confirmed that this scaffold self-assembled into the correct origami platform and correctly positioned DNA data strands using atomic force microscopy and DNA-PAINT super-resolution microscopy. This larger structure enables a 67% increase in the number of data points per origami and will support efforts to efficiently scale up origami-based dNAM.

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设计一个定制尺寸的DNA支架，用于更有效的DNA折纸核酸数据存储。

DNA已经成为解决日益增长的数据存储需求的一种有前途的材料。我们最近展示了一种基于结构的DNA数据存储方法，其中DNA探针在DNA折纸表面的空间定向，并使用DNA- paint进行解码。在这种方法中，较大的折纸结构可以提高读取和写入数据的效率。然而，更大的折纸需要长单链DNA支架，这是不常见的。在这里，我们报道了一种新的更长的DNA支架的工程设计，以产生更大的矩形折纸，需要扩展折纸为基础的数字核酸记忆（dNAM）方法。我们使用原子力显微镜和DNA- paint超分辨率显微镜证实了这种支架可以自组装成正确的折纸平台，并正确定位DNA数据链。这种更大的结构使每个折纸的数据点数量增加67%，并将支持有效扩展基于折纸的dNAM的努力。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Synthetic biology (Oxford, England)

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