Chromatin‐associated condensates as an inspiration for the system architecture of future DNA computers

IF 4.8 3区综合性期刊 Q1 MULTIDISCIPLINARY SCIENCES

Annals of the New York Academy of Sciences Pub Date : 2025-09-05 DOI:10.1111/nyas.15415

Lennart Hilbert, Aaron Gadzekpo, Simon Lo Vecchio, Mona Wellhäusser, Xenia Tschurikow, Roshan Prizak, Barbara Becker, Sandra Burghart, Ewa Anna Oprzeska‐Zingrebe

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Abstract

The genome stores and processes approximately 1.5 gigabytes of encoded information. In this article, we propose that the eukaryotic genome and its adaptable three‐dimensional packing in the form of chromatin offer a valuable template for the system architecture of DNA‐based digital computers. We examine embryonic and stem cells, which exhibit distinct chromatin‐associated condensates enriched in transcription machinery. These dynamic biomolecular condensates facilitate the spatial association of genes, genomic control elements, and molecular machinery responsible for reading the genomic code. Drawing a compelling analogy to the von Neumann computer architecture—which integrates storage, processing, and memory in most electronic computers—we reflect on how the operational principles of these condensates could inspire the design of a similar architecture for future DNA computers. In particular, we describe how one could recreate such an architecture by exploiting the process of surface condensation, which underlies the formation of chromatin‐associated condensates. We conclude by reviewing our initial steps of constructing synthetic DNA nanostructures that follow the same operational principles and enable programmable surface condensation. Finally, we outline how computational methods from accelerated materials design could further advance the development of DNA computer system architectures.

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染色质相关凝聚物作为未来DNA计算机系统架构的灵感

基因组存储和处理大约1.5 gb的编码信息。在本文中，我们提出真核生物基因组及其染色质形式的适应性三维包装为基于DNA的数字计算机的系统架构提供了一个有价值的模板。我们研究了胚胎和干细胞，它们表现出不同的染色质相关凝聚体，富集在转录机制中。这些动态的生物分子凝聚体促进了基因、基因组控制元件和负责读取基因组密码的分子机制的空间关联。与冯·诺伊曼计算机体系结构（在大多数电子计算机中集成了存储、处理和内存）进行了令人信服的类比，我们思考了这些凝聚体的操作原理如何启发未来DNA计算机类似体系结构的设计。特别是，我们描述了如何通过利用表面冷凝过程来重建这样的结构，这是染色质相关冷凝物形成的基础。最后，我们回顾了我们构建合成DNA纳米结构的初始步骤，这些纳米结构遵循相同的操作原则，并使可编程的表面冷凝成为可能。最后，我们概述了加速材料设计的计算方法如何进一步推动DNA计算机系统架构的发展。

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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来源期刊

Annals of the New York Academy of Sciences 综合性期刊-综合性期刊

CiteScore

11.00

自引率

1.90%

发文量

193

审稿时长

2-4 weeks

期刊介绍： Published on behalf of the New York Academy of Sciences, Annals of the New York Academy of Sciences provides multidisciplinary perspectives on research of current scientific interest with far-reaching implications for the wider scientific community and society at large. Each special issue assembles the best thinking of key contributors to a field of investigation at a time when emerging developments offer the promise of new insight. Individually themed, Annals special issues stimulate new ways to think about science by providing a neutral forum for discourse—within and across many institutions and fields.