哺乳动物细胞通过相分离进行二维和三维合成大规模从头图案化。

2- and 3-dimensional synthetic large-scale de novo patterning by mammalian cells through phase separation.

作者信息

Cachat Elise, Liu Weijia, Martin Kim C, Yuan Xiaofei, Yin Huabing, Hohenstein Peter, Davies Jamie A

机构信息

Centre for Integrative Physiology &Synthsys Centre for Synthetic &Systems Biology, University of Edinburgh, George Square, Edinburgh EH8 9XB, UK.

School of Engineering, University of Glasgow, Rankine Building, Oakfield Avenue, Glasgow G12 8LT, UK.

出版信息

Sci Rep. 2016 Feb 9;6:20664. doi: 10.1038/srep20664.

DOI:10.1038/srep20664

PMID:26857385

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4746622/

Abstract

Synthetic biology provides an opportunity for the construction and exploration of alternative solutions to biological problems - solutions different from those chosen by natural life. To this end, synthetic biologists have built new sensory systems, cellular memories, and alternative genetic codes. There is a growing interest in applying synthetic approaches to multicellular systems, especially in relation to multicellular self-organization. Here we describe a synthetic biological system that confers large-scale de novo patterning activity on 2-D and 3-D populations of mammalian cells. Instead of using the reaction-diffusion mechanisms common in real embryos, our system uses cadherin-mediated phase separation, inspired by the known phenomenon of cadherin-based sorting. An engineered self-organizing, large-scale patterning system requiring no prior spatial cue may be a significant step towards the construction of self-assembling synthetic tissues.

摘要

合成生物学为构建和探索生物学问题的替代解决方案提供了契机——这些解决方案不同于自然生命所选择的方案。为此，合成生物学家构建了新的传感系统、细胞记忆和替代遗传密码。将合成方法应用于多细胞系统的兴趣日益浓厚，特别是在多细胞自组织方面。在此，我们描述了一种合成生物学系统，该系统赋予哺乳动物细胞二维和三维群体大规模的从头模式形成活性。我们的系统并非使用真实胚胎中常见的反应扩散机制，而是受基于钙黏蛋白分选这一已知现象的启发，利用钙黏蛋白介导的相分离。一个无需预先空间线索的工程化自组织大规模模式形成系统，可能是迈向构建自组装合成组织的重要一步。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/cb6b/4746622/cf0de3671bbe/srep20664-f1.jpg

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哺乳动物细胞通过相分离进行二维和三维合成大规模从头图案化。

2- and 3-dimensional synthetic large-scale de novo patterning by mammalian cells through phase separation.

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