一种可重构的与非/或非基因逻辑门。

A reconfigurable NAND/NOR genetic logic gate.

作者信息

Goñi-Moreno Angel, Amos Martyn

机构信息

School of Computing, Mathematics and Digital Technology, Manchester Metropolitan University, Manchester M1 5GD, United Kingdom.

出版信息

BMC Syst Biol. 2012 Sep 18;6:126. doi: 10.1186/1752-0509-6-126.

DOI:10.1186/1752-0509-6-126

PMID:22989145

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3776446/

Abstract

BACKGROUND

Engineering genetic Boolean logic circuits is a major research theme of synthetic biology. By altering or introducing connections between genetic components, novel regulatory networks are built in order to mimic the behaviour of electronic devices such as logic gates. While electronics is a highly standardized science, genetic logic is still in its infancy, with few agreed standards. In this paper we focus on the interpretation of logical values in terms of molecular concentrations.

RESULTS

We describe the results of computational investigations of a novel circuit that is able to trigger specific differential responses depending on the input standard used. The circuit can therefore be dynamically reconfigured (without modification) to serve as both a NAND/NOR logic gate. This multi-functional behaviour is achieved by a) varying the meanings of inputs, and b) using branch predictions (as in computer science) to display a constrained output. A thorough computational study is performed, which provides valuable insights for the future laboratory validation. The simulations focus on both single-cell and population behaviours. The latter give particular insights into the spatial behaviour of our engineered cells on a surface with a non-homogeneous distribution of inputs.

CONCLUSIONS

We present a dynamically-reconfigurable NAND/NOR genetic logic circuit that can be switched between modes of operation via a simple shift in input signal concentration. The circuit addresses important issues in genetic logic that will have significance for more complex synthetic biology applications.

摘要

背景

构建基因布尔逻辑电路是合成生物学的一个主要研究主题。通过改变或引入基因元件之间的连接，构建新型调控网络，以模仿诸如逻辑门等电子设备的行为。虽然电子学是一门高度标准化的科学，但基因逻辑仍处于起步阶段，几乎没有公认的标准。在本文中，我们专注于根据分子浓度来解释逻辑值。

结果

我们描述了一种新型电路的计算研究结果，该电路能够根据所使用的输入标准触发特定的差异响应。因此，该电路可以动态重新配置（无需修改），以同时充当与非门/或非门逻辑门。这种多功能行为是通过以下方式实现的：a）改变输入的含义，以及b）使用分支预测（如在计算机科学中）来显示受限输出。进行了全面的计算研究，为未来的实验室验证提供了有价值的见解。模拟聚焦于单细胞和群体行为。后者特别深入地揭示了我们工程细胞在具有非均匀输入分布的表面上的空间行为。

结论

我们提出了一种动态可重新配置的与非门/或非门基因逻辑电路，它可以通过简单地改变输入信号浓度在操作模式之间切换。该电路解决了基因逻辑中的重要问题，这对于更复杂的合成生物学应用具有重要意义。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/dd52/3776446/240538f874d4/1752-0509-6-126-1.jpg

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一种可重构的与非/或非基因逻辑门。

A reconfigurable NAND/NOR genetic logic gate.

作者信息

机构信息

出版信息

BACKGROUND

RESULTS

CONCLUSIONS

背景

结果

结论

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