基因编码荧光生物传感器的状态依赖性运动。

State-dependent motion of a genetically encoded fluorescent biosensor.

作者信息

Rosen Paul C, Horwitz Samantha M, Brooks Daniel J, Kim Erica, Ambarian Joseph A, Waidmann Lidia, Davis Katherine M, Yellen Gary

机构信息

Department of Neurobiology, Harvard Medical School, Boston, MA 02115.

Department of Biology, Massachusetts Institute of Technology, Cambridge, MA 02139.

出版信息

Proc Natl Acad Sci U S A. 2025 Mar 11;122(10):e2426324122. doi: 10.1073/pnas.2426324122. Epub 2025 Mar 6.

DOI:10.1073/pnas.2426324122

PMID:40048274

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11912384/

Abstract

Genetically encoded biosensors can measure biochemical properties such as small-molecule concentrations with single-cell resolution, even in vivo. Despite their utility, these sensors are "black boxes": Very little is known about the structures of their low- and high-fluorescence states or what features are required to transition between them. We used LiLac, a lactate biosensor with a quantitative fluorescence-lifetime readout, as a model system to address these questions. X-ray crystal structures and engineered high-affinity metal bridges demonstrate that LiLac exhibits a large interdomain twist motion that pulls the fluorescent protein away from a "sealed," high-lifetime state in the absence of lactate to a "cracked," low-lifetime state in its presence. Understanding the structures and dynamics of LiLac will help to think about and engineer other fluorescent biosensors.

摘要

基因编码生物传感器能够以单细胞分辨率测量生物化学特性，如小分子浓度，甚至在体内也能做到。尽管这些传感器很有用，但它们就像“黑匣子”：对于其低荧光态和高荧光态的结构，以及在这两种状态之间转换所需的特征，我们知之甚少。我们使用LiLac（一种具有定量荧光寿命读数的乳酸盐生物传感器）作为模型系统来解决这些问题。X射线晶体结构和工程化的高亲和力金属桥表明，LiLac表现出较大的结构域间扭转运动，该运动将荧光蛋白从无乳酸时的“封闭”、高寿命状态拉到有乳酸时的“开裂”、低寿命状态。了解LiLac的结构和动力学将有助于思考和设计其他荧光生物传感器。

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基因编码荧光生物传感器的状态依赖性运动。

State-dependent motion of a genetically encoded fluorescent biosensor.

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