贝叶斯分析和高效算法的单分子荧光数据和步长计数

IF 3.1 3区生物学 Q2 BIOPHYSICS

Biophysical journal Pub Date : 2025-08-20 DOI:10.1016/j.bpj.2025.08.014

Chiara Mattamira, Alyssa Ward, Sriram Tiruvadi Krishnan, Rajan Lamichhane, Francisco N. Barrera, Ioannis Sgouralis

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引用次数: 0

摘要

随着单分子荧光实验的日益普及，对有效的统计方法和获得的测量结果的准确分析的需求越来越大。现有的分析框架，例如那些使用动力学模型的分析框架，通常依赖于对所研究的分子和荧光团的动力学的强假设，这使得它们不适合一般用途的步长计数应用，特别是当研究系统表现出未表征的动力学时。在这里，我们提出了一种新的贝叶斯非参数框架来分析与动力学模型无关的单分子荧光数据。为了评估我们的方法，我们开发了四种MCMC采样器，从基本到高度复杂，并证明增加的复杂性对于准确的数据分析是必不可少的。我们将我们的方法应用于绿色荧光蛋白标记的EphA2受体的TIRF光漂白实验数据。此外，我们用模拟现实条件的合成数据验证了我们的方法，并展示了其在高低信噪比数据下恢复地面真实值的能力，将其建立为荧光数据分析的通用工具。

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Bayesian analysis and efficient algorithms for single-molecule fluorescence data and step counting

With the growing adoption of single-molecule fluorescence experiments, there is an increasing demand for efficient statistical methodologies and accurate analysis of the acquired measurements. Existing analysis frameworks, such as those that use kinetic models, often rely on strong assumptions on the dynamics of the molecules and fluorophores under study that render them inappropriate for general purpose step counting applications, especially when the systems of study exhibit uncharacterized dynamics. Here, we propose a novel Bayesian nonparametric framework to analyze single-molecule fluorescence data that is kinetic model independent. For the evaluation of our methods, we develop four MCMC samplers, ranging from elemental to highly sophisticated, and demonstrate that the added complexity is essential for accurate data analysis. We apply our methods to experimental data obtained from TIRF photobleaching assays of the EphA2 receptor tagged with GFP. In addition, we validate our approach with synthetic data mimicking realistic conditions and demonstrate its ability to recover ground truth under high- and low-signal-to-noise data, establishing it as a versatile tool for fluorescence data analysis.

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来源期刊

Biophysical journal 生物-生物物理

CiteScore

6.10

自引率

5.90%

发文量

3090

审稿时长

2 months

期刊介绍： BJ publishes original articles, letters, and perspectives on important problems in modern biophysics. The papers should be written so as to be of interest to a broad community of biophysicists. BJ welcomes experimental studies that employ quantitative physical approaches for the study of biological systems, including or spanning scales from molecule to whole organism. Experimental studies of a purely descriptive or phenomenological nature, with no theoretical or mechanistic underpinning, are not appropriate for publication in BJ. Theoretical studies should offer new insights into the understanding ofexperimental results or suggest new experimentally testable hypotheses. Articles reporting significant methodological or technological advances, which have potential to open new areas of biophysical investigation, are also suitable for publication in BJ. Papers describing improvements in accuracy or speed of existing methods or extra detail within methods described previously are not suitable for BJ.