Quantifying the nuclear localization of fluorescently tagged proteins.

IF 2.4 Q2 MATHEMATICAL & COMPUTATIONAL BIOLOGY

Bioinformatics advances Pub Date : 2025-05-12 eCollection Date: 2025-01-01 DOI:10.1093/bioadv/vbaf114

Julien Hurbain, Pieter Rein Ten Wolde, Peter S Swain

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引用次数: 0

Abstract

Motivation: Cells are dynamic, continually responding to intra- and extracellular signals. Measuring the response to these signals in individual cells is challenging. Signal transduction is fast, but reporters for downstream gene expression are slow: fluorescent proteins must be expressed and mature. An alternative is to fluorescently tag and monitor the intracellular locations of transcription factors and other effectors. These proteins enter or exit the nucleus in minutes, after upstream signalling modifies their phosphorylation state. Although such approaches are increasingly popular, there is no consensus on how to quantify nuclear localization.

Results: Using budding yeast, we developed a convolutional neural network that determines nuclear localization from fluorescence and, optionally, bright-field images. Focusing on changing extracellular glucose, we generated ground-truth data using strains with a transcription factor and a nuclear protein tagged with fluorescent markers. We showed that the neural network-based approach outperformed seven published methods, particularly when predicting single-cell time series, which are key to determining how cells respond. Collectively, our results are conclusive-using machine learning to automatically determine the appropriate image processing consistently outperforms ad hoc approaches. Adopting such methods promises to both improve the accuracy and, with transfer learning, the consistency of single-cell analyses.

Availability and implementation: We performed our analysis in Python; code is available at https://git.ecdf.ed.ac.uk/v1jhurba/neunet-nucloc.git.

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定量荧光标记蛋白的核定位。

动机：细胞是动态的，不断响应细胞内和细胞外的信号。测量单个细胞对这些信号的反应是具有挑战性的。信号转导是快速的，但下游基因表达的报告者是缓慢的：荧光蛋白必须表达和成熟。另一种方法是荧光标记和监测转录因子和其他效应物的细胞内位置。在上游信号改变磷酸化状态后，这些蛋白在几分钟内进入或离开细胞核。虽然这些方法越来越流行，但如何量化核定位还没有达成共识。结果：利用出芽酵母，我们开发了一个卷积神经网络，可以从荧光和可选的亮场图像中确定核定位。专注于细胞外葡萄糖的变化，我们使用带有转录因子和带有荧光标记的核蛋白的菌株生成了基本事实数据。我们表明，基于神经网络的方法优于7种已发表的方法，特别是在预测单细胞时间序列时，这是确定细胞如何反应的关键。总的来说，我们的结果是结论性的-使用机器学习来自动确定适当的图像处理始终优于特设方法。采用这种方法有望提高准确性，并通过迁移学习提高单细胞分析的一致性。可用性和实现：我们使用Python执行分析；代码可从https://git.ecdf.ed.ac.uk/v1jhurba/neunet-nucloc.git获得。

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

Bioinformatics advances

CiteScore

1.60

自引率

0.00%

发文量