A unified hypothesis-free feature extraction framework for diverse epigenomic data.

IF 2.4 Q2 MATHEMATICAL & COMPUTATIONAL BIOLOGY

Bioinformatics advances Pub Date : 2025-03-08 eCollection Date: 2025-01-01 DOI:10.1093/bioadv/vbaf013

Ali Tuğrul Balcı, Maria Chikina

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引用次数: 0

Abstract

Motivation: Epigenetic assays using next-generation sequencing have furthered our understanding of the functional genomic regions and the mechanisms of gene regulation. However, a single assay produces billions of data points, with limited information about the biological process due to numerous sources of technical and biological noise. To draw biological conclusions, numerous specialized algorithms have been proposed to summarize the data into higher-order patterns, such as peak calling and the discovery of differentially methylated regions. The key principle underlying these approaches is the search for locally consistent patterns.

Results: We propose $L_{0}$ segmentation as a universal framework for extracting locally coherent signals for diverse epigenetic sources. $L_{0}$ serves to compress the input signal by approximating it as a piecewise constant. We implement a highly scalable $L_{0}$ segmentation with additional loss functions designed for sequencing epigenetic data types including Poisson loss for single tracks and binomial loss for methylation/coverage data. We show that the $L_{0}$ segmentation approach retains the salient features of the data yet can identify subtle features, such as transcription end sites, missed by other analytic approaches.

Availability and implementation: Our approach is implemented as an R package "l01segmentation" with a C++ backend. Available at https://github.com/boooooogey/l01segmentation.

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不同表观基因组数据的统一无假设特征提取框架。

动机：使用下一代测序技术的表观遗传学分析进一步加深了我们对基因组功能区域和基因调控机制的理解。然而，单个分析产生数十亿个数据点，由于技术和生物噪声的众多来源，关于生物过程的信息有限。为了得出生物学结论，已经提出了许多专门的算法来将数据总结为高阶模式，例如峰值调用和差异甲基化区域的发现。这些方法背后的关键原则是寻找局部一致的模式。结果：我们提出l0分割作为提取不同表观遗传源的局部相干信号的通用框架。l0通过将输入信号近似为分段常数来压缩输入信号。我们实现了一个高度可扩展的l0分割，附带额外的损失函数，用于测序表观遗传数据类型，包括单轨的泊松损失和甲基化/覆盖数据的二项损失。研究表明，l0分割方法保留了数据的显著特征，但可以识别出其他分析方法遗漏的细微特征，如转录末端位点。可用性和实现：我们的方法是通过一个带有c++后端的R包“01segmentation”来实现的。可在https://github.com/boooooogey/l01segmentation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