Peak analysis of cell-free RNA finds recurrently protected narrow regions with clinical potential

Peak analysis of cell-free RNA finds recurrently protected narrow regions with clinical potential

Abstract Background Cell-free RNAs (cfRNAs) can be detected in biofluids and have emerged as valuable disease biomarkers. Accurate identification of the fragmented cfRNA signals, especially those originating from pathological cells, is crucial for understanding their biological functions and clinica...

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Main Authors: Pengfei Bao, Taiwei Wang, Xiaofan Liu, Shaozhen Xing, Hanjin Ruan, Hongli Ma, Yuhuan Tao, Qing Zhan, Efres Belmonte-Reche, Lizheng Qin, Zhengxue Han, Minghui Mao, Mengtao Li, Zhi John Lu
Format: Article
Language:English
Published: BMC 2025-05-01
Series:Genome Biology
Subjects:
Cell-free RNA
CfRNA fragment
Peak calling
SncRNA
Liquid biopsy biomarker
Tissue-of-origin
Online Access:https://doi.org/10.1186/s13059-025-03590-x
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Summary:Abstract Background Cell-free RNAs (cfRNAs) can be detected in biofluids and have emerged as valuable disease biomarkers. Accurate identification of the fragmented cfRNA signals, especially those originating from pathological cells, is crucial for understanding their biological functions and clinical value. However, many challenges still need to be addressed for their application, including developing specific analysis methods and translating cfRNA fragments with biological support into clinical applications. Results We present cfPeak, a novel method combining statistics and machine learning models to detect the fragmented cfRNA signals effectively. When test in real and artificial cfRNA sequencing (cfRNA-seq) data, cfPeak shows an improved performance compared with other applicable methods. We reveal that narrow cfRNA peaks preferentially overlap with protein binding sites, vesicle-sorting sites, structural sites, and novel small non-coding RNAs (sncRNAs). When applied in clinical cohorts, cfPeak identified cfRNA peaks in patients’ plasma that enable cancer detection and are informative of cancer types and metastasis. Conclusions Our study fills the gap in the current small cfRNA-seq analysis at fragment-scale and builds a bridge to the scientific discovery in cfRNA fragmentomics. We demonstrate the significance of finding low abundant tissue-derived signals in small cfRNA and prove the feasibility for application in liquid biopsy. Graphical Abstract
ISSN:1474-760X

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