Integrative analysis of long extracellular RNAs reveals a detection panel of noncoding RNAs for liver cancer

Rationale: Long extracellular RNAs (exRNAs) in plasma can be profiled by new sequencing technologies, even with low abundance. However, cancer-related exRNAs and their variations remain understudied. Methods: We investigated different variations (i.e. differential expression, alternative splicing, a...

Descripción completa

Detalles Bibliográficos
Autores principales: Zhu, Yumin, Wang, Siqi, Xi, Xiaochen, Zhang, Minfeng, Liu, Xiaofan, Tang, Weina, Cai, Peng, Xing, Shaozhen, Bao, Pengfei, Jin, Yunfan, Zhao, Weihao, Chen, Yinghui, Zhao, Huanan, Jia, Xiaodong, Lu, Shanshan, Lu, Yinying, Chen, Lei, Yin, Jianhua, Lu, Zhi John
Formato: Online Artículo Texto
Lenguaje:English
Publicado: Ivyspring International Publisher 2021
Materias:
Research Paper
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC7681086/
https://www.ncbi.nlm.nih.gov/pubmed/33391469
http://dx.doi.org/10.7150/thno.48206
_version_ 1783612563922092032
author Zhu, Yumin
Wang, Siqi
Xi, Xiaochen
Zhang, Minfeng
Liu, Xiaofan
Tang, Weina
Cai, Peng
Xing, Shaozhen
Bao, Pengfei
Jin, Yunfan
Zhao, Weihao
Chen, Yinghui
Zhao, Huanan
Jia, Xiaodong
Lu, Shanshan
Lu, Yinying
Chen, Lei
Yin, Jianhua
Lu, Zhi John
author_facet Zhu, Yumin
Wang, Siqi
Xi, Xiaochen
Zhang, Minfeng
Liu, Xiaofan
Tang, Weina
Cai, Peng
Xing, Shaozhen
Bao, Pengfei
Jin, Yunfan
Zhao, Weihao
Chen, Yinghui
Zhao, Huanan
Jia, Xiaodong
Lu, Shanshan
Lu, Yinying
Chen, Lei
Yin, Jianhua
Lu, Zhi John
author_sort Zhu, Yumin
collection PubMed
description Rationale: Long extracellular RNAs (exRNAs) in plasma can be profiled by new sequencing technologies, even with low abundance. However, cancer-related exRNAs and their variations remain understudied. Methods: We investigated different variations (i.e. differential expression, alternative splicing, alternative polyadenylation, and differential editing) in diverse long exRNA species (e.g. long noncoding RNAs and circular RNAs) using 79 plasma exosomal RNA-seq (exoRNA-seq) datasets of multiple cancer types. We then integrated 53 exoRNA-seq datasets and 65 self-profiled cell-free RNA-seq (cfRNA-seq) datasets to identify recurrent variations in liver cancer patients. We further combined TCGA tissue RNA-seq datasets and validated biomarker candidates by RT-qPCR in an individual cohort of more than 100 plasma samples. Finally, we used machine learning models to identify a signature of 3 noncoding RNAs for the detection of liver cancer. Results: We found that different types of RNA variations identified from exoRNA-seq data were enriched in pathways related to tumorigenesis and metastasis, immune, and metabolism, suggesting that cancer signals can be detected from long exRNAs. Subsequently, we identified more than 100 recurrent variations in plasma from liver cancer patients by integrating exoRNA-seq and cfRNA-seq datasets. From these datasets, 5 significantly up-regulated long exRNAs were confirmed by TCGA data and validated by RT-qPCR in an independent cohort. When using machine learning models to combine two of these validated circular and structured RNAs (SNORD3B-1, circ-0080695) with a miRNA (miR-122) as a panel to classify liver cancer patients from healthy donors, the average AUROC of the cross-validation was 89.4%. The selected 3-RNA panel successfully detected 79.2% AFP-negative samples and 77.1% early-stage liver cancer samples in the testing and validation sets. Conclusions: Our study revealed that different types of RNA variations related to cancer can be detected in plasma and identified a 3-RNA detection panel for liver cancer, especially for AFP-negative and early-stage patients.
format Online
Article
Text
id pubmed-7681086
institution National Center for Biotechnology Information
language English
publishDate 2021
publisher Ivyspring International Publisher
record_format MEDLINE/PubMed
spelling pubmed-76810862021-01-01 Integrative analysis of long extracellular RNAs reveals a detection panel of noncoding RNAs for liver cancer Zhu, Yumin Wang, Siqi Xi, Xiaochen Zhang, Minfeng Liu, Xiaofan Tang, Weina Cai, Peng Xing, Shaozhen Bao, Pengfei Jin, Yunfan Zhao, Weihao Chen, Yinghui Zhao, Huanan Jia, Xiaodong Lu, Shanshan Lu, Yinying Chen, Lei Yin, Jianhua Lu, Zhi John Theranostics Research Paper Rationale: Long extracellular RNAs (exRNAs) in plasma can be profiled by new sequencing technologies, even with low abundance. However, cancer-related exRNAs and their variations remain understudied. Methods: We investigated different variations (i.e. differential expression, alternative splicing, alternative polyadenylation, and differential editing) in diverse long exRNA species (e.g. long noncoding RNAs and circular RNAs) using 79 plasma exosomal RNA-seq (exoRNA-seq) datasets of multiple cancer types. We then integrated 53 exoRNA-seq datasets and 65 self-profiled cell-free RNA-seq (cfRNA-seq) datasets to identify recurrent variations in liver cancer patients. We further combined TCGA tissue RNA-seq datasets and validated biomarker candidates by RT-qPCR in an individual cohort of more than 100 plasma samples. Finally, we used machine learning models to identify a signature of 3 noncoding RNAs for the detection of liver cancer. Results: We found that different types of RNA variations identified from exoRNA-seq data were enriched in pathways related to tumorigenesis and metastasis, immune, and metabolism, suggesting that cancer signals can be detected from long exRNAs. Subsequently, we identified more than 100 recurrent variations in plasma from liver cancer patients by integrating exoRNA-seq and cfRNA-seq datasets. From these datasets, 5 significantly up-regulated long exRNAs were confirmed by TCGA data and validated by RT-qPCR in an independent cohort. When using machine learning models to combine two of these validated circular and structured RNAs (SNORD3B-1, circ-0080695) with a miRNA (miR-122) as a panel to classify liver cancer patients from healthy donors, the average AUROC of the cross-validation was 89.4%. The selected 3-RNA panel successfully detected 79.2% AFP-negative samples and 77.1% early-stage liver cancer samples in the testing and validation sets. Conclusions: Our study revealed that different types of RNA variations related to cancer can be detected in plasma and identified a 3-RNA detection panel for liver cancer, especially for AFP-negative and early-stage patients. Ivyspring International Publisher 2021-01-01 /pmc/articles/PMC7681086/ /pubmed/33391469 http://dx.doi.org/10.7150/thno.48206 Text en © The author(s) This is an open access article distributed under the terms of the Creative Commons Attribution License (https://creativecommons.org/licenses/by/4.0/). See http://ivyspring.com/terms for full terms and conditions.
spellingShingle Research Paper
Zhu, Yumin
Wang, Siqi
Xi, Xiaochen
Zhang, Minfeng
Liu, Xiaofan
Tang, Weina
Cai, Peng
Xing, Shaozhen
Bao, Pengfei
Jin, Yunfan
Zhao, Weihao
Chen, Yinghui
Zhao, Huanan
Jia, Xiaodong
Lu, Shanshan
Lu, Yinying
Chen, Lei
Yin, Jianhua
Lu, Zhi John
Integrative analysis of long extracellular RNAs reveals a detection panel of noncoding RNAs for liver cancer
title Integrative analysis of long extracellular RNAs reveals a detection panel of noncoding RNAs for liver cancer
title_full Integrative analysis of long extracellular RNAs reveals a detection panel of noncoding RNAs for liver cancer
title_fullStr Integrative analysis of long extracellular RNAs reveals a detection panel of noncoding RNAs for liver cancer
title_full_unstemmed Integrative analysis of long extracellular RNAs reveals a detection panel of noncoding RNAs for liver cancer
title_short Integrative analysis of long extracellular RNAs reveals a detection panel of noncoding RNAs for liver cancer
title_sort integrative analysis of long extracellular rnas reveals a detection panel of noncoding rnas for liver cancer
topic Research Paper
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC7681086/
https://www.ncbi.nlm.nih.gov/pubmed/33391469
http://dx.doi.org/10.7150/thno.48206
work_keys_str_mv AT zhuyumin integrativeanalysisoflongextracellularrnasrevealsadetectionpanelofnoncodingrnasforlivercancer
AT wangsiqi integrativeanalysisoflongextracellularrnasrevealsadetectionpanelofnoncodingrnasforlivercancer
AT xixiaochen integrativeanalysisoflongextracellularrnasrevealsadetectionpanelofnoncodingrnasforlivercancer
AT zhangminfeng integrativeanalysisoflongextracellularrnasrevealsadetectionpanelofnoncodingrnasforlivercancer
AT liuxiaofan integrativeanalysisoflongextracellularrnasrevealsadetectionpanelofnoncodingrnasforlivercancer
AT tangweina integrativeanalysisoflongextracellularrnasrevealsadetectionpanelofnoncodingrnasforlivercancer
AT caipeng integrativeanalysisoflongextracellularrnasrevealsadetectionpanelofnoncodingrnasforlivercancer
AT xingshaozhen integrativeanalysisoflongextracellularrnasrevealsadetectionpanelofnoncodingrnasforlivercancer
AT baopengfei integrativeanalysisoflongextracellularrnasrevealsadetectionpanelofnoncodingrnasforlivercancer
AT jinyunfan integrativeanalysisoflongextracellularrnasrevealsadetectionpanelofnoncodingrnasforlivercancer
AT zhaoweihao integrativeanalysisoflongextracellularrnasrevealsadetectionpanelofnoncodingrnasforlivercancer
AT chenyinghui integrativeanalysisoflongextracellularrnasrevealsadetectionpanelofnoncodingrnasforlivercancer
AT zhaohuanan integrativeanalysisoflongextracellularrnasrevealsadetectionpanelofnoncodingrnasforlivercancer
AT jiaxiaodong integrativeanalysisoflongextracellularrnasrevealsadetectionpanelofnoncodingrnasforlivercancer
AT lushanshan integrativeanalysisoflongextracellularrnasrevealsadetectionpanelofnoncodingrnasforlivercancer
AT luyinying integrativeanalysisoflongextracellularrnasrevealsadetectionpanelofnoncodingrnasforlivercancer
AT chenlei integrativeanalysisoflongextracellularrnasrevealsadetectionpanelofnoncodingrnasforlivercancer
AT yinjianhua integrativeanalysisoflongextracellularrnasrevealsadetectionpanelofnoncodingrnasforlivercancer
AT luzhijohn integrativeanalysisoflongextracellularrnasrevealsadetectionpanelofnoncodingrnasforlivercancer

Ejemplares similares