Multi-omics Data Integration Using Ratio-based Quantitative Profiling with Quartet Reference Materials

Overview

Journal Nat Biotechnol

Specialty Biotechnology

Date 2023 Sep 7

PMID 37679543

Authors

Yuanting Zheng

Yaqing Liu

Jingcheng Yang

Lianhua Dong

Rui Zhang

Sha Tian

Ying Yu

Luyao Ren

Wanwan Hou

Feng Zhu

Yuanbang Mai

Jinxiong Han

Lijun Zhang

Hui Jiang

Ling Lin

Jingwei Lou

Ruiqiang Li

Jingchao Lin

Huafen Liu

Ziqing Kong

Depeng Wang

Fangping Dai

Ding Bao

Zehui Cao

Qiaochu Chen

Qingwang Chen

Xingdong Chen

Yuechen Gao

He Jiang

Bin Li

Bingying Li

Jingjing Li

Ruimei Liu

Tao Qing

Erfei Shang

Jun Shang

Shanyue Sun

Haiyan Wang

Xiaolin Wang

Naixin Zhang

Peipei Zhang

Ruolan Zhang

Sibo Zhu

Andreas Scherer

Jiucun Wang

Jing Wang

Yinbo Huo

Gang Liu

Chengming Cao

Li Shao

Joshua Xu

Huixiao Hong

Wenming Xiao

Xiaozhen Liang

Daru Lu

Li Jin

Weida Tong

Chen Ding

Jinming Li

Xiang Fang

Leming Shi

Affiliations

Soon will be listed here.

Abstract

Characterization and integration of the genome, epigenome, transcriptome, proteome and metabolome of different datasets is difficult owing to a lack of ground truth. Here we develop and characterize suites of publicly available multi-omics reference materials of matched DNA, RNA, protein and metabolites derived from immortalized cell lines from a family quartet of parents and monozygotic twin daughters. These references provide built-in truth defined by relationships among the family members and the information flow from DNA to RNA to protein. We demonstrate how using a ratio-based profiling approach that scales the absolute feature values of a study sample relative to those of a concurrently measured common reference sample produces reproducible and comparable data suitable for integration across batches, labs, platforms and omics types. Our study identifies reference-free 'absolute' feature quantification as the root cause of irreproducibility in multi-omics measurement and data integration and establishes the advantages of ratio-based multi-omics profiling with common reference materials.

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