Noninvasive Detection of Cancer-associated Genome-wide Hypomethylation and Copy Number Aberrations by Plasma DNA Bisulfite Sequencing

Overview

Journal Proc Natl Acad Sci U S A

Specialty Science

Date 2013 Nov 6

PMID 24191000

Citations 204

Authors

K C Allen Chan

Peiyong Jiang

Carol W M Chan

Kun Sun

John Wong

Edwin P Hui

Stephen L Chan

Wing Cheong Chan

David S C Hui

Simon S M Ng

Henry L Y Chan

Cesar S C Wong

Brigette B Y Ma

Anthony T C Chan

Paul B S Lai

Hao Sun

Rossa W K Chiu

Y M Dennis Lo

Affiliations

Soon will be listed here.

Abstract

We explored the detection of genome-wide hypomethylation in plasma using shotgun massively parallel bisulfite sequencing as a marker for cancer. Tumor-associated copy number aberrations (CNAs) could also be observed from the bisulfite DNA sequencing data. Hypomethylation and CNAs were detected in the plasma DNA of patients with hepatocellular carcinoma, breast cancer, lung cancer, nasopharyngeal cancer, smooth muscle sarcoma, and neuroendocrine tumor. For the detection of nonmetastatic cancer cases, plasma hypomethylation gave a sensitivity and specificity of 74% and 94%, respectively, when a mean of 93 million reads per case were obtained. Reducing the sequencing depth to 10 million reads per case was found to have no adverse effect on the sensitivity and specificity for cancer detection, giving respective figures of 68% and 94%. This characteristic thus indicates that analysis of plasma hypomethylation by this sequencing-based method may be a relatively cost-effective approach for cancer detection. We also demonstrated that plasma hypomethylation had utility for monitoring hepatocellular carcinoma patients following tumor resection and for detecting residual disease. Plasma hypomethylation can be combined with plasma CNA analysis for further enhancement of the detection sensitivity or specificity using different diagnostic algorithms. Using the detection of at least one type of aberration to define an abnormality, a sensitivity of 87% could be achieved with a specificity of 88%. These developments have thus expanded the applications of plasma DNA analysis for cancer detection and monitoring.

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