Fragment Length of Circulating Tumor DNA

Overview

Journal PLoS Genet

Specialty Genetics

Date 2016 Jul 19

PMID 27428049

Citations 322

Authors

Hunter R Underhill

Jacob O Kitzman

Sabine Hellwig

Noah C Welker

Riza Daza

Daniel N Baker

Keith M Gligorich

Robert C Rostomily

Mary P Bronner

Jay Shendure

Affiliations

Soon will be listed here.

Abstract

Malignant tumors shed DNA into the circulation. The transient half-life of circulating tumor DNA (ctDNA) may afford the opportunity to diagnose, monitor recurrence, and evaluate response to therapy solely through a non-invasive blood draw. However, detecting ctDNA against the normally occurring background of cell-free DNA derived from healthy cells has proven challenging, particularly in non-metastatic solid tumors. In this study, distinct differences in fragment length size between ctDNAs and normal cell-free DNA are defined. Human ctDNA in rat plasma derived from human glioblastoma multiforme stem-like cells in the rat brain and human hepatocellular carcinoma in the rat flank were found to have a shorter principal fragment length than the background rat cell-free DNA (134-144 bp vs. 167 bp, respectively). Subsequently, a similar shift in the fragment length of ctDNA in humans with melanoma and lung cancer was identified compared to healthy controls. Comparison of fragment lengths from cell-free DNA between a melanoma patient and healthy controls found that the BRAF V600E mutant allele occurred more commonly at a shorter fragment length than the fragment length of the wild-type allele (132-145 bp vs. 165 bp, respectively). Moreover, size-selecting for shorter cell-free DNA fragment lengths substantially increased the EGFR T790M mutant allele frequency in human lung cancer. These findings provide compelling evidence that experimental or bioinformatic isolation of a specific subset of fragment lengths from cell-free DNA may improve detection of ctDNA.

Citing Articles

A deep-learning model for quantifying circulating tumour DNA from the density distribution of DNA-fragment lengths.

Zhu G, Rahman C, Getty V, Odinokov D, Baruah P, Carrie H Nat Biomed Eng. 2025; .

PMID: 40055581 DOI: 10.1038/s41551-025-01370-3.

Genomic and fragmentomic landscapes of cell-free DNA for early cancer detection.

Bruhm D, Vulpescu N, Foda Z, Phallen J, Scharpf R, Velculescu V Nat Rev Cancer. 2025; .

PMID: 40038442 DOI: 10.1038/s41568-025-00795-x.

Cell-free DNA as a complementary diagnostic tool for neglected tropical diseases towards achieving the WHO NTDs elimination by 2030.

Osei-Poku P, Tritten L, Fordjour F, Kwarteng A J Liq Biopsy. 2025; 7:100283.

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size-selection of short circulating tumor DNA fragments from late-stage lung cancer patients enhance the detection of mutations and aneuploidies.

Maansson C, Thomsen L, Stokkebro L, Dissing J, Ulhoi M, Nielsen A J Liq Biopsy. 2025; 4:100141.

PMID: 40027141 PMC: 11863712. DOI: 10.1016/j.jlb.2024.100141.

Genomic alterations and transcriptional phenotypes in circulating free DNA and matched metastatic tumor.

Takahashi N, Pongor L, Agrawal S, Shtumpf M, Gurjar A, Rajapakse V Genome Med. 2025; 17(1):15.

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