Cell-free DNA topology depends on its subcellular and cellular origins in cancer
Ethan Z. Malkin, Steven De Michino, Meghan Lambie, Rita Gill, Zhen Zhao, Ariana Rostami, Andrea Arruda, Mark D. Minden, Scott V. Bratman
Ethan Z. Malkin, Steven De Michino, Meghan Lambie, Rita Gill, Zhen Zhao, Ariana Rostami, Andrea Arruda, Mark D. Minden, Scott V. Bratman
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Resource and Technical Advance Cell biology Oncology

Cell-free DNA topology depends on its subcellular and cellular origins in cancer

Abstract

Cancer cells release large quantities of cell-free DNA (cfDNA) into the surrounding tissue and circulation. As cfDNA is a common source of biomarkers for liquid biopsy and has been implicated as a functional mediator for intercellular communication, fundamental characterization of cfDNA topology has widespread biological and clinical ramifications. Whether the topology of cfDNA is such that it exists predominantly in membrane-bound extracellular vesicles (EVs) or in nonvesicular DNA-protein complexes remains poorly understood. Here, we employed a DNA-targeted approach to comprehensively assess total cfDNA topology in cancer. Using preclinical models and patient samples, we demonstrate that nuclear cfDNA is predominantly associated with nucleosomal particles and not EVs, while a substantial subset of mitochondrial cfDNA is membrane protected and disproportionately derived from nontumor cells. In addition, discrimination between membrane-protected and accessible mitochondrial cfDNA added diagnostic and prognostic value in a cohort of head and neck cancer patients. Our results support a revised model for cfDNA topology in cancer. Due to its abundance, nuclear cfDNA within nucleosomal particles is the most compelling liquid biopsy substrate, while EV-bound and accessible mitochondrial cfDNA represent distinct reservoirs of potential cancer biomarkers whose structural conformations may also influence their extracellular stability and propensity for uptake by recipient cells.

Authors

Ethan Z. Malkin, Steven De Michino, Meghan Lambie, Rita Gill, Zhen Zhao, Ariana Rostami, Andrea Arruda, Mark D. Minden, Scott V. Bratman

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Figure 4

Plasma-derived cf-nDNA is not vesicle associated in a healthy or tumor-bearing state.

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Plasma-derived cf-nDNA is not vesicle associated in a healthy or tumor-b...
(A) Permeabilization/degradation assays on select samples of HD (left), HPV+ HNC patient (middle), and AML patient (right) plasma. Values were normalized to their respective PBS/mock treatment. (B) Relative recovery of ctDNA from select samples of HPV+ HNC and AML patient plasma. (C) ctDNA abundance after permeabilization/degradation assay on select samples of HPV+ HNC and AML patient plasma. Values were normalized to the PBS/mock treatment. (D) DNA-IP was performed on select samples of HD (left), HPV+ HNC patient (middle), and AML patient (right) plasma, and lipid content in each fraction was quantified using a modified phospho-sulfo-vanillin assay. Values were normalized to their respective input fraction. (E) Human plasma was subjected to DNA-IP, and DNA fragment sizes in the input and DNA-IP pellet fractions were quantified by BioAnalyzer. Shown are both the BioAnalyzer electropherogram and gel image for each fraction. The green lower marker (LM) is 35 bp, and the purple upper marker (UM) is 10,380 bp. Representative data from 1 AML patient plasma sample. *P < 0.05, ****P < 0.0001; ordinary 2-way ANOVA with Tukey’s multiple-comparison test (A and C); unpaired 2-sided t test with Welch’s correction (D). n = 6 for human cohorts; n = 4 for mouse cohort.