Next-generation sequencing reveals mitogenome diversity in plasma extracellular vesicles from colorectal cancer patients
Bjørnetrø, Tonje; Bousquet, Paula; Redalen, Kathrine Røe; Siebke, Anne-Marie; Lüders, Torben; Stang, Espen; Sanabria-Moreno, Adriana Maria; Johansen, Christin; Fuglestad, Anniken Jørlo; Kersten, Christian; Meltzer, Sebastian; Ree, Anne Hansen
Peer reviewed, Journal article
Published version
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Date
2023Metadata
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Abstract
Background
Recent reports have demonstrated that the entire mitochondrial genome can be secreted in extracellular vesicles (EVs), but the biological attributes of this cell-free mitochondrial DNA (mtDNA) remain insufficiently understood. We used next-generation sequencing to compare plasma EV-derived mtDNA to that of whole blood (WB), peripheral blood mononuclear cells (PBMCs), and formalin-fixed paraffin-embedded (FFPE) tumor tissue from eight rectal cancer patients and WB and fresh-frozen (FF) tumor tissue from eight colon cancer patients.
Methods
Total DNA was isolated before the mtDNA was enriched by PCR with either two primer sets generating two long products or multiple primer sets (for the FFPE tumors), prior to the sequencing. mtDNA diversity was assessed as the total variant number, level of heteroplasmy (mutant mtDNA copies mixed with wild-type copies), variant distribution within the protein-coding genes, and the predicted functional effect of the variants in the different sample types. Differences between groups were compared by paired Student’s t-test or ANOVA with Dunnett’s multiple comparison tests when comparing matched samples from patients. Mann–Whitney U test was used when comparing differences between the cancer types and patient groups. Pearson correlation analysis was performed.
Results
In both cancer types, EV mtDNA presented twice as many variants and had significantly more low-level heteroplasmy than WB mtDNA. The EV mtDNA variants were clustered in the coding regions, and the proportion of EV mtDNA variants that were missense mutations (i.e., estimated to moderately affect the mitochondrial protein function) was significantly higher than in WB and tumor tissues. Nonsense mutations (i.e., estimated to highly affect the mitochondrial protein function) were only observed in the tumor tissues and EVs.
Conclusion
Taken together, plasma EV mtDNA in CRC patients exhibits a high degree of diversity.