Tumor-Specific Mitochondrial DNA Variants Are Rarely Detected in Cell-Free DNA.

The use of blood-circulating cell-free DNA (cfDNA) as a "liquid biopsy" in oncology is being explored for its potential as a cancer biomarker. Mitochondria contain their own circular genomic entity (mitochondrial DNA, mtDNA), up to even thousands of copies per cell. The mutation rate of mtDNA is several orders of magnitude higher than that of the nuclear DNA. Tumor-specific variants have been identified in tumors along the entire mtDNA, and their number varies among and within tumors. The high mtDNA copy number per cell and the high mtDNA mutation rate make it worthwhile to explore the potential of tumor-specific cf-mtDNA variants as cancer marker in the blood of cancer patients. We used single-molecule real-time (SMRT) sequencing to profile the entire mtDNA of 19 tissue specimens (primary tumor and/or metastatic sites, and tumor-adjacent normal tissue) and 9 cfDNA samples, originating from 8 cancer patients (5 breast, 3 colon). For each patient, tumor-specific mtDNA variants were detected and traced in cfDNA by SMRT sequencing and/or digital PCR to explore their feasibility as cancer biomarker. As a reference, we measured other blood-circulating biomarkers for these patients, including driver mutations in nuclear-encoded cfDNA and cancer-antigen levels or circulating tumor cells. Four of the 24 (17%) tumor-specific mtDNA variants were detected in cfDNA, however at much lower allele frequencies compared to mutations in nuclear-encoded driver genes in the same samples. Also, extensive heterogeneity was observed among the heteroplasmic mtDNA variants present in an individual. We conclude that there is limited value in tracing tumor-specific mtDNA variants in blood-circulating cfDNA with the current methods available.

Sensitive detection of mitochondrial DNA variants for analysis of mitochondrial DNA-enriched extracts from frozen tumor tissue.

Large variation exists in mitochondrial DNA (mtDNA) not only between but also within individuals. Also in human cancer, tumor-specific mtDNA variation exists. In this work, we describe the comparison of four methods to extract mtDNA as pure as possible from frozen tumor tissue. Also, three state-of-the-art methods for sensitive detection of mtDNA variants were evaluated. The main aim was to develop a procedure to detect low-frequent single-nucleotide mtDNA-specific variants in frozen tumor tissue. We show that of the methods evaluated, DNA extracted from cytosol fractions following exonuclease treatment results in highest mtDNA yield and purity from frozen tumor tissue (270-fold mtDNA enrichment). Next, we demonstrate the sensitivity of detection of low-frequent single-nucleotide mtDNA variants (≤1% allele frequency) in breast cancer cell lines MDA-MB-231 and MCF-7 by single-molecule real-time (SMRT) sequencing, UltraSEEK chemistry based mass spectrometry, and digital PCR. We also show de novo detection and allelic phasing of variants by SMRT sequencing. We conclude that our sensitive procedure to detect low-frequent single-nucleotide mtDNA variants from frozen tumor tissue is based on extraction of DNA from cytosol fractions followed by exonuclease treatment to obtain high mtDNA purity, and subsequent SMRT sequencing for (de novo) detection and allelic phasing of variants.

One-tube real-time isothermal amplification assay to identify and distinguish human immunodeficiency virus type 1 subtypes A, B, and C and circulating recombinant forms AE and AG.

To halt the human immunodeficiency virus type 1 (HIV-1) epidemic requires interventions that can prevent transmission of numerous HIV-1 subtypes. The most frequently transmitted viruses belong to the subtypes A, B, and C and the circulating recombinant forms (CRFs) AE and AG. A fast one-tube assay that identifies and distinguishes among subtypes A, B, and C and CRFs AE and AG of HIV-1 was developed. The assay amplifies a part of the gag gene sequence of the genome of all currently known HIV-1 subtypes and can identify and distinguish among the targeted subtypes as the reaction proceeds, because of the addition of subtype-specific molecular beacons with multiple fluorophores. The combination of isothermal nucleic acid sequence-based amplification and molecular beacons is a new approach in the design of real-time assays. To obtain a sufficiently specific assay, we developed a new strategy in the design of molecular beacons, purposely introducing mismatches in the molecular beacons. The subtype A and CRF AG isolates reacted with the same molecular beacon. We tested the specificity and sensitivity of the assay on a panel of the culture supernatant of 34 viruses encompassing all HIV-1 subtypes: subtypes A through G, CRF AE and AG, a group O isolate, and a group N isolate. Assay sensitivity on this panel was 92%, with 89% correct subtype identification relative to sequence analysis. A linear relationship was found between the amount of input RNA in the reaction mixture and the time that the reaction became positive. The lower detection level of the assay was approximately 10(3) copies of HIV-1 RNA per reaction. In 38% of 50 serum samples from HIV-1-infected individuals with a detectable amount of virus, we could identify subtype sequences with a specificity of 94% by using sequencing and phylogenetic analysis as the "gold standard." In conclusion, we showed the feasibility of the approach of using multiple molecular beacons labeled with different fluorophores in combination with isothermal amplification to identify and distinguish subtypes A, B, and C and CRFs AE and AG of HIV-1. Because of the low sensitivity, the assay in this format would not be suited for clinical use but can possibly be used for epidemiological monitoring as well as vaccine research studies.