Abstract
Recently, a new class of extrachromosomal circular DNA, called microDNA, was identified. They are on average 100 to 400 bp long and are derived from unique non-repetitive genomic regions with high gene density. MicroDNAs are thought to arise from DNA breaks associated with RNA metabolism or replication slippage. Given the paucity of information on this entirely novel phenomenon, we aimed to get an additional insight into microDNA features by performing the microDNA analysis in 20 independent human lymphoblastoid cell lines (LCLs) prior and after treatment with chemotherapeutic drugs. The results showed non-random genesis of microDNA clusters from the active regions of the genome. The size periodicity of 190 bp was observed, which matches DNA fragmentation typical for apoptotic cells. The chemotherapeutic drug-induced apoptosis of LCLs increased both number and size of clusters further suggesting that part of microDNAs could result from the programmed cell death. Interestingly, proportion of identified microDNA sequences has common loci of origin when compared between cell line experiments. While compatible with the original observation that microDNAs originate from a normal physiological process, obtained results imply complementary source of its production. Furthermore, non-random genesis of microDNAs depicted by redundancy between samples makes these entities possible candidates for new biomarker generation.
Highlights
Extrachromosomal nuclear circular DNAs have been known for almost 4 decades and have been characterized in several eukaryotic organisms including humans
Our findings suggest that microDNAs may reflect a particular status of the cell chromatin prior to cell death
Cell lines were selected from human EBV immortalized Lymphoblastoid Cell Lines (LCLs) obtained from different healthy individuals and purchased from the Coriell Institute for medical research (Camden, NJ, USA), based on their sensitivity phenotype to two major chemotherapeutic drugs, methotrexate (MTX) and L-asparaginase (ASP) (S1 Table), as defined in a prior independent experiment, by measuring their half maximal inhibitory concentrations (IC50)
Summary
Extrachromosomal nuclear circular DNAs (eccDNAs) have been known for almost 4 decades and have been characterized in several eukaryotic organisms including humans. These entities are homologous to chromosomal DNA and are heterogeneous in terms of size Mb), sequence complexity and regions of origin [1]. EccDNAs are a potential intermediate in processes driving satellite repeat evolution [2] while in yeasts, eccDNAs seem to derive from ribosomal or telomeric DNA [3,4].
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