Low-Dose Ionizing Radiation Affects Mesenchymal Stem Cells via Extracellular Oxidized Cell-Free DNA: A Possible Mediator of Bystander Effect and Adaptive Response.

We have hypothesized that the adaptive response to low doses of ionizing radiation (IR) is mediated by oxidized cell-free DNA (cfDNA) fragments. Here, we summarize our experimental evidence for this model. Studies involving measurements of ROS, expression of the NOX (superoxide radical production), induction of apoptosis and DNA double-strand breaks, antiapoptotic gene expression and cell cycle inhibition confirm this hypothesis. We have demonstrated that treatment of mesenchymal stem cells (MSCs) with low doses of IR (10 cGy) leads to cell death of part of cell population and release of oxidized cfDNA. cfDNA has the ability to penetrate into the cytoplasm of other cells. Oxidized cfDNA, like low doses of IR, induces oxidative stress, ROS production, ROS-induced oxidative modifications of nuclear DNA, DNA breaks, arrest of the cell cycle, activation of DNA reparation and antioxidant response, and inhibition of apoptosis. The MSCs pretreated with low dose of irradiation or oxidized cfDNA were equally effective in induction of adaptive response to challenge further dose of radiation. Our studies suggest that oxidized cfDNA is a signaling molecule in the stress signaling that mediates radiation-induced bystander effects and that it is an important component of the development of radioadaptive responses to low doses of IR.

Enhanced expression of iNOS in human endothelial cells during long-term culturing with extracellular DNA fragments.

NO synthesis by endothelial cells plays an important role in normal function of the cardiovascular system. This work was designed to evaluate the role of variations in properties of extracellular DNA in the regulation of NO synthesis. We studied the effect of four DNA samples with various base sequences (50 ng/ml) on functional activity of endothelial cells HUVEC during 24-h culturing. Human DNA fragments with high content of CG repeats increased intracellular content of NO and its metabolites (nitrites and nitrates) and accelerated oxidation of nitrites to nitrates. Changes in the content of NO metabolites after 24-h culturing was shown to depend on the expression of gene for inducible, but not for endothelial NO synthase. Increased expression of inducible NO synthase positively correlated with an increase in the content of mRNA for the adapter protein MyD88, but did not depend on TLR9 gene expression that encodes protein receptor for CG-DNA recognition. The intracellular concentration of MyD88 mRNA did not depend on the content of TLR9 mRNA. The existence of a variety of DNA-binding receptors apart from TLR9 receptor on the surface of endothelial cells was hypothesized. Activation of these receptors by extracellular DNA fragments stimulates expression of the adapter protein MyD88.

Extracellular DNA affects NO content in human endothelial cells.

Fragments of extracellular DNA are permanently released into the blood flow due to cell apoptosis and possible de novo DNA synthesis. To find out whether extracellular DNA can affect the synthesis of nitric oxide (NO), one of key vascular tone regulators, we studied in vitro effects of three artificial DNA probes with different sequences and 10 samples of extracellular DNA (obtained from healthy people and patients with hypertension and atherosclerosis) on NO synthesis in endothelial cell culture (HUVEC). For detection of NO in live cells and culture medium, we used a NO-specific agent CuFL penetrating into the cells and forming a fluorescent product FL-NO upon interaction with NO. Human genome DNA fragments affected the content of NO in endothelial cells; this effect depended on both the base sequence and concentration of DNA fragments. Addition of artificial DNA and extracellular DNA from healthy people into the cell culture in a low concentration (5 ng/ml) increased the detected NO concentration by 4-fold at most. Cytosine-guanine (CG)-rich fragment of the transcribed sequence of ribosomal repeat was the most powerful NO-inductor. The effect of DNA fragments on NO synthesis was comparable with that of low doses of oxidizing agents, H(2)O(2) and 17ß-estradiol. Extracellular DNA samples obtained from patients with hypertension and atherosclerosis decreased NO content in cells and medium by 1.3-28 times compared to the control; the effect correlated with the content of CG-rich sequences.