Title: Docosahexaenoic acid counteracts attenuation of CD95-induced cell death by inorganic mercury.

Authors: Gill, Randall; Lanni, Lydia; Jen, K-L Catherine; McCabe Jr, Michael J; Rosenspire, Allen

Published In Toxicol Appl Pharmacol, (2015 Jan 01)

Abstract: In the United States the principal environmental exposure to mercury is through dietary consumption of sea food. Although the mechanism by which low levels of mercury affect the nervous system is not well established, epidemiological studies suggest that low level exposure of pregnant women to dietary mercury can adversely impact cognitive development in their children, but that Docosahexaenoic acid (DHA), the most prominent n-polyunsaturated fatty acid (n-PUFA) present in fish may counteract negative effects of mercury on the nervous system. Aside from effects on the nervous system, epidemiological and animal studies have also suggested that low level mercury exposure may be a risk factor for autoimmune disease. However unlike the nervous system where a mechanism linking mercury to impaired cognitive development remains elusive, we have previously suggested a potential mechanism linking low level mercury exposures to immune system dysfunction and autoimmunity. In the immune system it is well established that disruption of CD95 mediated apoptosis leads to autoimmune disease. We have previously shown in vitro as well as in vivo that in lymphocytes burdened with low levels of mercury, CD95 mediated cell death is impaired. In this report we now show that DHA counteracts the negative effect of mercury on CD95 signaling in T lymphocytes. T cells which have been pre-exposed to DHA are able to cleave pro-caspase 3 and efficiently signal programmed cell death through the CD95 signaling pathway, whether or not they are burdened with low levels of mercury. Thus DHA may lower the risk of autoimmune disease after low level mercury exposures.

PubMed ID: 25461680

MeSH Terms: Apoptosis/drug effects*; Autoimmunity/drug effects; Caspase 3/metabolism; Cell Survival/drug effects; Cytoprotection; Docosahexaenoic Acids/pharmacology*; Dose-Response Relationship, Drug; Humans; Jurkat Cells; Mercuric Chloride/toxicity*; Signal Transduction/drug effects; T-Lymphocytes/drug effects*; T-Lymphocytes/immunology; T-Lymphocytes/metabolism; T-Lymphocytes/pathology; Water Pollutants, Chemical/toxicity*; fas Receptor/metabolism*