Chloroform release from ageing cells andDrosophila DJ-1βmutants.

Volatile organic compounds (VOCs) offer potential for non-invasive diagnosis as biomarkers of disease and metabolism. In complex biological matrices, such as breath however, identifying useful biomarkers from hundreds, or even thousands of VOCs can be challenging. Models of disease, such as cellular or animal models, offer a means to elucidate VOC metabolisms, for accurate targeted studies in patient samples. Neurodegenerative conditions, such as Parkinson's have been associated with changed VOCs, offering a potential for early diagnostics and interventions improving treatments and outcomes for patients. Here, three separate models including; human HEK-293t cells, isolated primary rat glial cells, andDrosophilafruit flies (wild type and a mutant of the Parkinson's associated gene,DJ-1β) were grown for an extended period and levels of the VOC chloroform investigated using custom static headspace sampling chambers. Samples were analysed using targeted gas chromatography mass spectroscopy with selected ion monitoring mode, measuring chloroform at masses 83/85. Chloroform levels were shown to dramatically increase in all models over time. HEK-293t cells revealed a 60-fold increase after 10 weeks, glial cells revealed a 10-fold increase after 3-4 weeks andDJ-1βmutant flies revealed significant increases compared to control flies at 4 weeks. These results, taken together, suggest that chloroform release is related to ageing in these models and may provide a target for neurodegenerative studies. We present here the first evidence of chloroform being actively produced by human and rat cells and the first observation of volatile metabolisms inDrosophila. Recent clinical studies have also identified increased chloroform flux in the breath of patients, supporting the translational potential of our findings.