The brains of bats foraging at wastewater treatment works accumulate arsenic, and have low non-enzymatic antioxidant capacities

• Published in: Neurotoxicology (Park Forest South) Vol. 69; pp. 232 - 241
• Main Authors: Hill, Kate, Schoeman, M. Corrie, Vosloo, Dalene
• Format: Journal Article
• Language: English
• Published: Netherlands Elsevier B.V 01.12.2018; Elsevier BV
• Subjects: Acetylcholinesterase; Animals; Anthropogenic factors; Antioxidants; Antioxidants - analysis; Antioxidants - metabolism; Apoptosis; Arsenic; Arsenic - analysis; Arsenic - metabolism; Arsenic - toxicity; Arsenic accumulation; Bats; Biomarkers; Blood-brain barrier; Brain; Brain - drug effects; Brain - metabolism; Brain Chemistry - drug effects; Brain Chemistry - physiology; Caspase; Caspase-3; Chiroptera; Circulatory system; Contaminants; Deoxyribonucleic acid; DNA; DNA fragmentation; Echolocation; Effects; Environmental effects; Environmental Monitoring - methods; Environmental Pollutants - analysis; Environmental Pollutants - metabolism; Environmental Pollutants - toxicity; Hair; Hair - chemistry; Hair - drug effects; Hair - metabolism; Heavy metals; Integrity; Iron; Lipid peroxidation; Lipids; Metal concentrations; Mitochondria; Neurotransmitters; Peroxidation; Pollutant removal; Pollutants; Pollution effects; South Africa; Urbanization; Waste Water - analysis; Waste Water - toxicity; Wastewater pollution; Wastewater treatment; Wastewater treatment works; Water pollution; Water treatment; Zinc; South Africa; Biomarkers; Brain; Bats; Wastewater treatment works; Arsenic accumulation
• ISSN: 0161-813X; 1872-9711
• DOI: 10.1016/j.neuro.2017.12.004

•Bats from WWTW accumulate arsenic in their hair and brain tissue.•Bats from WWTW have low non-enzymatic antioxidant capacity. Increasing rates of urbanisation cause ubiquitous infrastructures that remove anthropogenic contaminants – particularly Wastewater Treatment Works (WWTWs) – to become stressed, and hence pollute surrounding water systems. Neoromicia nana bats are suitable models to study the effects of pollution in these environments because they exploit abundant pollutant-tolerant chironomid midges that breed at WWTWs, and consequently accumulate metals such as iron, copper and zinc in their livers and kidneys. If these metals persist in their circulatory systems, and cross the blood brain barrier (BBB) they can have adverse effects on critical functions such as flight and echolocation. The aim of this study was to investigate the potential neurological effects on N. nana foraging at WWTWs versus bats at reference sites in Durban, South Africa. Our objectives were to 1) compare trace metal levels in brain and hair samples (as a proxy for circulating metals) between N. nana foraging at WWTWs and reference sites to determine if excess metals pass through the BBB via the circulatory system; and 2) compare biomarkers of neuron function (acetylcholinesterase activity), protection (antioxidant capacity), DNA integrity (DNA fragmentation), lipid integrity (lipid peroxidation) and cell viability (caspase-3 activity) between N. nana foraging at WWTW and reference sites. We found a significantly higher concentration of arsenic in hair (p < 0.05) and brain tissue (p < 0.1) of WWTW bats compared to bats at reference sites. By contrast, acetylcholinesterase activity did not differ in bats among sites and there was no evidence of significant differences in lipid peroxidation, compromised DNA integrity or apoptosis in the brains between WWTW bats and reference site bats. However, total antioxidant capacity was significantly lower in brains of WWTW bats than bats at reference sites suggesting that antioxidant protection may be compromised. Long-term exposure to environmental pollutants at WWTWs may therefore affect cellular processes and protection mechanisms in brains of N. nana bats. It may also affect other mechanisms and functions in the brain such as mitochondrial efficiency and other neurotransmitters but that remains to be tested.