Interaction of Naturally Occurring Phytoplankton with the Biogeochemical Cycling of Mercury in Aquatic Environments and Its Effects on Global Hg Pollution and Public Health.
Živan GojkovicSamuel SimanskyAlain SanabriaIvana MarovaInés GarbayoCarlos VílchezPublished in: Microorganisms (2023)
The biogeochemical cycling of mercury in aquatic environments is a complex process driven by various factors, such as ambient temperature, seasonal variations, methylating bacteria activity, dissolved oxygen levels, and Hg interaction with dissolved organic matter (DOM). As a consequence, part of the Hg contamination from anthropogenic activity that was buried in sediments is reinserted into water columns mainly in highly toxic organic Hg forms (methylmercury, dimethylmercury, etc.). This is especially prominent in the coastal shallow waters of industrial regions worldwide. The main entrance point of these highly toxic Hg forms in the aquatic food web is the naturally occurring phytoplankton. Hg availability, intake, effect on population size, cell toxicity, eventual biotransformation, and intracellular stability in phytoplankton are of the greatest importance for human health, having in mind that such Hg incorporated inside the phytoplankton cells due to biomagnification effects eventually ends up in aquatic wildlife, fish, seafood, and in the human diet. This review summarizes recent findings on the topic of organic Hg form interaction with natural phytoplankton and offers new insight into the matter with possible directions of future research for the prevention of Hg biomagnification in the scope of climate change and global pollution increase scenarios.
Keyphrases
- human health
- risk assessment
- climate change
- heavy metals
- fluorescent probe
- aqueous solution
- public health
- living cells
- water quality
- particulate matter
- endothelial cells
- air pollution
- physical activity
- oxidative stress
- high intensity
- health risk assessment
- induced apoptosis
- drinking water
- health risk
- cell therapy
- organic matter
- reactive oxygen species
- cell proliferation
- single molecule