Abstract
Carbonic anhydrase (CA) (EC 4.2.1.1), a ubiquitous enzyme in bacteria, plant, and animal kingdoms, catalyses the reversible hydration of CO2 to produce H+ and using zinc as cofactor. CA plays a fundamental role in a number of physiological processes, such as respiration, ionic transport, acid–base regulation, and calcification. The aim of the present work was to investigate the sensitivity of this enzyme to heavy metals with a view to possible future applications of CA activity inhibition measurement in biomonitoring as either an in vitro bioassay or a biomarker. CA activity was determined by modifying a previously described electrometric method: briefly, CA activity units were calculated from the rate of H+ production in the reaction mixture (where CO2 was present as a substrate) against a blank containing the specific CA inhibitor acetazolamide. As regards the possible application as an in vitro bioassay, the sensitivity to heavy metals (cadmium, mercury, and copper) of the commercially available purified carbonic anhydrase (isozyme II) from bovine erythrocyte was tested in vitro. In our experimental set-up, bovine CA activity was significantly inhibited by micromolar concentrations of heavy metals, showing a dose–response behaviour. As regards the possible application as biomarkers, CA was investigated in the filter-feeding Mytilus galloprovincialis, widely used in pollution-monitoring programmes as a sentinel organism. Following in vitro and in vivo exposure to 1.785 μM cadmium chloride as a reference toxicant, mantle CA activity was significant inhibited. In conclusion, the sensitivity to chemical pollutants and low cost and simplicity of the assay method make CA activity measurement suitable for in vitro bioassay of the toxicity of environmental samples and for field biomarker applications in the sentinel organism M. galloprovincialis.
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