posted on 2013-05-21, 00:00authored byRadomir Schmidt, Prapakorn Tantoyotai, Sirine C. Fakra, Matthew A. Marcus, Soo In Yang, Ingrid J. Pickering, Gary S. Bañuelos, Krassimira R. Hristova, John L. Freeman
An
engineered aquatic ecosystem was specifically designed to bioremediate
selenium (Se), occurring as oxidized inorganic selenate from hypersalinized
agricultural drainage water while producing brine shrimp enriched
in organic Se and omega-3 and omega-6 fatty acids for use in value
added nutraceutical food supplements. Selenate was successfully bioremediated
by microalgal metabolism into organic Se (seleno-amino acids) and
partially removed via gaseous volatile Se formation. Furthermore,
filter-feeding brine shrimp that accumulated this organic Se were
removed by net harvest. Thriving in this engineered pond system, brine
shrimp (Artemia franciscana Kellogg)
and brine fly (Ephydridae sp.) have
major ecological relevance as important food sources for large populations
of waterfowl, breeding, and migratory shore birds. This aquatic ecosystem
was an ideal model for study because it mimics trophic interactions
in a Se polluted wetland. Inorganic selenate in drainage water was
metabolized differently in microalgae, bacteria, and diatoms where
it was accumulated and reduced into various inorganic forms (selenite,
selenide, or elemental Se) or partially incorporated into organic
Se mainly as selenomethionine. Brine shrimp and brine fly larva then
bioaccumulated Se from ingesting aquatic microorganisms and further
metabolized Se predominately into organic Se forms. Importantly, adult
brine flies, which hatched from aquatic larva, bioaccumulated the
highest Se concentrations of all organisms tested.