Extreme Arsenic Bioaccumulation Factor Variability in Lake Titicaca, Bolivia

Overview

Journal Sci Rep

Specialty Science

Date 2019 Jul 25

PMID 31337829

Citations 2

Authors

Geraldine Sarret

Stephane Guedron

Dario Acha

Sarah Bureau

Florent Arnaud-Godet

Delphine Tisserand

Marisol Goni-Urriza

Claire Gassie

Celine Duwig

Olivier Proux

Anne-Marie Aucour

Affiliations

Soon will be listed here.

Abstract

Latin America, like other areas in the world, is faced with the problem of high arsenic (As) background in surface and groundwater, with impacts on human health. We studied As biogeochemical cycling by periphyton in Lake Titicaca and the mine-impacted Lake Uru Uru. As concentration was measured in water, sediment, totora plants (Schoenoplectus californicus) and periphyton growing on stems, and As speciation was determined by X-ray absorption spectroscopy in bulk and EDTA-extracted periphyton. Dissolved arsenic was between 5.0 and 15 μg L in Lake Titicaca and reached 78.5 μg L in Lake Uru Uru. As accumulation in periphyton was highly variable. We report the highest As bioaccumulation factors ever measured (BAFs up to 245,000) in one zone of Lake Titicaca, with As present as As(V) and monomethyl-As (MMA(V)). Non-accumulating periphyton found in the other sites presented BAFs between 1281 and 11,962, with As present as As(III), As(V) and arsenosugars. DNA analysis evidenced several taxa possibly related to this phenomenon. Further screening of bacterial and algal isolates would be necessary to identify the organism(s) responsible for As hyperaccumulation. Impacts on the ecosystem and human health appear limited, but such organisms or consortia would be of great interest for the treatment of As contaminated water.

Citing Articles

A review on arsenic in the environment: bio-accumulation, remediation, and disposal.

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