Flow conditions influence diuron toxicokinetics and toxicodynamics in freshwater biofilms

Betty Chaumet; Soizic Morin; Océane Hourtané; Joan Artigas; Brigitte Delest; Mélissa Eon; Nicolas Mazzella

doi:10.1016/j.scitotenv.2018.10.265

Flow conditions influence diuron toxicokinetics and toxicodynamics in freshwater biofilms

Sci Total Environ. 2019 Feb 20:652:1242-1251. doi: 10.1016/j.scitotenv.2018.10.265. Epub 2018 Oct 21.

Authors

Betty Chaumet¹, Soizic Morin², Océane Hourtané², Joan Artigas³, Brigitte Delest², Mélissa Eon², Nicolas Mazzella²

Affiliations

¹ Unité de recherche EABX, Groupement Irstea de Bordeaux, 50 Avenue de Verdun, 33612 Cestas Cedex, France. Electronic address: betty.chaumet@irstea.fr.
² Unité de recherche EABX, Groupement Irstea de Bordeaux, 50 Avenue de Verdun, 33612 Cestas Cedex, France.
³ Université Clermont Auvergne, CNRS, Laboratoire Microorganismes: Génome et Environnement, 63000 Clermont-Ferrand, France.

PMID: 30586810
DOI: 10.1016/j.scitotenv.2018.10.265

Abstract

Biofilms are considered as good bioindicators of contamination by means of their capacity to react quickly to xenobiotics exposure, and their pivotal role in sustaining the aquatic trophic web. The exchanges of dissolved substances between water column and biofilm can be modulated by flow velocity. This study deals with toxicokinetic (transfer mechanisms) and toxicodynamic (effects) modelling of pesticides under two contrasted flow conditions. Diuron was used to run a 2-h kinetic study on mature biofilms in river channels. Two flow conditions were considered (⋘1 cm·s^-1: lentic environments such as ponds, 2 cm·s^-1: lotic environments such as watercourses). Three concentrations were tested in order to estimate contamination levels in biofilms: 0, 5 (environmentally relevant concentration) and 50 (to determine the concentration effect) μg·L^-1. The effect of the above-mentioned factors was also assessed on biofilms photosynthesis inhibition. For successive sampling times between 0 and 2 h, the raw biofilms and EPS tightly bound to cells plus microorganisms (T-EPS-M), were physically separated and analysed for diuron accumulation and structural and functional microbial descriptors. Diuron amounts accumulated in biofilm increased with increasing diuron exposure. Biofilms accumulated higher amounts of diuron at the lower flow velocity compared to high flow for raw biofilms, while accumulation in the T-EPS-M fraction was similar between flow conditions. Consequently, both flow velocity and diuron exposure had an influence on diuron bioaccumulation and distribution. Photosynthesis inhibition over time was directly linked to the exposure concentration of diuron recorded in the T-EPS-M fraction. These results suggest that flow causes a loss of organic matter in biofilms, decreasing the total accumulation of diuron, especially within diffusible EPS. As pesticide distribution in biofilm is a major factor in the onset of toxicity, the novel fractioning method presented here will improve further toxicokinetic and toxicodynamic studies dealing with biofilms exposed to organic toxicants.

Keywords: Bioaccumulation; Distribution; Freshwater biofilms; Pesticide; Photosynthesis inhibition; TK-TD.

MeSH terms

Biofilms / drug effects*
Biofilms / growth & development
Diuron / metabolism
Diuron / toxicity*
Fresh Water* / chemistry
Fresh Water* / microbiology
Toxicokinetics
Water Movements*
Water Pollutants, Chemical / metabolism
Water Pollutants, Chemical / toxicity*

Substances

Water Pollutants, Chemical
Diuron