A Mystery Tale: Nickel Is Fickle When Snails Fail-Investigating the Variability in Ni Toxicity to the Great Pond Snail

Anne Crémazy; Kevin V Brix; D Scott Smith; Weibin Chen; Martin Grosell; Christian E Schlekat; Emily R Garman; Elizabeth T Middleton; Chris M Wood

doi:10.1002/ieam.4300

A Mystery Tale: Nickel Is Fickle When Snails Fail-Investigating the Variability in Ni Toxicity to the Great Pond Snail

Integr Environ Assess Manag. 2020 Nov;16(6):983-997. doi: 10.1002/ieam.4300. Epub 2020 Aug 31.

Authors

Anne Crémazy¹, Kevin V Brix^{2

3}, D Scott Smith⁴, Weibin Chen⁴, Martin Grosell³, Christian E Schlekat⁵, Emily R Garman⁵, Elizabeth T Middleton⁵, Chris M Wood^{3

6}

Affiliations

¹ Department of Biological Sciences, University of New Brunswick, New Brunswick, Canada.
² EcoTox, Miami, Florida, USA.
³ University of Miami, RSMAS, Miami, Florida, USA.
⁴ Department of Chemistry and Biochemistry, Wilfrid Laurier University, Waterloo, Ontario, Canada.
⁵ NiPERA, Inc, Durham, North Carolina, USA.
⁶ Department of Zoology, University of British Columbia, Vancouver, British Columbia, Canada.

PMID: 32543042
DOI: 10.1002/ieam.4300

Abstract

Dissolved Ni concentrations inhibiting the growth of juvenile great pond snails (Lymnaea stagnalis) have been documented to vary from about 1 to 200 µg L^-1 Ni. This variability makes L. stagnalis either a moderately sensitive or the most sensitive freshwater species to chronic Ni exposure tested to date. Given the role of sensitive species in environmental risk assessment frameworks, it is particularly important to understand this variability, i.e., to characterize the factors that modulate Ni toxicity and that may confound toxicity test outcomes when uncontrolled. In the present study, we tested if this variability was due to analytical (growth calculation: biomass versus growth rate), environmental (water quality), lab-specific practices, and/or snail population differences among earlier studies. Specifically, we reanalyzed previously published Ni toxicity data and conducted additional measurements of Ni aqueous speciation, short-term Ni uptake, and chronic Ni toxicity with test waters and snail cultures used in previous studies. Corrections for Ni bioavailability and growth calculations explained a large degree of variability in the published literature. However, a residual 16-fold difference remained puzzling between 2 studies: Niyogi et al. (2014) (low ECxs) and Crémazy et al. (2018) (high ECxs). Indeed, differences in metal bioavailability due to water chemistry, lab-specific practices, and snail population sensitivity could not explain the large variation in Ni toxicity in these 2 very similar studies. Other potentially important toxicity-modifying factors were not directly evaluated in the present work: test duration, diet, snail holding conditions, and snail age at onset of testing. The present analysis highlights the need for further studies to elucidate 1) the mechanisms of growth inhibition in Ni-exposed L. stagnalis and 2) the important abiotic and biotic factors affecting this biological response. Until these processes are understood, substantial uncertainties will remain about inclusion of this species in Ni environmental risk assessment. Integr Environ Assess Manag 2020;16:983-997. © 2020 SETAC.

Keywords: Bioavailability; Chronic toxicity; Freshwater; Growth inhibition; Lymnaea stagnalis.

MeSH terms

Animals
Fresh Water
Lymnaea
Nickel* / toxicity
Water Pollutants, Chemical* / toxicity
Water Quality

Substances

Water Pollutants, Chemical
Nickel

Abstract

MeSH terms

Substances

Grants and funding