Effects of marine contaminant mixtures on the copepod genus Pseudocalanus. How ambient contaminant mixtures affect mortality, food intake and fecal pellet production.
Abstract
Chemicals are present in almost every part of human society and their benefits to our everyday life are
undeniable. Besides those benefits, chemicals are known to cause harm to both human health and the
environment. As a consequence of runoff, discharge or leachates, a huge amount of chemicals produced
and used will finally be released into the environment. Thus, a broad variety of different chemicals end
up in the marine ecosystems, where organisms are exposed to a mixture of compounds.
Zooplankton play an important role in marine
ecosystems and represent several functions. Being grazers and
also grazed upon, zooplankton connect the producers at the base
of the food web with consumers at higher trophic levels.
Furthermore, zooplankton fuels the biological carbon pump by
producing fecal pellets that act as food source deeper in the water
column. The most abundant group of zooplankton are copepods.
Therefore, understanding impacts of different stressors on
copepod species is crucial and a lot of ecotoxicological studies
focus on those zooplankton group. The genus Pseudocalanus is
among the numerically most dominant copepod genera in several
marine ecosystems, including the Swedish and Norwegian west
coast.
The focus of this study was to determine changes of the copepod
genus Pseudocalanus and to understand how marine
contaminant mixtures from the west coast of Sweden affect those
organisms. Six chemical extracts derived from water samples at
six locations around Stenungsund were used. The municipality
Stenungsund and the surrounding area contains agriculture,
industry, harbours and hosts both thousands of inhabitants and
tourists, which represents a wide variety of potential chemical
sources and pathways for those compounds to reach the marine
environment. Even though the predicted toxicity of the six
chemical extracts containing polar organic compounds did not
raise any concern, the experimental approach was set-up to prove
the theoretical calculations.
The results of this study are both unexpected and worrying. Significant increase in mortality was
detected in concentrations five times higher than ambient environmental conditions (5x MEC).
Furthermore, food intake and fecal pellet production were significantly reduced, down to approximately
20 % and 40 % in the 5x MEC form site M6 and even the ambient environmental concentration (1x
MEC) indicated reduction (Figure 13 A, B). Both replicability and reliability of those results were
proven, and I therefore suggest further research on different copepod species, younger life stages and
additional endpoints. My results raise concern, especially when considering that the chemicals the
copepods were exposed to, do not represent the entire ambient contaminant situation. Compounds like
heavy metals and nonpolar organic compounds were not sampled, which results in an underestimation
of my findings. I therefore suggest further investigations in this and other related locations as well as
improved sampling techniques which represent the entire environmental contaminant mixture to ensure
a clear reflection of the environmental situation and to avoid underestimation of effects.
Degree
Student essay