Abstract
Toxin-producing cyanobacteria can be harmful to aquatic biota, although some grazers utilize them with often beneficial effects on their growth and reproduction. It is commonly assumed that gut microbiota facilitates host adaptation to the diet; however, the evidence for adaptation mechanisms is scarce. Here, we investigated the abundance of mlrA genes in the gut of the Baltic copepods Acartia bifilosa and Eurytemora affinis during cyanobacteria bloom season (August) and outside it (February). The mlrA genes are unique to microcystin and nodularin degraders, thus indicating the capacity to break down these toxins by the microbiota. The mlrA genes were expressed in the copepod gut year-round, being >10-fold higher in the summer than in the winter populations. Moreover, they were significantly more abundant in Eurytemora than Acartia. To understand the ecological implications of this variability, we conducted feeding experiments using summer- and winter-collected copepods to examine if/how the mlrA abundance in the microbiota affect: (1) uptake of toxic Nodularia spumigena, (2) uptake of a non-toxic algal food offered in mixtures with N. spumigena, and (3) concomitant growth potential in the copepods. The findings provide empirical evidence that the occurrence of mlrA genes in the copepod microbiome facilitates nutrient uptake and growth when feeding on phytoplankton mixtures containing nodularin-producing cyanobacteria; thus, providing an adaptation mechanism to the cyanobacteria blooms.
Highlights
The expansion of harmful cyanobacteria blooms and associated risks for environmental health is a matter of concern (O’Neil et al, 2012)
In the microbiome of Acartia bifilosa and Eurytemora affinis, bacterial genes mlrA are ubiquitously present, with their occurrence being significantly higher in the latter species
The abundance of mlrA genes in the copepod microbiome increased during summer, in concert with the stocks of hepatotoxic cyanobacteria in the water
Summary
The expansion of harmful cyanobacteria blooms and associated risks for environmental health is a matter of concern (O’Neil et al, 2012). The filamentous diazotrophic cyanobacteria Nodularia spumigena Mertens, Aphanizomenon sp., and Dolichospermum (formerly Anabaena) spp. are the major contributors of the Baltic cyanobacterial blooms (Wasmund, 1997). As most cyanobacteria, these species produce numerous bioactive compounds and toxins. Dolichospermum spp. are known to produce hepatotoxic microcystins in freshwaters (Sivonen and Börner, 2008); Baltic Dolichospermum can produce microcystins (Halinen et al, 2007). Of main concern is N. spumigena, a well-known producer of hepatotoxin nodularin, which makes up to∼90% of cyano-hepatotoxins in the Baltic Sea (Kankaanpää et al, 2009)
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