Physiological Responses of Oxyrrhis marina to the Altered Fatty Acid Composition of Virally Infected Emiliania huxleyi

Emiliania huxleyi is a coccolithophore that forms some of the largest phytoplankton blooms in the ocean. E. huxleyi abundance, distribution, and composition of essential fatty acids make them a key component in marine food webs. E. huxleyi-specific viruses have been shown to control the bloom duration and change the lipid composition of E. huxleyi cells. Alteration of essential fatty acids at the base of the food web may have downstream effects on trophic interactions. Oxyrrhis marina has been studied extensively, and is used as a micrograzer model organism. We investigated differential physiological responses of O. marina to a diet (~100:1 prey:predator ratio) of virallyinfected versus uninfected E. huxleyi cells over a maximum 7-day period. Our results showed higher O. marina grazing rates on uninfected cells (p<0.05). However, O. marina had faster growth rates (p<0.05) and a smaller relative increase in saturated fatty acids and decrease in monounsaturated fatty acids (p<0.05) when fed infected E. huxleyi cells. This suggests a higher nutritional value of infected cells and/or better assimilation by O. marina of infected cells’ carbon. In the marine environment this would translate into larger carbon transport to higher trophic levels when blooms become infected.