Molecular ecological responses of the dinoflagellate Karenia mikimotoi to phosphate stress

Abstract: Karenia mikimotoi is a toxic, widespread dinoflagellate which could produce hemolytic toxins and ichthyotoxins affecting fisheries within the area of its bloom. Previous ecophysiological studies indicated that the enhance of environmental phosphate concentration could promote the growth of K. mikimotoi. Intrinsic mechanisms regarding the effects of external phosphate on its photosynthesis, cell cycle succession and differential proteins’ expressions are still unknown. K. mikimotoi was cultured in phosphate-deprived medium, while the culture in f/2 medium (Guillard, 1975) was introduced as phosphate-sufficient control experiment. Cell counts and phosphate concentration detection were performed every other day. Flowcytometry was applied to measure cell cycle succession and chlorophyll fluorescence intensity fluctuation. Differential proteomics expression was examined by SDS-PAGE tandem LTQ Orbitrap MS/MS spectrometry. Functions of each differential protein were searched within NCBInr protein database and Swissprot database. Our study demonstrated that phosphate stress inhibited growth and cell cycle succession of K. mikimotoi remarkably (p <0.01). Algal chlorophyll fluorescence intensity was significantly affected by phosphate deprivation (p <0.05). 11 species of differential proteins were detected only in phosphate-limited culture sample which related to stress signal transduction, vacuolar phosphate release, phospholipid degradation, organic acid synthesis and phagotrophy. 4 kinds of differential proteins were identified only in f/2 medium culture sample which referred to cell proliferation, glycolysis, SAM cycle and polyamine production. Based on analysis of differential proteomic functional annotation, we hypothesized proteomic response mechanism of K. mikimotoi to phosphate stress. Molecular biological responses of dinoflagellate K. mikimotoi to phosphate stress was explored. [Copyright &y& Elsevier]