Role of transcription and translation during the early development of the brown algaEctocarpus

Abstract

AbstractBackground and aimsParthenogenesis, the embryonal development of an unfused gamete, is a widespread trait within the brown algae (Phaeophyceae). We hypothesized that the parthenogenetic development of male gametes of the model brown algaEctocarpusspecies 7 would rapidly be dependent onde novotranscription and translation because of the small size of the gamete cell.MethodsWe followed the development of maleEctocarpusgametes to parthenosporophytes in the presence of either the transcription inhibitor thiolutin or the translation inhibitor emetine. Responses in morphology and growth were compared to development in inhibitor-free control conditions at three time points over 12 days. Potentially persistent inhibitor effects were then investigated by growing parthenosporophytes in an inhibitor-free post-culture for 14 days.Key resultsThiolutin did not affect gamete germination, but growth of parthenosporophytes was significantly delayed. While almost all control parthenosporophytes had grown larger than 10 cells over 12 days, thiolutin inhibited growth beyond a size of 5-10 cells. The effects of thiolutin were reversible in the post-culture. Consequences of the emetine treatment were more severe, germination was already strongly inhibited by day 5, and on average only 27.5% of emetine-treated gametes had completed the first cell division on day 12. Emetine fully inhibited development beyond the 5-cell stage during the treatment, and induced morphological abnormalities (i.e., round cell shape and abnormal cell division planes) which persisted throughout the post-culture.ConclusionsThese results imply thatEctocarpusgametes contain sufficient proteins to germinate, and that the first cell cycles of parthenogenetic gamete development presumably utilize mRNA already present in the gametes. We discuss that storing mRNA and proteins in the developing gametes before release may be an adaptive trait inEctocarpusto ensure quick development after fertilization, or alternatively the vegetative completion of the life cycle in the absence of mates.