The specific inhibition of glycerol synthesis and the phosphorylation of a putative Mitogen-Activated Protein Kinase give insight into the mechanism of osmotic sensing in a dinoflagellate symbiont.

Signaling pathways are fundamental for the establishment and maintenance of diverse symbioses. The symbiosis of cnidarians and dinoflagellate algae is the foundation for the ecological success of coral reefs, involving the transfer of photosynthetic products from the symbiont to host. However, signal transduction pathways for this symbiosis remain uncharacterized.

Osmosensing and osmoregulation in unicellular eukaryotes.

Eukaryotic microorganisms possess mechanisms to detect osmotic variations in their surroundings, from specialized receptors and membrane transporters, to sophisticated systems such as two-component histidine kinases. Osmotic stimuli are transduced through conserved phosphorylation cascades that result in a rapid response to mitigate stress. This response allows for the maintenance of an optimal biochemical environment for cell functioning, as well as a suitable recovery in suboptimal environments that would otherwise endanger cell survival.

Induction of glycerol synthesis and release in cultured Symbiodinium.

Background: Symbiotic dinoflagellates transfer a substantial amount of their photosynthetic products to their animal hosts. This amount has been estimated to represent up to 90% of the photosynthetically fixed carbon and can satisfy in some instances the full respiratory requirements of the host. Although in several cnidarian-dinoflagellate symbioses glycerol is the primary photosynthetic product translocated to the host, the mechanism for its production and release has not been demonstrated conclusively.