Grazing and colony size development in Phaeocystis globosa (Prymnesiophyceae): the role of a chemical signal

The bloom-forming prymnesiophyte Phaeocystis globosa forms hollow,spherical, mucilaginous colonies that vary from micrometresto millimetres in size. A recent paper gave the first empiricalevidence that colony size increase in P. globosa is a defensiveresponse against grazers, and knowing the signalling mechanism(s)behind this response will thus be a key to understanding thetrophodynamics in systems dominated by this species. I conductedexperiments with specially designed diffusion incubators, eachof which consists of a non-grazing chamber (with P. globosaonly) and a grazing chamber (grazers + phytoplankton) connectedby 2 µm polycarbonate membrane filters. The results showedthat physical contact with grazers was not required to initiatethe defensive response; instead, P. globosa colony size increasewas found to be stimulated by dissolved chemicals generatedby ambient grazing activities. This signal was non-species specific,such that various combinations of three species of grazers andfour species of phytoplankton in the grazing chambers all resultedin significant, but different extents of colony enlargementin P. globosa in the non-grazing chambers (30–300% largerthan the ‘grazer-free’ control). High concentrationsof ambient solitary P. globosa cells and other phytoplanktonseemed to suppress colony enlargement in P. globosa, and grazerswould help reduce this inhibition by removing the ambient solitaryP. globosa cells and other phytoplankton. These non-species-specificmechanisms would allow P. globosa to regulate colony size developmentand defend itself in diverse planktonic systems, which may helpto explain the global success of this species.