Abstract

The growth, grazing, and cell volume of Strombidinopsis multjaurls, a large (-100 pm) coastal planktonic cil~ate, IS affected by food concentration and temperature. Using growth and grazlng data, we modelled small-scale bloom dynam~cs between the clliate and ~t s prey. Growth expenments were conducted at 13C on S. niultiauris fed the 10 pm d~noflagellate Gymnodiniurn simplex; changes in cell numbers and cell volume were monitored. Ingestion rate was measured by 3 methods (uptake of fluorescently labelled latex beads, heat-killed, fluorescently labelled G nmplex; and I4C-labelled G. simplex). Growth rate vprsus food concentration followed a rectangular hyperbolic response, with a maxlmum of p = 0 6 d ' above 104 prey ml-l (480 ng C ml-l), below 1.3 X 10"l-' (62 ng C ml-l), mortality occurred. Cell volume followed a rectangular hyperbolic response to food concentration, and showed a doubling in size between zero and maxmum prey levels. Grazing rate initially ~ncreased with food concentration and was then inhib~ted at levels >10"rey ml-l. The cil~ate ~ngested 14C-labelled live prey at higher rates than either dead or artificial prey at subsaturating concentrations; above saturating concentrations, ingestion rates were similar for the 3 prey types. The maximum observed grazlng rate was 35 prey cihate ' h-' Growth rate and cell volume were measured under steady-state conditions at 9 temperatures between 3 5 and 22C: clliates died at 3.5 and 5"C, growth rate increased hnearly to a maximum of p = 0.9 d-l at 15"C, did not change between 15 and 20C, and decreased at 22C. Cell volume ~ncreased between 5 and 10C and decreased between 10 and 22C. The population dynamlcs model revealed that the ciliate was able to control the dinoflagellate population. Over the 20 d model simulation, virtually no predator-prey cycle occurred when prey growth rates were p < 0.2 d-' As prey growth rate was increased bloom dynamics became apparent, with a minunum duration of -10 d for a bloom to begin and end at a prey growth rate of p = 0.65 d-l.