Examples of chemical defenses and their influence on predator-prey interactions abound in the terrestrial and marine benthic ecological literature. In contrast, considerably less is known about the role of chemical defenses in marine planktonic systems. In this study, we examined the potential for the phytoplankton-produced compound dimethylsulfoniopropionate (DMSP) and its cleavage products dimethyl sulfide (DMS) and acrylate to act as chemical defenses in seawater. Although added DMS and acrylate had no effect on protist grazers, added DMSP reduced grazing on the coccolithophorid Emiliania huxleyi by all four tested species (dinoflagellates Amphidinium longum, Gymnodinium sp., and Oxyrrhis marina and ciliate Coxliella sp.). A. longum and Gymnodinium were highly sensitive to 20-[micro]mol [L.sup.-1] concentrations of DMSP, nearly ceasing to feed, whereas O. marina and Coxliella showed only minor reductions in grazing activity. Grazing suppression in A. longum was DMSP concentration-dependent over the range 0.05 to 1,000 [micro]mol [L.sup.-1] and was also inhibited by added glycine betaine, a structural analog of DMSP. DMSP reduced A. longum grazing by similar amounts on five different algal species, some of which do not produce DMSP on their own. Thus, the efficacy of DMSP as a grazing deterrent appears to depend on grazer species, but not on algal strain or species. Because DMSP does not seem to be toxic, we hypothesize that DMSP and related compounds act as signals for the presence of potentially harmful algal cells. Should such sublethal chemical defense interactions be widespread in nature, they could be important in regulating the composition and biomass of phytoplankton communities.