Masting by Eighteen New Zealand Plant Species: the Role of Temperature as a Synchronizing Cue


Masting, the intermittent production of large flower or seed crops by a population of perennial plants, can enhance the reproductive success of participating plants and drive fluctuations in seed-consumer populations and other ecosystem components over large geographic areas. The spatial and taxonomic extent over which masting is synchronized can determine its success in enhancing individual plant fitness as well as its ecosystemlevel effects, and it can indicate the types of proximal cues that enable reproductive synchrony. Here, we demonstrate high intraand intergeneric synchrony in mast seeding by 17 species of New Zealand plants from four families across .150 000 km2. The synchronous species vary ecologically (pollination and dispersal modes) and are geographically widely separated, so intergeneric synchrony seems unlikely to be adaptive per se. Synchronous fruiting by these species was associated with anomalously high temperatures the summer before seedfall, a cue linked with the La Niña phase of El Niño–Southern Oscillation. The lone asynchronous species appears to respond to summer temperatures, but with a 2-yr rather than 1-yr time lag. The importance of temperature anomalies as cues for synchronized masting suggests that the timing and intensity of masting may be sensitive to global climate change, with widespread effects on taxonomically disparate plant and animal communities.

Extracted Key Phrases

7 Figures and Tables


Citations per Year

102 Citations

Semantic Scholar estimates that this publication has 102 citations based on the available data.

See our FAQ for additional information.

Cite this paper

@inproceedings{Schauber2002MastingBE, title={Masting by Eighteen New Zealand Plant Species: the Role of Temperature as a Synchronizing Cue}, author={Eric M. Schauber and Dave Kelly and Peter Turchin and Chris M Simon and William G. Lee and Robert B. Allen and Ian J. Payton and Peter Raymond Wilson and Phil E. Cowan and Robert E Brockie}, year={2002} }