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Journal of the Australian Rangeland Society
RESEARCH ARTICLE

Proximate causes and possible adaptive functions of mast seeding and barren flower shows in spinifex grasses (Triodia spp.) in arid regions of Australia

Boyd R. Wright A B F , Alain F. Zuur C D and Gary C. K. Chan E
+ Author Affiliations
- Author Affiliations

A Alice Springs Herbarium, Northern Territory Department of Land and Resource Management, PO Box 1120, Alice Springs, NT 0870, Australia.

B School of Agriculture and Food Science, The University of Queensland, Brisbane, Qld 4072, Australia.

C Highland Statistics Ltd, 9 St Clair Wynd, Newburgh AB41 6DZ, UK.

D Oceanlab, University of Aberdeen, AB41 6AA Newburgh, UK.

E School of Medicine, The University of Queensland, Brisbane, Qld 4072, Australia.

F Corresponding author. Email: desertecol@desertecol.com

The Rangeland Journal 36(3) 297-308 https://doi.org/10.1071/RJ13104
Submitted: 11 October 2013  Accepted: 10 June 2014   Published: 26 June 2014

Abstract

Mast seeding, the intermittent production of large synchronised seed crops among plant populations, is a phenomenon that occurs at exceptionally long intervals in spinifex grasses (Triodia spp.) from arid regions of Australia. This is despite the reliance of these fire-sensitive plants on seeds for post-fire regeneration, and that spinifex grasslands rate among Australia’s most flammable ecosystems. The proximate causes and possible adaptive functions of masting in seven species of spinifex from arid regions within the 350-mm rainfall isohyet were investigated. Specifically, the seed set percentages of 79 specimens collected between 1947 and 2012 were related to the following environmental covariates: antecedent rainfall over 6, 12 and 36 months, relative humidity, and the number of days above 40°C and below 0°C during anthesis. Given the potential importance of seeding events for post-fire regeneration, it was also investigated whether masting in Triodia could represent a fire-related form of environmentally predictive masting, by testing whether high-yield years corresponded to years of increased fire occurrence. Examination of the dataset showed that 43% of specimens contained completely aborted inflorescences (0% seed fill), while seed set ranged from 2 to 69% in the remaining specimens. High levels of insect activity were also found, with 42% of specimens showing evidence of insect occupation. Statistical analyses showed that the main environmental driver of seed set was high precipitation over the previous 12 months, and that high-yield years were strongly related to years of increased fire likelihood. The number of days over 40°C was a weakly significant driver of yield, while the remaining covariates were not significant. It is hypothesised that intermittent reproduction by Triodia is a fire-related form of environmentally predictive masting, which maximises chances of post-fire regeneration by satiating seed predators during flammable periods (i.e. after heavy rain years). Furthermore, it is suggested that non-viable flower crops after initial low rainfalls may have an adaptive function, by diluting pre-dispersal seed predator densities with ‘decoy’ ovules that do not mature and lead to the starvation of developing larvae.

Additional keywords: environmentally predictive masting, fire, seed bank, seed predation, spinifex.


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