Abstract
The low species diversity that often characterizes island ecosystems could result in low functional redundancy within communities. Flying foxes (large fruit bats) are important seed dispersers of large-seeded species, but their redundancy within island communities has never been explicitly tested. In a Pacific archipelago, we found that flying foxes were the sole effective disperser of 57 % of the plant species whose fruits they consume. They were essential for the dispersal of these species either because they handled >90 % of consumed fruit, or were the only animal depositing seeds away from the parent canopy, or both. Flying foxes were especially important for larger-seeded fruit (>13 mm wide), with 76 % of consumed species dependent on them for dispersal, compared with 31 % of small-seeded species. As flying foxes decrease in abundance, they cease to function as dispersers long before they become rare. We compared the seed dispersal effectiveness (measured as the proportion of diaspores dispersed beyond parent crowns) of all frugivores for four plant species in sites where flying foxes were, and were not, functionally extinct. At both low and high abundance, flying foxes consumed most available fruit of these species, but the proportion of handled diaspores dispersed away from parent crowns (quality) was significantly reduced at low abundance. Since alternative consumers (birds, rodents and land crabs) were unable to compensate as dispersers when flying foxes were functionally extinct, we conclude that there is almost no redundancy in the seed dispersal function of flying foxes in this island system, and potentially on other islands where they occur. Given that oceanic island communities are often simpler than continental communities, evaluating the extent of redundancy across different ecological functions on islands is extremely important.
Highlights
Resilience to disturbance is greatest in ecosystems that have high species diversity because of the buffering effect diversity can have on function (Mayfield et al 2010; Dalerum et al 2012; Reich et al 2012)
We addressed the following hypotheses: (i) relative to other dispersers, flying foxes disperse a disproportionately high proportion of seeds of large-seeded species; (ii) flying foxes disperse a higher proportion of handled seeds away from parent crowns than other dispersers, and mean dispersal distances are greater; (iii) flying foxes have greater ‘seed dispersal effectiveness’ (SDE 1⁄4 quantity × quality, Schupp et al 2010) for large diaspores than other dispersers and (iv) total SDE of plants is reduced at sites where flying foxes are functionally extinct
The frugivore community consisted of the insular flying fox Pteropus tonganus, Pacific pigeon Ducula pacifica (395 g), three small dove species (Ptilinopus perousii (90 g), P. porphyraceus (110 g) and Alopecoenas stairi
Summary
Resilience to disturbance is greatest in ecosystems that have high species diversity because of the buffering effect diversity can have on function (Mayfield et al 2010; Dalerum et al 2012; Reich et al 2012). Islands are characterized by inherently low species diversity compared with continents (MacArthur 1965; Whittaker and FernandezPalacios 2007), and they have been disproportionately further depleted by human-mediated extinctions Current island ecosystems might exhibit especially low functional redundancy, which makes the ongoing human-mediated disturbances to them (Brooks et al 2002; Whittaker and Fernandez-Palacios 2007) a serious threat to their stability (Cox et al 1991; Traveset et al 2012). Understanding the vulnerability of island species to a lack of functional redundancy is complicated, but important, to ensure that functional ecosystems are maintained
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
