High resilience masks underlying sensitivity to algal phase shifts of Pacific coral reefs
Authored by Peter J Mumby, Robert S Steneck, Mehdi Adjeroud, Suzanne N Arnold
Date Published: 2016
DOI: 10.1111/oik.02673
Sponsors:
National Geographic Society
Australian Research Council (ARC)
Sultan Living Oceans Foundation
Platforms:
No platforms listed
Model Documentation:
Other Narrative
Model Code URLs:
Model code not found
Abstract
A single ecosystem can exhibit great biogeographic and environmental
variability. While a given ecological driver might have a strong impact
in one region, it does not necessarily hold that its importance will
extend elsewhere. Coral reefs provide a striking example in that coral
communities have low resilience in the Atlantic and remarkable
resilience in parts of the species-rich Pacific. Recent experimental
evidence from the Atlantic finds that fishing of large herbivorous fish
can be a strong driver of coral resilience. Here, we repeat the Atlantic
experiment in the highly resilient forereef of Moorea (French
Polynesia), which has repeatedly recovered from disturbances. A
combination of cages, fish deterrents (FDs), and controls allowed us to
simulate the consequences of fishing large herbivores on algal
assemblages, coral recruitment, and the demographic rates of coral
juveniles. We find that the impacts of removing large herbivorous reef
fish vary with early coral ontogeny. Reduced herbivore access led to a
modest macroalgal bloom and reduction in coral recruitment. However, larger juvenile corals (> 1 cm diameter) survived better and grew faster
under these conditions because of a reduction in corallivory. To
determine the net impact of losing larger herbivorous fish, we combined
experimental results with estimated demographic parameters in an
individual-based model. Simulating coral recovery trajectories for five
years, we find that protecting larger reef fish led to better recovery
in 66-99\% of simulations, depending on underlying assumptions (with the
more credible assumptions being associated with greater likelihood of
net positive impacts). While we find that fishing effects are
detrimental to corals in both the Atlantic and Pacific systems studied, the nature of the interactions varied markedly. In the identical
previously-published study in the Atlantic, macroalgae exhibited a rapid
bloom and caused a sufficiently large reduction in coral recruitment to
force a predicted ecosystem shift to an alternative attractor. The
commensurate macroalgal bloom in Moorea was weak yet the corals were two
orders of magnitude more sensitive to its presence. We do not suggest
that a reduction in recruitment in Moorea will lead to alternative
attractors but the long-term risks of a reduction in recovery rate are
cause for concern as rates of coral mortality are projected to increase.
The emerging picture is that Pacific reefs are less likely to experience
macroalgal blooms but are surprisingly sensitive to such blooms if they
occur.
Tags
Competition
Ecosystem
Recruitment
Great-barrier-reef
Brown alga
Assemblages
Community structure
Herbivorous fishes
Macroalgal
cover
Marine reserve