Spatial resilience of the Great Barrier Reef under cumulative disturbance impacts

Camille Mellin; Samuel Matthews; Kenneth R.N. Anthony; Stuart C. Brown; M. Julian Caley; Kerryn A. Johns; Kate Osborne; Marjetta Puotinen; Angus Thompson; Nicholas H. Wolff; Damien A. Fordham; M. Aaron MacNeil

doi:10.1111/gcb.14625

Spatial resilience of the Great Barrier Reef under cumulative disturbance impacts

Camille Mellin, Samuel Matthews, Kenneth R.N. Anthony, Stuart C. Brown, M. Julian Caley, Kerryn A. Johns, Kate Osborne, Marjetta Puotinen, Angus Thompson, Nicholas H. Wolff, Damien A. Fordham, M. Aaron MacNeil

Medicine

Producción científica: Contribución a una revista › Artículo › revisión exhaustiva

107 Citas (Scopus)

Resumen

In the face of increasing cumulative effects from human and natural disturbances, sustaining coral reefs will require a deeper understanding of the drivers of coral resilience in space and time. Here we develop a high-resolution, spatially explicit model of coral dynamics on Australia's Great Barrier Reef (GBR). Our model accounts for biological, ecological and environmental processes, as well as spatial variation in water quality and the cumulative effects of coral diseases, bleaching, outbreaks of crown-of-thorns starfish (Acanthaster cf. solaris), and tropical cyclones. Our projections reconstruct coral cover trajectories between 1996 and 2017 over a total reef area of 14,780 km², predicting a mean annual coral loss of −0.67%/year mostly due to the impact of cyclones, followed by starfish outbreaks and coral bleaching. Coral growth rate was the highest for outer shelf coral communities characterized by digitate and tabulate Acropora spp. and exposed to low seasonal variations in salinity and sea surface temperature, and the lowest for inner-shelf communities exposed to reduced water quality. We show that coral resilience (defined as the net effect of resistance and recovery following disturbance) was negatively related to the frequency of river plume conditions, and to reef accessibility to a lesser extent. Surprisingly, reef resilience was substantially lower within no-take marine protected areas, however this difference was mostly driven by the effect of water quality. Our model provides a new validated, spatially explicit platform for identifying the reefs that face the greatest risk of biodiversity loss, and those that have the highest chances to persist under increasing disturbance regimes.

Idioma original	English
Páginas (desde-hasta)	2431-2445
Número de páginas	15
Publicación	Global Change Biology
Volumen	25
N.º	7
DOI	https://doi.org/10.1111/gcb.14625
Estado	Published - jul. 2019

Nota bibliográfica

Funding Information:
We thank members of the Australian Institute of Marine Science Long‐Term Monitoring Program that have contributed to collection of the data used in these analyses; and B Shaffelke, K Fabricius, S Connolly, S Heron and J Brodie for providing helpful comments. This publication was supported through funding from the Australian Government's National Environmental Science Programme. CM was funded by an ARC grant (DE140100701).

Funding Information:
The data and code used in this study are available at https://www.dropbox.com/s/2b6s5epx6mpokc5/Coral%20cover%20model.zip?dl=0 We thank members of the Australian Institute of Marine Science Long-Term Monitoring Program that have contributed to collection of the data used in these analyses; and B Shaffelke, K Fabricius, S Connolly, S Heron and J Brodie for providing helpful comments. This publication was supported through funding from the Australian Government's National Environmental Science Programme. CM was funded by an ARC grant (DE140100701).

Publisher Copyright:
© 2019 John Wiley & Sons Ltd

ASJC Scopus Subject Areas

Global and Planetary Change
Environmental Chemistry
Ecology
General Environmental Science

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title = "Spatial resilience of the Great Barrier Reef under cumulative disturbance impacts",

abstract = "In the face of increasing cumulative effects from human and natural disturbances, sustaining coral reefs will require a deeper understanding of the drivers of coral resilience in space and time. Here we develop a high-resolution, spatially explicit model of coral dynamics on Australia's Great Barrier Reef (GBR). Our model accounts for biological, ecological and environmental processes, as well as spatial variation in water quality and the cumulative effects of coral diseases, bleaching, outbreaks of crown-of-thorns starfish (Acanthaster cf. solaris), and tropical cyclones. Our projections reconstruct coral cover trajectories between 1996 and 2017 over a total reef area of 14,780 km2, predicting a mean annual coral loss of −0.67%/year mostly due to the impact of cyclones, followed by starfish outbreaks and coral bleaching. Coral growth rate was the highest for outer shelf coral communities characterized by digitate and tabulate Acropora spp. and exposed to low seasonal variations in salinity and sea surface temperature, and the lowest for inner-shelf communities exposed to reduced water quality. We show that coral resilience (defined as the net effect of resistance and recovery following disturbance) was negatively related to the frequency of river plume conditions, and to reef accessibility to a lesser extent. Surprisingly, reef resilience was substantially lower within no-take marine protected areas, however this difference was mostly driven by the effect of water quality. Our model provides a new validated, spatially explicit platform for identifying the reefs that face the greatest risk of biodiversity loss, and those that have the highest chances to persist under increasing disturbance regimes.",

author = "Camille Mellin and Samuel Matthews and Anthony, {Kenneth R.N.} and Brown, {Stuart C.} and Caley, {M. Julian} and Johns, {Kerryn A.} and Kate Osborne and Marjetta Puotinen and Angus Thompson and Wolff, {Nicholas H.} and Fordham, {Damien A.} and MacNeil, {M. Aaron}",

note = "Funding Information: We thank members of the Australian Institute of Marine Science Long‐Term Monitoring Program that have contributed to collection of the data used in these analyses; and B Shaffelke, K Fabricius, S Connolly, S Heron and J Brodie for providing helpful comments. This publication was supported through funding from the Australian Government's National Environmental Science Programme. CM was funded by an ARC grant (DE140100701). Funding Information: The data and code used in this study are available at https://www.dropbox.com/s/2b6s5epx6mpokc5/Coral%20cover%20model.zip?dl=0 We thank members of the Australian Institute of Marine Science Long-Term Monitoring Program that have contributed to collection of the data used in these analyses; and B Shaffelke, K Fabricius, S Connolly, S Heron and J Brodie for providing helpful comments. This publication was supported through funding from the Australian Government's National Environmental Science Programme. CM was funded by an ARC grant (DE140100701). Publisher Copyright: {\textcopyright} 2019 John Wiley & Sons Ltd",

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Spatial resilience of the Great Barrier Reef under cumulative disturbance impacts

Resumen

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ASJC Scopus Subject Areas

ODS de las Naciones Unidas

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