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Agent-based model of Eastern Pacific damselfish and sea urchin interactions shows increased coral reef erosion under post-ENSO conditions

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  • Glynn, Peter J
  • Glynn, Peter W
  • Maté, Juan
  • Riegl, Bernhard

Abstract

Significant increases in the population of the echinoid bioeroder Diadema mexicanum that may soon follow severe El Niño events, such as in 1982–1983, can have a significant negative impact on the carbonate budget of coral reefs. We developed a spatially explicit model that uses agent-based modeling techniques to simulate the interactions between damselfish and sea urchins on an eastern Pacific coral reef following an El Niño-Southern Oscillation (ENSO) event where high echinoid abundances and low coral cover were prevalent. Our modeling study suggests that the agonistic behavior of damselfish towards echinoids invading their defended algal lawn territories has a magnifying effect on the degree of bioerosion attributed to echinoids. This is due to the increased likelihood that sea urchins ejected from damselfish territories will form concentrated aggregations and remain grazing and eroding coral for longer periods of time. This is a novel insight that contrasts with the previous understanding of the positive effect that damselfish have on reef carbonate budgets by protecting carbonate substrates that lie within their defended algal lawn territories. The increased degradation of coral stands attributed to the indirect damselfish effect, if it results in sea urchins eroding subsurface coral framework structures, causing instability and collapse (especially during periods of high-water motion), may contribute to the fracturing of large portions of coral framework blocks, affecting the recovery trajectory of reefs following a severe El Niño disturbance event.

Suggested Citation

  • Glynn, Peter J & Glynn, Peter W & Maté, Juan & Riegl, Bernhard, 2020. "Agent-based model of Eastern Pacific damselfish and sea urchin interactions shows increased coral reef erosion under post-ENSO conditions," Ecological Modelling, Elsevier, vol. 423(C).
    • Handle: RePEc:eee:ecomod:v:423:y:2020:i:c:s0304380020300715
    DOI: 10.1016/j.ecolmodel.2020.108999
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    1. Robert M. Pringle & Tyler R. Kartzinel & Todd M. Palmer & Timothy J. Thurman & Kena Fox-Dobbs & Charles C. Y. Xu & Matthew C. Hutchinson & Tyler C. Coverdale & Joshua H. Daskin & Dominic A. Evangelist, 2019. "Predator-induced collapse of niche structure and species coexistence," Nature, Nature, vol. 570(7759), pages 58-64, June.
    2. Yñiguez, Aletta T. & McManus, John W. & DeAngelis, Donald L., 2008. "Allowing macroalgae growth forms to emerge: Use of an agent-based model to understand the growth and spread of macroalgae in Florida coral reefs, with emphasis on Halimeda tuna," Ecological Modelling, Elsevier, vol. 216(1), pages 60-74.
    3. Miñarro, Sara & Leins, Johannes & Acevedo-Trejos, Esteban & Fulton, Elizabeth A. & Reuter, Hauke, 2018. "SEAMANCORE: A spatially explicit simulation model for assisting the local MANagement of COral REefs," Ecological Modelling, Elsevier, vol. 384(C), pages 296-307.
    4. Grimm, Volker & Berger, Uta & DeAngelis, Donald L. & Polhill, J. Gary & Giske, Jarl & Railsback, Steven F., 2010. "The ODD protocol: A review and first update," Ecological Modelling, Elsevier, vol. 221(23), pages 2760-2768.
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    1. Lewis, Dakota M. & Vardi, Tali & Maher, Rebecca L. & Correa, Adrienne M.S. & Cook, Geoffrey S., 2022. "Predicting shifts in demography of Orbicella franksi following simulated disturbance and restoration," Ecological Modelling, Elsevier, vol. 472(C).

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