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Main Authors: Esquivel-Muelbert, Juan R, Fontoura, Luisa, Zawada, Kyle, Erickson, Katherine, Figueira, William, Madin, Joshua S, Bishop, Melanie J
Format: Artículo científico
Language:en
Published: Nature 2026
Subjects:
Online Access:https://pubmed.ncbi.nlm.nih.gov/41708850/
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author Esquivel-Muelbert, Juan R
Fontoura, Luisa
Zawada, Kyle
Erickson, Katherine
Figueira, William
Madin, Joshua S
Bishop, Melanie J
author_facet Esquivel-Muelbert, Juan R
Fontoura, Luisa
Zawada, Kyle
Erickson, Katherine
Figueira, William
Madin, Joshua S
Bishop, Melanie J
Esquivel-Muelbert, Juan R
Fontoura, Luisa
Zawada, Kyle
Erickson, Katherine
Figueira, William
Madin, Joshua S
Bishop, Melanie J
collection PubMed - marine biology
contents The natural architecture of oyster reefs maximizes recruit survival. Esquivel-Muelbert, Juan R Fontoura, Luisa Zawada, Kyle Erickson, Katherine Figueira, William Madin, Joshua S Bishop, Melanie J Animals Ecosystem Coral Reefs Fractals Ostreidae Population Dynamics Conservation of Natural Resources Biodiversity The three-dimensional architecture of natural habitats is a key determinant of species biodiversity, harvestable biomass and resilience to disturbance. Indeed, some species, including trees, corals and oysters, alter resource availability and modify biotic and abiotic pressures through their own three-dimensional structures-thereby enhancing their own survival. However, which aspects of the three-dimensional architecture of these ecosystem engineers shape ecosystem dynamics and species survival are rarely examined by empirical studies, leaving much of the broader ecological and conservation impact of ecosystem engineering underexplored. Here we show that oyster reefs have combinations of geometric variables that maximize recruit survival, which is a key factor influencing oyster reef growth and persistence. Using three-dimensional habitat designs that capture the full spectrum of natural oyster reef architectures, as well as a geometric theory that links habitat surface area, fractal dimension and height, we show that oyster settlement and survival are greatest at particular combinations of fractal dimension and height that minimize predation. Our study provides a template for understanding optimal three-dimensional habitat configurations for habitat restoration projects that are proliferating globally, without targeting key architectural features of habitat space that maximize restoration success.
format Artículo científico
id pubmed_41708850
institution PubMed
language en
publishDate 2026
publisher Nature
record_format pubmed
spellingShingle The natural architecture of oyster reefs maximizes recruit survival.
Esquivel-Muelbert, Juan R
Fontoura, Luisa
Zawada, Kyle
Erickson, Katherine
Figueira, William
Madin, Joshua S
Bishop, Melanie J
Animals
Ecosystem
Coral Reefs
Fractals
Ostreidae
Population Dynamics
Conservation of Natural Resources
Biodiversity
The natural architecture of oyster reefs maximizes recruit survival. Esquivel-Muelbert, Juan R Fontoura, Luisa Zawada, Kyle Erickson, Katherine Figueira, William Madin, Joshua S Bishop, Melanie J Animals Ecosystem Coral Reefs Fractals Ostreidae Population Dynamics Conservation of Natural Resources Biodiversity The three-dimensional architecture of natural habitats is a key determinant of species biodiversity, harvestable biomass and resilience to disturbance. Indeed, some species, including trees, corals and oysters, alter resource availability and modify biotic and abiotic pressures through their own three-dimensional structures-thereby enhancing their own survival. However, which aspects of the three-dimensional architecture of these ecosystem engineers shape ecosystem dynamics and species survival are rarely examined by empirical studies, leaving much of the broader ecological and conservation impact of ecosystem engineering underexplored. Here we show that oyster reefs have combinations of geometric variables that maximize recruit survival, which is a key factor influencing oyster reef growth and persistence. Using three-dimensional habitat designs that capture the full spectrum of natural oyster reef architectures, as well as a geometric theory that links habitat surface area, fractal dimension and height, we show that oyster settlement and survival are greatest at particular combinations of fractal dimension and height that minimize predation. Our study provides a template for understanding optimal three-dimensional habitat configurations for habitat restoration projects that are proliferating globally, without targeting key architectural features of habitat space that maximize restoration success.
title The natural architecture of oyster reefs maximizes recruit survival.
topic Animals
Ecosystem
Coral Reefs
Fractals
Ostreidae
Population Dynamics
Conservation of Natural Resources
Biodiversity
url https://pubmed.ncbi.nlm.nih.gov/41708850/