Shell Cover, Rugosity, and Tidal Elevation Impact Native and Non-Indigenous Oyster Recruitment: Implications for Reef Ball Design

Estuaries have been armored with artificial habitat to protect coastal infrastructure from erosion, but armoring can have negative ecological impacts. Other shoreline protection strategies, such as eco-engineered seawalls and living shorelines, offer more natural, rugose substrata to native species...

Full description

Bibliographic Details
Main Authors: Danielle C. Zacherl, Bryce D. Perog, Chelsea Bowers-Doerning, Carmen Y. Lopez Ramirez, Althea N. Marks
Format: Article in Journal/Newspaper
Language:unknown
Published: College of Natural Sciences and Mathematics 2023
Subjects:
Concrete
Living shoreline
Eco-engineering
Magallana gigas
Ostrea lurida
Recruitment
Pacific
Crassostrea gigas
Online Access:https://hdl.handle.net/20.500.12680/02871321g
id ftcalifstateuniv:oai:scholarworks:02871321g
record_format openpolar
spelling ftcalifstateuniv:oai:scholarworks:02871321g 2024-11-03T14:54:52+00:00 Shell Cover, Rugosity, and Tidal Elevation Impact Native and Non-Indigenous Oyster Recruitment: Implications for Reef Ball Design Danielle C. Zacherl Bryce D. Perog Chelsea Bowers-Doerning Carmen Y. Lopez Ramirez Althea N. Marks 2023-07 https://hdl.handle.net/20.500.12680/02871321g unknown College of Natural Sciences and Mathematics Department of Biological Sciences http://hdl.handle.net/20.500.12680/02871321g Concrete Living shoreline Eco-engineering Magallana gigas Ostrea lurida Recruitment Article 2023 ftcalifstateuniv https://doi.org/20.500.12680/02871321g 2024-10-15T01:33:10Z Estuaries have been armored with artificial habitat to protect coastal infrastructure from erosion, but armoring can have negative ecological impacts. Other shoreline protection strategies, such as eco-engineered seawalls and living shorelines, offer more natural, rugose substrata to native species while limiting coastal erosion. Concerns about recruitment of non-indigenous species (NIS) call into question whether structures can be engineered to foster native communities. In southern California, USA, we explored whether concrete reef balls that recruit native Olympia oysters, Ostrea lurida, could be engineered to increase recruitment of O. lurida and discourage recruitment of non-indigenous Pacific oysters, Magallana (formerly Crassostrea) gigas. We modified 15 × 15 cm concrete tiles with added shell cover and rugosity and deployed four treatments: two with surface shell (crushed, large fragments) and two without shell (smooth, rugose) at two sites in San Diego Bay and one site in Newport Bay at two tidal elevations (0.2 and 0.8 m MLLW) from May to September 2018. O. lurida generally recruited in highest abundance and percent cover to 0.2 m MLLW relative to 0.8 m MLLW; at 0.8 m MLLW, shelled treatments with high rugosity favored higher cover and abundance of O. lurida relative to unshelled, low-rugosity treatments. In contrast, M. gigas percent cover was generally higher on unshelled treatments relative to shelled treatments, and rugosity never had statistically significant positive effects on their abundance or cover. Recruitment strength and percent cover of both oyster species showed remarkable context-dependency but a generalized recommendation emerged across sites with strikingly different recruitment strengths: deployment of lower-elevation reef balls would favor O. lurida recruitment, and addition of shell fragments and rugosity will increase native O. lurida recruitment at higher tidal elevations. Shell additions and rugosity may also discourage non-indigenous M. gigas recruitment and cover in some ... Article in Journal/Newspaper Crassostrea gigas Scholarworks from California State University Pacific
institution Open Polar
collection Scholarworks from California State University
op_collection_id ftcalifstateuniv
language unknown
topic Concrete
Living shoreline
Eco-engineering
Magallana gigas
Ostrea lurida
Recruitment
spellingShingle Concrete
Living shoreline
Eco-engineering
Magallana gigas
Ostrea lurida
Recruitment
Danielle C. Zacherl
Bryce D. Perog
Chelsea Bowers-Doerning
Carmen Y. Lopez Ramirez
Althea N. Marks
Shell Cover, Rugosity, and Tidal Elevation Impact Native and Non-Indigenous Oyster Recruitment: Implications for Reef Ball Design
topic_facet Concrete
Living shoreline
Eco-engineering
Magallana gigas
Ostrea lurida
Recruitment
description Estuaries have been armored with artificial habitat to protect coastal infrastructure from erosion, but armoring can have negative ecological impacts. Other shoreline protection strategies, such as eco-engineered seawalls and living shorelines, offer more natural, rugose substrata to native species while limiting coastal erosion. Concerns about recruitment of non-indigenous species (NIS) call into question whether structures can be engineered to foster native communities. In southern California, USA, we explored whether concrete reef balls that recruit native Olympia oysters, Ostrea lurida, could be engineered to increase recruitment of O. lurida and discourage recruitment of non-indigenous Pacific oysters, Magallana (formerly Crassostrea) gigas. We modified 15 × 15 cm concrete tiles with added shell cover and rugosity and deployed four treatments: two with surface shell (crushed, large fragments) and two without shell (smooth, rugose) at two sites in San Diego Bay and one site in Newport Bay at two tidal elevations (0.2 and 0.8 m MLLW) from May to September 2018. O. lurida generally recruited in highest abundance and percent cover to 0.2 m MLLW relative to 0.8 m MLLW; at 0.8 m MLLW, shelled treatments with high rugosity favored higher cover and abundance of O. lurida relative to unshelled, low-rugosity treatments. In contrast, M. gigas percent cover was generally higher on unshelled treatments relative to shelled treatments, and rugosity never had statistically significant positive effects on their abundance or cover. Recruitment strength and percent cover of both oyster species showed remarkable context-dependency but a generalized recommendation emerged across sites with strikingly different recruitment strengths: deployment of lower-elevation reef balls would favor O. lurida recruitment, and addition of shell fragments and rugosity will increase native O. lurida recruitment at higher tidal elevations. Shell additions and rugosity may also discourage non-indigenous M. gigas recruitment and cover in some ...
format Article in Journal/Newspaper
author Danielle C. Zacherl
Bryce D. Perog
Chelsea Bowers-Doerning
Carmen Y. Lopez Ramirez
Althea N. Marks
author_facet Danielle C. Zacherl
Bryce D. Perog
Chelsea Bowers-Doerning
Carmen Y. Lopez Ramirez
Althea N. Marks
author_sort Danielle C. Zacherl
title Shell Cover, Rugosity, and Tidal Elevation Impact Native and Non-Indigenous Oyster Recruitment: Implications for Reef Ball Design
title_short Shell Cover, Rugosity, and Tidal Elevation Impact Native and Non-Indigenous Oyster Recruitment: Implications for Reef Ball Design
title_full Shell Cover, Rugosity, and Tidal Elevation Impact Native and Non-Indigenous Oyster Recruitment: Implications for Reef Ball Design
title_fullStr Shell Cover, Rugosity, and Tidal Elevation Impact Native and Non-Indigenous Oyster Recruitment: Implications for Reef Ball Design
title_full_unstemmed Shell Cover, Rugosity, and Tidal Elevation Impact Native and Non-Indigenous Oyster Recruitment: Implications for Reef Ball Design
title_sort shell cover, rugosity, and tidal elevation impact native and non-indigenous oyster recruitment: implications for reef ball design
publisher College of Natural Sciences and Mathematics
publishDate 2023
url https://hdl.handle.net/20.500.12680/02871321g
geographic Pacific
geographic_facet Pacific
genre Crassostrea gigas
genre_facet Crassostrea gigas
op_relation http://hdl.handle.net/20.500.12680/02871321g
op_doi https://doi.org/20.500.12680/02871321g
_version_ 1814714937090506752

Similar Items