Using genomics to design and evaluate the performance of underwater forest restoration

Georgina Wood; Ezequiel M Marzinelli; Adriana Vergés; Alexandra H Campbell; Peter D Steinberg; Melinda A Coleman

doi:10.1111/1365-2664.13707

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Using genomics to design and evaluate the performance of underwater forest restoration

Journal article

Peer reviewed

Using genomics to design and evaluate the performance of underwater forest restoration

Georgina Wood, Ezequiel M Marzinelli, Adriana Vergés, Alexandra H Campbell, Peter D Steinberg and Melinda A Coleman

Journal of Applied Ecology, Vol.57(10), pp.1988-1998

2020

DOI: https://doi.org/10.1111/1365-2664.13707

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Abstract

genetic diversity

seaweed

SNPs

kelp

marine ecology

restoration

climate change

Restoration is an emerging intervention to reverse the degradation and loss of marine habitat‐formers and the ecosystem services they underpin. Current best practice seeks to restore populations by transplanting donor individuals chosen to replicate genetic diversity and structure of extant, nearby populations. However, genetic characteristics are rarely empirically examined across generations, despite their potential role in influencing restoration success. We used genomics to design a restoration program for lost underwater forests of Phyllospora comosa, a dominant forest‐forming macroalga that went locally extinct from reefs off Sydney, Australia. Population genetic diversity and structure of nearby extant populations informed choice of donor sites. We tested whether donor provenance influenced adult transplant survival, condition (via metrics of epibiosis) and the genetic characteristics of recruits at restoration sites. Extant populations of Phyllospora within a 100‐km radius of Sydney comprised three distinct genetic clusters with similar levels of genetic diversity. We transplanted reproductive adults from two of these sites, with the aim of restoring five Phyllospora forests with levels of genetic structure and diversity similar to donor populations. Donor provenance influenced survival and condition of transplanted adults and recruitment levels varied significantly among restoration sites. Yet, recruitment was rapid and genetic diversity and structure of the F1 generation resembled extant populations. This likely occurred because transplanted individuals reproduced synchronously and rapidly post‐transplantation, prior to mortality of adult donor transplants. Synthesis and applications. As restoration and the need to ‘future‐proof’ marine ecosystems increase globally, it will be critical to understand and harness the role of donor provenance, genetic diversity and structure in restoration success. By incorporating ecological and genomic data into restoration design and assessment, this study demonstrates that evidence‐based selection of macroalgal donors can result in F1 generation recruits with similar levels of genetic diversity and structure as extant populations, despite an effect of provenance on transplant survival and condition. This study also highlights the need for ongoing refinement of transplantation techniques to ensure future recruitment success. As restoration and the need to ‘future‐proof’ marine ecosystems increase globally, it will be critical to understand and harness the role of donor provenance, genetic diversity and structure in restoration success. By incorporating ecological and genomic data into restoration design and assessment, this study demonstrates that evidence‐based selection of macroalgal donors can result in F1 generation recruits with similar levels of genetic diversity and structure as extant populations, despite an effect of provenance on transplant survival and condition. This study also highlights the need for ongoing refinement of transplantation techniques to ensure future recruitment success.

Details

Title: Using genomics to design and evaluate the performance of underwater forest restoration
Authors: Georgina Wood (Corresponding Author) - The University of Sydney
Ezequiel M Marzinelli (Author) - Sydney Institute of Marine Science
Adriana Vergés (Author) - UNSW Australia
Alexandra H Campbell (Author) - University of the Sunshine Coast, Queensland, School of Health and Sport Sciences - Legacy
Peter D Steinberg (Author) - Sydney Institute of Marine Science
Melinda A Coleman (Author) - National Marine Science Centre
Publication details: Journal of Applied Ecology, Vol.57(10), pp.1988-1998; 11
Publisher: Wiley-Blackwell Publishing Ltd.
Date published: 2020
DOI: 10.1111/1365-2664.13707
ISSN: 1365-2664; 0021-8901
Grants: Global threats to kelp forests from heatwaves, herbivores and diseases, DP170100023, Australian Research Council (Australia, Canberra) - ARC
The effect of microbial diversity vs function on marine holobionts, DP180104041, Australian Research Council (Australia, Canberra) - ARC
Restoration of Sydney's key habitat forming seaweed forests, LP160100836 , Australian Research Council (Australia, Canberra) - ARC
Grant note: Ecological Society of Australia (RG172379)
Organisation Unit: School of Health - Biomedicine; School of Health and Sport Sciences - Legacy; School of Health and Behavioural Sciences - Legacy
Language: English
Record Identifier: 99482308702621
Output Type: Journal article

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Collaboration types: Domestic collaboration; International collaboration
Web Of Science research areas: Biodiversity Conservation; Ecology

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