An Experimental Framework for Selectively Breeding Corals for Assisted Evolution

Coral cover on tropical reefs has declined during the last three decades due to the combined effects of climate change, destructive fishing, pollution, and land use change. Drastic reductions in greenhouse gas emissions combined with effective coastal management and conservation strategies are essen...

Full description

Saved in:
Bibliographic Details
Published in:Frontiers in Marine Science 2021-05, Vol.8
Main Authors: Humanes, Adriana, Beauchamp, Elizabeth A., Bythell, John C., Carl, Mitch K., Craggs, Jamie R., Edwards, Alasdair J., Golbuu, Yimnang, Lachs, Liam, Martinez, Helios M., Palmowski, Pawel, Paysinger, Faith, Randle, Janna L., van der Steeg, Eveline, Sweet, Michael, Treumann, Achim, Guest, James R.
Format: Article
Language:English
Subjects:
Breeding
Climate change
Climate effects
Coastal zone management
Colonies
Conservation
Coral reefs
Corals
Destructive fishing
Emissions
Endangered & extinct species
Evolution
Fishing
Greenhouse effect
Greenhouse gases
growth
Heat resistance
Heat tolerance
Individual rearing
Laboratories
Land pollution
Land use
larval rearing
nursery
outplanting
Ova
Pollution effects
Population
Reefs
Rehabilitation
Restoration
restorative efforts
Selective breeding
Survival
Temperature tolerance
Tropical climate
Wildlife conservation
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Coral cover on tropical reefs has declined during the last three decades due to the combined effects of climate change, destructive fishing, pollution, and land use change. Drastic reductions in greenhouse gas emissions combined with effective coastal management and conservation strategies are essential to slow this decline. Innovative approaches, such as selective breeding for adaptive traits combined with large-scale sexual propagation, are being developed with the aim of pre-adapting reefs to increased ocean warming. However, there are still major gaps in our understanding of the technical and methodological constraints to producing corals for such restoration interventions. Here we propose a framework for selectively breeding corals and rearing them from eggs to 2.5-year old colonies using the coral Acropora digitifera as a model species. We present methods for choosing colonies for selective crossing, enhancing early survivorship in ex situ and in situ nurseries, and outplanting and monitoring colonies on natal reefs. We used a short-term (7-day) temperature stress assay to select parental colonies based on heat tolerance of excised branches. From six parental colonies, we produced 12 distinct crosses, and compared survivorship and growth of colonies transferred to in situ nurseries or outplanted to the reef at different ages. We demonstrate that selectively breeding and rearing coral colonies is technically feasible at small scales and could be upscaled as part of restorative assisted evolution initiatives. Nonetheless, there are still challenges to overcome before selective breeding can be implemented as a viable conservation tool, especially at the post-settlement and outplanting phases. Although interdisciplinary approaches will be needed to overcome many of the challenges identified in this study, selective breeding has the potential to be a viable tool within a reef managers toolbox to support the persistence of selected reefs in the face of climate change.
ISSN:2296-7745
2296-7745
DOI:10.3389/fmars.2021.669995