Quick Summary
- New tech may transform how imperiled species are considered for protection
- Early migrating salmon 鈥 spring chinook and summer steelhead 鈥 evolved independently
- If lost, early migrating salmon not expected to re-evolve, as previously thought
- Study shows critical gaps in current management of vulnerable species
New technologies for analyzing DNA may transform how imperiled species are considered and managed for conservation protection, according to and led by the University of California, Davis.
These technologies can be applied to a wide range of species around the world 鈥 from mushrooms to walruses 鈥 but the study focuses on two iconic species of Pacific salmon: steelhead and chinook. While steelhead are a legendary sport fish, chinook are considered the workhorse of the West Coast salmon industry.
Spring chinook, summer steelhead can鈥檛 re-evolve easily
Using an inexpensive, efficient DNA analysis method called RAD (restriction-site associated DNA), developed by 嘿嘿视频 Assistant Professor Mike Miller, the authors found that early migrating salmon populations (called spring chinook and summer steelhead) depend on a single gene. The version of the gene that makes them migrate early evolved only once in each species.
This indicates that the existence of spring chinook and summer steelhead depends on the existence of the right version of the gene, and this genetic variant cannot be expected to easily re-evolve if lost. Spring chinook and summer steelhead are highly prized by fishermen, considered essential by indigenous cultures in the Pacific West, and ecologically important to watersheds.
The study鈥檚 findings are contrary to the previously held view that early migration evolved many times within each species, independently in different watersheds. If that were the case, and early migrating fish were lost due to habitat destruction or other factors, they could quickly re-evolve if habitats were restored. This view made it seem like the decline of early migrating populations wasn鈥檛 particularly concerning.
Management implications
The study鈥檚 findings carry significant management implications. In most watersheds, spring chinook and summer steelhead are currently not protected independently from their later-migrating counterparts (fall chinook and winter steelhead) even though early migrating populations are on the brink of extinction in most locations where they haven鈥檛 already been lost. Fall chinook and winter steelhead populations are relatively healthy in most watersheds.
鈥淣ow that genomic technologies allow us to uncover the genetic basis and evolutionary history of important adaptations, we need to begin using this information to improve conservation policies,鈥 said Miller. 鈥淐urrent conservation and management strategies are simply not sufficient to protect some types of irreplaceable biodiversity, which can be economically, culturally and ecologically beneficial.鈥
The study indicates that protecting specific adaptive variation 鈥 such as distinct run timings in Pacific salmon 鈥 can be necessary to prevent the permanent loss of important biodiversity.
Such analyses set the stage for new genetic technologies to play a role in improving conservation strategies and determining how to prioritize populations for protection under the Endangered Species Act.
The study was funded by the 嘿嘿视频 Department of Animal Science.
Media Resources
Kat Kerlin, 嘿嘿视频 News and Media Relations, 530-750-9195, kekerlin@ucdavis.edu
Michael Miller, 嘿嘿视频 Animal Science, 530-304-4719, micmiller@ucdavis.edu