Life-cycle models for the diverse and plastic Oncorhynchus mykiss: challenges and opportunities
Neala Kendall*§, Rich Zabel§, and Tom Cooney§
*Washington Department of Fish and Wildlife §NOAA Fisheries, Northwest Fisheries Science Oncorhynchus mykiss life history tactics and population dynamics • Life history strategies influenced by environmental and anthropogenic factors
• Life-cycle models used to better understand strategies, evaluate population dynamics spatially and temporally
Jonny Armstrong John McMillan Purpose of a life-cycle model
• Questions to answer using the model: – Is anadromy expected to persist into the future? – Under what environmental conditions will O. mykiss be resident or anadromous? – What life history stages represent population “bottlenecks?” – What patterns of anadromy and residency will we see given different freshwater habitat mitigation actions? O. mykiss life cycle models
Freshwater Ocean
Migration Decision to smolt to ocean as Mortality steelhead Immature trout Growth fish Growth Mature Maturing fish fish Maturing fish Mature Maturation fish Immature fish Maturation Mature fish Immature Spawning Mature Fishing fish Mature fish migration fish and Decision to natural return & spawn Spawning mortality
Natural Natural mortality mortality Ocean Natural mortality migration
Modified from Theriault et al. 2008 Existing models to help
1. Yakima River, WA anadromous/resident O. mykiss abundance and reproductive success life- cycle models (I. Courter & C. Frederiksen et al.) 2. Anadromy/residency and smolt age decision for O. mykiss (originally developed for CA populations; Satterthwaite et al. 2009, 2010) 3. Chinook and O. mykiss life-cycle matrix models for Interior Columbia River basin (but only anadromous component; ICTRT and Zabel 2007) Yakima River O. mykiss Fry Environmental Conditions life-cycle models Food Supply Temperature Flow Growth (bioenergetics) • Use freshwater food Body Size Territory Size Abundance Habitat Area (competition) (PHABSIM & 2D modeling)
supply, flow, and Capacity
temperature to predict Survival fish growth, survival, Cross-Ecotype capacity, and reproductive Exchange success by life history Marine Survival Freshwater Survival tactic Fecundity
Anadromous Reproductive Resident Spawners Success Spawners Courter et al. 2009 Model
predictions Anadromous Resident
Courter et al. 2009 Anadromy/residency life-cycle model for O. mykiss
• Based on fish emergence date, freshwater growth, survival, fecundity, and overall fitness • Predict maturation/residency and smolt age decision
Satterthwaite Maturation decision smolting et al. 2009, 2010 decision Model predictions
Maturity of age-0 females
mature
• Predict maturation/ residency and smolt age decision wait, smolt at age 0
mature Growth rate (mm/day) Growthrate
wait, smolt at age 1
Satterthwaite et al. 2009, 2010 Emergence date O. mykiss matrix models for Interior Columbia River basin • Steelhead-only life-cycle model • Beverton-Holt functions to include density-dependent survival in freshwater • Components (adjusted in different “scenarios”):
– Downstream survival (based on hydropower corridor passage)
– Estuary and early marine survival (based on climate conditions) – Later marine survival – Harvest, upstream survival – Overwinter survival in fw
ICTRT and Zabel 2007, Zabel et al. 2013 Interior Columbia River basin populations
• Rapid River (Little Salmon River) • Potlatch River • Catherine Creek • Umatilla River • Toppenish Creek • Naches River • Satus Creek • Upper Yakima River
Photo: John McMillan Example model run—Umatilla River
6000
5000
4000
3000
2000 spawners.raw[, , 3] , spawners.raw[,
1000
Population abundance Population 0 50 fish 20 40 60 80 100 Years into the future Model predictions (under baseline scenarios)
• Abundance decreased over time for Yakima River basin and Umatilla River populations
• Abundance increased over time for Potlatch River, Catherine Creek, & Rapid River populations Model predictions (under varying scenarios)
• Changes in habitat, upriver survival, and estuary/early ocean conditions resulted in largest spawner abundance changes • Changes in habitat resulted in greatest changes in quasi-extinction probability • Changes in harvest rates resulted in smaller abundance and extinction probability changes Population-specific model predictions under various scenarios—Umatilla River
Estuary and early Survival through the
marine survival hydropower corridor
after 100 100 years after Population abundance abundance Population
Survival through the Habitat (overwinter/ hydropower corridor prespawning survival) Population-specific model predictions under various scenarios—Umatilla River
Estuary and early Estuary and early
marine survival marine survival
after 100 100 years after Population abundance abundance Population
Later marine survival Harvest rate Future work
• Combine ICTRT and Zabel matrix model with Courter & Frederiksen et al. freshwater habitat conditions determinants and Satterthwaite et al. model of anadromy/residency decision
Photos: John McMillan Habitat considerations need to be incorporated
• First establish fish-specific side of the life-cycle model • Then incorporate freshwater habitat considerations into model • Understand how habitat changes (climate change and human modifications including restoration) may affect abundance and viability Incorporating habitat restoration into the models
• Develop landscape-to-habitat functional relationships • Develop habitat-to-fish relationships • Model habitat quality (e.g., flow and temperature) and quantity using land- use and geomorphic characteristics to estimate fish capacity and survival Bartz et al. 2006, Scheuerell et al. 2006, Beechie et al. 2006 Acknowledgements • National Research Council Postdoctoral Fellowship Program • Interior Columbia TRT life-cycle modeling group • Ian Courter (Mt. Hood Consulting), Chris Frederiksen (Yakama Nation), Ethan Crawford (WDFW), ODFW La Grande office, Brett Bowersox (IDFG), and others who supplied data • NOAA Northwest Fisheries Science Center • WDFW, especially Erik Neatherlin, Jeremy Cram, Andrew Murdoch, and Thomas Buehrens
Photo: John McMillan Questions?
Oncorhynchus mykiss: one (two?) cool fish
Photo: John McMillan Oncorhynchus mykiss: one (two?) cool fish
• Very diverse life history including migration tactics (“partial migration”)
• Valuable recreational and commercial fisheries
• Many natural populations have declined in abundance and life history diversity over the past century, are ESA listed
Photos: Jonny Armstrong Population-specific model predictions under various scenarios—Umatilla River
Estuary and early Later marine
marine survival survival
Population abundance Population
Habitat (overwinter/prespawning survival)