The Central Valley Salmonid Story: Six Million Years in the Making

For over six million years, salmon and steelhead (known as salmonids) have returned to the California Central Valley. After swimming under the Golden Gate Bridge and through the San Francisco Bay, adult salmonids swim hundreds of miles up the Sacramento or San Joaquin Rivers. Before dams were built, three out of the five salmonid species swam from the Central Valley into high-elevation, cold-water streams within the Sierra Nevada, southern Cascades, and Coastal Mountain ranges to finish their life cycles. Unfortunately, barriers such as dams cut-off salmonids from their home streams. When salmonid populations decrease, the effects are felt across the ecosystem—everything from microbes to humans feels the disconnection between the rivers and the ocean. Governmental agencies and their partners are teaming up to restore Central Valley salmonid populations by reconnecting them to their habitats and putting them back into high-elevation streams.


SALMONIDS: A CONNECTION BETWEEN THE OCEAN AND THE MOUNTAINS
Salmon and steelhead are two closely related fish that are complicated and fascinating. Together, they form a group called salmonids. SALMONIDS A group of fish that spawn in fresh water and have adipose fins. Some, like steelhead and salmon, live in the ocean as adults and migrate to the river to spawn.
Salmonids are anadromous fish, meaning they are born in rivers and

ANADROMOUS FISH
Fish that are born in rivers (freshwater), then spend their adult lives in the ocean (saltwater), and then return to rivers to reproduce. then migrate hundreds of miles from rivers to the ocean and back again, almost to the exact spot they were born, to reproduce and then die. Salmonids are a connection between the ocean and the mountains. In California (United States), anadromous fish evolved to migrate through specific rivers along the Central Valley and during di erent seasons. The Central Valley is an unusual place to find a fish often found in the ocean because the water is very di erent from the water in the ocean. The complex life cycle of salmonids helps them survive these di erences, but also exposes them to many threats that could lead to their extinction. Their extraordinary journey through diverse habitats makes these fish important to many di erent ecosystems throughout California. When given enough water and correct temperatures, salmonids have the ability to adapt and thrive in the rivers of the Central Valley [ ]. Since the early 's California's Central Valley has changed so much that scientists are not sure how much longer salmonids will survive. But, if people act quickly, we can still help these important species survive and thrive once again.

SALMONIDS EVOLVED WITH THE CALIFORNIA LANDSCAPE
The Sacramento and San Joaquin Rivers in the California Central Valley may seem like strange places to find a fish that spends most of its life in the ocean, given the Central Valley's distance from the ocean and high temperatures during the summer months. Yet, salmonids have lived there for millions of years. When a particular group of salmonids migrates together from the ocean to freshwater, it is called a run. Each

RUN
The time of year a salmonid travels from the ocean to the river. The Central Valley has four runs of salmon (winter, spring, fall, and late-fall) and one of steelhead. species' run occurs at a di erent time of the year, the same way some schools have di erent times for lunches so that the entire school is not using the cafeteria at the same time. Run timing divides Central Valley Chinook salmon into four special groups from which their names are based: fall-run, late fall-run, spring-run, and winter-run ( Figure ). The migration timing of the late-fall Chinook salmon run overlaps with that of Central Valley steelhead.
Adult fall-run salmon migrate into rivers during the fall when temperatures begin to drop. After migrating, they immediately begin building nests (also called redds) and spawning (laying eggs) in rivers SPAWNING When a female fish releases her eggs into her rock nest (called a redd). at lower elevations on the Valley floor. Adult winter-and spring-run salmon migrate into the rivers in the Central Valley while temperatures are still cool. When these salmon spawn in the late spring and summer, their eggs and juveniles need to be in cooler water than is found in the rivers. They used to spawn in high-elevation mountain streams, where water is kept very cool and clean by melting snow. Access to many of these cool mountain streams was blocked by dams ( Figure ). So, now these salmon are trapped! Winter-run must spawn in less preferred habitat downstream of a dam in the Sacramento River, while spring-run spawn in less than ideal habitats in either the Sacramento or San Joaquin Rivers. If these rivers become too hot during summer, winter-run and spring-run eggs will die. Unfortunately, this has already happened during the long drought of -Without access to naturally cold, high-elevation streams, winter-and spring-run salmon must depend on people to provide them with the cool, clean water they need to survive [ ]. Today, winter-and spring-run salmon are less abundant than fall-run salmon because of the dams ( Figure ).

SALMONIDS AT RISK OF EXTINCTION: FISH IN HOT WATER
Salmon must use their natural instincts to navigate the rivers of the Central Valley that connect San Francisco Bay to mountain streams.
The key for winter-and spring-run salmon to successfully complete their journey is the water produced by seasonal storms. Seasonal storms allow the rivers and streams to swell and fill their banks. This extra water helps fish get to areas that are out of reach during the dry season, because areas with boulders, steep waterfalls, or other obstacles are flooded allowing fish to migrate upstream. Without this stormwater, salmonids are trapped on the Valley floor where the water is too hot. Sadly, many of these fish die from the high temperatures before they can return to and spawn in the mountain streams where they were born.
Dams control floods, create electricity, and store water for people living in cities and for crops. But they also block winter-and spring-run salmon and steelhead from reaching the habitats they need to survive [ ]. Even a small dam, road crossing, or bridge can create an impassable barrier for a two-foot-long fish. Many dams include special passages for fish to swim up on their own, and sometimes scientists trap fish and move them past the dam in trucks full of water [ ]. But the dams in the Central Valley currently do not have any way for fish to get around them, and they block about % of winter-and spring-run spawning habitat (Figure ). As a result, these fish are limited to living only in habitats below dams, which puts their populations at risk of extinction [ ].
Dams also negatively change the movement of water, gravel, and wood debris between the mountains and the Central Valley, which fish all depend on. Dams trap the seasonal storm water that helps signal salmonids to swim into the Valley from the ocean and prevent streams from swelling with water, taking away the salmonids' access to the high elevation habitats they once used to survive the hot summer temperatures.

SALMONIDS ARE IMPORTANT FOR THE ENTIRE ECOSYSTEM
From microbes to humans, at least di erent species depend on salmon. Salmonids are a keystone species. Keystone species are

KEYSTONE SPECIES
A species with a large e ect on its ecosystem. The presence or absence of a keystone species a ects all the creatures in the ecosystem. like the glue on an art project-without them, the whole thing falls kids.frontiersin.org September | Volume | Article |

Figure Figure
The apart. An ecosystem will not survive without its keystone species. Salmonids link the rivers to the ocean by collecting ocean nutrients in their bodies as they eat and grow. They bring those nutrients with them when they return to the rivers to reproduce. Unlike salmon, which die after spawning, steelhead can return to spawn multiple times, delivering nutrients again and again. The dead bodies of adult salmonids release their ocean nutrients, enriching the habitats and food chains of the forests and mountains, the way fertilizer enriches a garden, improving soils and helping trees and plants near salmonid streams grow. Areas like the Central Valley have relied on salmonids to deliver these essential nutrients to the landscape for over six million years. Traditional/Indigenous cultures from the Central Valley recognized the role salmon play in the ecosystem and honor them through traditions, making salmon important to past and current residents in the Central Valley. Unfortunately, areas above Central Valley dams have been without those ocean nutrients for almost a century, putting the ecosystem at risk. California Central Valley and is one of the most endangered species in the United States, while spring-run Chinook salmon and steelhead are threatened.

THREATENED SPECIES
A species that is likely to become endangered in the foreseeable future (see endangered species).
The National Oceanic and Atmospheric Administration's (NOAA) Fisheries branch of the government is working to conserve and manage coastal and marine ecosystems and resources in the United States. NOAA Fisheries established three criteria that salmonid populations must meet to recover and be taken o the endangered species list [ , ]. First, salmonid populations must be able to survive changes in annual rainfall caused by climate change. Too much or too little water can be fatal during the wrong time of the year. Second, enough adults must return and spawn each year to support the population of the next generation. Third, there must be multiple salmonid populations in di erent rivers and streams, so catastrophic events such as diseases or fires don't wipe out the entire species at once [ ].
NOAA Fisheries and its partners are working to help Central Valley salmonid populations by finding new places for them to live, helping them move around dams, and looking for other ways to create resilience to climate change [ , ]. You can help, too! Salmonids can

RESILIENCE
The capacity of an ecosystem or organism to respond or adapt to a disturbance by resisting damage and recovering quickly.
be supported through community e orts as simple as picking up trash, planting trees, capturing rainwater for your garden, or saving water during your shower. Our job at NOAA Fisheries is to help scientists and land managers find new ways to help salmonids return home. By bringing fish back to high-elevation streams that are naturally cooler and less populated, we will help these fish survive climate change. Creating resilience involves working together with the people of the Central Valley to use and share water in ways that work for everyone, including the fish. It is everyone's responsibility to reconnect these salmonids to the rivers and streams they spent six million years evolving to inhabit. Afterall, this is their home!

Recovery Plan for the Evolutionarily Significant Units of Sacramento River Winter-Run Chinook Salmon and Central Valley Spring-Run Chinook Salmon and the DPS of California
Joaquin River. She is an education and outreach coordinator and seeks to bring a salmon culture to the Central Valley of California through collaborative projects and partnerships. Hilary graduated from the University of California at Santa Cruz with a B.S. in marine biology and Louisiana State University with an M.S. in oceanography. Hilary has also spent time teaching SCUBA, doing research on coral reefs, and working as an observer on fishing boats in Alaska. *hilary.glenn@noaa.gov

STACIE FEJTEK
Stacie Fejtek (Smith) currently works in the Central Valley with NOAA Fisheries West Coast Region on hydropower projects and reintroductions of salmonids to help with the recovery of endangered and threatened fish species. Stacie focuses on using interdisciplinary and network-based management strategies for addressing issues from river headwaters to the ocean. Stacie's approach is rooted in a strong academic and scientific foundation with a B.S. in Aquatic Biology from the University of California Santa Barbara, a M.S. in biology from San Diego State University, and doctoral work at the University of California Los Angeles in the multidisciplinary Environmental Science and Engineering Program. *stacie.smith@noaa.gov JACOB RENNERT Jacob Rennert is a fisheries biologist for Lynker Technologies, working with NOAA Fisheries. He is working alongside the Federal Emergency Management Agency (FEMA) to improve projects responding to natural disasters such as wildfires and floods, to help endangered and threatened salmonids and sturgeon. He graduated from the University of North Carolina Wilmington with a B.S. in marine biology and the Florida Institute of Technology with an M.S. in marine biology. Jake participated in research projects investigating tarpon, bonefish, and snook life history in Florida, Cuba, and the Bahamas. He loves playing ice hockey, skiing, and fly-fishing. *jake.rennert@noaa.gov