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Good News for Native Trout?

Joint Research by SRS and USGS Reveals Unexpected Resilience in Mountain Streams

By Sarah Farmer

Photo by USDA Forest Service, Coldwater Fisheries research team

"This will give managers
an effective tool to help prioritize locations for native brook trout survival."

At Stream Edge

Steve Moore

Steve Moore is a fisheries biologist and land manager in the Great Smoky Mountains National Park in East Tennessee. View an interview with Steve Moore.

A Land Manager Restores Native Trout

Land managers often act as the primary champions and protectors of a plant, animal or ecosystem, and to native eastern brook trout, Steve Moore, a fisheries biologist ...

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At Stream Edge

A Land Manager Restores Native Trout


Land managers often act as the primary champions and protectors of a plant, animal or ecosystem, and to native eastern brook trout, Steve Moore, a fisheries biologist and land manager in the Great Smoky Mountains National Park in East Tennessee, is a hero. Moore's spent almost 30 years restoring native trout habitat in the Park, across the Southeast, and throughout the country. "In the past, we haven't made the best management decisions when it comes to native trout," says Moore."But they're part of our heritage, and it's wise to protect and preserve these natives wherever we can."

"Native eastern brook trout are found all over the Southern Appalachians, and a lot of their range was my backyard playground, growing up," says Moore."So basically I get to work in the lands that I grew up playing in. I got my dream job at home." Moore's "office" encompasses the 814 square miles of America's most-visited national park, world-renowned for its unique and diverse aquatic ecosystems—and for the modern challenges to those ecosystems. When nonnative rainbow trout were introduced in the late 19th century to degraded streams, brook trout were forced to retreat to higher elevations. Some of these streams are now uninhabitable because of airborne acid deposition, leaving brook trout sandwiched between threats.

Native brook trout, or brookies, are also very sensitive to water temperatures, and require cold waters, below 70 degrees. With most climate change models in agreement that air temperatures will spike over the next century, brookies need a hand.

Moore and his team, along with volunteers and partners, have restored brook trout habitat all over the park; more than a fifth of the brook trout waters there are the fruit of their efforts. Each restored site historically hosted brook trout, has a natural barrier that prevents nonnative brown and rainbow trout from invading, and is small enough for successful and efficient removal of nonnative fishes like rainbow and brown trout. Moore's current project spans 7 miles of Lynn Camp Prong, a headwater stream in the park. "If this venture is successful, it will be the biggest contiguous watershed for brook trout in the park," says Moore. The restoration project involves clearing the stream of nonnative trout and re-populating it with native eastern brook trout.

Moore grew up fishing, but these days, it's only rainbow and brown trout that end up on his dinner table. "I've worked so hard to restore and save brook trout that it'd be hard to catch one and kill it," says Moore. "I don't have that problem with rainbow and brown trout. They're fair game for the table if I want fresh trout for dinner."

Other people fishing for trout apparently feel the same way; a survey Moore took in 2007 revealed that while many anglers wanted to catch a wild native brook trout, all but a few planned to release their catches. "That was a neat thing to find out," says Moore. "I certainly didn't anticipate that reaction."

Moore regularly takes his grandchildren on fishing and hiking trips, intent on teaching them to appreciate the natural resources that surround them."If we fail to train our kids and our grandkids, we're not going to have the champions we need in the future to carry on the cause."

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Videos: Water & Fish Management

CCRC Topic: Salmon & Trout

About those involved

Andy Dolloff

Andy Dolloff is the Team Leader for Aquatics, USFS Southern Research Station. For more informationcall Andy Dolloff at 540-231-4864.

Sarah Farmer Sarah Farmer is a student at the University of North Carolina, Asheville, majoring in Biology and science writing intern at the Southern Research Station.

With this story of the eastern brook trout, the CCRC starts a series unfolding the stories of climate change. Unlike research reports or topic briefings, these stories explore the experiences of land managers, scientists, and others as they study and cope with a changing climate.

It's not always the case that the "further research" scientists call for in their journal articles brings good news, but sometimes collecting more detailed data yields the unexpected. Results from collaborative research by the US Forest Service and the US Geological Survey may not only bring a sigh of relief to native trout lovers but also provide a precise planning tool for land managers in the Appalachian region faced with rising temperatures from climate change.

The Appalachian Mountains stretch from Maine to northern Georgia in an area crisscrossed by a web of headwaters, creeks, and rivers that teem with fish, crayfish, mussels, salamanders, and a host of aquatic insects. Anglers are drawn to the high-elevation streams of the mountains because of the native eastern brook trout that inhabit the cold, clean waters. Brook trout require cold water for survival, and cannot thrive in streams that warm beyond 70 degrees. Suitable eastern brook trout habitats are scattered along the spine of the Appalachian Mountains, with the southernmost populations of brook trout found in northern Georgia.

Dubbed brookies by locals, adult brook trout boast olive-green sides speckled with golden squiggles and red spots surrounded by blue-gray spheres. Brookies are beautiful, and they're the Southeast's only native trout—though they have company these days. Beginning in the late 1800s, people started stocking mountain streams with nonnative rainbow and brown trout brought in from the western United States and Europe. Since then, nonnative trout have flourished, often crowding out the native brook trout.

Federal agency managers, conservationists, anglers, and people in general have coalesced around the brook trout's plight in relation to the robust nonnative trout, in some cases completely removing all trout from a stream and then starting over with brookies. But in 2006, Forest Service research on the possible effects of rising air temperatures on stream water temperatures sent new ripples of alarm through the community of land managers and trout advocates. The research found that over the next century projected rises in temperature might leave only very high mountain headwaters as refuges for coldwater-dependent native brook trout.

The dismal projection relied on widely accepted assumptions about the relation between air and water temperatures; if the air temperature rises by a degree, the water temperature will follow suit, rising by approximately 0.8 of a degree. Since most climate change models predict a 4 degree rise in air temperature over the next century, this would mean a 3.2 degree increase in stream temperatures. For trout and other coldwater creatures that are already at the southern-most extent of their range, this temperature increase could make their homes too hot for comfort—and maybe for survival.

This seemed like very bad news, but it got Forest Service researcher Andrew Dolloff thinking about factors other than temperature rise—slope aspect, forest canopy, and elevation—that aren't taken into account in the large-scale climate models used in the trout habitat studies. "The models used in the coldwater fish habitat studies assumed a pretty close correspondence between rising air and water temperatures," says Dolloff. "My colleagues and I decided to try to verify this—and to provide some very specific information for future planning—by measuring air and water temperatures in streams that fell within patches identified as brook trout habitat."

What really keeps streams cool?

Dolloff claims he's been a friend to fish since he was floating in the womb. Growing up in Boothbay Harbor, a small town on the Maine coast, he often went with his father to the Bureau of Commercial Fisheries Laboratory, where the older Dolloff worked in maintenance. Andy, who now leads the Forest Service Southern Research Station Coldwater Fisheries team, pursued his fish passion at the University of Maine, studying the biology of ocean fishes until seasickness derailed his plans. "

After a couple of ocean voyages I realized that I would have to rethink my focus," says Dolloff. "So I shifted to land-based aquatics and ended up in coldwater fisheries in Blacksburg, Virginia. I wouldn't be anywhere else."

When studies, including one by researchers in Dolloff's team, suggested drastic reductions in the historical range of native eastern brook trout based on predictions of temperature rise from the major climate change models, scientists from the National Forest System and the Forest Service Southern and Northern Research Stations, launched a pilot study. Fifty study sites were randomly selected from habitats that presently or historically hosted brook trout populations. Mark Hudy, Forest Service Washington Office National Aquatic Biologist at James Madison University, identified the habitats or patches, which are located on both public and private lands. The researchers adorned each of the 50 study sites with two thermographs (digital thermometers) one in the water at the outlet of a brook trout stream and another dangling from a nearby tree.

Day in and day out, the thermographs record air and stream temperatures every 30 minutes. Originally the researchers intended to show how factors like slope and aspect might affect stream temperature, but were in for a surprise when they got readings back from the pilot study in Virginia. "Even in the 50 sites we used for the pilot study it was soon apparent that water temperatures are not always coupled with air temperature, sometimes not at all," says Dolloff. "This suggests that it's really a local matter, and that brook trout might not be as vulnerable to climate change as first projected." During the pilot study, Dolloff began collaborating with Paul Angermeier, a scientist with U.S. Geological Survey (USGS) also based in Blacksburg, to start developing models that combine stream information from the Forest Service and the USGS, a task long in the making and now in process because of a joint climate change research project launched in 2010. For Dolloff it was an easy fit: he and Angermeier have a 25-year history of collaboration.

A wider lens

What started in Virginia has spread, both conceptually and geographically and grown into a full collaboration between the Forest Service and USGS. The study now includes 204 sites and extends from Georgia to Maryland, and the first full year of data has brought good news for trout; the relationship between water and air temperature is relatively insensitive, which means that a rise in air temperature does not lock in a corresponding rise in water temperature. "That said, we also found that the correspondence between water and air temperatures varies a lot from one site to the next," says Dolloff, "It really matters where you are." In sites with a larger drainage area, for example, the water temperature tends to be much more sensitive to air temperature."

To see if the relationships they found in cold water apply to warmwater streams, the scientists started looking at air and water temperatures in the Piedmont and Coastal Plain. This part of the project will make use of the extensive data USGS has collected in this area, and will combine models from both agencies to look at how ecosystem services—basic needs provided by the environment—might be affected as temperatures rise in the region.

For both this and the cold water part of the study, USGS scientists are also looking at fish as part of a larger universe of ecosystem services. Their approach to ecosystem services goes beyond social benefits like fishing, swimming and boating, and includes the provision of clean water and the processes that regulate stream temperatures. Although essential to human and fish quality of life these ecosystem services are difficult to quantify in dollar amounts. The USGS approach to ecosystem services is unique in that it aims to bridge ecosystem service and fishery domains to look at how services flow from nature to human society, the ecosystem's capacity to provide services, and the degree to which the services are used by people.

This comprehensive, inter-agency collaboration will eventually wed data reflecting stream sensitivity to rises in air temperature with maps, giving land managers precise and science- based windows into the future temperatures of specific streams. Knowing which factors protect streams from rising temperatures can inform management strategies for the surrounding lands, and provide managers and planners with tools to look at how well different strategies will work under climate change and in relation to projected land use patterns.

Last but not least, back to the fish….

For the latest addition to the coldwater streams study, Andrew Rypel, Fisheries Professor at Virginia Tech, and graduate student Bonnie Myers, new members of Dolloff's team, will start summer 2012 collecting detailed information about the abundance, growth, and health of trout in study streams in 20 habitats representative of the study region that extends from Maryland to Georgia. Their work will focus on what's called fish production, which includes the number of fish in each stream and their age, length, and weight. Coupled with information such as the composition of the stream beds, the type and amount of cover, and water chemistry fish production will give the researchers a more accurate picture of the factors that influence the quality of stream habitats.

While difficult to obtain and time-consuming, fish production is the most comprehensive measurement of how fish are doing and whether they're thriving or just getting by. "Fish production will bring our models and projections to life, literally put flesh on the bones," says Dolloff.

Genetic analyses will be part of the fish production work too, giving researchers an idea of whether inbreeding is occurring and offering a general snapshot of how much genetic diversity is within and among population, and how closely related 'trout families' across streams and watersheds are.

This information is particularly pertinent if temperature in streams is changing. Healthy streams can host at least 30 to 40 native trout families, each of which spawns in the fall. The eggs incubate over the winter, emerging as fry in the spring. "This life cycle is susceptible to disruption from climate change, as warm winter temperatures may cause the trout to emerge too early, when there's nothing to eat, and many could starve," says Dolloff. "It looks like the winter effects of climate change's effects could impact coldwater species, but the resistance of stream temperatures to changes in air temperature we've found promises some protection."

Project scientists will use the data from the coldwater sites to identify, rank and map the resiliency of the mountain watersheds in the study area to climate change. "This will give managers a n effective tool to help prioritize locations for native brook trout survival," says Dolloff. "The unexpected good news is that it looks as if there are many streams that can provide resilient habitat over the next century."

For More Infomation:

To see the stream monitoring sites, go to: https://www.google.com/fusiontables/DataSource?snapid=S3753137OpY.

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