| August 4, 2006 Columbia Basin Bulletin |
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Oregon State
University scientists are teaming with commercial fishermen on a new
research effort to rapidly identify the home river basin of chinook
salmon found in the Pacific Ocean using genetic testing. Their goal is to
learn more about offshore schooling behavior and stock composition of
salmon and ultimately to prevent coast-wide fishing closures. The
closures aim to protect weak stocks like those of the Klamath River
basin that may constrain an otherwise healthy fishery. Funded by the Oregon
Watershed Enhancement Board, and managed by the Oregon Salmon
Commission, the pilot project is called the Cooperative Research for
Oregon's Ocean Salmon, or CROOS. The program is
already seeing results. During the June 4
salmon fishing opener, fishermen caught chinook salmon off the An ongoing project
coordinated and funded by the National Oceanic and Atmospheric
Administration involving 10 labs from California to Alaska --
including OSU's Hatfield Marine Science Center in Newport -- has
identified unique genetic profiles for 110 different salmon
populations based on their home river basin. Scientists and
resource managers previously were unable to identify stock composition
of both wild and hatchery fish originating from the Pacific Northwest,
Canada and Alaska. Project leaders say
that this new technology allows scientists to assess the origin of an
individual fish with remarkable accuracy. "This was the
key for us to utilize the technology," said Michael Banks, an OSU
geneticist and director of the Cooperative Institute for Marine
Resources Studies, a joint Oregon State-NOAA research collaborative.
"Having a bank of DNA profiles allows us to approach 'real-time'
identification of fish. What used to take months, or even years, we've
been able to pare down to about 48 hours." During the June field
testing, participating fishermen caught chinook salmon off the Traditional efforts
to identify the origin of ocean-caught salmon came from coded wire
tags inserted into the snouts of a small percentage of hatchery fish.
Those tags were useful for determining broad-scale distributions of
stocks caught in fisheries, but revealed only the origin of select
tagged fish. The time and location of these tagged fish also have been
too general – reported by week and catch area. The coded wire tag
data weren't usually available until several months after the season
ends. Using DNA testing,
however, will allow the scientists to rapidly assess the origin of any
chinook salmon caught off the West Coast -- not just coded wire-tagged
hatchery fish -- and identify with about 95 percent accuracy its home
river system. In theory,
researchers say, they could test several salmon in schools from
different locations to see what percentage of them originate from a
weak run. "This could lead
to the introduction of some degree of in-season harvest
management," said Gil Sylvia, an OSU economist and superintendent
of the Coastal Oregon Marine Experiment Station. "Having accurate
information could lead to reducing access to some stocks in certain
areas at certain times. But it is just as likely that it could result
in decisions to open areas of the coast where higher concentrations of
harvestable fish populations are." The researchers will
compare their genetic assessment with coded wire-tagged fish to test
the efficacy of the project. Many of Oregon's
commercial fishermen, who have been shut down from pursuing their
livelihood this summer, say they are excited by the research. "I started
fishing in 1970 and this is the most optimistic I've been about any
kind of research relating to salmon," said Paul Merz, who fishes
out of Charleston. "I'm still a cynic when it comes to management
decisions. But this is the science that has been missing in all of the
policy arguments -- and it's something where you can see the immediate
results." Jeff Feldner, a
fisherman from Logsden, Ore., said that seasons are designed to
minimize the impact on the weakest runs. "The
problem," he pointed out, "is that we haven't known enough
about the fish that are out there. Using information gathered over the
summer to help predict where the fish will be next year doesn't help
the fishermen. We haven't had a way of knowing in 'real time' where
the fish are and where they've come from. Now we do." The Oregon Watershed
Enhancement Board has funded this pilot study for one year with a
$586,391 grant, which will allow 50 Oregon commercial vessels to make
a total of 200 fishing trips, and allow the scientists to run 2,000
DNA samples. As many as 90 vessel owners have expressed an interest in
participating. "We need
additional funding to continue the research," said Nancy
Fitzpatrick, lead administrator of Project CROOS and an employee of
the Oregon Salmon Commission. "One year just begins to give you
information, but it isn't enough to determine all you need to know
about salmon. Fish have fins, as they say, and they tend to move from
one location to another. "Where you find
them one year isn't necessarily where you'll find them the next." Fitzpatrick says any
changes in how the oceans are managed for salmon would come from the
Pacific Fishery Management Council, a regional council with members
from Oregon, Washington, Idaho and California, that recommends fishery
management measures to the National Marine Fisheries Service. The OSU researchers
are keeping track of the salmon through an onboard electronic
traceability system developed by the university over the past several
years. This innovative barcode system allows commercial fishermen to
log the location, date and time of the capture, as well as onboard
handling techniques, for every fish captured. Each fish harvested
by a participant receives a metal tag with a unique number and
bar-code. A website under construction will eventually allow a
consumer to access basic information about the salmon: where and when
it was harvested, by whom, and from which river it originated. Eventually, such a
tool may play a major role in marketing, according to Michael
Morrissey, director of the OSU Seafood Laboratory in Astoria, and a
principal investigator in the CROOS project. "By identifying
the river system through genetics, and being able to accurately label
a fish as 'wild,' the potential exists for fishermen to brand their
product and increase the value to consumers," Morrissey said.
"One such example is Copper River salmon, which often command
twice the market price of similar fish, because of the attributes
attached to it." As part of the study,
local salmon processors and buyers are returning some of the heads
from the specially marked fish to the OSU Hatfield Marine Science
Center, where scientists will conduct tests on their otoliths.
Otoliths are crystalline structures located in the inner ear and act
like growth rings in trees, recording not only age, but chemical
elements that provide clues to the environment in which the fish
lived. Some of the fish
stomachs will be retained by participating fishermen and given to
scientists to reveal clues about the salmon's diet, including how the
proportion of baitfish consumed might vary by season and between
areas. The fishermen involved in the project will contribute data on
oceanographic conditions where the fish were caught, including depth
and temperature. Some of the fishermen participating in the project
say they are fascinated by the science and hope it will help them
locate fish more effectively, as well as keep the season opened. "Every year, it
seems like the challenges for commercial fishermen keep getting worse
with restricted limits followed by complete closures," Merz said.
"A lot of fishermen have packed it in. But this project gives me
some hope. If it works the way it seems like it can, and if management
is adjusted accordingly -- and that's a big if -- then it might be
enough to keep me going. If not, I'll be looking for a new line of
work and get on with my life." More information on this project is available at www.projectCROOS.com |