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December
25, 2006 Scientists can
predict how the
distance marine larvae travel varies with ocean temperature –
a key component
in conservation and management of fish, shellfish and other marine
species –
according to a new study from the Most marine life,
including
commercially important species, reproduces via larvae that drift far
along
ocean currents before returning to join adult populations. The distance
larvae
travel before maturing, called dispersal is directly linked to ocean
temperature, the researchers found. For example, larvae from the same
species
travel far less in warmer waters than in colder waters, said lead
author Mary
O'Connor, a graduate student in marine ecology in UNC's curriculum in
ecology
and the department of marine sciences in the "Temperature can
alter the
number and diversity of adult species in a certain area by changing
where
larvae end up," O'Connor said. "It is important to understand how a
fish population is replenished if we want to attempt to manage or
conserve
it." Using data from 72
marine
species, including cod, herring, American lobster, horseshoe crabs and
clams,
O'Connor and her colleagues developed a model that predicts how far
larvae
travel at a certain temperature. The predictions appear to hold for
virtually
all marine animals with a larval life cycle. "We can apply this
rule to
animals without having to go out and measure every species," O'Connor
said. "Our general model gives us a powerful new way to study larval
movement with knowledge about ocean temperature, which is much easier
to come
by. With models such as this, we can see what large-scale changes in
ocean
temperature may mean for adult populations." The study appeared
online the
week of December 25 in the Proceedings of
the National Academy of Sciences Early Edition. Knowing dispersal
distance is a
critical component for managing commercially important or invasive
species,
O'Connor said. "For many animals, the larval phase is the only chance
for
babies to get away from parents. Dispersal prevents inbreeding; for
some
species, this is a time to move from breeding ground to habitat where
they'll
mature," she said. But less than 1
percent of larvae
survive dispersal. They are consumed by predators, encounter harsh
environments
or never reach their destination and starve. For endangered species,
survival
of some animals may depend on whether offspring from parents in one
protected
area can get to another area where they are safe from harvest. "In
warmer
waters, marine protected areas may need to be closer together than in
colder
water, since in warmer water dispersal distances tend to be shorter,"
O'Connor said. While a one degree
increase in
temperature at the ocean surface means larvae will travel a shorter
distance in
warm seas, the effect is more severe when temperatures are below about
59
degrees Fahrenheit (15 degrees Celsius), O'Connor said. Along "On the up side,
shorter
dispersal can mean greater survival because the larvae spend less time
in the
water, where they are at a high risk of death. On the down side, it
could mean
they won't travel as far and may not make it to their juvenile
habitat,"
O'Connor said. The researchers
suspect
temperature plays an important role in larval dispersal because
metabolic
processes in larvae are sensitive to temperature and similar among
species.
Consequently, larvae in cold waters develop more slowly and drift
further
before beginning their next development stage because colder
temperatures cause
sluggish metabolisms.
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