If you leave something with a hard surface in the tropical
ocean long enough, coral will settle and grow-whether it’s a set of lost keys
or eyeglasses or a rock.
I’ve found coral growing on glass fishing floats and pieces
of marine debris—even plastic rope. It would suggest real resilience on the part of corals, but increasingly, they seem to be suffering.
(Image: On a pink background of corraline algae, two
just-attached coral juveniles form circular shapes, while a white larval coral
swims by. Credit: Hollie Putnam.)
But there’s a lot we don’t know about corals, and with coral
reefs at risk due to climate change and ocean acidification. Hawaiian
researchers are doing some of the seminal work needed to better understand some
of the issues involved. We’ll look at two of those efforts here.
In an article in the Proceedings of the Royal Society
B/Biological Sciences, authors found that there are certain genetic switches
that change during a coral’s life.
When coral is in larval form, free-floating, it doesn’t
produce a limestone skeleton. Only after it lands on a surface does the genetic
switch change positions, and it starts building rock.
“Our research on reproduction in the lace coral, Pocillopora damicornis, provided the
perfect opportunity to look at a natural on-off switch in coral
biomineralization,” said co-lead author Hollie Putnam, of the Hawai`i Institute
of Marine Biology (HIMB).
A team of researchers from University of Hawai`i, Rutgers
and the University of Haifa studied that process. A press release with more images is here.
The paper has the painful title, “Temporal
and spatial expression patterns of biomineralization proteins during early
development in the stony coral Pocillopora
damicornis.” The authors are Tali Mass, M. Putnam, Jeana L. Drake, Ehud
Zelzion, Gates, Debashish Bhattacharya and Paul G. Falkowski.
“The better we understand how corals grow, the better we
understand the way they respond to ocean acidification, rising sea surface
temperatures and pollution, and can therefore forecast and manage reefs
communities in the future,” said Ruth Gates, director of the Hawai`i Institute
of Marine Biology.
Another feature that’s important for a marine reef’s
survival during climate change is its genetic diversity. A team led by HIMB
researcher Kimberly Selkoe looked into the genetic diversity of reef corals by
taking more than 17,000 samples from 47 Hawaiian coral species.
(Image: Coral reef with fishes in the Papahānaumokuākea Marine
National Monument. Credit: James Watt, courtesy of PMNM/NOAA.)
Their work was also published in the Proceedings of the Royal Society B. A University of Hawai`i press release on the work is here. The paper is entitled “The DNA of coral reef biodiversity:
predicting and protecting genetic diversity of reef assemblages.”
The authors are Selkoe, Oscar E. Gaggiotti, Eric A. Treml,
Johanna L. K. Wren, Mary K. Donovan, Hawai‘i Reef Connectivity Consortium and Robert
J. Toonen. They hail from HIMB, the University of California Santa Barbara, University
of St. Andrews in Scotland, and the University of Melbourne in Australia.
The research team looked at reefs on 13 Hawaiian islands in
both the main Hawaiian Island group and the Northwestern Hawaiian Islands. One
finding: areas with higher species diversity—more different kinds of corals—also
had corals with greater internal genetic diversity.
They also found that certain reefs, ones that had been
bleached due to warm water temperatures, tended to have lower genetic
diversity.
“This negative impact of thermal stress on genetic diversity
suggests that climate change will compromise the adaptive capacity and genetic
integrity of not just corals but the entire coral reef community,” Selkoe said.
There’s an assumption that more genetically diverse reefs
have a stronger capacity to respond and survive threats like warming and
acidification of the oceans. The research team will be looking into that,
and whether the pattern of species diversity with genetic diversity is
confirmed.
“If these relationships can be confirmed and replicated
elsewhere, DNA sampling may one day allow rapid assessment of species diversity
and new metrics of resilience and adaptive capacity,” Selkoe said.
The authors make the point that one technique for preserving
coral reefs is to establish reserves to protect the areas with the greatest
species and genetic diversity.
“The results highlight inherent feedbacks between ecology
and genetics, raise concern that genetic resilience of entire reef communities
is compromised by factors that reduce coral cover or available habitat,
including thermal stress, and provide a foundation for new strategies for
monitoring and preserving biodiversity of entire reef ecosystems,” the paper
says.
But there’s still a lot to know. One question is why coral
species diversity is linked to genetic diversity. One suggestion is that it may
have something to do with the kinds and numbers of coral-eating fish that are in
the area. The researchers did find that where there are more vegetarian fish
(herbivores), there are more corals—is that just because there’s more food and
shelter there, or something else.
One bit of good news for Hawai`i is that coral bleaching due
to unusually high water temperatures, while a problem here, is a much worse
problem on reefs closer to the equator.
“Low-latitude Pacific reefs have experienced thermal stress
up to 240% higher than Hawai‘i and documented ecological effects have also been
more severe, suggesting that recent declines in genetic diversity might also be
more severe at lower latitudes,” the authors write.
© Jan TenBruggencate 2016
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