New research by UCLA life scientists could
lead to predictions of which plant species will escape extinction from climate
change.
Droughts
are worsening around the world, posing a great challenge to plants in all
ecosystems, said Lawren Sack, a UCLA professor of ecology and evolutionary
biology and senior author of the research. Scientists have debated for more
than a century how to predict which species are most vulnerable.
Sack
and two members of his laboratory have made a fundamental discovery that
resolves this debate and allows for the prediction of how diverse plant species
and vegetation types worldwide will tolerate drought, which is critical given
the threats posed by climate change, he said.
The
research is currently available in the online edition of Ecology Letters, and
will be published in an upcoming print edition.
Why
does a sunflower wilt and dessicate quickly when the soil dries, while the
native chaparral shrubs of California survive long dry seasons with their
evergreen leaves? Since there are many mechanisms involved in determining the
drought tolerance of plants, there has been vigorous debate among plant
scientists over which trait is most important. The UCLA team, funded by the
National Science Foundation, focused on a trait called "turgor loss point,
which had never before been proven to predict drought tolerance across plant
species and ecosystems.
A
fundamental difference between plants and animals is that plant cells are
enclosed by cell walls while animal cells are not. To keep their cells
functional, plants depend on "turgor pressure" -- pressure produced
in cells by internal salty water pushing against and holding up the cell walls.
When leaves open their pores, or stomata, to capture carbon dioxide for
photosynthesis, they lose a considerable amount of this water to evaporation.
This dehydrates the cells, inducing a loss of pressure.
During
drought, the cell's water becomes harder to replace. The turgor loss point is
reached when leaf cells get to a point at which their walls become flaccid;
this cell-level loss of turgor causes the leaf to become limp and wilted, and
the plant cannot grow, Sack said.
"Drying
soil may cause a plant's cells to reach turgor loss point, and the plant will
be faced with the choice of either closing its stomata and risking starvation
or photosynthesizing with wilted leaves and risking damaging its cell walls and
metabolic proteins," Sack said. "To be more drought-tolerant, the
plant needs to change its turgor loss point so that its cells will be able to
keep their turgor even when soil is dry."
The
biologists showed that within ecosystems and around the world, plants that are
more drought-tolerant had lower turgor loss points; they could maintain their
turgor despite drier soil.
The
team also resolved additional decades-old controversies, overturning the
long-held assumptions of many scientists about the traits that determine turgor
loss point and drought tolerance. Two traits related to plant cells have been
thought to affect plants' turgor loss point and improve drought tolerance:
Plants can make their cell walls stiffer or they can make their cells saltier
by loading them with dissolved solutes. Many prominent scientists have leaned
toward the "stiff cell wall" explanation because plants in dry zones
around the globe tend to have small, tough leaves. Stiff cell walls might allow
the leaf to avoid wilting and to hold onto its water during dry times,
scientists reasoned. Little had been known about the saltiness of cells for
plants around the world.
The
UCLA team has now demonstrated conclusively that it is the saltiness of the
cell sap that explains drought tolerance across species. Their first approach
was mathematical; the team revisited the fundamental equations that govern
wilting behavior and solved them for the first time. Their mathematical
solution pointed to the importance of saltier cell sap. Saltier cell sap in
each plant cell allows the plant to maintain turgor pressure during dry times
and to continue photosynthesizing and growing as drought ensues. The equation
showed that thick cell walls do not contribute directly to preventing wilting,
although they provide indirect benefits that can be important in some cases --
protection from excessive cell shrinking and from damage due to the elements or
insects and mammals.
The
team also collected for the first time drought-tolerance trait data for species
worldwide, which confirmed their result. Across species within geographic areas
and across the globe, drought tolerance was correlated with the saltiness of
the cell sap and not with the stiffness of cell walls. In fact, species with
stiff cell walls were found not only in arid zones but also in wet systems like
rainforests, because here too, evolution favors long-lived leaves protected
from damage.
The
pinpointing of cell saltiness as the main driver of drought tolerance cleared
away major controversies, and it opens the way to predictions of which species
could escape extinction from climate change, Sack said.
"The
salt concentrated in cells holds on to water more tightly and directly allows
plants to maintain turgor during drought," said research co-author
Christine Scoffoni, a UCLA doctoral student in the department of ecology and
evolutionary biology.
The
role of the stiff cell wall was more elusive.
"We
were surprised to see that having a stiffer cell wall actually reduced drought
tolerance slightly -- contrary to received wisdom -- but that many
drought-tolerant plants with lots of salt also had stiff cell walls," said
lead author Megan Bartlett, a UCLA graduate student in the department of
ecology and evolutionary biology.
This
seeming contradiction is explained by the secondary need of drought-tolerant
plants to protect their dehydrating cells from shrinking as they lose turgor
pressure, the researchers said.
"While
a stiff wall doesn't maintain the cell turgor, it prevents the cells from
shrinking as the turgor decreases and holds in water so that cells are still
large and hydrated, even at turgor loss point," Bartlett explained.
"So the ideal combination for a plant is to have a high solute concentration
to keep turgor pressure and a stiff cell wall to prevent it from losing too
much water and shrinking as the leaf water pressure drops. But even
drought-sensitive plants often have thick cell walls because the tough leaves
are also good protection against herbivores and everyday wear and tear."
Even
though the team showed that turgor loss point and salty cell sap have
exceptional power to predict a plant's drought tolerance, some of the most
famous and diverse desert plants -- including cacti, yuccas and agaves --
exhibit the opposite design, with many flexible-walled cells that hold dilute
sap and would lose turgor rapidly, Sack said.
"These
succulents are actually terrible at tolerating drought, and instead they avoid
it," he said. "Because much of their tissue is water storage cells,
they can open their stomata minimally during the day or at night and survive
with their stored water until it rains. Flexible cell walls help them release
water to the rest of the plant."
This
new study showed that the saltiness of cells in plant leaves can explain where
plants live and the kinds of plants that dominate ecosystems around the world.
The team is working with collaborators at the Xishuangbanna Tropical Botanical
Gardens in Yunnan, China, to develop a new method for rapidly measuring turgor
loss point across a large number of species and make possible the critical
assessment of drought tolerance for thousands of species for the first time.
"We're
excited to have such a powerful drought indicator that we can measure
easily," Bartlett said. "We can apply this across entire ecosystems
or plant families to see how plants have adapted to their environment and to
develop better strategies for their conservation in the face of climate
change."
Source:
University of California - Los Angeles
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