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Professor C. Robertson (Rob) McClung
studies the genetic and biochemical mechanisms underlying internal
biological clocks in plants. (Photo by Eli Burakian ’00)
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Dartmouth plant biologist C. Robertson (Rob) McClung is not your typical clock-watcher. His clocks are internal, biological, and operate in circadian rhythms—cycles based on a 24-hour period. Living organisms depend upon these clocks to keep pace with the Earth’s daily rotation and the recurring changes it imposes on the environment. These clocks allow the plant or animal to anticipate the changes and adapt to them by modifying its biology, behavior, and biochemistry.
“If you know that the sun is going to
go down, and if you are a photosynthetic plant, you have to readjust
your metabolism in order to make it through the night,” says
McClung, the Patricia F. and Williams B. Hale 1944 Professor in the
Arts and Sciences.
McClung uses the Arabidopsis plant
in his research on the mechanisms that affect plant behavior and its
genetics. He jokingly refers to it as “an inconsequential little
weed,” but holds it in high esteem as an experimental test bed.
According to the National Institutes of
Health, this member of the mustard family is the model organism for
studies of the cellular and molecular biology of flowering plants.
“Because plants are closely related, it is quite likely that
knowledge derived from Arabidopsis studies can be readily
transferred to agronomically important species,” says McClung.
Water and the Changing Climate
McClung sees internal clocks as
increasingly important in the face of global climate change, and to
agricultural productivity in particular. “In the context of climate
change and the need to exploit increasingly marginal habitats, fuller
understanding of clock mechanisms may offer strategies to improve
crop productivity,” says McClung. “We need to know how an
organism measures time and how it uses that information to coordinate
its physiology and behavior.”
Water is the landscape on which
biological clocks and climate change intersect. Agriculture consumes
the vast majority of our water, and warmer and dryer conditions are
predicted for much of the agricultural land of the United States.
This is based on our current understanding of the changes predicted
to be associated with global warming, and in this scenario our
aquatic resources will become increasingly scarce.
Water is lost during the gas exchange
that takes place in photosynthesis—carbon dioxide in, oxygen
out—through small pores in the surface of leaves that periodically
open and close under the control of a biological clock. Exercising
control over this clock could be a means of conserving water. “We
know that these little cells on the surface of the leaf are
controlled by the clock,” says McClung. “It could be that
different clocks regulate it slightly differently, and we would like
to find the best clock, fine-tune it, and perhaps optimize the
ability to get CO2 in without losing water.”
Water figures prominently in another
aspect of plant physiology. Water moves up through the stem to the
leaves, involving proteins called aquaporins. “There is a big
family of genes that encode aquaporins, and in Arabidopsis the
circadian clock governs the expression cycles of about a third of
those genes,” says McClung. “That suggests there is a mechanism
to actually regulate this hydraulic conductivity over time,
constituting another instance where the clock is involved in water
use efficiency.”
New Frontiers
Together with colleagues in Wyoming,
Wisconsin, and Missouri, McClung has been looking at another
crop, Brassica rapa, a close relative of which is the source of
canola oil. With a five-year National Science Foundation
grant of more than $5 million, the group is
investigating Brassica’s circadian patterns, looking at
inheritance and water use efficiency. “We have mapped 10 genetic
regions that are associated with water use efficiency,” says
McClung. “We have also traced circadian parameters to most of those
same areas, suggesting a link between the two. This association
suggests that we could potentially use the clock to manipulate water
use efficiency.”
In a related project, McClung will be
working with soybeans, attempting to correlate circadian period
length with latitude. “If we can understand the clock, we might
then manipulate the clock in ways to achieve desired goals, including
water use efficiency and better yield.”
Why and How?
McClung feels strongly that this sort
of basic research has the potential to contribute in significant ways
to food production increases. “Whether or not we achieve that
increase or whether it allows us to fertilize a little less and so
pollute a little less but maintain the same productivity level,
anything in the net direction that is positive is going to help,”
he says. “We can’t necessarily say exactly how it will help, but
I think it’s not unreasonable to think that this very basic
research can have a real world impact, and one hopes it will.”
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