Wilhelmina van de Ven and the laboratory
plants at UC Riverside. Credit: Stan Lim/UCR
UC Riverside researchers have
identified a mechanism that allows plants to rapidly slow growth in response to
extreme environmental stress. The finding could help farmers grow more
resilient crops, and one researcher continued the work years into retirement to
uncover it.
How plants mount a rapid defense
The rapid response system is based
on a process inside plant cells that produces compounds needed for growth,
development, and survival. If even one of the key enzymes in this process
fails, the plant cannot live.
Under stress conditions such as
intense light, this biological pathway behaves in an unexpected manner. Rather
than being governed by changes in gene expression, a standard mechanism in
biology, it is modulated instantly through direct alterations in enzyme
activity.
In most living things, cells adjust
their RNA levels to alter protein production, which then changes the balance of
other important molecules. But this process takes time that plants may not have
when faced with sudden light or heat stress. In plants, the response is much
faster. Stress directly alters the activity of enzymes already present in the
cell, allowing leaves to respond immediately without waiting for new proteins
to be made.
Wilhelmina van de Ven. Credit: Stan Lim/UCR
"This kind of response has to
be immediate," said Katie Dehesh, UCR distinguished professor of molecular
biochemistry. "Changing gene expression takes time, but modifying enzyme
activity allows the plant to react right away and survive."
Reactive oxygen molecules interfere with the enzymes, reducing their
activity and slowing the pathway. At the same time, new compounds build up,
blocking earlier steps in the process and preventing some enzymes from working
efficiently.
The immediate effect is protective.
By limiting the pathway's output, the plant reduces production of
growth-related compounds, effectively pausing development while it copes with
stress.
A two-stage strategy with tradeoffs
Over time, a second phase begins as the plant adjusts its internal
machinery to prolonged stress. These longer-term changes help the plant adapt,
but often at a cost, redirecting resources away from growth and resulting in
smaller or slower development.
There have been many efforts
to engineer plants to increase crop yields and drought tolerance as
well as produce valuable molecules like carotenoids, which protect against
damage. However, these engineering efforts often fail because they did not
account for the two-stage response identified by the Dehesh laboratory
and described in the Proceedings of the National
Academy of Sciences.
The painstaking detective work behind it
The breakthrough was the result of
painstaking work led by Mien van de Ven, a former lab manager and research
supervisor who continued contributing to the project even after retiring. She
systematically measured intermediate compounds at each step of the pathway,
even though they are present in extremely small amounts.
"There were both conceptual
and experimental challenges," Dehesh said. "The metabolites are at
very low levels, and even identifying them required careful, step-by-step
work."
The team's progress began with an
unexpected clue. A mutation in one enzyme caused plants to grow smaller without
dying. Following this lead, the researchers analyzed each step of the pathway
and discovered that one downstream compound accumulated at unusually high
levels. They eventually determined why. The compound binds to an upstream
enzyme, blocking it and slowing the entire pathway.
Proving this interaction was
technically difficult. The team had to isolate delicate enzymes and recreate
the right conditions for them to function outside the plant. Even then, the
work was challenging. Proteins can become unstable outside their natural
environment, and excess materials can interfere with measurements.
"It took a lot of time to get
all the components working together under the right conditions," van de
Ven said.
Implications for crops and a devoted career
The work culminated in a clearer
picture of how plants balance survival and growth under stress. Because similar
pathways exist in bacteria, the findings may reflect a broader strategy used by
living organisms to respond to environmental change. The research also has
practical applications.
Enhancing this natural pathway
could help scientists develop crops that are more resilient to drought and high
light as well as temperature extremes and salinity.
Equally notable is the path to the
discovery. Van de Ven continued working on the project for two years after
retiring, returning to the lab to complete key experiments.
"She just kept going,"
Dehesh said. "It shows how much impact one person can have on science
through dedication."
For van de Ven, now enjoying baking
and line dancing in retirement, the decision was simple: finish what she
started.
"I didn't know it would take as long as it did," van de Ven said. "But it was worth continuing to see it through."
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