As food demands rise to unprecedented levels,
farmers are in a race against time to grow plants that can withstand
environmental challenges--infestation, climate change and more. Now, new
research reveals details into a fundamental mechanism of how plants
manage their energy intake, which could potentially be harnessed to
improve yield.
ULL STORY
In plants, chloroplasts can
accumulate high levels of toxic singlet oxygen, a reactive oxygen
species formed during photosynthesis. In these cells, most of the
chloroplasts (green organelles) and mitochondria (red organelles) appear
healthy. However, the chloroplast in the top left of the image is being
selectively degraded and is interacting with the central vacuole
(blue). Salk scientists reveal how this strategy to degrade singlet
oxygen-damaged chloroplasts may help a cell avoid any further oxidative
damage during photosynthesis.
Credit: Salk Institute
As food demands rise to unprecedented
levels, farmers are in a race against time to grow plants that can
withstand environmental challenges--infestation, climate change and
more. Now, new research at the Salk Institute, published in Science
on October 23, 2015, reveals details into a fundamental mechanism of
how plants manage their energy intake, which could potentially be
harnessed to improve yield.
"Plants are unique in that they are stuck wherever they germinate, so
they must use a variety of ways to deal with environmental challenges,"
says Joanne Chory, senior author of the paper and director of Salk's
Plant Molecular and Cellular Biology Laboratory. "Understanding the
techniques plants use to cope with stress can help us to engineer
stronger crops with improved yield to face our growing food shortage."
Plants have cellular organelles akin to tiny solar panels in each
leaf. These microscopic structures, called chloroplasts, convert
sunlight into chemical energy to enable the plant to grow. The command
center of the cell, the nucleus, occasionally sends out signals to
destroy all of the 50-100 chloroplasts in the cell, such as in autumn
when leaves turn brown and drop off. However, the Salk team found how
the plant nucleus begins to degrade and reuse the materials of select,
malfunctioning chloroplasts--a mechanism that had been suspected but
never shown until now.
"We've discovered a new pathway that lets a cell do a quality control
check on the chloroplasts," says Jesse Woodson, Salk staff scientist
and first author of the paper. Chloroplasts are full of enzymes,
proteins and other materials that the plant can otherwise use if the
chloroplast is defective (for example, creating toxic materials) or not
needed.
While studying a mutant version of the model plant Arabidopsis, the
team noticed the plant was making defective chloroplasts that created a
reactive, toxic molecule called singlet oxygen that accumulated in the
cells. The team noticed that the cells were marking the damaged
chloroplasts for degradation with a protein tag called ubiquitin, which
is used in organisms from yeast to humans to modify the function of a
protein. Under closer investigation, the team observed that a protein
called PUB4 was initiating the tagging.
"Damaged chloroplasts were being coated in this ubiquitin protein,"
says Woodson. "We think this is fundamentally different than the
cell-wide signal, because the cell wants to continue doing
photosynthesis, but has some bad chloroplasts to target and remove."
While PUB4 had been tied to cell death in other work, the Salk team
showed that this protein initiates the degradation of chloroplasts by
placing ubiquitin tags to mark the organelle for cellular recycling.
This process, says Woodson, is like labeling defective solar panels to
break them down for other materials.
"Understanding the basic biology of plants like this selective
chloroplast degradation leads us a step closer to learning how to
control chloroplasts and design crops that are more resistant to
stressors," says Chory, who is also a Howard Hughes Medical Institute
investigator and holder of the Howard H. and Maryam R. Newman Chair in
Plant Biology. For example, if a plant is growing in an environment that
is fairly relaxed, one could potentially reduce the degradation of
chloroplasts to boost the growth of the plant. Or, if the environment
contained a lot of sun, spurring on the breakdown and regeneration of
chloroplasts could help the plant thrive.
Interestingly, chloroplasts could help us understand our brains as
well. Neurons have energy-generating organelles similar to chloroplasts
called mitochondria. "Recently it's become apparent that mitochondria
are selectively degraded in the cell and that bad mitochondria
accumulation could lead to disease like Parkinson's and maybe
Alzheimer's," says Woodson. "Cells, whether plant or animal, learn how
to degrade defunct energy organelles selectively to survive."
By better understanding this process in chloroplasts, the Salk team
may be able to also glean insight into how the cells handle misbehaving
mitochondria. "So far it seems like it might be a parallel process,"
Woodson adds. "We're hoping with our molecular and genetic tools
available for plants we can continue to uncover general concepts on how
cells do these quality control checks on organelles and learn something
about neurodegenerative disease as well."
Story Source:
The above post is reprinted from
materials provided by
Salk Institute.
Note: Materials may be edited for content and length.
Journal Reference:
- Jesse D. Woodson, Matthew S. Joens, Andrew B. Sinson, Jonathan
Gilkerson, Patrice A. Salomé, Detlef Weigel, James A. Fitzpatrick, and
Joanne Chory. Ubiquitin facilitates a quality-control pathway that removes damaged chloroplasts. Science, 23 October 2015: 450-454 DOI: 10.1126/science.aac7444
In plants, chloroplasts can accumulate high levels of toxic singlet oxygen, a reactive oxygen species formed during photosynthesis. In these cells, most of the chloroplasts (green organelles) and mitochondria (red organelles) appear healthy. However, the chloroplast in the top left of the image is being selectively degraded and is interacting with the central vacuole (blue). Salk scientists reveal how this strategy to degrade singlet oxygen-damaged chloroplasts may help a cell avoid any further oxidative damage during photosynthesis.Credit: Salk InstituteAs food demands rise to unprecedented levels, farmers are in a race against time to grow plants that can withstand environmental challenges--infestation, climate change and more. Now, new research at the Salk Institute, published in Science on October 23, 2015, reveals details into a fundamental mechanism of how plants manage their energy intake, which could potentially be harnessed to improve yield."Plants are unique in that they are stuck wherever they germinate, so they must use a variety of ways to deal with environmental challenges," says Joanne Chory, senior author of the paper and director of Salk's Plant Molecular and Cellular Biology Laboratory. "Understanding the techniques plants use to cope with stress can help us to engineer stronger crops with improved yield to face our growing food shortage."
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