Plant
growth is driven by light and is powered by photosynthesis of green leaves. The
same is true for roots that grow in the dark—they receive the products of
photosynthesis, specifically sucrose, or sugar, through a central transport
pathway in the phloem. Dr. Stefan Kircher and Prof. Peter Schopfer from the
Faculty of Biology at the University of Freiburg have shown in experiments
using the model plant Arabidopsis thaliana that sucrose not only ensures the
supply of carbohydrates to the roots, but also acts as a signal transmitter for
the formation of light-dependent root structures. It does this in two ways:
First, sucrose directly directs the elongation of the taproot. Second, sucrose
is transported to the root tip, which then regulates the production of the plant hormoneauxin. This hormone drives the rate of new lateral root formation, synchronized
with the elongation of the main root by joint signal transmitters. "This
allows root growth to adapt to changes in light and other environmental
conditions, such as a change from day to night, to the current photosynthetic
performance of the leaf," Kircher said.
To
demonstrate that sucrose, produced through photosynthesis, was the decisive
signal transmitter, Kircher and Schopfer placed plants in a room with light but
no carbon dioxide (CO2) in the air, rendering photosynthesis
impossible. The result is that no more lateral roots are formed. This result
was confirmed in another experiment in which the two biologists treated leaves
or roots with a sucrose solution in the dark. In both methods, lateral root
development was the same as in light-exposed control plants. "These results
show that sucrose production in leaves is necessary for lateral root formation.
It confirms the hypothesis of sucrose as a signal transmitter for light
stimulation," says Kircher.
In
earlier studies, the researchers had shown that auxin, produced in roots from
the amino acid tryptophan, drives the rate at which new lateral roots develop.
Kircher and Schopfer now show how sucrose triggers this process. To do this,
they kept the plants in a dark room for two days and performed various
experiments to discover their effect on lateral root formation. Applying
tryptophan to the roots at the same time as treating the leaves with sucrose
worked best. In contrast, if tryptophan was applied to leaves or roots without
sucrose, it had little effect. "These observations confirm that auxin
synthesis can be triggered by sucrose produced through photosynthesis,"
Kircher said.
Collected
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lactulose.
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