CUT FLOWER

How plant cell compartments ‘chat’ with each other

10 November 2015

Using these chemical signatures, the plants regulate, for instance, the formation of organs and react to water stress. The results may be used in the future to optimise horticultural crops. The reputable journal, The Plant Cell, reports on the results in its current issue.

Plants react to stimuli from their environment by specific responses: if available water becomes limiting, they curb evaporation from their leaves. If a pathogen attacks, they arm themselves with chemical weapons. If a soil fungus wishes to collaborate with a plant root for mutual benefit, both partners discuss their duties. "All of these fine adjustments require a great deal of communication between the individual compartments of the plant cell," says Dr. Markus Schwarzlaender, principle investigator of an Emmy Noether group at the Institute of Crop Science and Resource Conservation at the University of Bonn.

When the various components of plant cells communicate with another, they do not use words but calcium ions, i.e. positively charged calcium atoms, instead. "The information is encoded in the fluctuations of the calcium concentration of the various cell compartments," explains Dr. Schwarzlaender. How can a single ion contain and transduce so much information? This is the question scientists have been asking themselves since it became known how various cell compartments 'chat' with each other.

The MICU protein is a central relay station

Dr. Schwarzlaender, together with scientists from Italy, France, England, Australia and the Max Planck Institute for Plant Breeding Research in Cologne and the University of Muenster, have now shed light on this question. Investigating the cellular power stations (mitochondria) of thale cress (Arabidopsis thaliana), the scientists discovered that the MICU protein fulfills a central role in the control of the calcium ion concentration in the mitochondria.

"In mammals, there is a very similar protein which also regulates the concentration of calcium ions," says Dr. Stephan Wagner from the team working with Dr. Schwarzlaender. Like a turbocharger, it prompts the mitochondria of mammals to provide more energy. The scientists speculated that this could be an interesting candidate, but they were taken by surprise when they found the closely related plant-based MICU to be a central relay station in the communication system of Arabidopsis. "The two, similar proteins in animals and plants have evidently arisen from a common ancestor but over the course of millennia, they have developed distinct characteristics," says Dr. Schwarzlaender.

Fluorescing cellular power stations provide information

By destroying the gene with the MICU blueprint in the Arabidopsis genome, the researchers were able to experimentally explore what influence the protein has on the calcium communication of the plant cells. They equipped the mitochondria with a fluorescing sensor protein. Using the variable fluorescence intensities of the sensor, it was possible to visualise changes in the calcium concentrations of the cellular power stations in the living plants. "We were able to identify a clear influence on the communication of the mitochondria," reports Dr. Wagner. Knockout of the MICU gene resulted, among other consequences, in modified properties of cell respiration.

"With our findings, we have established a basis for influencing the calcium signals in specific parts of the plant cell," Dr. Schwarzlaender summarises. Since Arabidopsis is considered to be an experimental model for plants in general, the findings may be usable in the future for optimising crops. Looking ahead the researchers note that if, for example, specific plants could be taught to ally themselves with nitrogen-fixing soil bacteria via modified calcium signals, a large amount of fertiliser used in horticulture may be saved.