15 May 2024

Now we know, what gets roots to grow: Can help in future droughts

Plants

A biological mechanism familiar to people who fast helps plant roots grow strong. The discovery by University of Copenhagen scientists provides an answer to a long-unanswered question and a deeper understanding of the "mouths" of plants that can help to develop climate-resilient crops.

plants
Autophagy means 'self-eating' and is a key mechanism when plants develop roots. Photo: Getty

Imagine eating with your feet and having half your body underground. Such is the life of most plants, with roots as the mouths through which they eat and drink. Roots also serve to anchor plants and keep them safe in wind and rain. Indeed, roots are critical for a plant's life.

But many things remain unknown about the life of plants. How they grow their roots big and strong has long been a question and there are key pieces missing to the puzzle.

In a new study published recently, researchers from the University of Copenhagen’s Department of Biology share their discovery of how plants control root growth.

It turns out that a beneficial clean-up mechanism in plant cells called autophagy plays a key role. The same mechanism exists in humans and is part of a popular health trend.

"Fasting has become popular as it seems to have a range of health-promoting effects in humans, as periods without food cause the body to activate a clean-up processes to dispose of various waste products in cells. In our study, we have proven that the same mechanism, which also exists in the plant kingdom, plays a vital role in the ability of plant roots to grow and absorb water and nutrients for the rest of the plant," explains Assistant Professor Eleazar Rodriguez from the Department of Biology, who led the study. 

 

 

Roots have a heartbeat

It has long been known that auxin, a plant hormone, controls plant growth, root growth included. Auxin is a fuel for a kind of heartbeat that beats in each and every root tip of a plant. Roughly every four to six hours, auxin levels and the heartbeat in a plant’s roots reach a maximum that causes new roots to grow.

"The movement of a root is almost like watching a snake slithering forward in search of water and nourishment in the soil. And we can see that the heartbeat is strongest every time the root meanders forth," says Eleazar Rodriguez.  

But how plants control its heartbeat so as to optimize root growth, has remained an unanswered question. This is where the plant's internal clean-up mechanism comes into the picture.

"In our experiments, we disabled the clean-up mechanism to understand its significance. Imagine if every garbage collector in Copenhagen went on strike – it wouldn’t be long before trash filled the streets. The same thing happened in the plant cells, as the heartbeats that drive root growth became much weaker and went out of sync," explains Eleazar Rodriguez.

Doing this allowed the researchers to conclude that the clean-up mechanism helps keep levels of different biochemical components in perfect balance to provide the most efficient root growth.

To investigate the significance of autophagy, the researchers developed a mutant Arabidopsis (thale cress) plant in which it's autophagy was disabled which is shown on the right. With an enzyme from fire flies the researchers made it possible to distinguish the normal plant from the plant with it's autophagy function disabled. The plant to the right hos fewer light areas and thereby fewer potential places to grow new roots with it's autophagy function turned off.

Can help germinate new climate-resilient crops

According to the researchers, the new knowledge about plant roots may prove important in the fight against climate change. Extended periods of drought and floods are a new normal that place greater demands on food security. As such, the roots of the crops, which must be able to grow even in these harsh conditions.

“Numerous methods to change the genetic characteristics of plants are available today. These can be used to get plants to develop longer roots, faster, and in doing so, become more resistant to droughts or floods. One of the methods enlists the help of bacteria that live in symbiosis with the plant and can cause the plant to change its growth pattern. Several companies in Denmark are working on this right now," explains Ph.D. student Jeppe Ansbøl who co-authored the study..

The new knowledge applies to all flowering plants and perhaps more, according to the researcher. In principle, crops like tomatoes, potatoes, rice, wheat and corn could be altered to grow more and denser roots, because we now know how plants get their roots to grow.

"The more roots the plants have the more water and nutrients they can take, so the plants grow better faster. We’re heavily dependent on plants because they feed us, extract CO2 from the atmosphere and produce the oxygen we breathe. As such, it is extremely important to understand them fully, to which end we have just taken a big step forward," concludes Eleazar Rodriguez.

 

Two researchers
Jeppe Ansbøl and Eleazar Rodriguez from Department of Biology in the lab.

 

 

Contact

Eleazar Rodriguez
Assistant Professor
Department of Biology
University of Copenhagen
eleazar.rodriguez@bio.ku.dk

Jeppe Ansbøl
Ph.D. fellow
Department of Biology
University of Copenhagen

Michael Skov Jensen
Journalist and team coordinator
The Faculty of Science
+ 45 93 56 58 97
msj@science.ku.dk

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