Get all your news in one place.
100’s of premium titles.
One app.
Start reading
The Conversation
The Conversation
Etienne Farcot, Associate professor of Mathematics, University of Nottingham

Plant roots mysteriously pulsate and we don't know why – but finding out could change the way we grow things

Nikita M production/Shutterstock

You probably don’t think about plant roots all that much – they’re hidden underground after all. Yet they’re continually changing the shape of the world. This process happens in your garden, where plants use invisible mechanisms for their never-ending growth.

Scientists discovered about 15 years ago that genes at the root tip (or more precisely, the level of proteins produced from some genes) seem to pulsate. It’s still a bit of a mystery but recent research is giving us new insights.

What we do know is this oscillation is a basic mechanism underlying the growth of roots. If we better understood this process, it would help farmers and scientists design or choose the best plants to grow in different types of soil and climate. With increasingly extreme weather such as droughts and floods, damaging crops around the world, it is more important to understand how plants grow than ever before.

To really understand how plants grow, you need to look at processes which happen inside cells. There are numerous chemical reactions and changes in the activity of genes happening all the time inside cells.

Some of these reactions happen in response to external signals, such as changes in light, temperature or nutrient availability. But many are part of each plant’s developmental programme, encoded in its genes.


Many people think of plants as nice-looking greens. Essential for clean air, yes, but simple organisms. A step change in research is shaking up the way scientists think about plants: they are far more complex and more like us than you might imagine. This blossoming field of science is too delightful to do it justice in one or two stories.

This article is part of a series, Plant Curious, exploring scientific studies that challenge the way you view plantlife.


Some of these cell processes have regular oscillations – some families of molecules rhythmically appear and disappear every few hours. The most well known example is circadian rhythms, the internal clock in plants and animals (including humans).


Read more: How understanding plant body clocks could help transform how food is grown


Natural cycles

There are many other examples of spontaneous oscillations in nature. Some are fast such as heart beats and the mitotic cell cycle, which is the cycle of cell divisions. Others, like the menstrual cycle and hibernation, are slow.

Man holding plant root while transplanting the flower plant
There are intricate chemical processes happening inside those plant roots. Zamrznuti tonovi/Shutterstock

Most often, they can be explained by an underlying negative feedback loop. This is where a process triggers a series of events which then represses the very activity it triggered. This seems to be the case for the root growth pulsation.

Shortly after the root tip gene oscillation was discovered, scientists noticed this pulsation leaves an invisible mark. They found this out by using fluorescent markers visible under a microscope. These marks are left at places where the root can grow sideways. This means they provide regular cues that lead to the root system taking its shape.

Its cause is unknown today, although scientists have ruled out theories that it may be driven by circadian oscillations.

We do know there are many feedback loops involved. A plant hormone called auxin seems to be crucial to the process. It wakes up some genes coding for proteins, such as those needed for growth. Charles Darwin hypothesised the existence of auxin and its chemical structure was confirmed around 100 years ago.

The genes which oscillate are the auxin “targets”. When auxin enters a cell, these target genes tend to become more active. Some of these genes are related to growth but not all. Auxin triggers the removal of “repressors”, proteins which can block the activity in genes. Animals have repressors in their cells too.

But these repressors are activated by the genes they block. It could be that this feedback loop triggers the oscillations we see, but we don’t know for sure.

We know auxin moves from cell to cell via an intricate network of transporter proteins. The way proteins direct travel to parts of cells depends on the surrounding levels of auxin itself. This is another feedback loop. The pulsation happens in growing roots, where cells at the tip are continually dividing as a result of the cell cycle (which involves separate feedback loops).

What a conundrum

Scientists often turn to mathematics to help explain things. Researchers have used geometry since ancient history to study the visible part of plants. A branch of mathematics developed in the 19th century called Dynamical Systems Theory (DST), has given scientists some clarity about why plant roots oscillate. Scientists have been using tools from DST to try and show how auxin patterns are affected by rounds of cell divisions.

If these rounds of cell division were well synchronised, we could show that, in theory, this would produce a regular pulse of auxin.

But this doesn’t solve the mystery because cells do not typically divide all at the same time, and so any pulsation of auxin would be fairly irregular.

When my team looked under the microscope for fluorescent auxin markers, we found a lack of regularity in auxin, in the parts of the root where its target genes oscillate regularly.

This suggests that the root tip gene oscillation may be linked to root growth but doesn’t happen at the same time as root stem cells are dividing.

Though still mysterious, we are now better equipped to decipher this enigma. The answer is probably not with one single process, but a result of an interplay between various processes. We know the key players, but the rules of the game they play are yet to be discovered.


Read more: Why do cauliflowers look so odd? We've cracked the maths behind their 'fractal' shape


The Conversation

Etienne Farcot does not work for, consult, own shares in or receive funding from any company or organisation that would benefit from this article, and has disclosed no relevant affiliations beyond their academic appointment.

This article was originally published on The Conversation. Read the original article.

Sign up to read this article
Read news from 100’s of titles, curated specifically for you.
Already a member? Sign in here
Related Stories
Top stories on inkl right now
One subscription that gives you access to news from hundreds of sites
Already a member? Sign in here
Our Picks
Fourteen days free
Download the app
One app. One membership.
100+ trusted global sources.