How ancient plants ‘learnt’ to use water when they moved on to land – new research

Focal point/Shutterstock

“Plants, whether they are enormous, or microscopic, are the basis of all life including ourselves.” This was David Attenborough’s introduction to The Green Planet, the latest BBC natural history series.

Over the last 500 million years, plants have become interwoven into every aspect of our lives. Plants support all other life on Earth today. They provide the oxygen people breathe, as well as cleaning the air and cooling the Earth’s temperature. But without water, plants would not survive. Originally found in aquatic environments, there are estimated to be around 500,000 land plant species that emerged from a single ancestor that floated through the water.

In our recent paper, published in New Phytologist, we investigate, at the genetic level, how plants have learnt to use and manipulate water – from the first tiny moss-like plants to live on land in the Cambrian period (around 500 million years ago) through to the giant trees forming complex forest ecosystems of today.

How plants evolved

By comparing more than 500 genomes (an organism’s DNA), our results show that different parts of plant anatomies involved in the transport of water – pores (stomata), vascular tissue, roots – were linked to different methods of gene evolution. This is important because it tells us how and why plants have evolved at distinct moments in their history.

Plants’ relationship with water has changed dramatically over the last 500 million years. Ancestors of land plants had a very limited ability to regulate water but descendants of land plants have adapted to live in drier environments. When plants first colonised land, they needed a new way to access nutrients and water without being immersed in it. The next challenge was to increase in size and stature. Eventually, plants evolved to live in arid environments such as deserts. The evolution of these genes was crucial for enabling plants to survive, but how did they help plants first adapt and then thrive on land?

Stomata, the minute pores in the surface of leaves and stems, open to allow the uptake of carbon dioxide and close to minimise water loss. Our study found that the genes involved in the development of stomata were in the first land plants. This indicates that the first land plants had the genetic tools to build stomata, a key adaptation for life on land.

The speed in which stomata respond varies between species. For example, the stomata of a daisy close more quickly than those of a fern. Our study suggests that the stomata of the first land plants did close but this ability speeded up over time thanks to gene duplication as species reproduced. Gene duplication leads to two copies of a gene, allowing one of these to carry out its original function and the other to evolve a new function. With these new genes, the stomata of plants that grow from seeds (rather reproducing via spores) were able to close and open faster, enabling them to be more adaptable to environmental conditions.

Images of a plant's stomata, open and closed.
Shutterstock

Old genes and new tricks

Vascular tissue is a plant’s plumbing system, enabling it to transport water internally and grow in size and stature. If you have ever seen the rings of a chopped tree, this is the remnants of the growth of vascular tissue.

We found that rather than evolving by new genes, vascular tissue emerged through a process of genetic tinkering. Here, old genes were repurposed to gain new functions. This shows that evolution does not always occur with new genes but that old genes can learn new tricks.

Before the move to land, plants were found in freshwater and marine habitats, such as the algal group Spirogyra. They floated and absorbed the water around them. The evolution of roots enabled plants to access water from deeper in the soil as well as providing anchorage. We found that a few key new genes emerged in the ancestor of plants that live on land and plants with seeds, corresponding to the development of root hairs and roots. This shows the importance of a complex rooting system, allowing ancient plants to access previously unavailable water.

A dam floor cracked by lack of water.
Hot weather and climate changes left this Bulgarian dam almost empty in 2021.
Minko Peev/Shutterstock

The development of these features at every major step in the history of plants highlights the importance of water as a driver of plant evolution. Our analyses shed new light on the genetic basis of the greening of the planet, highlighting the different methods of gene evolution in the diversification of the plant kingdom.

Planting for the future

As well as helping us make sense of the past, this work is important for the future. By understanding how plants have evolved, we can begin to understand the limiting factors for their growth. If researchers can identify the function of these key genes, they can begin to improve water use and drought resilience in crop species. This has particular importance for food security.

Plants may also hold the key to solving some of the most pressing questions facing humanity, such as reducing our reliance on chemical fertilisers, improving the sustainability of our food and reducing our greenhouse gas emissions.

By identifying the mechanisms controlling plant growth, researchers can begin to develop more resilient, efficient crop species. These crops would require less space, water and nutrients and would be more sustainable and reliable. With nature in decline, it is vital to find ways to live more harmoniously in our green planet.The Conversation

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This blog has been written by Alexander Bowles, research associate, University of Bristol.

This article is republished from The Conversation under a Creative Commons license. Read the original article.

Alexander Bowles

 

 

Festival of Nature 2015: Roots and soil erosion

Seed lucky dips, 3D-printer pens, and Bill Oddie with a puffin. All in a day’s volunteering for the Festival of Nature 2015!

 

Bristol’s Festival of Nature is the UK’s largest celebration of the natural world, and has recently spread over into Bath too. This year, I helped Kevin Smyth and Tom Denbigh from the School of Biological Sciences. Their work in Prof Claire Grierson’s lab group looks at plant roots, especially how important they are at preventing soil erosion. This work is funded by the Leverhulme Trust.

We also had some smaller plants growing in transparent media. The bean on the left
has thicker roots and very few side shoots, whereas the tomato on the right has much
thinner roots but more side shoots.

The stall really helped reveal what’s going under our feet in any park, garden or green space. Like the well-known tip of the iceberg, there’s often a lot going on below the surface! For the sunflowers in this rhizotron, the roots were taller than many of the kids we saw!

We also had some smaller plants growing in transparent media (see image above). The bean on the left has thicker roots and very few side shoots, whereas the tomato on the right has much thinner roots but more side shoots.

If you want evidence that plants do help combat soil erosion, just look at the pictures! Soil without plants (right) can be really crumbly and doesn’t hold itself together well. A slight slope and some rainfall would wash it away easily, leading to soil erosion. Soil and plants is a far more effective solution, holding itself together with ease – even without a supporting pot. One of so many reasons why we need more plants around!

 

Seed lucky dip at the Festival of Nature.

Are you inspired to lend a hand with increasing the plant numbers in your area? Perhaps you are curious about the medical-looking pots are behind the bowl of soil in the image above. We can help with both – it’s a seed lucky dip!

In the lab, Kevin’s group studies roots to try and understand why plants are so effective at preventing soil erosion. To do this, they can make mutations in some plants and see if it changes the roots. The mutant plants of choice are Arabadopsis, weedy relatives of the mustard plant and perhaps the most studied plant in the world.

Looking down the microscope at the samples, you could work out which plant was the “bald” mutant (below left) and which was the “werewolf” (below right) compared to the normal roots in the middle. If we understand how the plant’s genetics affects their roots, perhaps in the future we could grow plants that are better at holding the soil together.

Looking down the microscope at the samples, you could work out which plant
was the “bald” mutant (left) and which was the “werewolf” (right) compared
to the normal roots in the middle.
A 3D printing pen was used to create root structures at the Festival of Nature.

There was art as well as science! You could draw your own root structure on a plant template, then one of us lucky volunteers got to use this amazing 3D-printing pen to made a “real” version of it. You could either take it home or donate it to our ever-growing wall…

As a bonus, my lunch break timed nicely with Bill Oddie’s talk so I got to hear him tell a bunch of amusing anecdotes about his young life and how that led to a passion for wildlife. One of these apparently required a stuffed puffin!

Bill Oddie at the Festival of Nature.

There was plenty to do at the stall, in the tent and throughout the festival. I was genuinely impressed at the range of activities and how interesting they were, something for all ages and experiences. I had a great time helping out and look forward to next year’s Festival of Nature already! It also fit in as a pretty wild indeed #30dayswild.
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This blog is written by Emily Coyte, and has been reproduced from her blog Memetic Drift.  Emily is an Assistant Teacher in the School of Biochemistry at the University of Bristol.

Emily Coyte