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Helping plants remove natural toxins could boost crop yields by 47%

As climate changes and the population grows, meeting the demand for food will become more difficult as arable land declines

Paul South
Wednesday 08 August 2018 05:59 EDT
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Scientists have been exploring whether genetic modification could boost the production of crops
Scientists have been exploring whether genetic modification could boost the production of crops (Alamy)

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Can you imagine the entire population of the United States, Canada, Mexico, Brazil, the United Kingdom and France going hungry?

You don’t need to imagine. That is exactly what happens every day when an estimated 815 million people around the globe go hungry.

In the short term, the problem is likely to get worse as the global population grows, diets change and urban sprawl forces farmers to produce more food on less land.

Recent reports suggest that by the time children born today reach their thirties, the planet must increase food production by at least 70 per cent.

As a biochemist, I started my career in biomedical research, but I shifted to agricultural research in 2013 because everybody needs to eat. Now I’m working with an international research project exploring how to boost food production.

Researcher Patricia Lopez working with tobacco seedlings in the lab
Researcher Patricia Lopez working with tobacco seedlings in the lab (Monica Kennedy)

The goal of Realizing Increased Photosynthetic Efficiency is to increase the efficiency of photosynthesis – the process plants use to convert energy from the sun into the food we eat.

In our most recent publication we’ve shown that it is possible to dramatically boost crop yield by enabling the plant to get rid of its toxins more quickly.

It’s critical we begin developing new crops now, because it can still take at least a decade for agricultural innovations to reach farmers.

When it comes to photosynthesis, plants use sunlight to power a chemical reaction that converts carbon dioxide and water to sugars, oxygen and energy. But that isn’t the only chemical reaction that occurs in plants.

A quirk in the evolution of the protein, called rubisco, is that sometimes instead of converting carbon dioxide during photosynthesis it uses oxygen instead. This produces waste products such as glycolate and ammonia, which can be toxic to plants and slow or stunt their growth.

To remove these toxic chemicals, another process needs to kick into gear. Photorespiration is a part of natural plant metabolism that recycles these toxins. It is a necessary process in major crops including rice, wheat and soybeans, as well as most fruit and vegetable crops.

Recycling these toxic byproducts sucks up a huge portion of the plant’s energy – and can inhibit the plant’s growth by more than 30 per cent.

At higher temperatures plants tend to increase the amount of oxygen they convert, so as growing season temperatures rise and heatwaves strike, up to 50 per cent of the energy generated from photosynthesis can be required for photorespiration to recycle toxins in major crops like wheat and soybeans.

Engineers have figured out a way to make plants glow

That slashes yields in the hotter and drier regions of the world, such as Sub-Saharan Africa and Southeast Asia, where food is most needed.

To meet the growing demand for increased food production, I worked with an international team to explore whether speeding up photorespiration might boost crop yields.

The work, led by Professor Christine Raines and lead author Patricia Lopez-Calcagno from the University of Essex and the United States Department of Agriculture-Agricultural Research Service (USDA-ARS), explored whether this modification could boost the production of tobacco plants.

We managed to speed up the recycling of these toxins by designing plants that produce more of a protein, called the H-protein, that is already present in our crop plants and plays a role in photorespiration.

Previous work in the lab using the small plant arabidopsis, the “lab rat” of plant research, suggested that increasing the quantity of H-protein could speed up photorespiration and enable our plants to grow larger.

Our team translated this idea from the lab to the field using a strain of tobacco, Nicotiana tabacum, which we grew outside at a research field station near the University of Illinois at Urbana-Champaign where I work as a USDA-ARS scientist.

We discovered pretty quickly that we had to carefully control the quantity of the H-protein we engineered plants to produce. Too much H-protein in all parts of the plant was harmful, stunting growth and reducing yield of tobacco leaves.

Thus, we finetuned our approach and engineered plants that manufactured the H-protein only in the leaves. This increased photosynthesis and plant growth, probably because of faster recycling of the toxic chemicals.

Paul South measures the rate of photosynthesis in the tobacco plants in a field site in Illinois
Paul South measures the rate of photosynthesis in the tobacco plants in a field site in Illinois (Claire Benjamin)

We tested our hypothesis in tobacco because it is an excellent model for proof-of-concept research. It is easy to genetically engineer and only has a four month life cycle, allowing us to conduct several trials in one field season.

This allows us to test various genetic modifications in tobacco and then translate those discoveries to make improvements in targeted food crops.

To fine tune the expression of the H-protein, the team engineered the tobacco using DNA from a close relative, Solanum tuberosum, or potato. Using a known sequence of potato DNA, we were able to boost the H-protein specifically in the desired leaf tissue.

That proved to be the key to increasing yield without harming the plant.

Initially, I was sceptical that boosting the production of a single protein out of thousands in the plant could have such a dramatic impact on crop yield.

But, after two years of field trials, my colleagues and I have demonstrated that increasing H-protein levels leads to larger plants, boosting the crop yield by 27-47 per cent.

You might wonder whether plants with extra H-protein are safe to eat? It is too early to answer that question.

Once we have engineered “high H-protein food crops”, these plants must be proved safe, which includes allergen and environmental impact before these transgenic plants will be approved by the US Food and Drug Administration and United States Department of Agriculture.

Because part of the DNA comes from a foreign source (potato), these plants are considered genetically modified organisms, or GMOs. There’s no doubt that the idea of using GMOs as part of our food source is quite controversial.

A drone shot of the field where South and his colleagues test their genetically modified tobacco plants
A drone shot of the field where South and his colleagues test their genetically modified tobacco plants (Beau Barber)

Many individuals have rejected the use of GMO technology, and some countries have prohibitions or restrictions of the use in their food supply.

However, many studies have shown extensive evidence that GMOs are safe to eat, including this definitive report by the National Academies of Sciences, Engineering and Medicine.

We believe it is important to have this technology to increase crop productivity so farmers and consumers will have many high-yielding options available to them.

There are different techniques to create new crops, including traditional crop-breeding techniques, GMOs and more recently CRISPR-based gene editing technology – which allow us to directly rewrite a plant’s DNA without adding foreign genes.

But regardless of the technique, the goal is the same: produce plants that can thrive in farmers’ fields to create a more secure and sustainable food supply for everyone.

Our next goal is to bump up levels of the H-protein in important food crops including legumes – soybean and cowpea – as well as the root crop cassava, which are major staple foods worldwide.

If we can increase the production of these target plants by between 27 and 47 per cent, similar to what was observed in this study, it will go a long way towards meeting the goal of feeding another 2 to 3 billion people by 2050.

Paul South is a postdoctoral researcher at the Carl R Woese Institute for Genomic Biology, University of Illinois at Urbana-Champaign. This article was originally published on TheConversation.com

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