Detective work inside plant cells finds a key piece of the C4 photosynthesis puzzle

An impressive body of evidence published this week reveals the answer to a mystery that has puzzled plant scientists for more than 30 years: the role of the molecule suberin in the leaves of some of our most productive crops. This discovery could be the key to engineering better crops and ensuring future food security.

Plant Science

Plant Science. Image Credit: Dusan Petkovic/

Highly productive crops such as sugarcane, sorghum, and maize belong to the type of plants that use the more efficient C4 photosynthetic pathway to transform water, sunlight, and carbon dioxide (CO2) into sugars.

Scientists have known for a long time that one of the key factors that make C4 photosynthesis more efficient is that they have the capacity to enclose CO2 inside a gas-tight compartment in the leaf tissue, making it easier for the inefficient photosynthetic enzyme Rubisco to fix carbon. "The big question we haven't been able to answer until now is what makes this compartment gas tight so CO2 can't escape?" says lead author Dr. Florence Danila, from the ARC Centre of Excellence for Translational Photosynthesis (CoETP) at the Australian National University (ANU).

Our research provides several pieces of evidence about the responsibility of suberin on making the leaf cells of C4 plants, gas-tight. Suberin forms a layer that keeps CO2 gas inside a layer of cells called the bundle sheath. We have grown mutant plants that don't develop this layer and we have seen the deleterious effect this mutation has in their growth and in their capacity to photosynthesize,"

Dr. Danila, C4 Rice Project, Oxford University

This discovery is the result of many years of work, a bit of serendipity, and access to modern techniques that were not available until recently, including faster and cheaper genome mapping, high throughput phenotyping, electron microscopy, and gas exchange measures.

"We have known for a long time that suberin is in the bundle sheath cells of the C4 plants leaves. However, we didn't have the experimental evidence to prove its essential role in C4 photosynthesis. Now, for the first time, we have been able to see clearly under the microscope, the anatomical differences between plants with and without suberin. The key element in this discovery is that we found a mutant population of green foxtail millet (Setaria viridis) that didn't have the gene that produces suberin," says CoETP's Deputy Director Professor Susanne von Caemmerer, one of the co-authors of this study.

This elusive mutant population was generated in the International Rice Research Institute (IRRI) by screening hundreds of plants under low CO2 conditions and then selecting those plants that didn't perform well.

Using high throughput screening, we identified only three mutants with impaired photosynthetic capacity. We sent the seeds to ANU in Canberra and they grew and analyzed them using the electron microscope and gas exchange techniques. To our surprise, one of these mutants was the one that lacked suberin"

Dr. Rob Coe

Centre Director and co-author of the paper Bob Furbank says that "this is a very exciting discovery, one of the last mechanistic pieces of the C4 photosynthesis puzzle, as Hal Hatch, the discoverer of the C4 pathway noted some time ago".

"It shows that scientific discoveries can take a long time to be solved and that the recipe for eureka moments like this is the collaborative work of several experts combined with modern technologies, plus a pinch of serendipity. It seems that all the stars were aligned this time for us, but it was certainly a hard nut to crack," he says.

Dr. Danila says that the team's next steps involve applying their discovery and newly developed methodologies to projects like the C4 rice project that aims to convert rice (a C3 photosynthesis crop) into the more productive C4 path.

We will also focus on another unsolved mystery: the case of a group of grasses which use C4 photosynthesis but do not have suberin,"

This research has been funded by the ARC Centre of Excellence for Translational Photosynthesis, which aims to improve the process of photosynthesis to increase the production of major food crops such as sorghum, wheat, and rice.

The research started as part of the C4 Rice Project consortium, which comprises the Academia Sinica, Australian National University, Max Planck Institute of Molecular Plant Physiology, Leibniz Institute of Biochemistry, University of Cambridge, University of Oxford, and Washington State University and is funded by a grant from the Bill & Melinda Gates Foundation to the University of Oxford.


The opinions expressed here are the views of the writer and do not necessarily reflect the views and opinions of AZoLifeSciences.
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