Scientists have solved the structure of one of the key components of photosynthesis, a discovery that could lead to photosynthesis being ‘redesigned’ to achieve higher yields and meet urgent food security needs.
The study, led by the University of Sheffield and published today (date) in the journalNature, reveals the structure of cytochromeb6f– the protein complex that significantly influences plant growth via photosynthesis.
Photosynthesis is the foundation of life on Earth providing the food, oxygen and energy that sustains the biosphere and human civilisation.
Using a high-resolution structural model, the team found that the protein complex provides the electrical connection between the two light-powered chlorophyll-proteins (Photosystems I and II) found in the plant cell chloroplast that convert sunlight into chemical energy.
Lorna Malone, the first author of the study and a PhD student in the University of Sheffield’s Department of Molecular Biology and Biotechnology, said: “Our study provides important new insights into how cytochromeb6futilises the electrical current passing through it to power up a ‘proton battery’. This stored energy can then be then used to make ATP, the energy currency of living cells. Ultimately this reaction provides the energy that plants need to turn carbon dioxide into the carbohydrates and biomass that sustain the global food chain.”
The high-resolution structural model, determined using single-particle cryo-electron microscopy, reveals new details of the additional role of cytochromeb6fas a sensor to tune photosynthetic efficiency in response to ever-changing environmental conditions. This response mechanism protects the plant from damage during exposure to harsh conditions such as drought or excess light.
Dr Matt Johnson, reader in Biochemistry at the University of Sheffield and one of the supervisors of the study added: “Cytochromeb6fis the beating heart of photosynthesis which plays a crucial role in regulating photosynthetic efficiency.
“Previous studies have shown that by manipulating the levels of this complex we can grow bigger and better plants. With the new insights, we have obtained from our structure we can hope to rationally redesign photosynthesis in crop plants to achieve the higher yields we urgently need to sustain a projected global population of 9-10 billion by 2050”.
The research was conducted in collaboration with the Astbury Centre for Structural Molecular Biology at the University of Leeds using their cryo-electron microscopy facilities.
Researchers now aim to establish how cytochromeb6fis controlled by a myriad of regulatory proteins and how these regulators affect the function of this complex.