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New discovery reveals how diatoms capture CO2 so effectively

Diatoms frozen on an electron microscopy grid (copper)
Diatoms (blue/white/yellow) frozen on an electron microscopy grid (copper) during a sample preparation step for cryo-electron tomography. (Image: Benoit Gallet and Martin Oeggerli, Micronaut)

Tiny diatoms in the ocean are masters at capturing carbon dioxide (CO2) from the environment. They fix up to 20 percent of the Earth’s CO2. A research team at the University of Basel has now discovered a protein shell in these algae that is necessary for efficient CO2 fixation. This groundbreaking discovery can provide ideas for bioengineering approaches to reduce CO2 in the atmosphere.

17 October 2024 | Heike Sacher

Diatoms frozen on an electron microscopy grid (copper)
Diatoms (blue/white/yellow) frozen on an electron microscopy grid (copper) during a sample preparation step for cryo-electron tomography. (Image: Benoit Gallet and Martin Oeggerli, Micronaut)

Diatoms are too small to see with the naked eye, yet they are one of the most productive algae species in the ocean and play an important role in the global carbon cycle. Using photosynthesis, they absorb large amounts of CO2 from the environment and convert it into nutrients that feed much of the life in the ocean. Despite their importance, it has remained largely unknown how diatoms carry out this process so efficiently.

Researchers led by Professor Ben Engel at the Biozentrum of the University of Basel together with researchers at the University of York, UK, and the Kwansei-Gakuin University in Japan have now discovered a protein shell that plays a key role in the diatoms' CO2 fixation. Using cutting-edge imaging technologies such as cryo-electron tomography (cryo-ET), the researchers were able to reveal the molecular architecture of the so-called PyShell protein sheath and decipher its function. The results of the studies have now been published in two articles in "Cell".

PyShell crucial for efficient CO2 fixation

In plants and algae, photosynthesis takes place in chloroplasts. Inside these chloroplasts, energy from sunlight is harvested by thylakoid membranes and then used to help the enzyme Rubisco fix CO2.

Illustration of a diatom with the structure of a chloroplast
Cryo-electron tomography reveals the molecular architecture of the diatom pyrenoid, showing how Rubisco is surrounded by the PyShell, increasing the efficiency of CO2 fixation. (Image: Gröger et al. / Manon Demulder, Biozentrum, Universität Basel)

However, algae have an advantage: they pack all their Rubisco into small compartments called pyrenoids, where CO2 can be captured more efficiently. “We have now discovered that diatom pyrenoids are encased in a lattice-like protein shell,” says Dr. Manon Demulder, author on both studies. “The PyShell not only gives the pyrenoid its shape, but it helps create a high CO2 concentration in this compartment. This enables Rubisco to efficiently fix CO2 from the ocean and convert it into nutrients.”


Original publications

Ginga Shimakawa, Manon Demulder, Serena Flori, Akihiro Kawamoto, Yoshinori Tsuji, Hermanus Nawaly, Atsuko Tanaka, Rei Tohda, Tadayoshi Ota, Hiroaki Matsui, Natsumi Morishima, Ryosuke Okubo, Wojciech Wietrzynski, Lorenz Lamm, Ricardo D. Righetto, Clarisse Uwizeye, Benoit Gallet, Pierre-Henri Jouneau, Christoph Gerle, Genji Kurisu, Giovanni Finazzi, Benjamin D. Engel, Yusuke Matsuda
Diatom pyrenoids are encased in a protein shell that enables efficient CO₂ fixation.
Cell (2024), doi: 10.1016/j.cell.2024.09.013

Onyou Nam, Sabina Musial, Manon Demulder, Caroline McKenzie, Adam Dowle, Matthew Dowson, James Barrett, James N. Blaza, Benjamin D. Engel, Luke C. M. Mackinder
A Protein Blueprint of the Diatom CO₂-Fixing Organelle.
Cell (2024), doi: 10.1016/j.cell.2024.09.025

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