Diatom pyrenoids are encased in a protein shell that enables efficient CO₂fixation

Abstract: Pyrenoids are subcompartments of algal chloroplasts that concentrate Rubisco enzymes and their CO2 substrate, thereby increasing the efficiency of carbon fixation. Diatoms perform up to 20% of global CO2 fixation, but their pyrenoids remain poorly characterized at a molecular level. Here, we used in vivo photo-crosslinking to catalogue components of diatom pyrenoids and identified a pyrenoid shell (PyShell) protein, which we localized to the pyrenoid periphery of both the pennate diatom, Pheaodactylum tricornu… Show more

“…A similar concept has been suggested for encapsulins which self-assemble and have been demonstrated to encapsulate specific cargo (Giessen & Silver, 2017). The recent identification of encapsulated pyrenoids provides further models for novel Rubisco compartmentalisation systems (Nam et al, 2023;Shimakawa et al, 2023). Collectively, these examples demonstrate that novel synthetic biology approaches could be considered to transplant a faster Rubisco into plants whilst also providing a localised and optimal CO 2 concentration for the enzyme to operate within.…”

“…Surrounding this Rubisco matrix is a starch sheath that minimises CO 2 leakage (Toyokawa et al, 2020), while tubules also traverse the matrix and are speculated to deliver CO 2 (Engel et al, 2015). In recent analyses of diatom pyrenoids, protein shells have been identified as potential diffusional barriers to substrate entry (Nam et al, 2023;Shimakawa et al, 2023). Similar to carboxysomes, pyrenoid Rubisco phaseseparates with EPYC1 to form a dynamic, flexible matrix (Freeman-Rosenzweig et al, 2017;He et al, 2020He et al, , 2023Wunder et al, 2018), in an interaction mediated by Rubisco small subunit helices (Atkinson et al, 2019;Meyer et al, 2012).…”

A carboxysome‐based CO₂ concentrating mechanism for C₃ crop chloroplasts: advances and the road ahead

“…A similar concept has been suggested for encapsulins which self-assemble and have been demonstrated to encapsulate specific cargo (Giessen & Silver, 2017). The recent identification of encapsulated pyrenoids provides further models for novel Rubisco compartmentalisation systems (Nam et al, 2023;Shimakawa et al, 2023). Collectively, these examples demonstrate that novel synthetic biology approaches could be considered to transplant a faster Rubisco into plants whilst also providing a localised and optimal CO 2 concentration for the enzyme to operate within.…”

“…Surrounding this Rubisco matrix is a starch sheath that minimises CO 2 leakage (Toyokawa et al, 2020), while tubules also traverse the matrix and are speculated to deliver CO 2 (Engel et al, 2015). In recent analyses of diatom pyrenoids, protein shells have been identified as potential diffusional barriers to substrate entry (Nam et al, 2023;Shimakawa et al, 2023). Similar to carboxysomes, pyrenoid Rubisco phaseseparates with EPYC1 to form a dynamic, flexible matrix (Freeman-Rosenzweig et al, 2017;He et al, 2020He et al, , 2023Wunder et al, 2018), in an interaction mediated by Rubisco small subunit helices (Atkinson et al, 2019;Meyer et al, 2012).…”

A carboxysome‐based CO₂ concentrating mechanism for C₃ crop chloroplasts: advances and the road ahead

Comparing Diatom Photosynthesis with the Green Lineage

Translocation of Proteins into Four Membrane-Bound Complex Plastids of Red Algal Origin