Energetic robustness to large scale structural fluctuations in a photosynthetic supercomplex

Dvir Harris, Hila Toporik, Gabriela S. Schlau-Cohen*, Yuval Mazor*

*Corresponding author for this work

Research output: Contribution to journalArticlepeer-review

3 Scopus citations


Photosynthetic organisms transport and convert solar energy with near-unity quantum efficiency using large protein supercomplexes held in flexible membranes. The individual proteins position chlorophylls to tight tolerances considered critical for fast and efficient energy transfer. The variability in protein organization within the supercomplexes, and how efficiency is maintained despite variability, had been unresolved. Here, we report on structural heterogeneity in the 2-MDa cyanobacterial PSI-IsiA photosynthetic supercomplex observed using Cryo-EM, revealing large-scale variances in the positions of IsiA relative to PSI. Single-molecule measurements found efficient IsiA-to-PSI energy transfer across all conformations, along with signatures of transiently decoupled IsiA. Structure based calculations showed that rapid IsiA-to-PSI energy transfer is always maintained, and even increases by three-fold in rare conformations via IsiA-specific chls. We postulate that antennae design mitigates structural fluctuations, providing a mechanism for robust energy transfer in the flexible membrane.

Original languageAmerican English
Article number4650
JournalNature Communications
Issue number1
StatePublished - Dec 2023

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