Protein shape and crowding drive domain formation and curvature in biological membranes
Publication date
2008-01
Authors
Frese, R.N.
Pàmies, J.C.
Olsen, J.D.
Bahatyrova, S.
Weij-de Wit, C.D. van der
Aartsma, T.J.
Otto, C.
Hunter, N.
Frenkel, D.
Grondelle, R. van
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DOI
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Article
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Abstract
Folding, curvature, and domain formation are characteristics of many biological membranes. Yet the mechanisms
that drive both curvature and the formation of specialized domains enriched in particular protein complexes are unknown.
For this reason, studies in membranes whose shape and organization are known under physiological conditions are of great
value. We therefore conducted atomic force microscopy and polarized spectroscopy experiments on membranes of the
photosynthetic bacterium Rhodobacter sphaeroides. These membranes are densely populated with peripheral light harvesting
(LH2) complexes, physically and functionally connected to dimeric reaction center-light harvesting (RC-LH1-PufX) complexes.
Here, we show that even when converting the dimeric RC-LH1-PufX complex into RC-LH1 monomers by deleting the gene
encoding PufX, both the appearance of protein domains and the associated membrane curvature are retained. This suggests
that a general mechanism may govern membrane organization and shape. Monte Carlo simulations of a membrane model
accounting for crowding and protein geometry alone confirm that these features are sufficient to induce domain formation and
membrane curvature. Our results suggest that coexisting ordered and fluid domains of like proteins can arise solely from
asymmetries in protein size and shape, without the need to invoke specific interactions. Functionally, coexisting domains of
different fluidity are of enormous importance to allow for diffusive processes to occur in crowded conditions.