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Phonon-mediated passive transport in lipid membranes
13-06-2016
Through an experiment at the ESRF, scientists from Brookhaven National Laboratory have found evidence for propagating in-plane transverse phonon modes in a DPPC lipid membrane. These transverse phonon modes exhibit phononic gaps upon temperature increase, providing a direct signature of the existence of transient voids caused by short-lived lipid density fluctuations that mediate solute permeation across the membrane. The finding supports the mechanism of passive transport through entropic expulsion of the solute from higher to lower lipid density regions across the membrane.
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A biological membrane serves as a selective barrier between the internal compartment of the cell and the cell's surroundings. Most biological molecules are unable to diffuse across the lipid bilayer. However, due to thermally-induced vibrations in the membrane, a cell can passively transport molecules using these natural thermal motions. It has been experimentally shown that many factors, such as solute nature, molecule type or membrane thickness define the permeation process. Different theories were proposed to account for other parameters such as solute hydrophobicity, molecular size and shape, membrane fluidity and packing density. However, despite these efforts, inconsistencies still persist and the exact mechanism of passive transport still remains unknown.
We used a new approach to study lipid dynamics, which pinpoints the importance of collective molecular excitations in passive transport across the lipid bilayer. Using the high resolution inelastic X-ray scattering (IXS) technique combined with a newly-developed phonon theory of liquids [1], two important discoveries were made. First, the IXS experiment identified propagating in-plane transverse phonon modes in a DPPC (1,2-dipalmitoyl-sn-glycero-3-phosphocholine) lipid membrane that have not been experimentally observed before. Second, the measurements revealed the opening of a phononic gap in the transverse excitations with increasing temperature across the main (gel to liquid) phase transition.
The measurements were performed at beamline ID28, collecting data below (20°C) and above (45°C) the main transition temperature (Tm = 41°C). Figure 1 illustrates the scattering geometry of the IXS experiment and the experimentally-obtained longitudinal and transverse phonon dispersion curves.
The observation of the phononic gap is highly significant as it reveals a possible mechanism for transmembrane passive transport. Specifically, the results confirmed the theoretical prediction [2] that phononic interaction induces transverse phononic gaps in disordered materials. Such gaps are related to the diffusion and relaxation processes occurring in the lipid membrane and are a direct signature of short-lived (picosecond scale) local lipid clustering in the membrane over short-to-intermediate length scales (Figure 2). On long length scales, the opening of the phononic gap in the transverse phonon modes signifies the formation of short-lived voids stipulating that the transverse phonon propagation is no longer supported due to the increasing lipid chain disorder.
Our results support the notion that the local lipid chain disorder directly mediates solute diffusion across the membrane. The entropic expulsion of the solute from the higher to lower lipid density regions is essentially thermally-triggered. The simultaneous lipid clustering and void formation provide the mechanism for the solute to diffuse across the membrane by hopping between voids. Both local lipid density fluctuations on short-to-intermediate length scales and void formation on longer length scales is clear evidence for the universal phonon-triggered mechanism of passive membrane transport.
Principal publication and authors
Revealing the mechanism of passive transport in lipid bilayers via phonon-mediated nanometre-scale density fluctuations, M. Zhernenkov (a), D. Bolmatov (a), D. Soloviov (b,c), K. Zhernenkov (d), B.P. Toperverg (e,f), A. Cunsolo (a), A. Bosak (g), Y.Q. Cai (a), Nat. Commun. 7, 11575 (2016); doi: 10.1038/ncomms11575.
(a) National Synchrotron Light Source II, Brookhaven National Laboratory, Upton (USA)
(b) Frank Laboratory of Neutron Physics, Joint Institute for Nuclear Research, Dubna (Russia)
(c) Moscow Institute of Physics and Technology, Dolgoprudny (Russia)
(d) Institut Nanosciences et Cryogénie, CEA, Grenoble (France)
(e) Petersburg Nuclear Physics Institute, Gatchina (Russia)
(f) ILL, Grenoble (France)
(g) ESRF
References
[1] D. Bolmatov, D. Zav’yalov, M. Zhernenkov, E.T. Musaev, Y.Q. Cai, Ann. Phys. 363, 221–242 (2015).
[2] D. Bolmatov, M. Zhernenkov, D. Zav’yalov, S. Stoupin, A. Cunsolo, Y.Q. Cai, Sci. Rep. 6, 19469 (2016).
Top image: Phonon-mediated mechanism of passive transport through a lipid membrane.