Neutron scattering studies of photosynthetic membranes in aqueous dispersion

A method for structural analysis of biological membranes using neutron scattering from suspensions is described and applied to photosynthetic membranes from bacteria. The variation of scattering density across the membrane is analysed using small-angle scattering and contrast variation with H₂O/²H₂O mixtures. Effects due to membrane curvature and scattering density variation in the plane of the membrane are evaluated. Thickness parameters (D) are obtained from the small-angle scattering data, which are the one-dimensional analogues of radii of gyration. The formalism of contrast variation is used to describe the change of intensity and thickness parameter with H₂O/²H₂O mixture. The results are expressed in terms of a thickness parameter at infinite contrast, which is directly related to the physical thickness of the membrane, and a measure of the variation of the scattering density across the membrane, produced, for example, by the higher scattering densities of the polar surfaces relative to a hydrocarbon interior of the membrane. Asymmetry in the membrane scattering density is also evaluated.The results for photosynthetic membranes demonstrate a lipid hydrocarbon core in the membrane. About two-thirds of the protein is closely associated with the lipid layer, and no substantial amounts of protein project more than short distances from the lipid layer. There is a contribution to the variation in scattering density across the membrane that cannot be attributed to lipid, and may involve scattering density heterogeneity within the protein, giving a high proportion of hydrophobic protein segments at the interior of the membrane that have lower scattering densities than the hydrophilic segments at the surfaces of the membrane. The membrane scattering density is not markedly asymmetric. Several alternative structures previously proposed for photosynthetic membranes are incompatible with these results.