Abstract:
Analysis of the nuclear spin relaxation rates of lipid membranes provides a powerful means of studying the dynamics of these important biological representatives of soft matter. Here, temperature- and frequency-dependent 2H and 13C nuclear magnetic resonance (NMR) relaxation rates for vesicles and multilamellar dispersions of 1,2-dimyristoyl-sn-glycero-3-phosphocholine (DMPC) in the liquid-crystalline state have been fitted simultaneously to various dynamic models for different positions of the acyl chains. The data include 2H R1z rates (Zeeman order of electric quadrupolar interaction) acquired at 12 external magnetic field strengths from 0.382 to 14.6 T, corresponding to a frequency range from ωD/2π=2.50-95.3 MHz; and 2H R1Q rates (quadrupolar order of electric quadrupolar interaction) at 15.3, 46.1, and 76.8 MHz. Moreover, 13C R1z data (Zeeman order of magnetic dipolar interaction) for DMPC are included at six magnetic field strengths, ranging from 1.40 to 17.6 T, thereby enabling extension of the frequency range to effectively (ωC+ωH)/2π=938.7 MHz. Use of the generalized approach allows formulation of noncollective segmental and molecular diffusion models, as well as collective director fluctuation models, which were tested by fitting the 2H R1Z data at different frequencies and temperatures (30 °C and 50 °C). The corresponding 13C relaxation rates were predicted theoretically and compared to experiment, thus allowing one to unify the 13C and 2H NMR data for bilayer lipids in the fluid state. A further new aspect is that the spectral densities of motion have been explicitly calculated from the 2H R1Z and R1Q data at 40 °C. We conclude that the relaxation in fluid membrane bilayers is governed predominantly by relatively slow motions, which modulate the residual coupling remaining from faster local motions (order fluctuations). Only the molecular diffusion model, including an additional slow motional process, and the membrane deformation model describing three-dimensional collective fluctuations fit the 2H NMR data and predict the 13C NMR data in the MHz range. Orientational correlation functions have been calculated, which emphasizes the importance of NMR relaxation as a unique tool for investigating the dynamics of lipid bilayers and biological membranes. © 1997 American Institute of Physics.
Abstract:
The quadrupolar relaxation of deuterium-labeled lipid bilayers has been analyzed using standard Redfield theory and is discussed with regard to the problem of chain segmental motion and order in membranes. Considering the segmental reorientation as a stochastic process, the T1 and T2 relaxation rates are interpreted in terms of the rate of motion, characterized by one or more correlation times τ2M, and statistical amplitude, characterized by the segmental order parameter SCD. For the case of phospholipid bilayers with |SCD| ≲ 0.2, the relaxation rates are predominantly determined by the rate of motion, rather than the ordering. Recently obtained T, relaxation data for selectively deuterated and perdeuterated multilamellar dispersions of 1,2-dipalmitoyl-sn-glycero-3-phosphocholine are analyzed and compared to the results of previous carbon-13 T1 relaxation studies. The available experimental results suggest that the fast segmental motions affecting T1 in these systems can be treated to a reasonable degree of approximation in terms of a single effective correlation time. © 1979.
