Phospholipid head group dynamics have been studied by pulsed phosphorus-31 nuclear magnetic resonance (31P-NMR) of unoriented and macroscopically aligned dimyristoylphosphatidylcholine model membranes in the temperature range, 203-343 K. Lineshapes and echo intensities have been recorded as a function of interpulse delay times, temperature and macroscopic orientation of the bilayer normal with respect to the magnetic field. The dipolar proton-phosphorus (1H-31P) contribution to the transverse relaxation time, T2E, and to lineshapes was eliminated by means of a proton spin-lock sequence. In case of longitudinal spin relaxation, T1Z, the amount of dipolar coupling was evaluated by measuring the maximum nuclear Overhauser enhancement. Hence, the results could be analyzed by considering chemical shift anisotropy as the only relaxation mechanism. The presence of various minima both in T1Z and T2E temperature plots as well as the angular dependence of these relaxation times allowed description of the dynamics of the phosphate head group in the 31P-NMR time window, by three different motional classes, i.e., intramolecular, intermolecular and collective motions. The intramolecular motions consist of two hindered rotations and one free rotation around the bonds linking the phosphate head group to the glycerol backbone. These motions are the fastest in the hierarchy of time with correlation times varying from less than 10(-12) to 10(-6) s in the temperature range investigated. The intermolecular motions are assigned to phospholipid long axis rotation and fluctuation. They have correlation times ranging from 10(-11) s at high temperatures to 10(-3) s at low temperatures. The slowest motion affecting the 31P-NMR observables is assigned to viscoelastic modes, i.e., so called order director fluctuations and is only detected at high temperatures, above the main transition in pulse frequency dependent T2ECP experiments. Comprehensive analysis of the phosphate head group dynamics is achieved by a dynamic NMR model based on the stochastic Liouville equation. In addition to correlation times, this analysis provides activation energies and order parameters for the various motions, and a value for the bilayer elastic constant.
Multipulse dynamic NMR has been employed to study molecular order and dynamics of deuteron (2H) labeled phospholipid membranes. Variation of pulse sequence and pulse separation provides the large number of independent experiments necessary for a proper molecular characterization of the systems. Analysis of these experiments is achieved by employing a density matrix formalism, based on the stochastic Liouville equation. Arbitrary relaxation rates and line shapes of single and multiple quantum transitions are considered. The various 2H NMR experiments of macroscopically unoriented bilayers of 1,2-dimyristoyl-sn-glycero-3-phosphocholine (DMPC), specifically deuterated at the 6- and 14-position of the 2-chain, are faithfully reproduced by the model. Computer simulations provide the orientational distributions and conformations of the hydrocarbon chains and the correlation times of the various motions. In the Lα phase the correlation times τR∥ and τR⊥ for chain rotation and chain fluctuation are of the order of 10−8 s, while trans–gauche isomerization occurs significantly faster (τJ∼10−10 s). At the main transition all chain motions slow down abruptly. Further cooling in the Pβ′ phase first continuously decreases the motions. However, 10 K below the pretransition (hysteresis), there is another abrupt slow down of the chain dynamics. In the Lβ′ phase at T=265 K all three motions occur with correlation times of 10−6 to 10−5 s. Because of higher activation energies, however, intermolecular chain motions freeze out first on the time scale of a particular NMR experiment. Thus, at temperatures T<210 K, trans–gauche isomerization becomes the dominant process. Detection of this motion is possible even at T=168 K, where τJ is of the order of 10−4 s. Arrhenius plots of the various correlation times provide the motional activation energies. Values of 9<EJ<14 kJ/mol for trans–gauche isomerization correspond to the local character of this process. As expected, the activation energies for chain rotation (50<ER∥ <69 kJ/mol) and chain fluctuation (53<ER⊥ <79 kJ/mol) are substantially higher. The correlation times for methyl group rotation form a continuous straight line on the Arrhenius plot throughout the three phases studied, yielding an activation energy of EJ(CD3) =9.9 kJ/mol. Molecular order of the chains is discussed in terms of two parameters SZZ and SZ′Z′, characterizing the orientational order of the chains as a whole and the conformational order at a particular segment. In the Lα phase the hydrocarbon chains are partially disordered (0.44<SZZ <0.6) and melted, exhibiting segmental order parameters of SZ′Z′ (C-6)∼0.75 and SZ′Z′ (C-13)∼0.35, respectively. As expected, conformational order decreases from the central unit to the terminal one (order gradient). The Pβ′ phase exhibits two different chain order parameters of SZZ ∼0.6 and SZZ ∼0.9, indicating heterogeneous chain packing. A unique structural interpretation of this result is not yet possible since the microscopic heterogeneity is compatible with most proposed models. In the Lβ′ phase we find SZZ >0.95, SZ′Z′ (C-6)>0.95, and SZ′Z′ (C-13)>0.9, consistent with highly ordered, fully extended hydrocarbon chains.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
customersupport@researchsolutions.com
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
This site is protected by reCAPTCHA and the Google Privacy Policy and Terms of Service apply.
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.