Temperature and Compositional Dependence of the Structure of Hydrated Dimyristoyl Lecithin
Overview
Authors
Affiliations
Differential scanning calorimetry and x-ray diffraction techniques have been used to investigate the structure and phase behavior of hydrated dimyristoyl lecithin (DML) in the hydration range 7.5 to 60 weight % water and the temperature range -10 to +60 degrees C. Four different calorimetric transitions have been observed: T1, a low enthalpy transition (deltaH approximately equal to 1 kcal/mol of DML) at 0 degrees C between lamellar phases (L leads to Lbeta); T2, the low enthalpy "pretransition" at water contents greater than 20 weight % corresponding to the transition Lbeta leads to Pbeta; T3, the hydrocarbon chain order-disorder transition (deltaH = 6 to 7 kcal/mol of DML) representing the transition of the more ordered low temperature phases (Lbeta, Pbeta, or crystal C, depending on the water content) to the lamellar Lalpha phase; T4, a transition occurring at 25--27 degrees C at low water contents representing the transition from the lamellar Lbeta phase to a hydrated crystalline phase C. The structures of the Lbeta, Pbeta, C, and Lalpha phases have been examined as a function of temperature and water content. The Lbeta structure has a lamellar bilayer organization with the hydrocarbon chains fully extended and tilted with respect to the normal to the bilayer plane, but packed in a distorted quasihexagonal lattice. The Pbeta structure consists of lipid bilayer lamellae distorted by a periodic "ripple" in the plane of the lamellae; the hydrocarbon chains are tilted but appear to be packed in a regular hexagonal lattice. The diffraction pattern from the crystalline phase C indexes according to an orthorhombic cell with a = 53.8 A, b = 9.33 A, c = 8.82 A. In the lamellae bilayer Lalpha strucure, the hydrocarbon chains adopt a liquid-like conformation. Analysis of the hydration characteristics and bilayer parameters (lipid thickness, surface area/molecule) of synthetic lecithins permits an evaluation of the generalized hydration and structural behavior of this class of lipids.
Magalhaes F, Vieira E, Batista M, Costa-Filho A, Basso L Membranes (Basel). 2024; 14(12).
PMID: 39728717 PMC: 11678188. DOI: 10.3390/membranes14120267.
"Head-to-Toe" Lipid Properties Govern the Binding and Cargo Transfer of High-Density Lipoprotein.
Weber F, Axmann M, Sezgin E, Amaro M, Sych T, Hochreiner A Membranes (Basel). 2024; 14(12.
PMID: 39728711 PMC: 11677176. DOI: 10.3390/membranes14120261.
Crystallization of -Alkanes under Anisotropic Nanoconfinement in Lipid Bilayers.
Wurl A, Ott M, Schwieger C, Ferreira T J Phys Chem B. 2024; 129(1):435-446.
PMID: 39696749 PMC: 11726633. DOI: 10.1021/acs.jpcb.4c04332.
Structure and thermodynamics of supported lipid membranes on hydrophobic van der Waals surfaces.
Read H, Benaglia S, Fumagalli L Soft Matter. 2024; 20(29):5724-5732.
PMID: 38979701 PMC: 11268427. DOI: 10.1039/d4sm00365a.
Hybrid bilayer membranes as platforms for biomimicry and catalysis.
Zeng T, Gautam R, Ko D, Wu H, Hosseini A, Li Y Nat Rev Chem. 2023; 6(12):862-880.
PMID: 37117701 DOI: 10.1038/s41570-022-00433-2.