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Lipids constitute a diverse group of biomolecules of varied biologic roles. Their major function is to serve as building blocks of the biologic membranes. According to the fluid‐mosaic model, the biomembranes are liquid‐crystalline lipid bilayers with embedded proteins. This model includes two references to the lipid phase state— liquid crystalline and bilayer —both of which are of critical importance for the proper membrane functioning. The majority of lipids are amphiphilic compounds, which, similarly to other surfactants, also can form a large variety of other, non‐liquid‐crystalline and nonbilayer phases by transforming into each other via different kinds of phase transitions. In particular, the impressive variety of lipids in the biomembranes includes a large fraction of species that in isolation prefer to adopt curved, hexagonal, or cubic phases rather than the lamellar phase. The physiologic importance of the lipid diversity and mesomorphic behavior stems from the possibility of finely tuning and optimizing the properties of the biomembranes by regulating their lipid composition.
Lipids constitute a diverse group of biomolecules of varied biologic roles. Their major function is to serve as building blocks of the biologic membranes. According to the fluid‐mosaic model, the biomembranes are liquid‐crystalline lipid bilayers with embedded proteins. This model includes two references to the lipid phase state— liquid crystalline and bilayer —both of which are of critical importance for the proper membrane functioning. The majority of lipids are amphiphilic compounds, which, similarly to other surfactants, also can form a large variety of other, non‐liquid‐crystalline and nonbilayer phases by transforming into each other via different kinds of phase transitions. In particular, the impressive variety of lipids in the biomembranes includes a large fraction of species that in isolation prefer to adopt curved, hexagonal, or cubic phases rather than the lamellar phase. The physiologic importance of the lipid diversity and mesomorphic behavior stems from the possibility of finely tuning and optimizing the properties of the biomembranes by regulating their lipid composition.
The kinetics of the lamellar gel (Lp) to inverse hexagonal (Hll) phase transition as well as the L,+La phase change of aqueous suspensions of glycolipids were characterized using ms laser T-jump techniques in combination with synchrotron X-ray diffraction. The glycolipids employed were 1,2-di-O-alkyl-3-0-P-D-glucosyl-snglycerols with identical alkyl chains of 16 and 18 carbon atoms, respectively, and 1,2-di-O-alky1-3-O-P-D-galactosyl-sn-glycerol with C,, chains. The time course of the Lc-+La phase transition was probed using 1,2-di-O-hexadecyl-3-O-~-D-lactosyl-sn-glycerol, whose head group consists of the disaccharide P-D-galactopyranosyl-(1 -4)-P-D-glucopyranoside. Surprisingly the phase change from the lamellar to the inverse hexagonal topology is very fast despite the major structural changes involved in the lipid-water interface. The overall phase change of both glucolipids can be quantitatively described by a sequential mechanism of the type Lp A I A HIl.The intermediate I is thinner than both the Lp and the HI, phases. It has a relatively broad distribution of d-spacings and relaxes into the HI, phase with half times of approximately 125 ms (16-1,Z-Glc) and 244 ms (18-1,2-Glc), respectively. Both rate constants, k, and k,, are chain length dependent.The galactolipid transforms into the HI, phase following a sequential mechanism of the type Lg & I' % I & HII. The additional intermediate I' can be assigned to a lamellar phase bearing similarity to a thin La phase. The specific features of the galactose head group compared to glucose as head group that have been previously observed in equilibrium studies are also evident in the kinetic mechanism in that comparative structural changes in the intermediates are slower in the galactolipid than in the chain-homologous glucolipid.There is evidence from the X-ray data that the general transition mechanism is identical for gluco-and galactolipids. However, the first intermediate I' disappears too fast in the glucolipid phase change to be detectable with the present time resolution of the X-ray measurements.The kinetics of the phase change of the lactolipid is characterized within the resolution of the X-ray sequence (5ms) by a strict two-state mechanism L, --t La with transient coexistence of the initial and final phase during the kinetic phase transformation. The relaxation time has been found to be highly temperature dependent, being 57 ms at 79.1 "C and 14 ms at 81.1 "C.It is worth noting that there appears to be a principal difference in the phase change mechanism between glycolipids with mono-or disaccharide head groups in that the latter (16-1.2-Lac) shows no sign of any kinetic intermediate state. k k k k arrangements of the lipids, as seen in the HI, phase formed by a variety of lipids [8 -101. Prominent members of these lipids that form readily non-bilayer structures are glycolipids, both synthetic and natural, provided they have head groups that are small in surface area in comparison to the hydrophobic part of the molecule [l I]. Glycolipids show the most s...
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