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ABSTRACT: Oxidative modification of phospholipids generates a variety of oxidized phospholipid (Ox-PL) species which differ considerably in their chemical compositions and molecular structures. Recent results suggest that even closely related Ox-PL species can have considerably different biological effects. However, the molecular mechanism for this is not yet clear. In truncated Ox-PLs (tOx-PLs) the fatty acyl chain is shorter in length than the parent nonoxidized phospholipid molecules and contains a polar functional group(s). In a previous study we showed that two closely related tOx-PL species having a similar polar functional group and differing only in the length of the oxidized fatty acyl chain exerts significantly different effects on the physicochemical properties of the nonoxidized phospholipid particles containing these lipids (Kar et al., Chem Phys Lipids 164:54-61, 2011). In this study we have characterized the effect of polar functional groups of oxidized fatty acyl chain on the physicochemical properties of the nonoxidized phospholipid particles containing these lipids. Our results show that Ox-PL species differing only in the chemical nature of polar functional groups in their oxidized fatty acyl chain modify the properties of nonoxidized phospholipid particles containing them in a distinctive way. These results indicate that different species of Ox-PLs induce unique changes in the physicochemical properties of lipid particles/membranes containing them and that this may lead to their different biological effects.
Journal of Membrane Biology 05/2013; · 1.81 Impact Factor
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ABSTRACT: Apolipoprotein-derived peptides are promising candidates for the treatment of various inflammatory conditions and the main mechanism proposed for the protective action of these peptides includes binding to pro-inflammatory lipid mediators with high affinity and facilitating their sequestration/metabolism/clearance in the body. Molecules that act as pro-inflammatory lipid mediators differ considerably in their molecular structures, chemical compositions and physicochemical properties. Importance of the properties of pro-inflammatory lipid mediators on the biological activity of apolipoprotein-derived peptides has not been studied in detail. In this study, we characterized the physicochemical properties of aggregates containing lyso-PAF, acetyl-PAF and butanoyl-PAF, three closely related pro-inflammatory lipid mediators, and studied their interaction with peptides derived from the C-terminal domains of human apolipoprotein E. These PAF-analogs differ only in the chemical composition of the functional groups they carry at the sn-2 positions. Our results show that physicochemical properties of aggregates containing lyso-PAF, acetyl-PAF and butanoyl-PAF differ considerably and affect their apolipoprotein-derived peptides-binding capacity.
Biochimie 01/2013; · 3.02 Impact Factor
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ABSTRACT: High density lipoprotein (HDL) particles are made up of lipid and protein constituents and apolipoprotein A-I (apoA-I) is a principal protein component that facilitates various biological activities of HDL particles. Increase in Ox-PL content of HDL particles makes them 'dysfunctional' and such modified HDL particles not only lose their athero-protective properties but also acquire pro-atherogenic and pro-inflammatory functions. The details of Ox-PL-induced alteration in the molecular properties of HDL particles are not clear. Paraoxonase 1 (PON1) is an HDL-associated enzyme that possesses anti-inflammatory and anti-atherogenic properties; and many of the athero-protective functions of HDL are attributed to the associated PON1. In this study we have characterized the physicochemical properties of reconstituted HDL (rHDL) particles containing varying amounts of Ox-PL and have compared their PON1 stimulation capacity. Our results show that increased Ox-PL content (a) modifies the physicochemical properties of the lipid domain of the rHDL particles, (b) decreases the stability and alters the conformation as well as orientation of apoA-I molecules on the rHDL particles, and (c) decreases the PON1 stimulation capacity of the rHDL particles. Our data indicate that the presence of Ox-PLs destabilizes the structure of the HDL particles and modifies their function.
Biochimica et Biophysica Acta 05/2012; 1821(9):1200-10. · 4.66 Impact Factor
