Influence of polar and nonpolar carotenoids on structural and adhesive properties of model membranes

[Display omitted] •1mol% β-carotene resulted in a twofold increase of adhesion in DPPC liposomes.•1mol% zeaxanthin caused adhesion increase in DPPC vesicles by a factor of 10.•Occurrence of subphases in the gel lamellar state of DPPC bilayers was observed.•Bifurcation of these subphases was detected...

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Published in:Chemico-biological interactions 2015-09, Vol.239, p.19-25
Main Authors: Augustynska, Dominika, Jemioła-Rzemińska, Małgorzata, Burda, Kvetoslava, Strzałka, Kazimierz
Format: Article
Language:English
Subjects:
1,2-Dipalmitoylphosphatidylcholine - chemistry
Adhesion
Atomic force microscopy
beta Carotene - chemistry
Calorimetry, Differential Scanning
Carotenoids - chemistry
Carotenoids - pharmacology
Cell Adhesion
Cell Membrane - chemistry
Differential scanning calorimetry
Lipid Bilayers - chemistry
Liposomes - chemistry
Microscopy, Atomic Force
Model membrane
Phase Transition
Temperature
Xanthophylls - chemistry
Zeaxanthin
Zeaxanthins - chemistry
β-Carotene
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Summary:[Display omitted] •1mol% β-carotene resulted in a twofold increase of adhesion in DPPC liposomes.•1mol% zeaxanthin caused adhesion increase in DPPC vesicles by a factor of 10.•Occurrence of subphases in the gel lamellar state of DPPC bilayers was observed.•Bifurcation of these subphases was detected for DPPC liposomes with β-carotene. Carotenoids, which are known primarily for their photoprotective and antioxidant properties, may also strongly influence the physical properties of membranes. The localization and orientation of these pigments in the lipid bilayer depends on their structure and is determined by their interactions with lipid molecules. This affects both phase behavior and the mechanical properties of membranes. Differential scanning calorimetry (DSC) and atomic force microscopy (AFM) allowed us to gain a direct insight into the differences between the interaction of the non-polar β-carotene and polar zeaxanthin embedded into DPPC liposomes. DSC results showed that zeaxanthin, having polar ionone rings, interacts more strongly with the membrane lipids than β-carotene. The decrease in molar heat capacity by a factor of 2 with a simultaneous broadening of the main phase transition (gel-to-liquid crystalline phase transition) as compared to the two other systems studied suggests some increased length of the coupled interactions between the polar xanthophyll and lipids. Long-distance interactions lead to the formation of larger clusters which may exhibit higher flexibility than small clusters when only short-distance interactions occur. AFM experiments show that adhesive forces are 2 and 10 times higher for DPPC membranes enriched in β-carotene and zeaxanthin, respectively, than those observed for an untreated system. Temperature dependent measurements of adhesion revealed that subphases can be formed in the gel lamellar state of DPPC bilayers. The presence of the non-polar carotenoid enhanced the effect and even a bifurcation of the substates was detected within a temperature range of 30.0–32.5°C prior to pretransition. It is the first time when the presence of subphases has been demonstrated. This knowledge can be helpful in better understanding the functioning of carotenoids in biological membranes. AFM seem to be a very unique and sensitive method for detecting such fine changes in the lipid bilayers.
ISSN:0009-2797
1872-7786
DOI:10.1016/j.cbi.2015.06.021