Cholesterol modulates curcumin partitioning and membrane effects.

Curcumin, a polyphenol molecule, presents a wide range of biological activities as antioxidant, anticancer, anti-inflammatory, antimicrobial and wound healing. Although some strengths attributed to curcumin derive from promiscuous biological activity, possibly because curcumin can interfere on many membrane located processes, knowledge of underlying interactions are lacking. Mammalian cell membranes characteristically contain 25 to 50% cholesterol/phospholipid ratio; however, most studies involving lipid bilayers and curcumin consider pure phosphatidylcholine and compare effects of curcumin on membranes with those of cholesterol. We investigated the interaction of curcumin with lipid bilayers containing cholesterol mimicking mammalian cells, and used spectroscopy techniques to determine partition coefficients, rigidity parameters and lytic activity. We found that curcumin partitions into different lipid bilayers (104 order coefficients that vary by less than a factor of two), containing cholesterol or not, and in the presence of sphingomyelin or phosphatidylserine. Curcumin decreases rigidity in all tested compositions, except that containing 40% cholesterol in which it increases the lipid packing order. In addition, curcumin induces leakage from giant unilamellar vesicles on a cholesterol concentration dependent way. Our results are compatible with the hypothesis of curcumin interaction with membranes being modulated by the liquid disordered phase and by the coexistence of liquid-ordered/liquid disordered phases. In bilayers containing cholesterol, curcumin assumes a more superficial location, drastically stiffens the 40% cholesterol bilayer and decreases the lytic effect. Our study may help researchers in the analysis of the biological effects of curcumin and curcumin-derived formulations by calling the attention to the discriminating role of the cholesterol content.

New insight into the mechanism of action of wasp mastoparan peptides: lytic activity and clustering observed with giant vesicles.

Antimicrobial peptides of the mastoparans family exert their bactericidal activity by binding to lipid membranes, inducing pores or defects and leaking the internal contents of vesicles and cells. However, this does not seem to be the only mechanism at play, and they might be important in the search for improved peptides with lower undesirable side effects. This work deals with three mastoparans peptides, Polybia-MP-1(MP-1), N2-Polybia-MP-1 (N-MP-1), and Mastoparan X (MPX), which exhibit high sequence homology. They all have three lysine residues and amidated C termini, but because of the presence of two, one, and no aspartic acid residues, respectively, they have +2, +3, and +4 net charges at physiological pH. Here we focus on the effects of these mastoparans peptides on anionic model membranes made of palmitoleyoilphosphatidylcholine (POPC) and palmitoleyoilphosphatidylglycerol (POPG) at 1:1 and 3:1 molar ratios in the presence and in the absence of saline buffer. Zeta potential experiments were carried out to measure the extent of the peptides' binding and accumulation at the vesicle surface, and CD spectra were acquired to quantify the helical structuring of the peptides upon binding. Giant unilamellar vesicles were observed under phase contrast and fluorescence microscopy. We found that the three peptides induced the leakage of GUVs at a gradual rate with many characteristics of the graded mode. This process was faster in the absence of saline buffer. Additionally, we observed that the peptides induced the formation of dense regions of phospholipids and peptides on the GUV surface. This phenomenon was easily observable for the more charged peptides (MPX > N-MP-1 > MP-1) and in the absence of added salt. Our data suggest that these mastoparans accumulate on the bilayer surface and induce a transient interruption to its barrier properties, leaking the vesicle contents. Next, the bilayer recovers its continuity, but this happens in an inhomogeneous way, forming a kind of ply with peptides sandwiched between two juxtaposed membranes. Eventually, a peptide-lipid aggregate forming a lump is formed at high peptide-to-lipid ratios.