Ethanol-lipid bilayer interactions have been a recurrent theme in membrane biophysics, due to their contribution to the understanding of membrane structure and dynamics. The main purpose of this study was to assess the interplay between membrane lateral heterogeneity and ethanol effects. This was achieved by in situ atomic force microscopy, following the changes induced by sequential ethanol additions on supported lipid bilayers formed in the absence of alcohol. Binary phospholipid mixtures with a single gel phase, dipalmitoylphosphatidylcholine (DPPC)/cholesterol, gel/fluid phase coexistence DPPC/dioleoylphosphatidylcholine (DOPC), and ternary lipid mixtures containing cholesterol, mimicking lipid rafts (DOPC/DPPC/cholesterol and DOPC/sphingomyelin/cholesterol), i.e., with liquid ordered/liquid disordered (ld/lo) phase separation, were investigated. For all compositions studied, and in two different solid supports, mica and silicon, domain formation or rearrangement accompanied by lipid bilayer thinning and expansion was observed. In the case of gel/fluid coexistence, low ethanol concentrations lead to a marked thinning of the fluid but not of the gel domains. In the case of ld/lo all the bilayer thins simultaneously by a similar extent. In both cases, only the more disordered phase expanded significantly, indicating that ethanol increases the proportion of disordered domains. Water/bilayer interfacial tension variation and freezing point depression, inducing acyl chain disordering (including opening and looping), tilting, and interdigitation, are probably the main cause for the observed changes. The results presented herein demonstrate that ethanol influences the bilayer properties according to membrane lateral organization.
Anthrax is an infectious disease caused by Bacillus anthracis, a bioterrorism agent that develops resistance to clinically used antibiotics. Therefore, alternative mechanisms of action remain a challenge. Herein, we disclose deoxy glycosides responsible for specific carbohydrate-phospholipid interactions, causing phosphatidylethanolamine lamellar-to-inverted hexagonal phase transition and acting over B. anthracis and Bacillus cereus as potent and selective bactericides. Biological studies of the synthesized compound series differing in the anomeric atom, glycone configuration and deoxygenation pattern show that the latter is indeed a key modulator of efficacy and selectivity. Biomolecular simulations show no tendency to pore formation, whereas differential metabolomics and genomics rule out proteins as targets. Complete bacteria cell death in 10 min and cellular envelope disruption corroborate an effect over lipid polymorphism. Biophysical approaches show monolayer and bilayer reorganization with fast and high permeabilizing activity toward phosphatidylethanolamine membranes. Absence of bacterial resistance further supports this mechanism, triggering innovation on membrane-targeting antimicrobials.
Phytoceramide is the backbone of major sphingolipids in fungi and plants and is essential in several tissues of animal organisms, such as human skin. Its sphingoid base, phytosphingosine, differs from that usually found in mammals by the addition of a hydroxyl group to the 4-ene, which may be a crucial factor for the different properties of membrane microdomains among those organisms and tissues. Recently, sphingolipid hydroxylation in animal cells emerged as a key feature in several physiopathological processes. Hence, the study of the biophysical properties of phytosphingolipids is also relevant in that context since it helps us to understand the effects of sphingolipid hydroxylation. In this work, binary mixtures of N-stearoyl-phytoceramide (PhyCer) with palmitoyloleoylphosphatidylcholine (POPC) were studied. Steady-state and time-resolved fluorescence of membrane probes, X-ray diffraction, atomic force microscopy, and confocal microscopy were employed. As for other saturated ceramides, highly rigid gel domains start to form with just ∼5 mol % PhyCer at 24 °C. However, PhyCer gel-enriched domains in coexistence with POPC-enriched fluid present additional complexity since their properties (maximal order, shape, and thickness) change at specific POPC/PhyCer molar ratios, suggesting the formation of highly stable stoichiometric complexes with their own properties, distinct from both POPC and PhyCer. A POPC/PhyCer binary phase diagram, supported by the different experimental approaches employed, is proposed with complexes of 3:1 and 1:2 stoichiometries which are stable at least from ∼15 to ∼55 °C. Thus, it provides mechanisms for the in vivo formation of sphingolipid-enriched gel domains that may account for stable membrane compartments and diffusion barriers in eukaryotic cell membranes.
Nystatin (Nys) is a pore forming broad-spectrum and efficient antifungal drug with significant toxicity in mammalian organisms. In order to develop a non-toxic and more effective Nys formulation, its molecular mechanism of action at the cell membrane needs to be better understood. It is widely accepted that Nys activity and toxicity depend on the presence and type of membrane sterols. Taking advantage of multiple biophysical methodologies, we now show that the formation and stabilization of Nys aqueous pores, which are associated with Nys cytotoxicity, occur in the absence of membrane sterols. Our results suggest that the Nys mechanism of action is driven by the presence of highly ordered membrane domains capable of stabilizing the Nys oligomers. Moreover, Nys pore formation is accompanied by strong Nys-induced membrane reorganization that depends on membrane lipid composition and seems to underlie the Nys cytotoxic effect. Accordingly, in membranes enriched in a gel-phase forming phospholipid, Nys incorporates within the phospholipid-enriched gel domains, where it forms pores able to expand the gel domains. In contrast, in membranes enriched in gel domain forming sphingolipids, Nys-induced pore formation occurs through the destabilization of the gel phase. These results show that the Nys mechanism of action is complex and not only dependent on membrane sterols, and provide further insight into the molecular details governing Nys activity and toxicity.
The number of applications of fluorescence spectroscopy in different areas of chemistry has increased dramatically, in part because a variety of instruments are used to measure fluorescence, including high-throughput microplate readers. Therefore, it is important to introduce students to different instruments. With many instruments, several experimental limitations hamper quantitative treatment of data, unless ratiometric measurements, that is, the ratio of intensity at two different excitation or emission wavelengths, are made. However, such methods are not always applicable. The denaturation of proteins often induces a red-shift of the tryptophan residues emission. Such a shift permits the use of ratiometric measures to obtain the fraction of native and denatured protein. To our knowledge, the use of ratiometric analysis with fluorescence measurements obtained from a microplate reader for the study of protein (biomolecular) denaturation has not been applied as a teaching exercise. In this experiment, the denaturation of hen egg-white lysozyme by guanidine hydrochloride is studied. Students perform ratiometric and single-wavelength measurements and obtain thermodynamic parameters for the denaturation process; they also test the reversibility of denaturation. In these studies the advantages of the ratiometric method are highlighted. Students develop analytical skills and, simultaneously, their understanding of the physical-chemical principles behind protein structural changes.
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