Effects of polyvalent ions on the lateral packing of phospholipids have been known for decades, but the physiological consequences have not been systematically studied. Gd(3+) is a relatively nonspecific agent that blocks mechano-gated channels with a variable affinity. In this study, we show that the large mechanosensitive channel MscL of Escherichia coli is effectively blocked by Gd(3+) only when reconstituted with negatively charged phospholipids (e.g., PS). Taking this lead, we studied effects of Gd(3+) on monolayers and unilamellar vesicles made of natural brain PS, DMPS, and its mixtures with DMPC. In monolayer experiments, we found that muM Gd(3+) present in the subphase leads to approximately 8% lateral compaction of brain PS (at 35 mN/m). Gd(3+) more strongly shrinks and rigidifies DMPS films causing a spontaneous liquid expanded-to-compact transition to the limiting 40 A(2)/mol. Pressure-area isotherms of uncharged DMPC were unaffected by Gd(3+), and neutralization of DMPS surface by low pH did not produce strong compaction. Upshifts of surface potential isotherms of DMPS monolayers reflected changes in the diffuse double layer due to neutralization of headgroup charges by Gd(3+), whereas the increased packing density produced up to a 200 mV change in the interfacial dipole potential. The slopes of surface potential versus reciprocal area predicted that Gd(3+) induced a modest ( approximately 18%) increase in the magnitude of the individual lipid dipoles in DMPS. Isothermal titration calorimetry indicated that binding of Gd(3+) to DMPS liposomes in the gel state is endothermic, whereas binding to liquid crystalline liposomes produces heat consistent with the isothermal liquid-to-gel phase transition induced by the ion. Both titration curves suggested a K(b) of approximately 10(6) M(-1). We conclude that anionic phospholipids serve as high-affinity receptors for Gd(3+) ions, and the ion-induced compaction generates a lateral pressure increase estimated as tens of mN/m. This pressure can "squeeze" the channel and shift the equilibrium toward the closed state.
The surface charge of semiconductor nanoparticles, Q, is an important parameter which determines their electrokinetic behavior, stability in water and polar solvents, functions of optical and electronic devices, self-assembly properties, and interactions with cell membranes. We have developed a simple method for quantitative determination of Q in their native aqueous environment. The method does not require the knowledge of exact atomic structure or make assumptions about effects of drying on charge distribution. The method is based on titration of nanoparticle dispersion with a solution of oppositely charged polyelectrolyte. The point of complete neutralization is recognized as an inflection point on the dependence of fluorescence intensity on the amount of polyelectrolyte added. Thioglycolic acid-stabilized CdTe nanoparticles 2 nm in diameter were found to carry an average Q from -2.6 to -5.5 for pH 7.5 to 10, respectively. This charge is found to be smaller than that calculated theoretically for an analogous structure (i.e., Q = -8), presumably due to adsorption of Cd(2+) ions on the stabilizer shell and on Te atoms with unsaturated valence located on the side planes of CdTe tetrahedrons.
Mycobacteria, especially Mycobacterium tuberculosis, are one of the most dangerous types of microorganisms to cause diseases and mortality. Due to the known distinctive structure of their cell wall, mycobacteria are resistant to majority of antibiotics and common chemical disinfectants, including quaternized low molecular weight and polymer biocides. In this work, nonquaternary protonated polydiallylamines (PDAAs) based on protonated monomers of the diallylamine (DAA) series have been synthesized, secondary s-PDAA and tertiary t-Me-PDAA and t-Et-PDAA (with Me and Et N-substituents). The antimicrobial actions of PDAAs on M. tuberculosis and Mycobacterium smegmatis have been studied, namely, dependences of the activity on the amine structure, length of alkyl N-substituents, M w of polymers, treatment time, and cell concentration. All PDAAs examined at different conditions have been found to exhibit strong bactericidal effect on M. smegmatis and M. tuberculosis, including "nonculturable" dormant M. tuberculosis cells. The quaternary counterpart poly(diallyldimethylammonium chloride) (PDADMAC) and current antibiotics rifampicin and ciprofloxacin have been also tested and shown to be significantly less efficient or inactive at all (at the maximum tested concentration of 500 μg mL(-1)). s-PDAA appeared to be the most effective or exhibited similar activity to t-Me-PDAA, while t-Et-PDAA appeared to be less active, especially against M. tuberculosis. The results obtained indicate a key role of the nonquaternary ammonium groups in the mycobactericidal action of PDAAs. Examination under an optical microscope in the epifluorescence mode has evidenced damage of the inner membrane permeability of M. smegmatis cells under the impact of PDAAs after 20 min. Studies on electrophoretic mobility (zeta-potential) of M. smegmatis cells and some model liposomes in the presence of PDAAs have revealed a small negative charge of mycobacteria outer surface and recharge in the presence of PDAAs. A conclusion was made that bactericidal activity of PDAAs is related to the disturbance of the integrity of the mycobacterial cell wall followed by damage of the inner membrane permeability.
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