A convenient synthesis of cadmium chalcogenide quantum dots from cadmium acetate and bis(diphenylphosphino)methane monosulfide and –selenide or 1,4-bis(diphenylphosphino)butane monoselenide

The synthesis of both cadmium selenide and cadmium sulfide quantum dots has been effected using a synthetic protocol that avoids the use of volatile, toxic organocadmium reagents and alkyl phosphines.     

Drying and rehydration of DLPC/DSPC symmetric and asymmetric supported lipid bilayers: a combined AFM and fluorescence microscopy study

This work characterizes the impact of lipid symmetry/asymmetry on drying/rehydration reorganization in phase-separated dilauroylphosphatidylcholine (DLPC)/distearoylphosphatidylcholine (DSPC) supported lipid bilayers (SLBs) at the submicron and micron-scale. In addition the prevention of major drying/rehydration reorganization by the use of trehalose is demonstrated. Even though it was found using fluorescence microscopy that micrometer scale structure is preserved in the presence and absence of trehalose upon drying/rehydration, AFM and FRAP experiments successfully revealed major changes in the phase-separated structure such as defects, obstructions, lipid condensation, collapse structures, and complex incomplete DLPC-DSPC mixing/exchange in the absence of trehalose. In the presence of trehalose the membrane preserves its structure at the nanometer scale and mobility. We found that SLBs with asymmetric domain configurations underwent major rearrangements during drying and rehydration, whereas the symmetric domain configuration mainly rearranged during rehydration, that we hypothesize is related to lower transmembrane cohesiveness or lack of anchoring to the substrate in the case of the asymmetric domains.     

Molecular-scale structure in fluid-gel patterned bilayers: stability of interfaces and transmembrane distribution

Variations in two-dimensional membrane structures on the molecular length scale are considered to have an effect on the mechanisms by which living cell membranes maintain their functionality. We created a molecular model of a patterned bilayer to asses the static and dynamic variations of membrane lateral and transbilayer distribution in two-component lipid bilayers on the molecular level. We study DSPC (distearoylphosphatidylcholine) nanometer domains in a fluid DLPC (dilauroylphosphatidylcholine) background. The system exhibits coexisting fluid and gel phases and is studied on a microsecond time scale. We characterize three different kinds of patterns: symmetric domains, asymmetric domains, and symmetric-asymmetric domains. Preferred bilayer configurations on the nanoscale are those that minimize the hydrophobic mismatch. We find nanoscale patterns to be dynamic structures with mainly lateral and rotational diffusion affecting their stability on the microsecond time scale.     

Phase and mixing behavior in two-component lipid bilayers: a molecular dynamics study in DLPC/DSPC mixtures

Phase and mixing behavior of dilauroylphosphatidylcholine (DLPC)/distearoylphosphatidylcholine (DSPC) lipid mixtures are studied by molecular dynamics simulations with use of a coarse-grained model over a wide range of concentrations. The results reveal that phase transformations from the fluid to the gel state can be followed over a microsecond time scale. The changes in structure suggest regions of phase coexistence allowing us to outline the entire phase diagram for this lipid mixture using a molecular based model. We show that simulations yield good agreement with the experimental phase diagram. We also address the effect of macroscopic phase separation on the determination of the transition temperature, different leaflet composition, and finite size effects. This study may have implications on lateral membrane organization and the associated processes dependent on these membrane regions on different time and length scales.     

Interactions of lipid bilayers with supports: a coarse-grained molecular simulation study

The study of lipid structure and phase behavior at the nanoscale is of utmost importance due to implications in understanding the role of the lipids in biochemical membrane processes. Supported lipid bilayers play a key role in understanding real biological systems, but they are vastly underrepresented in computational studies. In this paper, we discuss molecular dynamics simulations of supported lipid bilayers using a coarse-grained model. We first focus on the technical implications of modeling solid supports for biomembrane simulations. We then describe noticeable influences of the support on the systems. We are able to demonstrate that the bilayer system behavior changes when supported by a hydrophilic surface. We find that the thickness of the water layer between the support and the bilayer (the inner-water region in the latter part of this paper) adapts through water permeation on the microsecond time scale. Additionally, we discuss how different surface topologies affect the bilayer. Finally, we point out the differences between the two leaflets induced by the support.     

PREPARATION OF LARGE-PARTICLE-SIZE MONODISPERSE LATEXES IN SPACE: POLYMERIZATION KINETICS AND PROCESS DEVELOPMENT

Monodisperse polystyrene latexes are prepared by seeded emulsion polymerization; however, sizes larger than 2μm are difficult to prepare because of the creaming and settling of the particles, and their sensitivity to mechanical shear. Preparation in space would obviate the creaming and settling, and allow agitation just sufficient for good heat transfer and mixing. Three polymerizations yielding 3-5μm size particles were carried out successfully on the third flight of the “Columbia” launched March 22, 1982; however, four polymerizations yielding sizes up to 10μm on the fourth flight launched June 27, 1982, were incomplete owing to apparatus malfunction. The results of these polymerizations and the prospects of developing a preparative space process are reviewed     

pH-Dependent Cu(II) coordination to amyloid-β peptide: impact of sequence alterations, including the H6R and D7N familial mutations

Copper ions have been proposed to intervene in deleterious processes linked to the development of Alzheimer's disease (AD). As a direct consequence, delineating how Cu(II) can be bound to amyloid-β (Aβ) peptide, the amyloidogenic peptide encountered in AD, is of paramount importance. Two different forms of [Cu(II)(Aβ)] complexes are present near physiological pH, usually noted components I and II, the nature of which is still widely debated in the literature, especially for II. In the present report, the phenomenological pH-dependent study of Cu(II) coordination to Aβ and to ten mutants by EPR, CD, and NMR techniques is described. Although only indirect insights can be obtained from the study of Cu(II) binding to mutated peptides, they reveal very useful for better defining Cu(II) coordination sites in the native Aβ peptide. Four components were identified between pH 6 and 12, namely, components I, II, III and IV, in which the predominant Cu(II) equatorial sites are {-NH(2), CO (Asp1-Ala2), N(im) (His6), N(im) (His13 or His14)}, {-NH(2), N(-) (Asp1-Ala2), CO (Ala2-Glu3), N(im)}, {-NH(2), N(-) (Asp1-Ala2), N(-) (Ala2-Glu3), N(im)} and {-NH(2), N(-) (Asp1-Ala2), N(-) (Ala2-Glu3), N(-) (Glu3-Phe4)}, respectively, in line with classical pH-induced deprotonation of the peptide backbone encountered in Cu(II) peptidic complexes formation. The structure proposed for component II is discussed with respect to another coordination model reported in the literature, that is, {CO (Ala2-Glu3), 3 N(im)}. Cu(II) binding to the H6R-Aβ and D7N-Aβ peptides, where the familial H6R and D7N mutations have been linked to early onset of AD, has also been investigated. In case of the H6R mutation, some different structural features (compared to those encountered in the native [Cu(II)(Aβ)] species) have been evidenced and are anticipated to be important for the aggregating properties of the H6R-Aβ peptide in presence of Cu(II).     

A Bioinorganic View of Alzheimer’s Disease: When Misplaced Metal Ions (Re)direct the Electrons to the Wrong Target

Metal ions Cu, Zn and Fe, seem to play a pivotal role in Alzheimer’s disease and other neurodegenerative diseases. In order to understand this in a broader sense, one has to considerer the peculiarities of metal metabolism in the brain compared to most other tissues, as well as the importance of the redox active metal ions, Fe and Cu, in oxygen metabolism and the connected oxidative stress.