Pattern of rise in subplasma membrane Ca concentration determines type of fusing insulin granules in pancreatic β cells

We simultaneously analyzed insulin granule fusion with insulin fused to green fluorescent protein and the subplasma membrane Ca²⁺ concentration ([Ca²⁺]_PM) with the Ca²⁺ indicator Fura Red in rat β cells by dual-color total internal reflection fluorescence microscopy. We found that rapid and marked elevation in [Ca²⁺]_PM caused insulin granule fusion mostly from previously docked granules during the high KCl-evoked release and high glucose-evoked first phase release. In contrast, the slow and sustained elevation in [Ca²⁺]_PM induced fusion from newcomers translocated from the internal pool during the low KCl-evoked release and glucose-evoked second phase release. These data suggest that the pattern of the [Ca²⁺]_PM rise directly determines the types of fusing granules.     

Amyloidogenic Propensities and Conformational Properties of ProIAPP and IAPP in the Presence of Lipid Bilayer Membranes

Human islet amyloid polypeptide (hIAPP), which is considered the primary culprit for β-cell loss in type 2 diabetes mellitus patients, is synthesized in β-cells of the pancreas from its precursor pro-islet amyloid polypeptide (proIAPP), which may be important in early intracellular amyloid formation as well. We compare the amyloidogenic propensities and conformational properties of proIAPP and hIAPP in the presence of negatively charged lipid membranes, which have been discussed as loci of initiation of the fibrillation reaction. Circular dichroism studies verify the initial secondary structures of proIAPP and hIAPP to be predominantly unordered with small amounts of ordered secondary structure elements, and exhibit minor differences between these two peptides only. Using attenuated total reflection-Fourier transform infrared spectroscopy and thioflavin T fluorescence spectroscopy, as well as atomic force microscopy, we show that in the presence of negatively charged membranes, proIAPP exhibits a much higher amyloidogenic propensity than in bulk solvent. Compared to hIAPP, it is still much less amyloidogenic, however. Although differences in the secondary structures of the aggregated species of hIAPP and proIAPP at the lipid interface are small, they are reflected in morphological changes. Unlike hIAPP, proIAPP forms essentially oligomeric-like structures at the lipid interface. Besides the interaction with anionic membranes [1,2-dioleoyl-sn-glycero-3-phosphocholine (DOPC) + x1,2-dioleoyl-sn-glycero-3-[phospho-rac-(1-glycerol)]], interaction with zwitterionic homogeneous (DOPC) and heterogeneous (1,2-dipalmitoyl-sn-glycero-3-phosphocholine:DOPC:cholesterol 1:2:1 model raft mixture) membranes has also been studied. Both peptides do not aggregate significantly at DOPC bilayers. In the presence of the model raft membrane, hIAPP aggregates markedly as well. Conversely, proIAPP clusters into less ordered structures and to a minor extent at raft membranes only. The addition of proIAPP to hIAPP retards the hIAPP fibrillation process also in the presence of negatively charged lipid bilayers. In excess proIAPP, increased aggregation levels are finally observed, however, which could be attributed to seed-induced cofibrillation of proIAPP.     

IMMUNOGOLD LABELLING OF FIBROBLAST FOCAL ADHESION SITES VISUALISED IN FIXED MATERIAL USING SCANNING ELECTRON MICROSCOPY, AND LIVING, USING INTERNAL REFLECTION MICROSCOPY

A new immunogold labelling method for the visualisation of vinculin, an integral protein in focal adhesions of cells, is reported. Quantification of vinculin is indicative of substrate cytocompatibility (cytocompatibility is one aspect of biocompatibility; it is the cellular response to a biomaterial). For efficient labelling, most of the cell body above the cell-substrate interface was removed with detergent. The antigen blocking procedure, size of label (5 nm) and duration of silver-enhancement (6 min), for visualisation of the labelled sites on the whole cell by scanning electron microscopy (SEM), were determined. Imaging living cells with interference reflection light microscopy, followed by backscattered electron (BSE) imaging of the same fixed and immunolabelled cells confirmed the results. Collecting low voltage BSE images of embedded cells after the substrate had been removed provided 'sectional' views through the cell. This enabled visualisation of vinculin exclusively within the cell-substrate contact zone; the focal adhesions. The method could be of general use in the imaging of protein distribution at biological tissue/substrate interfaces.     

On simultaneous transport of water and solute through plant cell membranes: Evidence for the absence of solvent drag effect and insensitivity of the reflection coefficient

The simultaneous efflux of tritiated water and ¹⁴C labelled ethanol from inner epidermal cells of the bulb scale of Allium cepa was measured with a specially designed efflux chamber. It was found that water and ethanol moved essentially independently. Rates of efflux of tritiated water and ¹⁴C ethanol were essentially the same in the presence or absence of a simultaneous influx of water. Using the same technique the efflux of tritiated water from the epidermal cells was measured during a simultaneous flow of nonlabelled ethanol. When tritiated water and ethanol moved in opposite directions, the water permeability values became slightly reduced depending upon the concentration of ethanol. When ethanol and tritiated water moved in the same direction, however, no effect on water permeability values could be detected. These results are best explained by the molecular theory of diffusion across lipid bilayer membranes, and are consistent with the above findings of lack of interaction between water and ethanol as they are transported across the cell membrane. In another study, the solute permeability coefficients (K_s) for non-electrolytes such as urea and methyl urea were measured by plasmolyzing the epidermal cells and transferring them to equimolal solutions of urea and methyl urea. This method was also used to measure the reflection coefficient (σ) for these nonelectrolytes. The K_s values for methyl urea were 16 times greater than the ones for urea. The values of σ for both of these solutes, however, were very close to 1. Using the K_s data available in the literature for the subepidermal cells of the Pisum sativum stem basis, the σ values were calculated for malonamide, glycerol, methyl urea, ethyl urea, dimethyl urea, and formamide. Again the K_s values for these nonelectrolytes varied by several orders of magnitude, whereas all σ values were found to be close to 1. These findings point out that σ is an insensitive parameter and that K_s, the solute permeability constant, has to be used for characterizing solute transport through the membrane. The present study shows that fast (e.g. ethanol, formamide) as well as slowly permeating molecules do not interact with water as they are transported across the cell membrane. Aqueous pores for the simultaneous transport of water and solutes, therefore, are absent in the plant cell membranes investigated here.     

50例兔在体和离体器官组织射频介电性能的测量与分析

根据同轴传输线反射原理,建立起计算机控制的生物组织介电测量系统;在６０—３０００ＭＨｚ频率范围对５０例兔器官组织进行了有效的在体和离体介电测量。测量结果的统计分析表明,不同兔器官组织之间介电参数的最大差异可达３０·４％;在体和离休测量得出的介电常数之间未见显著性差异,但电导率有频率依赖性的显著差异,因此将人体的离体介电参数延用到实际活体场合时,必须慎重。     

Unraveling the structures and modes of action of bacterial toxins

The mechanism by which a soluble protein converts into a protein that spans a membrane remains a central question in understanding the molecular mechanism of toxicity of bacterial protein toxins. Using crystallographic structures of soluble toxins as templates, the past year has seen a number of experiments that are designed to probe the membrane state using other structural methods. In addition, crystallographic information concerning the clostridial neurotoxins has emerged, suggesting a novel mechanism of pore formation and new relationships between toxin binding domains.     

Chemistry and physics of giant vesicles as biomembrane models

The giant vesicle is becoming an object of intense scrutiny by chemists, biologists, and physicists who are interested in membrane behavior. Recent advances include new models to explain morphological changes, new experimental methods for studying vesicle adhesion, layering and adsorption, and new cataloging of ‘cytomimetic’ processes.     

Structure and orientation study of fusion peptide FP23 of gp41 from HIV-1 alone or inserted into various lipid membrane models (mono-, bi- and multibi-layers) by FT-IR spectroscopies and Brewster angle microscopy

In the present work, we study the structure and the orientation of the 23 N-terminal peptide of the HIV-1 gp 41 protein (AVGIGALFLGFLGAAGSTMGARS) called FP23. The behaviour of FP23 was investigated alone at the air/water interface and inserted into various lipid model systems: in monolayer or multibilayers of a DOPC/cholesterol/DOPE/DOPG (6/5/3/2) and in a DMPC bilayer. PMIRRAS and polarized ATR spectroscopy coupled with Brewster angle microscopy and spectral simulations were used to precisely determine the structure and the orientation of the peptide in its environment as well as the lipid perturbations induced by the FP23 insertion. The infra-red results show the structural polymorphism of the FP23 and its ability to transit quasi irreversibly from an α-helix to antiparallel β-sheets. At the air/water interface, the transition is induced by compression of the peptide alone and is modulated by compression and lipid to peptide ratio (Ri) when FP23 is inserted into a lipid monolayer. In multibilayers and in a single bilayer, there is coexistence in quasi equal proportions of α-helix and antiparallel β-sheets of FP23 at low peptide content (Ri = 100, 200) while antiparallel β-sheets are predominant at high FP23 concentration (Ri = 50). In (multi)bilayer systems, evaluation of dichroic ratios and sprectral simulations show that both the α-helix and the antiparallel β-sheets are tilted at diluted FP23 concentrations (tilt angle of α-helix with respect to the normal of the interface = 36.5 ± 3.0° for FP23 in multibilayers of DOPC/Chol/DOPE/DOPG at Ri = 200 and 39.0 ± 5.0° in a single bilayer of DMPC at Ri = 100 and tilt angle of the β-sheets = 36.0 ± 2.0° for the β-sheets in multibilayers and 30.0 ± 2.0° in the lipid bilayer). In parallel, the FP23 induces an increase of the lipid chain disorder which shows both by an increase of the methylene stretching frequencies and an increase of the average C-C-C angle of the acyl chains. At high FP23 content (Ri = 50), the antiparallel β-sheets induce a complete disorganization of the lipid chains in (multi)bilayers.     

Promotion of amyloid beta protein misfolding and fibrillogenesis by a lipid oxidation product

Oxidatively damaged lipid membranes are known to promote the aggregation of amyloid β proteins and fibril formation. Oxidative damage typically produces 4-hydroxy-2-nonenal when lipid membranes contain ω-6 polyunsaturated fatty acyl chains, and this compound is known to modify the three His residues in Aβ proteins by Michael addition. In this report, the ability of 4-hydroxy-2-nonenal to reproduce the previously observed amyloidogenic effects of oxidative lipid damage on amyloid β proteins is demonstrated and the mechanism by which it exerts these effects is examined. Results indicate that 4-hydroxy-2-nonenal modifies the three His residues in amyloid beta proteins, which increases their membrane affinity and causes them to adopt a conformation on membranes that is similar to their conformation in a mature amyloid fibril. As a consequence, fibril formation is accelerated at relatively low protein concentrations, and the ability to seed the formation of fibrils by unmodified amyloid beta proteins is enhanced. These in vitro findings linking oxidative stress to amyloid fibril formation may be significant to the in vivo mechanism by which oxidative stress is linked to the formation of amyloid plaques in Alzheimer's disease.     

Photoactivation of pa-GFP in 3D: optical tools for spatial confinement

Photoactivatable fluorescent proteins represent an innovative tool for the direct observation of time dependent macromolecular events in living systems. The possibility of switching on a selected and confined subset of the expressed target proteins allows to follow biological processes reaching high signal to noise ratios. In particular, use of non-linear interactions to bring the molecules in the activated fluorescent form make it possible to extend the advantages of photoactivation to events that requires 3D spatial localization. In this work, we show the possibility to realize confined activated volumes in living cells, by employing photoactivatable green fluorescent protein (paGFP) in two-photon microscopy. The analysis of the kinetics of two-photon paGFP activation in dependence of the wavelength, the laser intensity and the exposure time is provided. This study allowed to assess the optimal conditions to induce photoactivation in living samples and to track the behaviour of tagged histone H2B during cellular division. Furthermore we investigate paGFP photoactivation under evanescent wave illumination. Total internal reflection set-up has been used to selectively activate subresolved distribution of proteins localized in the basal membrane surroundings. These two photoactivation methods provide a suitable tool for many biological applications, combining subresolved surface and in-depth three-dimensionally confined investigations.