Axisymmetric Drop Shape Analysis for Estimating the Surface Tension of Cell Aggregates by Centrifugation

Biological tissues behave in certain respects like liquids. Consequently, the surface tension concept can be used to explain aspects of the in vitro and in vivo behavior of multicellular aggregates. Unfortunately, conventional methods of surface tension measurement cannot be readily applied to small cell aggregates. This difficulty can be overcome by an experimentally straightforward method consisting of centrifugation followed by axisymmetric drop shape analysis (ADSA). Since the aggregates typically show roughness, standard ADSA cannot be applied and we introduce a novel numerical method called ADSA-IP (ADSA for imperfect profile) for this purpose. To examine the new methodology, embryonic tissues from the gastrula of the frog, Xenopus laevis, deformed in the centrifuge are used. It is confirmed that surface tension measurements are independent of centrifugal force and aggregate size. Surface tension is measured for ectodermal cells in four sample batches, and varies between 1.1 and 7.7 mJ/m². Surface tension is also measured for aggregates of cells expressing cytoplasmically truncated EP/C-cadherin, and is approximately half as large. In parallel, such aggregates show a reduction in convergent extension-driven elongation after activin treatment, reflecting diminished intercellular cohesion.     

Aqueous dispersions of DMPG in low salt contain leaky vesicles

Aqueous dispersions of dimyristoyl phosphatidylglycerol (DMPG), at low ionic strength, display uncommon thermal behavior. Models for such behavior need to assign a form to the lipid aggregate. Although most studies accept the presence of lipid vesicles in the lipid gel and fluid phases, this is still controversial. With electron spin resonance (ESR) spectra of spin labels incorporated into DMPG aggregates, quantification of [(14)C]sucrose entrapped by the aggregates, and viscosity measurements, we demonstrate the existence of leaky vesicles in dispersions of DMPG at low ionic strength, in both gel and fluid phases of the lipid. As a control system, the ubiquitous lipid dimyristoyl phosphatidylcholine (DMPC) was used. For DMPG in the gel phase, spin labeling only indicated the presence of lipid bilayers, strongly suggesting that DMPG molecules are organized as vesicles and not micelles or bilayer fragments (bicelles), as the latter has a non-bilayer structure at the edges. Quantification of [(14)C]sucrose entrapping by DMPG aggregates revealed the presence of highly leaky vesicles. Due to the short hydrocarbon chains ((14)C atoms), DMPC vesicles were also found to be partially permeable to sucrose, but not as much as DMPG vesicles. Viscosity measurements, with the calculation of the intrinsic viscosity of the lipid aggregate, showed that DMPG vesicles are rather similar in the gel and fluid phases, and quite different from aggregates observed along the gel-fluid transition. Taken together, our data strongly supports that DMPG forms leaky vesicles at both gel and fluid phases.     

CD Spectroscopy of Peptides and Proteins Bound to Large Unilamellar Vesicles

Circular dichroism (CD) spectroscopy is an essential tool for determining the conformation of proteins and peptides in membranes. It can be particularly useful for measuring the free energy of partitioning of peptides into lipid vesicles. The belief is broadly held that such CD measurements can only be made using sonicated small unilamellar vesicles (SUVs) because light scattering associated with extruded large unilamellar vesicles (LUVs) is unacceptably high. We have examined this issue using several experimental approaches in which a chiral object (i.e., peptide or protein) is placed both on the membrane and outside the membrane. We show that accurate CD spectra can be collected in the presence of LUVs. This is important because SUVs, unlike LUVs, are metastable and consequently unsuitable for equilibrium thermodynamic measurements. Our data reveal that undistorted CD spectra of peptides can be measured at wavelengths above 200 nm in the presence of up to 3 mM LUVs and above 215 nm in the presence of up to 7 mM LUVs. We introduce a simple way of characterizing the effect on CD spectra of light scattering and absorption arising from suspensions of vesicles of any diameter. Using melittin as an example, we show that CD spectroscopy can be used to determine the fractional helical content of peptides in LUVs and to measure their free energy of partitioning of into LUVs.     

Role of nonacidic endosomes in recycling of ADH-sensitive water channel structures.

Toad urinary bladder epithelial cells respond to the hormone ADH by increasing the water permeability of their luminal membrane. This action is mediated by insertion into the apical membrane of specific water channels. In the absence of ADH these channels appear to be present in tubular cytoplasmic vesicles as morphologically distinctive intramembrane structures called particle aggregates. ADH induces these vesicles to fuse with the apical membrane, transferring their aggregate-water channels into the apical membrane. When ADH stimulation is removed (ADH reversal), aggregates and fluid-phase markers from the mucosal bath appear in water-permeable vesicles in the cytoplasm. We have examined the fate of fluid-phase markers and aggregates with time after ADH reversal. Although the fluid-phase markers horseradish peroxidase and colloidal gold are initially found predominantly in tubular vesicles near the apical surface, by 30 min the markers were found in perinuclear multivesicular bodies (MVBs) of heterogeneous size and shape. These MVBs appear to be nonacidic since they fail to accumulate DAMP. Acid phosphatase (AcPase) was undetectable in these structures. After 60 min, labeled MVBs tended to be smaller, and some of these structures displayed DAMP accumulation and AcPase activity. By evaluation of uncleaned replicas it was possible to localize recycled aggregate-water channels with respect to internalized fluid-phase markers. Thirty minutes after retrieval from the apical surface in tubular vesicles, aggregates could be localized to both the central body and tubular projections of labeled MVBs. At 60 min following reversal, most MVBs had a reduced number of aggregates compared with 30 min, and compact structures could be identified that contained markers but no detectable aggregates. These observations show that aggregates and fluid-phase markers enter a nonacidic endosomal compartment with an MVB morphology following ADH reversal. At extended times following reversal, labeled MVBS having lysosomal characteristics and labeled MVBs having no detectable aggregates can be found, suggesting that aggregates are sorted or degraded prior to this stage.     

Effect of protein-protein interaction on light adaptation of bacteriorhodopsin

Triton X-100 solubilized monomers of bacteiorhodopsin (bR) show a decrease in the extent of light adaptation; the red shift and the absorbance increase of the visible absorption band are reduced no less than half the values observed in purple membrane (p.m.) with a corresponding reduction in the isomerization of 13-cis- to all-trans-retinal. Cross-linking of bR with glutaraldehyde before exposure to Triton prevents dissociation of the lattice and reduction in light adaptation. Experiments with cross-linked and lipid-extracted p.m. show that Triton effectively substitutes for the native membrane lipids and that the lattice structure apparently stabilizes the light-adapted state of bR under illumination. In lipid vesicles at molar lipid protein ratios greater than or equal to 80, bR exists as monomers above the lipid-phase transition and aggregates below the phase transition. Above the lipid-phase transition and aggregates below the phase transition. Above the lipid-phase transition light adaptation in the monomers, measured as either the red shift of the visible absorbance maximum or the isomerizaiton o 13-cis- to all-trans-retinal, is also reduced to less than half of the extent observed in intact purple membrane or in the bR aggregates formed in lipid vesicles below the plhase transition. At very high lipid to protein ratios, bR molecules cannot aggregate when the temperature is decreased below the phase transition, and these monomers in a solid lipid phase show the same reduced extent of light adaptation as monomers above the phase transition, thus confirming that this effect is mainly due to the absence of protein-protein interaction and not to the state of the lipid. The extent of the red shift upon light adaptation may be used as a convenient indicator to distinguish the aggregated and monomeric states of bR.     

The role of the gel <=> liquid-crystalline phase transition in the lung surfactant cycle

Lipid polymorphism plays an important role in the lung surfactant cycle. A better understanding of the influence of phase transitions on the formation of a lipid film from dispersions of vesicles will help to describe the mechanism of action of lung surfactant. The surface pressure (or tension) of dispersions of DPPC, DMPC, and DPPE unilamellar vesicles was studied as a function of temperature. These aggregates rapidly fuse with a clean air-water interface when the system is at their phase transition temperature (Tm), showing a direct correlation between phase transition and film formation. Based on these results, an explanation on how fluid aggregates in the alveolar subphase can form a rigid monolayer at the alveolar interface is proposed.     

Asymmetric Oxidation of Giant Vesicles Triggers Curvature-Associated Shape Transition and Permeabilization

Oxidation of unsaturated lipids is a fundamental process involved in cell bioenergetics as well as in cell death. Using giant unilamellar vesicles and a chlorin photosensitizer, we asymmetrically oxidized the outer or inner monolayers of lipid membranes. We observed different shape transitions such as oblate to prolate and budding, which are typical of membrane curvature modifications. The asymmetry of the shape transitions is in accordance with a lowered effective spontaneous curvature of the leaflet being targeted. We interpret this effect as a decrease in the preferred area of the targeted leaflet compared to the other, due to the secondary products of oxidation (cleaved-lipids). Permeabilization of giant vesicles by light-induced oxidation is observed after a lag and is characterized in relation with the photosensitizer concentration. We interpret permeabilization as the opening of a pore above a critical membrane tension, resulting from the budding of vesicles. The evolution of photosensitized giant vesicle lysis tension was measured and yields an estimation of the effective spontaneous curvature at lysis. Additionally photo-oxidation was shown to be fusogenic.     

Divalent cation induced fusion and lipid lateral segregation in phosphatidylcholine-phosphatidic acid vesicles

The interactions of unilamellar vesicles containing phosphatidylcholine (PC) and phosphatidic acid (PA) in the presence of calcium and magnesium were examined by fluorometric assays of vesicle lipid mixing, contents mixing, and contents leakage and by spray-freezing freeze-fracture electron microscopy. These results were correlated with calorimetric and fluorometric measurements of divalent cation induced lateral segregation of lipids in these vesicles under comparable conditions. PA-PC vesicles in the presence of calcium show a rapid but limited intermixing of vesicle lipids and contents, the extent of which increases as the vesicle size decreases or the PA content increases. Calcium produces massive aggregation and efficient mixing of the contents of vesicles containing high proportions of dioleoyl-PA or egg PA, but vesicle coalescence in the latter case is followed rapidly by vesicle collapse and massive leakage of contents. The effects of magnesium are similar for vesicles of very high PA content. However, in the presence of magnesium, vesicles containing lower amounts of PA exhibit "hemifusion", a mode of interaction in which vesicles aggregate and mix approximately 50% of their lipids, apparently representing the lipids of the outer monolayer of each vesicle, without significant mixing of vesicle contents or collapse of the vesicles. Fluorometric measurements of lipid lateral segregation demonstrate that lateral redistribution of lipids in PA-PC vesicles begins at submillimolar concentrations of divalent cations and shows no abrupt change at the "threshold" divalent cation concentration, above which coalescence of vesicles is observed. By correlating calorimetric and fluorometric measurements of lipid lateral segregation and mixing of vesicle components, we can demonstrate that lipid segregation is at least strongly correlated with calcium-promoted coalescence of PA-PC vesicles and is essential to the magnesium-promoted interactions of vesicles of low PA contents.     

Electron microscopic investigation of the morphology and calcium-induced fusion of lipid vesicles with an oligomerised inner leaflet

The lipid head groups in the inner leaflet of unilamellar bilayer vesicles of the synthetic lipids DHPBNS and DDPBNS can be selectively oligomerised. Earlier studies have established that these vesicles fuse much slower and less extensively upon oligomerisation of the lipid head groups. The morphology and calcium-induced fusion of vesicles of DHPBNS and DDPBNS were investigated using cryo-electron microscopy. DHPBNS vesicles are not spherical but flattened, ellipsoidal structures. Upon addition of CaCl(2), DHPBNS vesicles with an oligomerised inner leaflet were occasionally observed in an arrested hemifused state. However, the evidence for hemifusion is not equivocal due to potential artefacts of sample preparation. DDPBNS vesicles show the expected spherical morphology. Upon addition of excess CaCl(2), DDPBNS vesicles fuse into dense aggregates that show a regular spacing corresponding to the bilayer width. Upon addition of EDTA, the aggregates readily disperse into large unilamellar vesicles. At low concentration of calcium ion, DDPBNS vesicles with an oligomerised inner leaflet form small multilamellar aggregates, in which a spacing corresponding to the bilayer width appears. Addition of excess EDTA results in slow dispersal of the Ca2+-lipid aggregates into a heterogeneous mixture of bilamellar, spherical vesicles and networks of thread-like vesicles. These lipid bilayer rearrangements are discussed within the context of shape transformations and fusion of lipid membranes.     

Visualization of endocytosed markers in freeze-fracture studies of toad urinary bladder

Antidiuretic hormone (ADH) stimulation increases the apical membrane water permeability of granular cells in toad urinary bladder. This response correlates closely with the fusion of tubular cytoplasmic vesicles with the membrane and delivery of intramembrane particle (IMP) aggregates from the tubules (aggrephores) to the apical membrane. These aggregates are believed to be associated with the channels responsible for the water permeability increase. Removal of ADH triggers apical membrane endocytosis and disappearance of aggregates from the apical membrane. However, it has been unclear whether aggregate disappearance is due to disassembly of aggregates within the apical membrane or to their endocytic retrieval as intact structures. Using colloidal gold and horseradish peroxidase to follow endocytosis from the apical surface after ADH removal, we have directly observed in cross-fractured bladder cells the intramembrane structure of intracellular vesicles that contain these fluid-phase markers. Under these conditions, intact aggregates can be identified in the membrane of tubular endocytosed vesicles. This directly demonstrates that conditions which lower apical membrane water permeability cause the tubular aggrephores to "shuttle" intact aggregates from the apical membrane back into the cytoplasm. An additional population of vesicles with tracer are found which are spherical and display structural features of the apical membrane, as well as occasional aggregates. These vesicles may be responsible for retrieval of aggregates from the surface apical membrane.     

Concentration effect on the aggregation of a self-assembling oligopeptide

Concentration is a key parameter in controlling the aggregation of self-assembling oligopeptides. By investigating the concentration effects, an aggregation mechanism of EAK16-II is proposed. Depending on the critical aggregation concentration (CAC) of EAK16-II, the oligopeptide aggregates into protofibrils through seeding and/or a nucleation process. Protofibrils then associate with each other to form fibrils. The CAC was found to be approximately 0.1 mg/ml by surface tension measurements. The nanostructures of aggregates were imaged and analyzed by atomic force microscopy. Globular and fibrillar aggregates were observed, and their dimensions were further quantified. To ensure that the aggregates were formed in bulk solution, light scattering (LS) measurements were conducted to monitor the fibril formation with time. The LS profile showed two different rates of aggregation depending on whether the peptide concentration was above or below the CAC. At high concentrations, the LS intensity increased strongly at early times. At low concentrations, the LS intensity increased only slightly. Our study provides information about the nature of the oligopeptide self-assembly, which is important to the understanding of the fibrillogenesis occurring in conformational diseases and to many biomedical engineering applications.     

pH-dependent stability and fusion of liposomes combining protonatable double-chain amphiphiles with phosphatidylethanolamine

We have prepared a series of novel double-chain amphiphiles with protonatable head groups, including acylated derivatives of various 2-substituted palmitic acids, amino acid conjugates of these species, and 1,2-dioleoyl-3-succinylglycerol. These species can be combined with phosphatidylethanolamine (PE) to prepare reverse-phase evaporation vesicles that are stable and trap hydrophilic solutes at pH 7. At weakly acidic pH values (as high as 6.5, depending on the titratable amphiphilic component), these pH-sensitive vesicles exhibit fusion, with a limited extent of contents mixing and extensive mixing of lipids, accompanied by leakage of aqueous contents. Protons and divalent cations show strong synergistic effects in promoting mixing of both lipids and aqueous contents between pH-sensitive vesicles prepared with any of a variety of double-chain titratable amphiphiles. Calorimetric results indicate that the relative stabilities of different types of pH-sensitive liposomes at low pH cannot be simply correlated with the propensity of the lipids to form a hexagonal II phase under these conditions. Fluorescence measurements demonstrate that single-chain fatty acids, but not double-chain titratable amphiphiles such as N-acyl-2-aminopalmitic acids, are rapidly removed from pH-sensitive vesicles in the presence of other lipid vesicles, serum albumin, or serum. Additionally, pH-sensitive liposomes containing double-chain titratable amphiphiles retain their aqueous contents better than do those containing single-chain amphiphiles in the presence of lipid membranes or albumin. Surprisingly, however, pH-sensitive vesicles of either type show retention of contents in the presence of serum that is comparable to that observed with vesicles composed purely of phospholipids. A model is proposed to explain these latter findings.     

Effect of water-soluble polymers on the state of aggregation, vesicle size, and phase transformations in mixtures of phosphatidylcholine and sodium cholate.

The state of aggregation and the steady-state size of mixed aggregates made of phospholipids and surfactants are both determined by the surfactant/lipid ratio in the mixed aggregates (Re). Water-soluble polymers, such as dextrans and polyethylene glycols (PEGs) of different molecular weights, induce reversible aggregation of phospholipid vesicles, mostly due to dehydration of the vesicle surface and depletion forces, and only at much higher concentrations, PEGs (but not dextran) also induce irreversible size growth of the vesicles. Here we show that the water-soluble polymers dextrans and PEGs do not affect the vesicle-micelle phase boundaries in mixtures of phosphatidylcholine and the anionic surfactant sodium cholate. By contrast, these polymers affect markedly the steady-state size of cholate-containing vesicles. As compared with pure phosphatidylcholine vesicles, the cholate-containing vesicles have a lower tendency to undergo polymer-induced aggregation, probably due to the electrostatic repulsion between the negatively charged vesicles, but a higher tendency to undergo irreversible size growth at relatively low polymer concentrations. Such irreversible size growth was observed not only for PEG but also for dextran, which in the absence of cholate is incapable of inducing vesicle size growth. These findings are consistent with the prevailing concept that the polymer-induced size growth is due to the effect of large structural fluctuations in the bilayers of deformed aggregated vesicles, the surface of which is dehydrated by the polymer. The presence of cholate in the bilayers at sufficiently high concentrations induces such fluctuations, yielding irreversible size growth within the clusters of dehydrated vesicles formed upon mixing with polymers.     

Schistosoma mansoni: eggshell formation is regulated by pH and calcium

The protein precursors of the schistosome eggshell are synthesized and packaged into secretory vesicles in the vitelline cells. These vesicles appear to contain an emulsion of eggshell precursor material. Evidence is presented to show that these secretory vesicles are acidic as in other systems and that this acidity stabilizes the emulsion and prevents the eggshell cross-linking reactions from occurring. Alkalinizing treatments trigger eggshell formation within the secretory vesicles as shown by (1) the induction of autofluorescence and (2) by electron microscopy which shows that the eggshell precursors have aggregated within the secretory vesicles into spherical particles bearing microspines. These aggregates formed in the secretory vesicles were isolated and shown to have the same protease resistance and amino acid composition as authentic eggshell. The calcium ionophore A23187 induces scattered autofluorescence in intact female worms which electron micrographs show to be due to exocytosis of eggshell material. Based on these observations we propose a model for the formation of schistosome eggshell and suggest that it may apply to all trematodes in which the eggshell precursors are present as stable emulsions in the secretory vesicles of the vitelline cells.     

Surface behavior and lipid interaction of Alzheimer beta-amyloid peptide 1-42: a membrane-disrupting peptide

Amyloid aggregates, found in patients that suffer from Alzheimer's disease, are composed of fibril-forming peptides in a beta-sheet conformation. One of the most abundant components in amyloid aggregates is the beta-amyloid peptide 1-42 (Abeta 1-42). Membrane alterations may proceed to cell death by either an oxidative stress mechanism, caused by the peptide and synergized by transition metal ions, or through formation of ion channels by peptide interfacial self-aggregation. Here we demonstrate that Langmuir films of Abeta 1-42, either in pure form or mixed with lipids, develop stable monomolecular arrays with a high surface stability. By using micropipette aspiration technique and confocal microscopy we show that Abeta 1-42 induces a strong membrane destabilization in giant unilamellar vesicles composed of palmitoyloleoyl-phosphatidylcholine, sphingomyelin, and cholesterol, lowering the critical tension of vesicle rupture. Additionally, Abeta 1-42 triggers the induction of a sequential leakage of low- and high-molecular-weight markers trapped inside the giant unilamellar vesicles, but preserving the vesicle shape. Consequently, the Abeta 1-42 sequence confers particular molecular properties to the peptide that, in turn, influence supramolecular properties associated to membranes that may result in toxicity, including: 1), an ability of the peptide to strongly associate with the membrane; 2), a reduction of lateral membrane cohesive forces; and 3), a capacity to break the transbilayer gradient and puncture sealed vesicles.     

Effect of temperature on the formation of liquid phase-separating giant unilamellar vesicles (GUV)

Giant unilamellar vesicles (GUVs) are widely used as model systems to study both, lipid and membrane protein behavior. During their preparation by the commonly applied electroformation method, a number of issues must be considered to avoid the production of artifacts due to a poor lipid hydration and protein degradation. Here we focus on the effect of preparation temperature on GUVs composed of the most commonly used domain-forming mixture dioleoylelphospatidylcholine/shingomyelin/cholesterol (DOPC/SM/chol) (2/2/1). Lower production temperatures are generally preferable when aiming at a functional reconstitution of proteins into the membrane. On the other hand, lower growth temperature is suspected to alter the lipid composition and the yield of phase-separating vesicles. By confocal imaging, we find that vesicles prepared significantly above and below the melting temperature T(m) have the same overall morphology, similar size distributions of vesicles and a similar area coverage by liquid-ordered (L(o)) domains. However, a large population analysis indeed reveals a different overall yield of phase-separating vesicles. Two-focus scanning fluorescence correlation spectroscopy measurements did not show any divergence of lipid analog mobility in (L(o)) and (L(d)) phases in vesicles prepared at different temperatures, indicating that the lowered growth temperature did not influence the lipid organization within the two phases. Moreover, the expected advantages of lower preparation temperature for proteo-GUVs could be exemplified by the reconstitution of voltage dependent anion channel (VDAC) into DOPC/SM/chol GUVs, which aggregates at high, but not at low preparation temperatures.     

Migration-Directing Liquid Properties of Embryonic Amphibian Tissues

Deep ectoderm, mesoderm and endoderm excised from gastrulatingamphibian embryos spontaneously undergo liquid-like movementsin organ culture. Cell populations of these tissues on nonadhesivesubstrata will round up into spheres, spread over one anotherand segregate (sort out) from one another just as immiscibleliquid droplets do. In ordinary liquids, movements like theseare controlled by surface tensions; perhaps surface tensionsalso control the similar movements of liquid-like tissues. Onenecessary condition for tissue surface tension analysis is thatthe tissue must be able (just as ordinary liquids are able)to spontaneously relax internal stretching forces (shear stresses).When cellular aggregates of the germ layers were deformed bygentle compression between parallel glass plates, cells withinthe aggregates were initially stretched. However, the cellssoon returned to their original undistorted shapes. Thus, cellstretching forces were gradually relaxed by cell rearrangements.The in vitro spreading movements of the deep germ layers implythat the surface tension of ectoderm should be greater thanthe surface tension of mesoderm which should be greater thanthe surface tension of endoderm. Quantitative measurements oftissue surface tensions made by parallel plate compression confirmprecisely that relationship. Furthermore, the surface tensionsof these tissues remain constant regardless of the amount ofaggregate flattening—another necessary condition for validsurface tension measurements. These results demonstrate thatamphibian deep germ layers possess fundamental liquid propertieswhich are sufficient to direct their liquid-like rearrangementsin organ culture. Furthermore, I also report that one of theseproperties, surface tension, displays a preliminary correlationwith density of cell surface charge (assessed by electrophoreticmobility) and with the onset of in vivo mesodermal involution.     

Evidence that the heads of ADH-sensitive aggrephores are clathrin-coated vesicles: implications for aggrephore structure and function

Antidiuretic hormone (ADH) induces the fusion of long tubular organelles (aggrephores) with the luminal membrane of the receptor cell, and the delivery of particle aggregates to the membrane. Water flow is believed to take place through the particles. Nothing is known about the origin of the particle aggregates, their incorporation into the aggrephores, or the possible relationship of the aggrephores to the vesicular traffic that takes place in the epithelial cell. In the present studies of the ADH-sensitive epithelial cells of the toad urinary bladder, we have found that the spherical heads of the aggrephores appear to be clathrin-coated vesicles. We propose that vesicles originating from sites such as the Golgi or the luminal membrane may be engaged in aggrephore assembly, the resupply of particle aggregates to the aggrephores, and/or the removal of aggregates, and that the aggrephores may be central points in the pattern of vesicular traffic in the cell.     

Organ printing: fiction or science

Aggregates of living cells (i.e. model tissue fragments) under appropriate conditions fuse like liquid drops. According to Steinberg's differential adhesion hypothesis (DAH), this may be understood by assuming that cells are motile and tissues made of such cells possess an effective surface tension. Here we show that based on these properties three-dimensional cellular structures of prescribed shape can be constructed by a novel method: cell aggregate printing. Spherical aggregates of similar size made of cells with known adhesive properties were prepared. Aggregates were embedded into biocompatible gels. When the cellular and gel properties, as well as the symmetry of the initial configuration were appropriately adjusted the contiguous aggregates fused into ring-like organ structures. To elucidate the driving force and optimal conditions for this pattern formation, Monte Carlo simulations based on a DAH motivated model were performed. The simulations reproduced the experimentally observed cellular arrangements and revealed that the control parameter of pattern evolution is the gel-tissue interfacial tension, an experimentally accessible parameter.     

A light-scattering measurement of membrane vesicle permeability.

Light-scattering/intensity autocorrelation measurements of vesicle diffusivity were used to follow the time course of the osmotic response of lobster abdominal sarcoplasmic reticulum vesicles to five lipophobic nonelectrolytes. Steady-state portions of the resulting time traces show these vesicles to be permeable to ethylene glycol and glycerol and impermeable to erythritol, glucose, and sucrose. Using measured values of the hydrodynamic radii of these nonelectrolytes, it is concluded that under passive transport conditions, these vesicles may be thought of as having pores whose radii lie between 3.1 and 3.5 A. In addition, the results presented here indicated that above a certain impermeable nonelectrolyte concentration, vesicles did not respond osmotically even though they had not collapsed. This suggests that at least under the experimental conditions reported here, vesicles behaved as if rigid when their average volume had decreased to about 50% of its original isotonic value.