Impact of the acidic C-terminal region comprising amino acids 109-140 on alpha-synuclein aggregation in vitro

The aggregation of alpha-synuclein, involved in the pathogenesis of several neurodegenerative disorders such as Parkinson's disease, is enhanced in vitro by biogenic polyamines binding to the highly charged C-terminal region aa109-140. In this study, we investigated the influence of this region on the aggregation kinetics, monitored by thioflavin T binding and static light scattering, and morphology, assessed by electron microscopy, fluorescence microscopy, and turbidity, by comparing the effect of various solution conditions on the wild-type protein, the disease related mutants A53T and A30P, and two truncated variants, syn(1-108) and syn(1-124), lacking the complete or the C-terminal half of the polyamine binding site. In the presence of the intact C-terminus, aggregation was strongly retarded in physiological buffer. This inhibition of aggregation was overridden by (i) addition of spermine or MgCl(2) or lowering of pH, leading to strong charge shielding in the C-terminus or (ii) by truncation of aa125-140 or aa109-140. Addition of MgCl(2) or spermine or acidification were not effective in promoting aggregation of syn(1-108). The impact of the disease-related mutations on the aggregation kinetics was dependent on the solution conditions, with the aggregation propensity order A53T approximately wt > A30P at low ionic strength, but A53T > wt approximately A30P at high ionic strength, with exceedingly potent promotion of aggregation by the A53T mutation in the presence of spermine. In contrast to full-length alpha-synuclein aggregates, those formed from syn(1-108) did not exhibit a pronounced polymorphism. The effects of the C-terminus on aggregation cannot be rationalized merely by a contribution to the protein net charge, but rather suggest a specific role of aa109-140 in the regulation of aggregation, presumably involving formation of intramolecular contacts.     

Effect of protein charge on the generation of aggregation-prone conformers

This study describes how charge modification affects aggregation of ovalbumin, thereby distinguishing the role of conformational and electrostatic stability in the process. Ovalbumin variants were engineered using chemical methylation or succinylation to obtain a range of protein net charge from -1 to -26. Charge modification significantly affected the denaturation temperature. From urea-induced equilibrium denaturation studies, it followed that unfolding proceeded via an intermediate state. However, the heat-induced denaturation process could still be described as a two-state irreversible unfolding transition, suggesting that the occurrence of an intermediate has no influence on the kinetics of unfolding. By monitoring the aggregation kinetics, the net charge was found not to be discriminative in the process. It is concluded that the dominant factor determining ovalbumin aggregation propensity is the rate of denaturation and not electrostatic repulsive forces.     

Amyloid Fibril-Like Structure Underlies the Aggregate Structure across the pH Range for β-Lactoglobulin

The protein β-lactoglobulin aggregates into two apparently distinct forms under different conditions: amyloid fibrils at pH values away from the isoelectric point, and spherical aggregates near it. To understand this apparent dichotomy in behavior, we studied the internal structure of the spherical aggregates by employing a range of biophysical approaches. Fourier transform infrared studies show the aggregates have a high β-sheet content that is distinct from the native β-lactoglobulin structure. The structures also bind the amyloidophilic dye thioflavin-T, and wide-angle x-ray diffraction showed reflections corresponding to spacings typically observed for amyloid fibrils composed of β-lactoglobulin. Combined with small-angle x-ray scattering data indicating the presence of one-dimensional linear aggregates at the molecular level, these findings indicate strongly that the aggregates contain amyloid-like substructure. Incubation of β-lactoglobulin at pH values increasingly removed from the isoelectric point resulted in the increasing appearance of fibrillar species, rather than spherical species shown by electron microscopy. Taken together, these results suggest that amyloid-like β-sheet structures underlie protein aggregation over a much broader range of conditions than previously believed. Furthermore, the results suggest that there is a continuum of β-sheet structure of varying regularity underlying the aggregate morphology, from very regular amyloid fibrils at high charge to short stretches of amyloid-like fibrils that associate together randomly to form spherical particles at low net charge.     

Secondary and tertiary structures involving chondroitin and chondroitin sulphates in solution, investigated by rotary shadowing/electron microscopy and computer simulation.

Rotary shadowing/electron microscopy of chondroitin 6-sulphate (CS6) and 4-sulphate (CS4) showed that the former, but not the latter, aggregated to mesh works. Preparations made from salt (ammonium acetate) solutions showed enhanced aggregation. Computer modelling, using molecular mechanics and dynamics, was applied to secondary structures (twofold helices) derived from NMR studies, to determine geometric and energetic constraints on duplex and higher-aggregate formation. The calculations suggested that chondroitin, CS6 and undersulphated CS4 could form duplexes, while CS4 could not, thus bridging the gap between atomic dimensions (NMR) and high polymer scale (electron microscopy). Calculations suggested that water structure helped to stabilise the twofold helix. It is proposed that the twofold helical, flat, tape-like molecules aggregate via hydrophobic bonding between the very extensive hydrophobic patches (9 CH units) repeated on alternating sides of the polymers. The negative charge of the polyanions opposes aggregate formation. Calculations showed that duplexes were formed with decreasing stability as the charge density increased, and as the charge was concentrated towards the centre line of the polymer (i.e. in CS4). The unsulphated polymer chondroitin could form duplexes and higher aggregates as readily as hyaluronan. Hyaluronan was calculated to form stable heteroduplexes with CS6 and CS4. The frequency and positioning of the sulphate-ester group within the polymer thus determines whether the molecule participates in duplex formation.     

Cationic surfactant mediated fibrillogenesis in bovine liver catalase: a biophysical approach

Protein aggregation into oligomers and mature fibrils are associated with more than 20 diseases in humans. The interactions between cationic surfactants dodecyltrimethylammonium bromide (DTAB) and tetradecyltrimethylammonium bromide (TTAB) with varying alkyl chain lengths and bovine liver catalase (BLC) were examined by various biophysical approaches. The delicate coordination of electrostatic and hydrophobic interactions with protein, play imperative role in aggregation. In this article, we have reconnoitered the relation between charge, hydrophobicity and cationic surfactants DTAB and TTAB on BLC at pH 7.4 and 9.4 which are two and four units above pI, respectively. We have used techniques like turbidity, Rayleigh light scattering, far-UV CD, ThT, ANS, Congo red binding assay, DLS, and transmission electron microscopy. The low concentration ranges of DTAB (0–600 μM) and TTAB (0–250 μM) were observed to increase aggregation at pH 9.4. Nevertheless, at pH 7.4 only TTAB was capable of inducing aggregate. DTAB did not produce any significant change in secondary structure at pH 7.4 suggestive of the role of respective charges on surfactants and protein according to the pI and alkyl chain length. The morphology of aggregates was further determined by TEM, which proved the existence of a fibrillar structure. The surfactants interaction with BLC was primarily electrostatic as examined by ITC. Our work demystifies the critical role of charge as well as hydrophobicity in amyloid formation.     

Analysis of the thermodynamic non-ideality of proteins by sedimentation equilibrium experiments

This paper presents a modified method to determine experimentally the second virial coefficient of protein solutions by sedimentation equilibrium experiments. The improvement is based on the possibility of fitting simultaneously up to seven radial concentration distribution curves of solutions with different loading concentrations. The possibility of precise determination of the second virial coefficient allows estimation of the net charge and the excluded volume of a monomeric protein. Application of the method is demonstrated for lysozyme and ovalbumin. In 0.1 M sodium acetate buffer, pH 4.5, the second virial coefficient of hen egg white lysozyme amounts to 24 +/- 1 ml/g. Analysis based on spherical particle theory yield an excluded volume of 3.5 ml/g and a charge dependent value of 20.5 ml/g which is induced by a net charge number of 14.1 +/- 1. Under low salt conditions self-association processes on lysozyme are unfavorable due to electrostatic repulsion. To overcome these repulsive contributions, either a shift to neutral pH or addition of at least 2% NaCl is necessary. In this way the charge dependent contribution decreases below the value responsible for the excluded volume and allows crystallization of the protein. Similar effects can be observed with ovalbumin. The high virial coefficient observed at pH 8.5 is induced by the high net charge number of 27 +/- 1.     

Systematic of alcohol-induced simple coacervation in aqueous gelatin solutions

Turbidity measurements performed at 450 nm were used to follow the process of simple coacervation when 1% (w/v) aqueous alkali processed gelatin (type-B) solutions were titrated with methanol, ethanol, propanol, and tert-butyl alcohol at various pHs of the solution ranging from pH = 5 to 8 and ionic strengths varying from I = 0.01 to 0.1 M NaCl. The titration profiles clearly established the transition points in terms of the percentage of volume of alcohol added relative to that of solvent corresponding to the first occurrence of turbidity (Vt) and a point of turbidity maximum (Vp). Addition of more alcohol drove the system toward precipitation. The values of Vt and Vp characterized the initiation of intramolecular folding and intermolecular aggregate formation of the charge neutralized gelatin molecules and the subsequent micro coacervate droplet formation. The state of intermolecular aggregates and that of folded gelatin molecules could be characterized by dynamic laser light scattering experiments, which implied spontaneous segregation of particle sizes preceding coacervation. The aggregates constitute the coacervate phase while the folded gelatin molecules mostly stay dispersed in the supernatant. The data taken together reveal the role played by solution entropy in addition to that of electrostatic and solute-solvent interactions, which had been overlooked hitherto.     

The effects of dipalmitoyl phosphatidyl choline on the precipitation of native fibrils and segment-long-spacing aggregates from collagen solution

The effect of dipalmitoyl phosphatidyl choline (DPPC), the major phospholipid component of pulmonary surfactant, on the precipitation of collagen in the form of native fibrils and segment-long-spacing (SLS) aggregates was studied in vitro. The effects of DPPC on both phases of collagen fibrillogenesis were analyzed spectrophotometrically, and alterations in the morphology of precipitated fibrils and SLS aggregates were ascertained by transmission electron microscopy (TEM). Low concentrations of DPPC inhibited the growth phase of fibrillogenesis, while higher concentrations were required to inhibit nucleation. Both the meshwork density and mean width of precipitated fibrils were altered by DPPC, as was the size of SLS aggregates. Segment-long-spacing aggregates prepared from pepsin-treated collagen were inhibited to a greater degree than SLS aggregates prepared from untreated collagen, indicating that the pepsin-susceptible residues of the telopeptide extensions of tropocollagen molecules stabilize SLS aggregates against the effects of DPPC. Based on these results and the inhibition of the growth phase at lower concentrations than those which inhibited the nucleation phase of fibrillogenesis, it was concluded that the primary mechanism of DPPC inhibition is electrostatic interference between the positively charged phospholipid molecules and the net positive charge of collagen. It is proposed that pathological conditions involving the pulmonary epithelium may allow interaction between surfactant and collagen, which could further weaken the interstitial connective tissue.     

Cartilage proteoglycan aggregates. Electronmicroscopic studies of native and fragmented molecules

1. Proteoglycan aggregates from bovine nasal cartilage were studied by using electron microscopy of proteoglycan/cytochrome c monolayers. 2. The aggregates contained a variably long central filament of hyaluronic acid with an average length of 1037nm. The proteoglycan monomers attached to the hyaluronic acid appeared as side chain filaments varying in length (averaging 249nm). They were distributed along the central filament at an average distance of about 36nm. 3. Chondroitin sulphate side chains were removed from the proteoglycan monomers of the aggregates by partial chondroitinase digestion. The molecules obtained had the same general appearance as intact aggregates. 4. Proteoglycan aggregates were treated with trypsin and the largest fragment, which contains the hyaluronic acid, link protein and hyaluronic acid-binding region, was recovered and studied with electron microscopy. Filaments that lacked the side chain extensions and had the same length as the central filament in the intact aggregate were observed. 5. Hyaluronic acid isolated after papain digestion of cartilage extracts gave filaments with similar length and size distribution as observed for the central filament both in the intact aggregate and in the trypsin digests. 6. Umbilical-cord hyaluronic acid was also studied and gave electron micrographs similar to those described for hyaluronic acid from cartilage. However, the length of the filament was somewhat shorter. 7. The electron micrographs of both intact and selectively degraded proteoglycans corroborate the current model of cartilage proteoglycan structure.     

Amyloid fibrils of human prion protein are spun and woven from morphologically disordered aggregates

Propagation and infectivity of prions in human prionopathies are likely associated with conversion of the mainly α-helical human prion protein, HuPrP, into an aggregated form with amyloid-like properties. Previous reports on efficient conversion of recombinant HuPrP have used mild to harsh denaturing conditions to generate amyloid fibrils in vitro. Herein we report on the in vitro conversion of four forms of truncated HuPrP (sequences 90-231 and 121-231 with and without an N-terminal hexa histidine tag) into amyloid-like fibrils within a few hours by using a protocol (phosphate buffered saline solutions at neutral pH with intense agitation) close to physiological conditions. The conversion process monitored by thioflavin T, ThT, revealed a three stage process with lag, growth and equilibrium phases. Seeding with preformed fibrils shortened the lag phase demonstrating the classic nucleated polymerization mechanism for the reaction. Interestingly, comparing thioflavin T kinetics with solubility and turbidity kinetics it was found that the protein initially formed non-thioflavionophilic, morphologically disordered aggregates that over time matured into amyloid fibrils. By transmission electron microscopy and by fluorescence microscopy of aggregates stained with luminescent conjugated polythiophenes (LCPs); we demonstrated that HuPrP undergoes a conformational conversion where spun and woven fibrils protruded from morphologically disordered aggregates. The initial aggregation functioned as a kinetic trap that decelerated nucleation into a fibrillation competent nucleus, but at the same time without aggregation there was no onset of amyloid fibril formation. The agitation, which was necessary for fibril formation to be induced, transiently exposes the protein to the air-water interface suggests a hitherto largely unexplored denaturing environment for prion conversion.     

Structure and stability of Z* DNA

The structure and stability of the left handed Z* DNA aggregate was examined by spectroscopic methods and by electron microscopy. Poly(dGdC), upon heating in the presence of Mn++, forms a large aggregate which may be sedimented at 12,000 X g, with a circular dichroism spectrum characteristic of left handed DNA. Aggregation gives rise to turbidity changes at visible wavelengths, providing a convenient means of monitoring the transition in solution. The wavelength dependence of turbidity is consistent with the scattering behavior of a long thin rod. Electron microscopy shows that Z* DNA is a large fibrous structure of indeterminant length, with a uniform diameter of approximately 20 nm. The results obtained in solution and under the requisite conditions for electron microscopy are mutually consistent. Poly(dGdC) preparations with average lengths of 60, 240, 500, and 2000 base pairs all form Z* DNA. Poly(dGm5dC) forms Z* DNA in the presence of Mn++ without heating, but poly(dAdC)-poly(dGdT) and calf thymus DNA cannot be induced to the Z* form under any conditions tried. Kinetic studies, monitored by turbidity changes, provide evidence that the formation of Z* DNA proceeds by a nucleated condensation mechanism. Dissolution of the Z* aggregate results from the chelation of Mn++ or by the addition of the intercalator ethidium bromide. The allosteric conversion of Z* DNA to an intercalated, right handed form by ethidium is demonstrated by kinetic studies, equilibrium binding studies and circular dichroism spectroscopy. Electron microscopy provides a striking visualization of the dissolution of the Z* aggregate by ethidium.     

Fabrication and Characterization of Polyelectrolyte Microparticles with Protein

The incorporation of proteins into microparticles fabricated by layer-by-layer adsorption of oppositely charged polyelectrolytes (dextran sulfate and protamine) on protein microaggregates was studied. Microaggregates with insulin were prepared by two different techniques: 1) formation of insoluble polyelectrolyte complex consisting of insulin and dextran sulfate (aggregate size of 7-20 micro m), or 2) salting out of insulin from solution by sodium chloride (aggregate size of 5-13 micro m). Microparticles varying in the number of cycles (from 1 to 8) of polyelectrolyte adsorption on protein aggregates were examined and compared. Morphology of the microparticles was studied by scanning electron and optical microscopy. It was shown that polyelectrolyte microparticles retained the shape and dimensions of the initial protein aggregates used as a template. Ultrasonication of microparticles obtained using salted out protein aggregates resulted in the formation of stable nanoparticles (100-200 nm). Regulation of protein release from the microparticles of both types by varying the number of polyelectrolyte adsorption cycles and pH of the medium was demonstrated. Insulin not bound to polyelectrolytes was released from the microparticles at pH values between 6 and 8, which corresponds to the pH of the human small intestine and ileum.     

Quantitative analysis of aggregation in dilute solutions of effectively rigid biomacromolecules via the combination of oscillatory flow birefringence and viscoelasticity measurements: example study of aggregation of bovine fibrinogen in aqueous glycerol, and detection of a large aggregate formed on addition of guanidine hydrochloride

Oscillatory flow birefringence (OFB) properties have been measured for dilute solutions of bovine fibrinogen in 65-68% aqueous glycerol with the Miller-Schrag Thin Fluid Layer (TFL) apparatus employing either titanium or stainless steel surfaces in contact with the solutions. The shearing frequency range was 1 to 2500 Hz, the concentrations ranged from 4 to 8 mg/ml, and measurement temperatures were 9.9, 10.0, and 15.8 degrees C. The data showed evidence of significant amounts of aggregation that apparently is caused by the presence of glycerol; contributions from the various aggregates were readily detected since the staggered half-overlap aggregation in this system results in substantial differences in the rotational relaxation times of the various effectively rigid aggregates. The combination of oscillatory flow birefringence and viscoelasticity (VE) data provided sensitive and precise characterization of aggregation in these example systems; all aggregates exhibited the expected positive optical anisotropy. The length of unaggregated fibrinogen in solution was found to be that obtained via electron microscopy. Addition of guanidine hydrochloride to hopefully reduce aggregation did so but also resulted in formation of a very large (2800 to 3500 A), apparently nearly monodisperse, negatively birefringent aggregate, suggesting that this new species might be formed by lateral aggregation.     

Cryogelation in vitro

Cryogel is a physical gel formed by the heterophilic aggregation of extra domain A containing fibronectin (EDA(+)FN), plasma fibronectin (pFN), fibrinogen (Fbg) and heparin (Hep). Cryogelation is controlled by the interactions between each aggregate and the amount of aggregates. Therefore, the present study attempted to elucidate these properties by studying turbidity (tau). Although only Fbg formed a self-aggregate under low temperatures, from the temperature dependence of tau, the amount of aggregate in three-element (pFN/Fbg/Hep) solution surpassed that of the EDA(+)FN/Fbg/Hep system. The optimal condition for cryogelation was afforded by a solution with Fbg/EDA(+)FN/pFN/Hep expressed in the molar ratio of 12:0.04:0.79:1. This cryogel structure in solution was probably formed via structural changes induced by pFN in Fbg. The structural change in Fbg was examined by circular dichroism under optimal conditions. This concept was based on observations of the direct transmission scanning electron microscopy of a cryogel. The EDA(+)FN/pFN/Fbg/Hep aggregates displayed a network structure that manifested particulate crosslinkage. Cryogelation, a phenomenon related to induction of rheumatoid arthritis in humans, was facilitated by both the EDA(+)FN-Hep interaction and the structural changes of Fbg induced by pFN.     

Rapid assembly of amyloid-beta peptide at a liquid/liquid interface produces unstable beta-sheet fibers

Accumulation of aggregated amyloid-beta peptide (Abeta) in the brain is a pathological hallmark of Alzheimer's disease (AD). In vitro studies indicate that the 40- to 42-residue Abeta peptide in solution will undergo self-assembly leading to the transient appearance of soluble protofibrils and ultimately to insoluble fibrils. The Abeta peptide is amphiphilic and accumulates preferentially at a hydrophilic/hydrophobic interface. Solid surfaces and air-water interfaces have been shown previously to promote Abeta aggregation, but detailed characterization of these aggregates has not been presented. In this study Abeta(1-40) introduced to aqueous buffer in a two-phase system with chloroform aggregated 1-2 orders of magnitude more rapidly than Abeta in the buffer alone. The interface-induced aggregates were released into the aqueous phase and persisted for 24-72 h before settling as a visible precipitate at the interface. Thioflavin T fluorescence and circular dichroism analyses confirmed that the Abeta aggregates had a beta-sheet secondary structure. However, these aggregates were far less stable than Abeta(1-40) protofibrils prepared in buffer alone and disaggregated completely within 3 min on dilution. Atomic force microscopy revealed that the aggregates consisted of small globules 4-5 nm in height and long flexible fibers composed of these globules aligned roughly along a longitudinal axis, a morphology distinct from that of Abeta protofibrils prepared in buffer alone. The relative instability of the fibers was supported by fiber interruptions apparently introduced by brief washing of the AFM grids. To our knowledge, unstable aggregates of Abeta with beta-sheet structure and fibrous morphology have not been reported previously. Our results provide the clearest evidence yet that the intrinsic beta-sheet structure of an in vitro Abeta aggregate depends on the aggregation conditions and is reflected in the stability of the aggregate and the morphology observed by atomic force microscopy. Resolution of these structural differences at the molecular level may provide important clues to the further understanding of amyloid formation in vivo.     

Dependence of alpha-synuclein aggregate morphology on solution conditions

Alpha-synuclein is the major component of Lewy bodies and Lewy neurites, which are granular and filamentous protein inclusions that are the defining pathological features of several neurodegenerative conditions such as Parkinson's disease. Fibrillar aggregates formed from alpha-synuclein in vitro resemble brain-derived material, but the role of such aggregates in the etiology of Parkinson's disease and their relation to the toxic molecular species remain unclear. In this study, we investigated the effects of pH and salt concentration on the in vitro assembly of human wild-type alpha-synuclein, particularly with regard to aggregation rate and aggregate morphology. Aggregates formed at pH 7.0 and pH 6.0 in the absence of NaCl and MgCl(2) were fibrillar; the pH 6.0 fibrils displayed a helical twist, as clearly evident by scanning force and electron microscopy. Incubations at pH 7.0 remained transparent during the process of aggregation and exhibited strong thioflavin-T and weak 8-anilino-1-naphthalenesulfonate (ANS) binding; furthermore, they were efficient in seeding fibrillization of fresh solutions. In contrast, incubating alpha-synuclein at low pH (pH 4.0 or pH 5.0) resulted in the rapid formation of turbid suspensions characterized by strong ANS binding, reduced thioflavin-T binding and reduced seeding efficiency. At pH 4.0, fibril formation was abrogated; instead, very large aggregates (dimensions approximately 100 microm) of amorphous appearance were visible by light microscopy. As with acidic conditions, addition of 0.2M NaCl or 10mM MgCl(2) to pH 7.0 incubations led to a shorter aggregation lag time and formation of large, amorphous aggregates. These results demonstrate that the morphology of alpha-synuclein aggregates is highly sensitive to solution conditions, implying that the fibrillar state does not necessarily represent the predominant or most functionally significant aggregated state under physiological conditions.     

Structure and Stability of Z* DNA

Abstract

The structure and stability of the left handed Z* DNA aggregate was examined by spectroscopic methods and by electron microscopy. Poly(dGdC), upon heating in the presence of Mn⁺⁺, forms a large aggregate which may be sedimented at 12,000 X g, with a circular dichroism spectrum characteristic of left handed DNA Aggregation gives rise to turbidity changes at visible wavelengths, providing a convenient means of monitoring the transition in solution. The wavelength dependence of turbidity is consistent with the scattering behavior of a long thin rod. Electron microscopy shows that Z* DNA is a large fibrous structure of indeterminant length, with a uniform diameter of approximately 20 nm. The results obtained in solution and under the requisite conditions for electron microscopy are mutually consistent Poly(dGdC) preparations with average lengths of 60,240,500, and 2000 base pairs all form Z* DNA Poly(dGm⁵dC) forms Z* DNA in the presence of Mn⁺⁺ without heating, but poly(dAdC)-poly(dGdT) and calf thymus DNA cannot be induced to the Z* form under any conditions tried. Kinetic studies, monitored by turbidity changes, provide evidence that the formation of Z* DNA proceeds by a nucleated condensation mechanism. Dissolution of the Z* aggregate results from the chelation of Mn⁺⁺ or by the addition of the intercalator ethidium bromide. The allosteric conversion of Z* DNA to an intercalated, right handed form by ethidium is demonstrated by kinetic studies, equilibrium binding studies and circular dichroism spectroscopy. Electron microscopy provides a striking visualization of the dissolution of the Z* aggregate by ethidium.     

Lutein Dispersed in Acetone Aqueous Solution; Spectroscopic Analysis and Electron Microscope Observation

The sizes and shapes of lutein aggregates in acetone aqueous solution were examined by spectroscopic analyses and electron microscopic observation, since lutein dispersed into acetone aqueous solution and provided a much simpler system than others. This system is suitable for basic research on lutein aggregates. The lutein aggregate gave maximum molar ellipticity in acetone concentrations from 35 to 45% aqueous solution. When the acetone concentration increased, CD spectra were reversed in 45% concentration from a negative exciton chirality to the positive. Since the aggregates were most slender in these acetone concentrations, it was found that the length of the lutein aggregate was closely related to the molar ellipticity. The apparent widths of the aggregates became large with increases of the acetone concentration after the reversion of CD spectra, where the molar ellipticities were diminished. These results are similar to those for the lutein aggregates in dilute surfactant solution, and this system is clearer and simpler for electron microscopic observation than those in surfactant solutions.     

Aggregation of 3,5-dihydroxybenzyl alcohol based dendrimers and hyperbranched polymers, and encapsulation of DR1 in such dendritic aggregates

The aggregation behavior of 3,5-dihydroxybenzyl alcohol based dendritic polymers through intermolecular hydrogen bonding between periphery situated variable number of OH groups was studied using dynamic light scattering and transmission electron microscopy. Size of the aggregates was found to be dependent on the generation number of dendrimers: generations 1-3 form aggregates above critical aggregation concentration (cac), while higher generations (4-5) aggregate even at concentrations much lower than cac. Encapsulation of the dye disperse red 1 (DR1) into dendrimer aggregates was accompanied by a blue shift in the UV-Vis absorption spectrum of DR1.     

Structural evaluation of phospholipid bicelles for solution-state studies of membrane-associated biomolecules

Several complementary physical techniques have been used to characterize the aggregate structures formed in solutions containing dimyristoylphosphatidylcholine (DMPC)/dihexanoylphosphatidylcholine (DHPC) at ratios of < or =0.5 and to establish their morphology and lipid organization as that of bicelles. (31)P NMR studies showed that the DMPC and DHPC components were highly segregated over a wide range of DMPC/DHPC ratios (q = 0.05-0.5) and temperatures (15 degrees C and 37 degrees C). Only at phospholipid concentrations below 130 mM did the bicelles appear to undergo a change in morphology. These results were corroborated by fluorescence data, which demonstrated the inverse dependence of bicelle size on phospholipid concentration as well as a distinctive change in phospholipid arrangement at low concentrations. In addition, dynamic light scattering and electron microscopy studies supported the hypothesis that the bicellar phospholipid aggregates are disk-shaped. The radius of the planar domain of the disk was found to be directly proportional to the ratio of DMPC/DHPC and inversely proportional to the total phospholipid concentration when the DMPC/DHPC ratio was held constant at 0.5. Taken together, these results suggest that bicelles with low q retain the morphology and bilayer organization typical of their liquid-crystalline counterparts, making them useful membrane mimetics.