Rapid self-assembly of alpha-synuclein observed by in situ atomic force microscopy

Self-assembly of alpha-synuclein resulting in protein aggregates of diverse morphology has been implicated in the pathogenesis of Parkinson's disease and other neurodegenerative disorders known as synucleinopathies. Apart from its biomedical relevance, this aggregation process is representative of the interconversion of an unfolded protein into nanostructures with typical amyloid features. We have used in situ tapping mode atomic force microscopy to continuously monitor the self-assembly of wild-type alpha-synuclein, its disease-related mutants A30P and A53T, and the C-terminally truncated variant alpha-synuclein(1-108). Different aggregation modes were observed depending on experimental conditions, i.e. pH, protein concentration, polyamine concentration, temperature and the supporting substrate. At pH 7.5, in the absence of the biogenic polyamines spermidine or spermine, elongated sheets 1.1(+/-0.2)nm in height and presumably representing individual beta-sheet structures, were formed on mica substrates within a few minutes. Their orientation was directed by the crystalline substructure of the substrate. In contrast, sheet formation was not observed with hydrophobic highly oriented pyrolytic graphite substrates, suggesting that negatively charged surfaces promote alpha-synuclein self-assembly. In the presence of spermidine or spermine 5.9(+/-1.0)nm high spheroidal structures were preferentially formed, sharing characteristics with similar structures previously reported for several amyloidogenic proteins and linked to neurotoxicity. alpha-Synuclein spheroid formation depended critically on polyamine binding to the C terminus, revealing a promoting effect of the C terminus on alpha-synuclein assembly in the bound state. In rare cases, fibril growth from spheroids or preformed aggregates was observed. At pH 5.0, fibrils were formed initially and incorporated into amorphous aggregates in the course of the aggregation process, providing evidence for the potential of amyloid fibril surfaces to act as nucleation sites in amorphous aggregation. This study provides a direct insight into different modes of alpha-synuclein self-assembly and identifies key factors modulating the aggregation process.     

Secondary structure of alpha-synuclein oligomers: characterization by raman and atomic force microscopy

Formation of alpha-synuclein aggregates is proposed to be a crucial event in the pathogenesis of Parkinson's disease. Large soluble oligomeric species are observed as probable intermediates during fibril formation and these, or related aggregates, may constitute the toxic element that triggers neurodegeneration. Unfortunately, there is a paucity of information regarding the structure and composition of these oligomers. Here, the morphology and the conformational characteristics of the oligomers and filaments are investigated by a combined atomic force microscopy (AFM) and Raman microscopic approach on a common mica surface. AFM showed that in vitro early stage oligomers were globular with variable heights, while prolonged incubation caused the oligomers to become elongated as protofilaments. The height of the subsequently formed alpha-synuclein filaments was similar to that of the protofilaments. Analysis of the Raman amide I band profiles of the different alpha-synuclein oligomers establishes that the spheroidal oligomers contain a significant amount of alpha-helical secondary structure (47%), which decreases to about 37% in protofilaments. At the same time, when protofilaments form, beta-sheet structure increases to about 54% from the approximately 29% observed in spheroidal oligomers. Upon filament formation, the major conformation is beta-sheet (66%), confirmed by narrowing of the amide I band and the profile maximum shifting to 1667 cm(-1). The accumulation of spheroidal oligomers of increasing size but unchanged vibrational spectra during the fibrillization process suggests that a cooperative conformational change may contribute to the kinetic control of fibrillization.     

Structural Evidence for α-Synuclein Fibrils Using in Situ Atomic Force Microscopy

Human α-synuclein is a presynaptic terminal protein and can form insoluble fibrils that are believed to play an important role in the pathogenesis of several neurodegenerative diseases such as Parkinson‘s disease, dementia with Lewy bodies and Lewy body variant of Alzheimer‘s disease. In this paper, in situ atomic force microscopy has been used to study the structural properties of α-synuclein fibrils in solution using two different atomic force microscopy imaging modes: tapping mode and contact mode. In the in situ contact mode atomic force microscopy experiments α-synuclein fibrils quickly broke into fragments, and a similar phenomenon was found using tapping mode atomic force microscopy in which α-synuclein fibrils were incubated with guanidine hydrochloride (0.6 M). The α-synuclein fibrils kept their original filamentous topography for over 1h in the in situ tapping mode atomic force microscopy experiments. The present results provide indirect evidence on how 13-sheets assemble into α-synuclein fibrils on a nanometer scale.     

Contour and persistence length of Corynebacterium diphtheriae pili by atomic force microscopy

Many bacteria are characterized by nanoscale ultrastructures, for example S-layers, flagella, fimbriae, or pili. The last two are especially important for attachment to different abiotic and biotic surfaces and for host-pathogen interactions. In this study, we investigated the geometric and elastic properties of pili of different Corynebacterium diphtheriae strains by atomic force microscopy (AFM). We performed quantitative contour-length analysis of bacterial pili and found that the visible contour length of the pili can be described by a log-normal distribution. Our data revealed significant strain-specific variations in the mean visible contour length of the pili, ranging from 260 to 1,590 nm. To estimate their full contour length, which is not directly accessible from the AFM images, we developed a simple correction model. Using this model, we determined the mean full contour length as 510-2,060 nm. To obtain the persistence length we used two different methods of analysis, one based on the end-to-end distance of the pili and one based on the bending angles of short segments. In comparison, the bending angle analysis proved to be more precise and resulted in persistence lengths in the narrow range of 220-280 nm, with no significant strain-specific variations. This is small compared with some other bacterial polymers, for example type IV pili, F-pili, or flagella.     

Dynamics of nucleosomes assessed with time-lapse high-speed atomic force microscopy

A fundamental challenge of gene regulation is the accessibility of DNA within nucleosomes. Recent studies performed by various techniques, including single-molecule approaches, led to the realization that nucleosomes are quite dynamic rather than static systems, as they were once considered. Direct data are needed to characterize the dynamics of nucleosomes. Specifically, if nucleosomes are dynamic, the following questions need to be answered. What is the range of nucleosome dynamics? Is a non-ATP-dependent unwrapping of nucleosomes possible? What are the factors facilitating the large-scale opening and unwrapping of nucleosomes? In previous studies using time-lapse atomic force microscopy (AFM) imaging, we were able, for the first time, to observe spontaneous, ATP-independent unwrapping of nucleosomes. However, low temporal resolution did not allow visualization of various pathways of nucleosome dynamics. In the studies described here, we applied high-speed time-lapse AFM (HS-AFM) capable of visualizing molecular dynamics on the millisecond time scale to study the nucleosome dynamics. The mononucleosomes were assembled on a 353 bp DNA substrate containing nucleosome-specific 601 sequence. With HS-AFM, we were able to observe the dynamics of nucleosome on a subsecond time scale and visualize various pathways of nucleosome dynamics, such as sliding and unwrapping to various extents, including complete dissociation. These studies highlight an important role of electrostatic interactions in chromatin dynamics. Overall, our findings shed new light on nucleosome dynamics and provide a novel hypothesis for the mechanisms controlling the spontaneous dynamics of chromatin.     

Effect of different anti-Abeta antibodies on Abeta fibrillogenesis as assessed by atomic force microscopy

Extensive data suggest that the conversion of the amyloid-beta (Abeta) peptide from soluble to insoluble forms is a key factor in the pathogenesis of Alzheimer's disease (AD). In recent years, atomic force microscopy (AFM) has provided useful insights into the physicochemical processes involving Abeta morphology, and it can now be used to explore factors that either inhibit or promote fibrillogenesis. We used ex situ AFM to explore the impact of anti-Abeta antibodies directed against different domains of Abeta on fibril formation. For the AFM studies, two monoclonal antibodies (m3D6 and m266.2) were incubated in solution with Abeta(1-42) with a molar ratio of 1:10 (antibody to Abeta) over several days. Fibril formation was analyzed quantitatively by determining the number of fibrils per microm(2) and by aggregate size analysis. m3D6, which is directed against an N-terminal domain of Abeta (amino acid residues 1-5) slowed down fibril formation. However, m266.2, which is directed against the central domain of Abeta (amino acid residues 13-28) appeared to completely prevent the formation of fibrils over the course of the experiment. Inhibition of fibril formation by both antibodies was also confirmed by thioflavin-T (ThT) fluorescence experiments carried out with Abeta(1-40) incubated for five days. However, unlike AFM results, ThT did not differentiate between the samples incubated with m3D6 versus m266.2. These results indicate that AFM can be not only reliably used to study the effect of different molecules on Abeta aggregation, but that it can provide additional information such as the role of epitope specificity of antibodies as potential inhibitors of fibril formation.     

Imaging polysaccharides by atomic force microscopy

Techniques have been developed for the routine reliable imaging of polysaccharides by atomic force microscopy (AFM). The polysaccharides are deposited from aqueous solution onto the surface of freshly cleaved mica, air dried, and then imaged under alcohols. The rationale behind the development of the methodology is described and data is presented for the bacterial polysaccharides xanthan, acetan, and the plant polysaccharides 1-carrageenan and pectin. Studies on uncoated polysaccharides have demonstrated the improved resolution achievable when compared to more traditional metal-coated samples or replicas. For acetan the present methodology has permitted imaging of the helical structure. Finally, in addition to data obtained on individual polysaccharides, AFM images have also been obtained of the network structures formed by κ-carrageenan and gellan gum. © 1996 John Wiley & Sons, Inc.     

Plasmodium falciparum-infected erythrocytes: qualitative and quantitative analyses of parasite-induced knobs by atomic force microscopy

We used the combination of an atomic force microscope and a light microscope equipped with epifluorescence to serially image Plasmodium falciparum-infected erythrocytes. This procedure allowed us to determine unambiguously the presence and developmental stage of the malaria parasite as well as the number and size of knobs in singly, doubly, and triply infected erythrocytes. Knobs are not present during the ring stage of a malaria infection but a lesion resulting from invasion by a merozoite is clearly visible on the erythrocyte surface. This lesion is visible into the late trophozoite stage of infection. Knobs begin to form during the early trophozoite stage of infection and have a single-unit structure. Our data suggest the possibility that a two-unit structure of knobs, which was reported by Aikawa et al. (1996, Exp. Parasitol. 84, 339-343) using atomic force microscopy, appears to be a double-tipped image. The number of knobs per unit of host cell surface area is directly proportional to parasite number in both early and late trophozoite stages. These results indicate that knob formation by one parasite does not influence knob formation by other parasites in a multiply infected erythrocyte. In addition, knob volume is not influenced by either parasite stage or number at the late trophozoite stage, indicating that the number of component molecules per knob is constant throughout the parasite maturation process.     

Fruit softening and pectin disassembly: an overview of nanostructural pectin modifications assessed by atomic force microscopy

Background

One of the main factors that reduce fruit quality and lead to economically important losses is oversoftening. Textural changes during fruit ripening are mainly due to the dissolution of the middle lamella, the reduction of cell-to-cell adhesion and the weakening of parenchyma cell walls as a result of the action of cell wall modifying enzymes. Pectins, major components of fruit cell walls, are extensively modified during ripening. These changes include solubilization, depolymerization and the loss of neutral side chains. Recent evidence in strawberry and apple, fruits with a soft or crisp texture at ripening, suggests that pectin disassembly is a key factor in textural changes. In both these fruits, softening was reduced as result of antisense downregulation of polygalacturonase genes. Changes in pectic polymer size, composition and structure have traditionally been studied by conventional techniques, most of them relying on bulk analysis of a population of polysaccharides, and studies focusing on modifications at the nanostructural level are scarce. Atomic force microscopy (AFM) allows the study of individual polymers at high magnification and with minimal sample preparation; however, AFM has rarely been employed to analyse pectin disassembly during fruit ripening.

Scope

In this review, the main features of the pectin disassembly process during fruit ripening are first discussed, and then the nanostructural characterization of fruit pectins by AFM and its relationship with texture and postharvest fruit shelf life is reviewed. In general, fruit pectins are visualized under AFM as linear chains, a few of which show long branches, and aggregates. Number- and weight-average values obtained from these images are in good agreement with chromatographic analyses. Most AFM studies indicate reductions in the length of individual pectin chains and the frequency of aggregates as the fruits ripen. Pectins extracted with sodium carbonate, supposedly located within the primary cell wall, are the most affected.     

Hyaluronic acid by atomic force microscopy.

Hyaluronic acid (HA) of different molecular weights has been examined by atomic force microscopy (AFM) in air. This technique allows 3-D surface images of soft samples without any pretreatment, such as shadowing or staining. In the present study we examined the supermolecular organization of HA chains when deposited on mica and graphite, to better understand the interchain and intrachain interactions of HA molecules in solution. The concentration of the solution deposited varied from 0.001 to 1 mg/ml. On both substrates, and independent of the concentration, high-molecular-mass HA formed networks in which molecules ran parallel for hundreds of nanometers, giving rise to flat sheets and tubular structures that separate and rejoin into similar neighboring aggregates. Accurate measurements of the thickness of the thinnest sheets were consistent with a monolayer of HA molecules, 0.3 nm thick, strongly indicating lateral aggregation forces between chains as well as rather strong hydrophilic interactions between mica and HA. The results agree with an existing model of HA tertiary structure in solution in which the network is stabilized by both hydrophilic and hydrophobic interactions. Our images support this model and indicate that hydrophobic interactions between chains may exert a pivotal role in aqueous solution.     

Biomolecular interactions measured by atomic force microscopy

Atomic force microscopy (AFM) is nowadays frequently applied to determine interaction forces between biological molecules. Starting with the detection of the first discrete unbinding forces between ligands and receptors by AFM only several years ago, measurements have become more and more quantitative. At the same time, theories have been developed to describe and understand the dynamics of the unbinding process and experimental techniques have been refined to verify this theory. In addition, the detection of molecular recognition forces has been exploited to map and image the location of binding sites. In this review we discuss the important contributions that have led to the development of this field. In addition, we emphasize the potential of chemically well-defined surface modification techniques to further improve reproducible measurements by AFM. This increased reproducibility will pave the way for a better understanding of molecular interactions in cell biology.     

A general model for amyloid fibril assembly based on morphological studies using atomic force microscopy

Based on atomic force microscopy analysis of the morphology of fibrillar species formed during fibrillation of alpha-synuclein, insulin, and the B1 domain of protein G, a previously described model for the assembly of amyloid fibrils of immunoglobulin light-chain variable domains is proposed as a general model for the assembly of protein fibrils. For all of the proteins studied, we observed two or three fibrillar species that vary in diameter. The smallest, protofilaments, have a uniform height, whereas the larger species, protofibrils and fibrils, have morphologies that are indicative of multiple protofilaments intertwining. In all cases, protofilaments intertwine to form protofibrils, and protofibrils intertwine to form fibrils. We propose that the hierarchical assembly model describes a general mechanism of assembly for all amyloid fibrils.     

原子力显微镜单分子力谱研究生物分子间相互作用

原子力显微镜单分子力谱是近年来发展起来的能在单分子水平研究生物分子相互作用的新工具。本文综述了单分子力谱的测定原理、方法及其在研究蛋白．蛋白、蛋白-DNA相互作用,蛋白质去折叠和活细胞上配体／受体结合中的应用进展。     

Micromanipulation of phospholipid bilayers by atomic force microscopy

The molecular details of adhesion mechanics in phospholipid bilayers have been studied using atomic force microscopy (AFM). Under tension fused bilayers of dipalmitoylphosphatidylcholine (DPPC) yield to give non-distance dependent and discrete force plateaux of 45.4, 81.6 and 113+/-3.5 pN. This behaviour may persist over distances as great as 400 nm and suggests the stable formation of a cylindrical tube which bridges the bilayers on the two surfaces. The stability of this connective structure may have implications for the formation of pili and hence for the initial stage of bacterial conjugation. Dimyristoylphosphatidylcholine (DMPC) bilayers also exhibit force plateaux but with a much less pronounced quantization. Bilayers composed of egg PC, sterylamine and cholesterol stressed in a similar way show complex behaviour which can in part be explained using the models demonstrated in the pure lipids.     

Micromanipulation of phospholipid bilayers by atomic force microscopy

The molecular details of adhesion mechanics in phospholipid bilayers have been studied using atomic force microscopy (AFM). Under tension fused bilayers of dipalmitoylphosphatidylcholine (DPPC) yield to give non-distance dependent and discrete force plateaux of 45.4, 81.6 and 113±3.5 pN. This behaviour may persist over distances as great as 400 nm and suggests the stable formation of a cylindrical tube which bridges the bilayers on the two surfaces. The stability of this connective structure may have implications for the formation of pili and hence for the initial stage of bacterial conjugation. Dimyristoylphosphatidylcholine (DMPC) bilayers also exhibit force plateaux but with a much less pronounced quantization. Bilayers composed of egg PC, sterylamine and cholesterol stressed in a similar way show complex behaviour which can in part be explained using the models demonstrated in the pure lipids.