Surface-charge differentiation of streptavidin and avidin by atomic force microscopy-force spectroscopy.

Chemical information can be obtained by using atomic force microscopy (AFM) and force spectroscopy (FS) with atomic or molecular resolution, even in liquid media. The aim of this paper is to demonstrate that single molecules of avidin and streptavidin anchored to a biotinylated bilayer can be differentiated by using AFM, even though AFM topographical images of the two proteins are remarkably alike. At physiological pH, the basic glycoprotein avidin is positively charged, whereas streptavidin is a neutral protein. This charge difference can be determined with AFM, which can probe electrostatic double-layer forces by using FS. The force curves, owing to the electrostatic interaction, show major differences when measured on top of each protein as well as on the lipid substrate. FS data show that the two proteins are negatively charged. Nevertheless, avidin and streptavidin can be clearly distinguished, thus demonstrating the sensitivity of AFM to detect small changes in the charge state of macromolecules.

Tau aggregation followed by atomic force microscopy and surface plasmon resonance, and single molecule tau-tau interaction probed by atomic force spectroscopy.

Intracellular neurofibrillary tangles, composed mainly of tau protein, and extracellular plaques, containing mostly amyloid-beta, are the two types of protein aggregates found upon autopsy within the brain of Alzheimer's disease patients. Polymers of tau protein can also be found in other neurodegenerative disorders known as tauopathies. Tau is a highly soluble protein, intrinsically devoid of secondary or tertiary structure, as many others proteins particularly prone to form fibrillar aggregations. The mechanism by which this unfolded molecule evolves to the well ordered helical filaments has been amply studied. In fact, it is a very slow process when followed in the absence of aggregation inducers. Herein we describe the use of surface plasmon resonance, atomic force microscopy, and atomic force spectroscopy to detect tau-tau interactions and to follow the process of aggregation in the absence of aggregation inducers. Tau-tau interactions are clearly detected, although a very long period of time is needed to observe filaments formation. Tau oligomers showing a granular appearance, however, are observed immediately as a consequence of this interaction. These granular tau oligomers slowly evolve to larger structures and eventually to filaments having a size smaller than those reported for paired helical filaments purified from Alzheimer's disease.

Unbinding molecular recognition force maps of localized single receptor molecules by atomic force microscopy.

Atomic force microscopy is a technique capable to study biological recognition processes at the single-molecule level. In this work we operate the AFM in a force-scan based mode, the jumping mode, where simultaneous topographic and tip-sample adhesion maps are acquired. This approach obtains the unbinding force between a well-defined receptor molecule and a ligand attached to the AFM tip. The method is applied to the avidin-biotin system. In contrast with previous data, we obtain laterally resolved adhesion maps of avidin-biotin unbinding forces highly correlated with single avidin molecules in the corresponding topographic map. The scanning rate 250 pixel s(-1) (2 min for a 128 x 128 image) is limited by the hydrodynamic drag force. We are able to build a rupture-force distribution histogram that corresponds to a single defined molecule. Furthermore, we find that due to the motility of the polymer used as spacer to anchor the ligand to the tip, its direction at rupture does not generally coincide with the normal to the tip-sample, this introduces an appreciable error in the measured force.

Biochemical, ultrastructural, and reversibility studies on huntingtin filaments isolated from mouse and human brain.

Huntington's disease (HD) and eight additional inherited neurological disorders are caused by CAG triplet-repeat expansions leading to expanded polyglutamine-sequences in their respective proteins. These triplet-CAG repeat disorders have in common the formation of aberrant intraneuronal proteinaceous inclusions containing the expanded polyglutamine sequences. These aggregates have been postulated to contribute to pathogenesis caused by conformational toxicity, sequestration of other polyglutamine-containing proteins, or by interfering with certain enzymatic activities. Testing these hypotheses has been hampered by the difficulty to isolate these aggregates from brain. Here we report that polyglutamine aggregates can be isolated from the brain of the Tet/HD94 conditional mouse model of HD, by following a method based on high salt buffer homogenization, nonionic detergent extraction, and gradient fractionation. We then verified that the method can be successfully applied to postmortem HD brains. Immunoelectron microscopy, both in human and mouse samples, revealed that the stable component of the inclusions are mutant huntingtin-containing and ubiquitin-containing fibrils. Atomic-force microscopy revealed that these fibrils have a "beads on a string" morphology. Thus, they resemble the in vitro assembled filaments made of recombinant mutant-huntingtin, as well as the Abeta and alpha-synuclein amyloid protofibrils. Finally, by shutting down transgene expression in the Tet/HD94 conditional mouse model of HD, we were able to demonstrate that these filaments, although stable in vitro, are susceptible to revert in vivo, thus demonstrating that the previously reported reversal of ubiquitin-immunoreactive inclusions does not simply reflect disassembling of the inclusions into their constituent fibrils and suggesting that any associated conformational or protein-sequestration toxicity is also likely to revert.

Characterization by atomic force microscopy and cryoelectron microscopy of tau polymers assembled in Alzheimer's disease.

The structure of the Paired Helical filaments (PHF), a polymer of the microtubule associated protein tau, has been studied by Atomic Force Microscopy (AFM) and by cryoelectron microscopy. Mica and graphite were used as substrates in the AFM analysis with no differences in the results. A banding pattern of 8-12 nm width within the helical structure is found when detailed analysis of the data is performed. High AFM resolution images obtained by using an ultra sharp tip confirm the previous results and suggest that the structures observed are compatible with a helical ribbon made up of two parallel strands. These results were confirmed by cryoelectron microscopy experiments.