Force-induced conformational changes in PIEZO1.

PIEZO1 is a mechanosensitive channel that converts applied force into electrical signals. Partial molecular structures show that PIEZO1 is a bowl-shaped trimer with extended arms. Here we use cryo-electron microscopy to show that PIEZO1 adopts different degrees of curvature in lipid vesicles of different sizes. We also use high-speed atomic force microscopy to analyse the deformability of PIEZO1 under force in membranes on a mica surface, and show that PIEZO1 can be flattened reversibly into the membrane plane. By approximating the absolute force applied, we estimate a range of values for the mechanical spring constant of PIEZO1. Both methods of microscopy demonstrate that PIEZO1 can deform its shape towards a planar structure. This deformation could explain how lateral membrane tension can be converted into a conformation-dependent change in free energy to gate the PIEZO1 channel in response to mechanical perturbations.

Severe Inflammatory Idiopathic Multicentric Castleman's Disease Coexisting with Advanced Renal Cancer: A Case Report.

The present case study was conducted on a 74-year-old man who visited our department due to a left renal and retroperitoneal tumor on computed tomography (CT). The patient was diagnosed with left renal cancer lymph node metastasis and was hospitalized a few weeks prior to surgery due to fever, malaise, and severe appetite loss. Biochemical laboratory findings at admission showed markedly high levels of inflammation. The cause of high inflammatory response was paraneoplastic syndrome. Tumor resection was considered necessary, and left nephrectomy and lymphadenectomy were performed; however, it did not improve the inflammatory response. After operation, positron emission tomography-CT revealed hyperaccumulation of 18F-fluorodeoxyglucose in the bone marrow throughout the body. Pathological examination of the resected specimen and bone marrow aspiration revealed the coexistence of idiopathic multicentric Castleman disease (CD) and renal cancer. Prednisolone and tocilizumab were administered for idiopathic multicentric CD and a tyrosine kinase inhibitor for renal cancer; however, they had poor therapeutic effect, and the patient died. CD is characterized by systemic symptoms due to the overproduction of interleukin-6. Treatment for idiopathic multicentric CD involves steroid and anti-interleukin-6 therapy. The diagnostic criteria for CD require the exclusion of malignant tumors although there are some cases in which CD and malignant tumors coexist. The prognosis for CD is relatively good; however, as in this case, the prognosis of CD coexisting with uncontrollable renal cancer is insufficient due to poor improvement in the inflammatory response.

Direct visualization of glutamate transporter elevator mechanism by high-speed AFM.

Glutamate transporters are essential for recovery of the neurotransmitter glutamate from the synaptic cleft. Crystal structures in the outward- and inward-facing conformations of a glutamate transporter homolog from archaebacterium Pyrococcus horikoshii, sodium/aspartate symporter GltPh, suggested the molecular basis of the transporter cycle. However, dynamic studies of the transport mechanism have been sparse and indirect. Here we present high-speed atomic force microscopy (HS-AFM) observations of membrane-reconstituted GltPh at work. HS-AFM movies provide unprecedented real-space and real-time visualization of the transport dynamics. Our results show transport mediated by large amplitude 1.85-nm "elevator" movements of the transport domains consistent with previous crystallographic and spectroscopic studies. Elevator dynamics occur in the absence and presence of sodium ions and aspartate, but stall in sodium alone, providing a direct visualization of the ion and substrate symport mechanism. We show unambiguously that individual protomers within the trimeric transporter function fully independently.

High-Speed Atomic Force Microscopy Reveals the Inner Workings of the MinDE Protein Oscillator.

The MinDE protein system from E. coli has recently been identified as a minimal biological oscillator, based on two proteins only: The ATPase MinD and the ATPase activating protein MinE. In E. coli, the system works as the molecular ruler to place the divisome at midcell for cell division. Despite its compositional simplicity, the molecular mechanism leading to protein patterns and oscillations is still insufficiently understood. Here we used high-speed atomic force microscopy to analyze the mechanism of MinDE membrane association/dissociation dynamics on isolated membrane patches, down to the level of individual point oscillators. This nanoscale analysis shows that MinD association to and dissociation from the membrane are both highly cooperative but mechanistically different processes. We propose that they represent the two directions of a single allosteric switch leading to MinD filament formation and depolymerization. Association/dissociation are separated by rather long apparently silent periods. The membrane-associated period is characterized by MinD filament multivalent binding, avidity, while the dissociated period is defined by seeding of individual MinD. Analyzing association/dissociation kinetics with varying MinD and MinE concentrations and dependent on membrane patch size allowed us to disentangle the essential dynamic variables of the MinDE oscillation cycle.

Influence of Japanese consumer gender and age on sensory attributes and preference (a case study on deep-fried peanuts).

BACKGROUND: Detailed exploration of sensory perception as well as preference across gender and age for a certain food is very useful for developing a vendible food commodity related to physiological and psychological motivation for food preference. Sensory tests including color, sweetness, bitterness, fried peanut aroma, textural preference and overall liking of deep-fried peanuts with varying frying time (2, 4, 6, 9, 12 and 15 min) at 150 °C were carried out using 417 healthy Japanese consumers. To determine the influence of gender and age on sensory evaluation, systematic statistical analysis including one-way analysis of variance, polynomial regression analysis and multiple regression analysis was conducted using the collected data. RESULTS: The results indicated that females were more sensitive to bitterness than males. This may affect sensory preference; female subjects favored peanuts prepared with a shorter frying time more than male subjects did. With advancing age, textural preference played a more important role in overall preference. Older subjects liked deeper-fried peanuts, which are more brittle, more than younger subjects did. CONCLUSION: In the present study, systematic statistical analysis based on collected sensory evaluation data using deep-fried peanuts was conducted and the tendency of sensory perception and preference across gender and age was clarified. These results may be useful for engineering optimal strategies to target specific segments to gain greater acceptance in the market. © 2017 Society of Chemical Industry.

Temperature-Controlled High-Speed AFM: Real-Time Observation of Ripple Phase Transitions.

With nanometer lateral and Angstrom vertical resolution, atomic force microscopy (AFM) has contributed unique data improving the understanding of lipid bilayers. Lipid bilayers are found in several different temperature-dependent states, termed phases; the main phases are solid and fluid phases. The transition temperature between solid and fluid phases is lipid composition specific. Under certain conditions some lipid bilayers adopt a so-called ripple phase, a structure where solid and fluid phase domains alternate with constant periodicity. Because of its narrow regime of existence and heterogeneity ripple phase and its transition dynamics remain poorly understood. Here, a temperature control device to high-speed atomic force microscopy (HS-AFM) to observe dynamics of phase transition from ripple phase to fluid phase reversibly in real time is developed and integrated. Based on HS-AFM imaging, the phase transition processes from ripple phase to fluid phase and from ripple phase to metastable ripple phase to fluid phase could be reversibly, phenomenologically, and quantitatively studied. The results here show phase transition hysteresis in fast cooling and heating processes, while both melting and condensation occur at 24.15 °C in quasi-steady state situation. A second metastable ripple phase with larger periodicity is formed at the ripple phase to fluid phase transition when the buffer contains Ca2+ . The presented temperature-controlled HS-AFM is a new unique experimental system to observe dynamics of temperature-sensitive processes at the nanoscopic level.

Active-site structure of the thermophilic Foc-subunit ring in membranes elucidated by solid-state NMR.

FoF1-ATP synthase uses the electrochemical potential across membranes or ATP hydrolysis to rotate the Foc-subunit ring. To elucidate the underlying mechanism, we carried out a structural analysis focused on the active site of the thermophilic c-subunit (TFoc) ring in membranes with a solid-state NMR method developed for this purpose. We used stereo-array isotope labeling (SAIL) with a cell-free system to highlight the target. TFoc oligomers were purified using a virtual ring His tag. The membrane-reconstituted TFoc oligomer was confirmed to be a ring indistinguishable from that expressed in E. coli on the basis of the H(+)-translocation activity and high-speed atomic force microscopic images. For the analysis of the active site, 2D (13)C-(13)C correlation spectra of TFoc rings labeled with SAIL-Glu and -Asn were recorded. Complete signal assignment could be performed with the aid of the C(α)i+1-C(α)i correlation spectrum of specifically (13)C,(15)N-labeled TFoc rings. The C(δ) chemical shift of Glu-56, which is essential for H(+) translocation, and related crosspeaks revealed that its carboxyl group is protonated in the membrane, forming the H(+)-locked conformation with Asn-23. The chemical shift of Asp-61 C(γ) of the E. coli c ring indicated an involvement of a water molecule in the H(+) locking, in contrast to the involvement of Asn-23 in the TFoc ring, suggesting two different means of proton storage in the c rings.

Sensory preferences among general Japanese consumers and physicochemical evaluation of deep-fried peanuts.

BACKGROUND: The development of food that satisfies consumer preferences is very important for producing commodities. In the present study, 132 Japanese consumers carried out sensory evaluation of deep-fried peanuts with varying frying times (2, 4, 6, 9, 12 and 15 min) at 150 °C, and the relationships among sensory elements and physicochemical properties were investigated. RESULT: The sensory scores for colour, bitterness, and deep-fried peanut aroma increased (darker or stronger) with frying time, whereas the sweetness score was relatively high (strong) for frying times of 2, 4, 6 and 9 min, and then decreased (weaker) with increasing frying time. Frying times of 4, 6 and 9 min scored higher in overall liking than other times. Multiple-regression analysis indicated that the overall liking score was positively correlated with sweetness (standardised regression coefficient, ß = +0.51) and deep-fried peanut aroma (ß = +0.26) scores but negatively correlated with bitterness score (ß = -0.25). Multiple-regression analysis also indicated a difference in sensory preference by gender. Sensory elements were closely related to the physicochemical properties, including the colour indexes (CIELAB colour space) and the sucrose and water contents. When L(*) (CIELAB colour space, lightness index) was 53-64 and water content was 10-30 g kg(-1), the mean overall liking score was relatively high implying acceptable fried peanut quality. CONCLUSION: Relationships among individual sensory elements were confirmed. Multiple-regression analysis indicated a strong positive correlation between sweetness and overall liking and a small difference in sensory preference by gender. Sensory evaluations can thus be expressed by physicochemical properties.

HS-AFM single-molecule structural biology uncovers basis of transporter wanderlust kinetics.

The Pyrococcus horikoshii amino acid transporter GltPh revealed, like other channels and transporters, activity mode switching, previously termed wanderlust kinetics. Unfortunately, to date, the basis of these activity fluctuations is not understood, probably due to a lack of experimental tools that directly access the structural features of transporters related to their instantaneous activity. Here, we take advantage of high-speed atomic force microscopy, unique in providing simultaneous structural and temporal resolution, to uncover the basis of kinetic mode switching in proteins. We developed membrane extension membrane protein reconstitution that allows the analysis of isolated molecules. Together with localization atomic force microscopy, principal component analysis and hidden Markov modeling, we could associate structural states to a functional timeline, allowing six structures to be solved from a single molecule, and an inward-facing state, IFSopen-1, to be determined as a kinetic dead-end in the conformational landscape. The approaches presented on GltPh are generally applicable and open possibilities for time-resolved dynamic single-molecule structural biology.

Atomic force microscopy studies of APOBEC3G oligomerization and dynamics.

The DNA cytosine deaminase APOBEC3G (A3G) is a two-domain protein that binds single-stranded DNA (ssDNA) largely through its N-terminal domain and catalyzes deamination using its C-terminal domain. A3G is considered an innate immune effector protein, with a natural capacity to block the replication of retroviruses such as HIV and retrotransposons. However, knowledge about its biophysical properties and mechanism of interaction with DNA are still limited. Oligomerization is one of these unclear issues. What is the stoichiometry of the free protein? What are the factors defining the oligomeric state of the protein? How does the protein oligomerization change upon DNA binding? How stable are protein oligomers? We address these questions here using atomic force microscopy (AFM) to directly image A3G protein in a free-state and in complexes with DNA, and using time-lapse AFM imaging to characterize the dynamics of A3G oligomers. We found that the formation of oligomers is an inherent property of A3G and that the yield of oligomers depends on the protein concentration. Oligomerization of A3G in complexes with ssDNA follows a similar pattern: the higher the protein concentrations the larger oligomers sizes. The specificity of A3G binding to ssDNA does not depend on stoichiometry. The binding of large A3G oligomers requires a longer ssDNA substrate; therefore, much smaller oligomers form complexes with short ssDNA. A3G oligomers dissociate spontaneously into monomers and this process primarily occurs through a monomer dissociation pathway.

Specificity of binding of single-stranded DNA-binding protein to its target.

Single-stranded DNA-binding proteins (SSBs) bind single-stranded DNA (ssDNA) and participate in all genetic processes involving ssDNA, such as replication, recombination, and repair. Here we applied atomic force microscopy to directly image SSB-DNA complexes under various conditions. We used the hybrid DNA construct methodology in which the ssDNA segment is conjugated to the DNA duplex. The duplex part of the construct plays the role of a marker, allowing unambiguous identification of specific and nonspecific SSB-DNA complexes. We designed hybrid DNA substrates with 5'- and 3'-ssDNA termini to clarify the role of ssDNA polarity on SSB loading. The hybrid substrates, in which two duplexes are connected with ssDNA, were the models for gapped DNA substrates. We demonstrated that Escherichia coli SSB binds to ssDNA ends and internal ssDNA regions with the same efficiency. However, the specific recognition by ssDNA requires the presence of Mg(2+) cations or a high ionic strength. In the absence of Mg(2+) cations and under low-salt conditions, the protein is capable of binding DNA duplexes. In addition, the number of interprotein interactions increases, resulting in the formation of clusters on double-stranded DNA. This finding suggests that the protein adopts different conformations depending on ionic strength, and specific recognition of ssDNA by SSB requires a high ionic strength or the presence of Mg(2+) cations.

Nanoscale structure and dynamics of ABOBEC3G complexes with single-stranded DNA.

The DNA cytosine deaminase APOBEC3G (A3G) is capable of blocking retrovirus replication by editing viral cDNA and impairing reverse transcription. However, the biophysical details of this host-pathogen interaction are unclear. We applied atomic force microscopy (AFM) and hybrid DNA substrates to investigate properties of A3G bound to single-stranded DNA (ssDNA). Hybrid DNA substrates included ssDNA with 5' or 3' ends attached to DNA duplexes (tail-DNA) and gap-DNA substrates, in which ssDNA is flanked by two double-stranded fragments. We found that A3G binds with similar efficiency to the 5' and 3' substrates, suggesting that ssDNA polarity is not an important factor. Additionally, we observed that A3G binds the single-stranded region of the gap-DNA substrates with the same efficiency as tail-DNA. These results demonstrate that single-stranded DNA ends are not needed for A3G binding. The protein stoichiometry does not depend on the ssDNA substrate type, but the ssDNA length modulates the stoichiometry of A3G in the complex. We applied single-molecule high-speed AFM to directly visualize the dynamics of A3G in the complexes. We were able to visualize A3G sliding and protein association-dissociation events. During sliding, A3G translocated over a 69-nucleotide ssDNA segment in <1 s. Association-dissociation events were more complex, as dimeric A3G could dissociate from the template as a whole or undergo a two-step process with monomers capable of sequential dissociation. We conclude that A3G monomers, dimers, and higher-order oligomers can bind ssDNA substrates in a manner independent of strand polarity and availability of free ssDNA ends.

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.

AAA+ chaperone ClpX regulates dynamics of prokaryotic cytoskeletal protein FtsZ.

AAA(+) chaperone ClpX has been suggested to be a modulator of prokaryotic cytoskeletal protein FtsZ, but the details of recognition and remodeling of FtsZ by ClpX are largely unknown. In this study, we have extensively investigated the nature of FtsZ polymers and mechanisms of ClpX-regulated FtsZ polymer dynamics. We found that FtsZ polymerization is inhibited by ClpX in an ATP-independent manner and that the N-terminal domain of ClpX plays a crucial role for the inhibition of FtsZ polymerization. Single molecule analysis with high speed atomic force microscopy directly revealed that FtsZ polymer is in a dynamic equilibrium between polymerization and depolymerization on a time scale of several seconds. ClpX disassembles FtsZ polymers presumably by blocking reassembly of FtsZ. Furthermore, Escherichia coli cells overproducing ClpX and N-terminal domain of ClpX show filamentous morphology with abnormal localization of FtsZ. These data together suggest that ClpX modulates FtsZ polymer dynamics in an ATP-independent fashion, which is achieved by interaction between the N-terminal domain of ClpX and FtsZ monomers or oligomers.

Single molecule kinetics of bacteriorhodopsin by HS-AFM.

Bacteriorhodopsin is a seven-helix light-driven proton-pump that was structurally and functionally extensively studied. Despite a wealth of data, the single molecule kinetics of the reaction cycle remain unknown. Here, we use high-speed atomic force microscopy methods to characterize the single molecule kinetics of wild-type bR exposed to continuous light and short pulses. Monitoring bR conformational changes with millisecond temporal resolution, we determine that the cytoplasmic gate opens 2.9 ms after photon absorption, and stays open for proton capture for 13.2 ms. Surprisingly, a previously active protomer cannot be reactivated for another 37.6 ms, even under excess continuous light, giving a single molecule reaction cycle of ~20 s-1. The reaction cycle slows at low light where the closed state is prolonged, and at basic or acidic pH where the open state is extended.

Visualization of intrinsically disordered regions of proteins by high-speed atomic force microscopy.

Intrinsically disordered (ID) regions of proteins are recognized to be involved in biological processes such as transcription, translation, and cellular signal transduction. Despite the important roles of ID regions, effective methods to observe these thin and flexible structures directly were not available. Herein, we use high-speed atomic force microscopy (AFM) to observe the heterodimeric FACT (facilitates chromatin transcription) protein, which is predicted to have large ID regions in each subunit. Successive AFM images of FACT on a mica surface, captured at rates of 5-17 frames per second, clearly reveal two distinct tail-like segments that protrude from the main body of FACT and fluctuate in position. Using deletion mutants of FACT, we identify these tail segments as the two major ID regions predicted from the amino acid sequences. Their mechanical properties estimated from the AFM images suggest that they have more relaxed structures than random coils. These observations demonstrate that this state-of-the-art microscopy method can be used to characterize unstructured protein segments that are difficult to visualize with other experimental techniques.

A novel phase-shift-based amplitude detector for a high-speed atomic force microscope.

In any atomic force microscope operated in amplitude modulation mode, aka "tapping mode" or "oscillating mode," the most crucial operation is the detection of the cantilever oscillation amplitude. Indeed, it is the change in the cantilever oscillation amplitude that drives the feedback loop, and thus, the accuracy and speed of amplitude detection are of utmost importance for improved atomic force microscopy operation. This becomes even more crucial for the operation of a high-speed atomic force microscope (HS-AFM), where feedback operation on a single or a low number of cantilever oscillation cycles between 500 kHz and 1000 kHz oscillation frequency is desired. So far, the amplitude detection was performed by Fourier analysis of each oscillation, resulting in a single output amplitude value at the end of each oscillation cycle, i.e., 360° phase delay. Here, we present a novel analog amplitude detection circuit with theoretic continuous amplitude detection at 90° phase delay. In factual operation, when exposed to an abrupt amplitude change, our novel amplitude detector circuit reacted with a phase delay of ∼138° compared with the phase delay of ∼682° achieved by the Fourier analysis method. Integrated to a HS-AFM, the novel amplitude detector should allow faster image acquisition with lower invasiveness due to the faster and more accurate detection of cantilever oscillation amplitude change.

Tip-sample distance control using photothermal actuation of a small cantilever for high-speed atomic force microscopy.

We have applied photothermal bending of a cantilever induced by an intensity-modulated infrared laser to control the tip-surface distance in atomic force microscopy. The slow response of the photothermal expansion effect is eliminated by inverse transfer function compensation. By regulating the laser power and regulating the cantilever deflection, the tip-sample distance is controlled; this enables much faster imaging than that in the conventional piezoactuator-based z scanners because of the considerably higher resonant frequency of small cantilevers. Using this control together with other devices optimized for high-speed scanning, video-rate imaging of protein molecules in liquids is achieved.

High-frequency microrheology reveals cytoskeleton dynamics in living cells.

Living cells are viscoelastic materials, with the elastic response dominating at long timescales (≳1 ms)1. At shorter timescales, the dynamics of individual cytoskeleton filaments are expected to emerge, but active microrheology measurements on cells accessing this regime are scarce2. Here, we develop high-frequency microrheology (HF-MR) to probe the viscoelastic response of living cells from 1Hz to 100 kHz. We report the viscoelasticity of different cell types and upon cytoskeletal drug treatments. At previously inaccessible short timescales, cells exhibit rich viscoelastic responses that depend on the state of the cytoskeleton. Benign and malignant cancer cells revealed remarkably different scaling laws at high frequency, providing a univocal mechanical fingerprint. Microrheology over a wide dynamic range up to the frequency of action of the molecular components provides a mechanistic understanding of cell mechanics.

Real-time Visualization of Phospholipid Degradation by Outer Membrane Phospholipase A using High-Speed Atomic Force Microscopy.

Phospholipases are abundant in various types of cells and compartments, where they play key roles in physiological processes as diverse as digestion, cell proliferation, and neural activation. In Gram-negative bacteria, outer membrane phospholipase A (OmpLA) is involved in outer-membrane lipid homeostasis and bacterial virulence. Although the enzymatic activity of OmpLA can be probed with an assay relying on an artificial monoacyl thioester substrate, only little is known about its activity on diacyl phospholipids. Here, we used high-speed atomic force microscopy (HS-AFM) to directly image enzymatic phospholipid degradation by OmpLA in real time. In the absence of Ca2+, reconstituted OmpLA diffused within a phospholipid bilayer without revealing any signs of phospholipase activity. Upon the addition of Ca2+, OmpLA was activated and degraded the membrane with a turnover of ~2 phospholipid molecules per second and per OmpLA dimer until most of the membrane phospholipids were hydrolyzed and the protein became tightly packed.