Tungsten-containing formate dehydrogenase from Methylorubrum extroquens AM1 (FoDH1) was investigated from structural biology and bioelectrochemistry. The electron transfer (ET) pathways were investigated by structural information,... more
Tungsten-containing formate dehydrogenase from Methylorubrum extroquens AM1 (FoDH1) was investigated from structural biology and bioelectrochemistry. The electron transfer (ET) pathways were investigated by structural information, electrostatic interactions between the electrode and the enzyme, and the differences in the substrates. Two electrode-active sites and multiple ET pathways in FoDH1 were discovered.
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We are in the midst of the historic coronavirus infectious disease 2019 (COVID-19) pandemic caused by severe respiratory syndrome coronavirus 2 (SARS-CoV-2). Although countless efforts to control the pandemic have been attempted--most... more
We are in the midst of the historic coronavirus infectious disease 2019 (COVID-19) pandemic caused by severe respiratory syndrome coronavirus 2 (SARS-CoV-2). Although countless efforts to control the pandemic have been attempted--most successfully, vaccination--imbalances in accessibility to vaccines, medicines, and diagnostics among countries, regions, and populations have been problematic. Camelid variable regions of heavy chain-only antibodies (VHHs or nanobodies) have unique modalities: they are smaller, more stable, easier to customize, and, importantly, less expensive to produce than conventional antibodies. We present the sequences of nine alpaca nanobodies that detect the spike proteins of four SARS-CoV-2 variants of concern (VOCs)--namely, the alpha, beta, gamma, and delta variants. We show that they can quantify or detect spike variants via ELISA and lateral flow, kinetic, flow cytometric, microscopy, and Western blotting assays. The panel of nanobodies broadly neutralized...
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The bacterial flagellar MS ring is a transmembrane complex acting as the core of the flagellar motor and template for flagellar assembly. The C ring attached to the MS ring is involved in torque generation and rotation switch, and a large... more
The bacterial flagellar MS ring is a transmembrane complex acting as the core of the flagellar motor and template for flagellar assembly. The C ring attached to the MS ring is involved in torque generation and rotation switch, and a large symmetry mismatch between these two rings has been a long puzzle, especially with respect to their role in motor function. Here, using cryoEM structural analysis of the flagellar basal body and the MS ring formed by full-length FliF from Salmonella enterica, we show that the native MS ring is formed by 34 FliF subunits with no symmetry variation. Symmetry analysis of the C ring shows a variation with a peak at 34-fold, suggesting flexibility in C ring assembly. Finally, our data also indicate that FliF subunits assume two different conformations, contributing differentially to the inner and middle parts of the M ring and thus resulting in 23- and 11-fold subsymmetries in the inner and middle M ring, respectively. The internal core of the M ring, fo...
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The bacterial flagellar MS ring is a transmembrane complex acting as the core of the flagellar motor. It not only acts as the template for rod and C ring assembly but also houses the type III protein export gate for assembly of the rod,... more
The bacterial flagellar MS ring is a transmembrane complex acting as the core of the flagellar motor. It not only acts as the template for rod and C ring assembly but also houses the type III protein export gate for assembly of the rod, hook and filament. The cytoplasmic C ring, involved in torque generation and rotation switch, is directly attached to the MS ring, and a symmetry mismatch between 26-fold MS ring and 34-fold C ring had been a long puzzle as to whether this would play some role in motor function. Although this puzzle seemed to have been resolved by the recent high-resolution structure of the MS ring with 33-fold symmetry with a variation from 32-fold to 35-fold because the C ring also shows a similar symmetry variation, it still remained ambiguous whether their symmetries are matched in the native motor structure. Here we show that the native MS ring structure formed by full-length FliF is 34-fold with no symmetry variation whereas the C ring has a small symmetry vari...
The bacterial flagellum is a motility organelle, consisting of the basal body acting as a rotary motor, the filament as a helical propeller and the hook connecting these two as a universal joint1,2. The basal body contains three rings:... more
The bacterial flagellum is a motility organelle, consisting of the basal body acting as a rotary motor, the filament as a helical propeller and the hook connecting these two as a universal joint1,2. The basal body contains three rings: the MS ring as the transmembrane core of the rotor; the C ring essential for torque generation and switching regulation; and the LP ring as a bushing supporting the distal rod for its rapid, stable rotation without much friction. The negatively charged surface of the distal rod suggested electrostatic repulsive force in supporting high-speed rotation of the rod as a drive shaft3, but the LP ring structure was needed to see the actual mechanisms of its bushing function and assembly against the repulsive force. Here we report the LP ring structure by electron cryomicroscopy at 3.5 Å resolution, showing 26-fold rotational symmetry and intricate intersubunit interactions of each subunit with up to six partners that explains the structural stability. The i...
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Bacteria swim in viscous liquid environments by using the flagellum. The flagellum is composed of about 30 different proteins and can be roughly divided into three parts: the basal body, the hook and the filament. The basal body acts as a... more
Bacteria swim in viscous liquid environments by using the flagellum. The flagellum is composed of about 30 different proteins and can be roughly divided into three parts: the basal body, the hook and the filament. The basal body acts as a rotary motor powered by ion motive force across the cytoplasmic membrane as well as a protein export apparatus to construct the axial structure of the flagellum. The filament is as a helical propeller, and it is a supercoiled form of a helical tubular assembly consisting of a few tens of thousands of flagellin molecules. The hook is a relatively short axial segment working as a universal joint connecting the basal body and the filament for smooth transmission of motor torque to the filament. The structure of hook has been studied by combining X-ray crystal structure of a core fragment of hook protein FlgE and electron cryomicroscopy (cryoEM) helical image analysis of the polyhook in the straight form and has given a deep insight into the universal ...
The bacterial flagellar hook connects the helical flagellar filament to the rotary motor at its base. Bending flexibility of the hook allows the helical filaments to form a bundle behind the cell body to produce thrust for bacterial... more
The bacterial flagellar hook connects the helical flagellar filament to the rotary motor at its base. Bending flexibility of the hook allows the helical filaments to form a bundle behind the cell body to produce thrust for bacterial motility. The hook protein FlgE shows considerable sequence and structural similarities to the distal rod protein FlgG; however, the hook is supercoiled and flexible as a universal joint whereas the rod is straight and rigid as a drive shaft. A short FlgG specific sequence (GSS) has been postulated to confer the rigidity on the FlgG rod, and insertion of GSS at the position between Phe-42 and Ala-43 of FlgE actually made the hook straight. However, it remains unclear whether inserted GSS confers the rigidity as well. Here, we provide evidence that insertion of GSS makes the hook much more rigid. The GSS insertion inhibited flagellar bundle formation behind the cell body, thereby reducing motility. This indicates that the GSS insertion markedly reduced th...
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A novel bacterial type III secretion effector, VopV, from the enteric pathogen Vibrio parahaemolyticus has been identified as a key factor in pathogenicity due to its interaction with cytoskeletal actin. One of the repeat units in the... more
A novel bacterial type III secretion effector, VopV, from the enteric pathogen Vibrio parahaemolyticus has been identified as a key factor in pathogenicity due to its interaction with cytoskeletal actin. One of the repeat units in the long repetitive region of VopV, named VopVrep1, functions as an actin-binding module. Despite its importance in pathogenesis, the manner in which the effector binds to actin and the subsequent effects on actin dynamics remain unclear. Here, we report the molecular basis of the VopVrep1/actin interaction. VopVrep1 exists as an unstructured protein in solution but potently and specifically binds filamentous actin (F-actin) and not globular actin (G-actin). The F-actin/VopVrep1 complex was directly visualized at 9.6-Å resolution using electron cryomicroscopy (cryoEM) and helical image reconstitution. The density map revealed the binding site of VopVrep1 at the interface between two actin strands, which is close to the binding site of the bicyclic heptapeptide toxin phalloidin. Consistent with this observation, VopVrep1 alone prevented the depolymerization of F-actin. Overall, VopVrep1 demonstrated unique characteristics in comparison to known actin-binding proteins, but was relatively similar to phalloidin. The phalloidin-like behavior, targeting the interstrand region of actin filaments to stabilize the filament structure, likely contributes to the pathogenicity of V. parahaemolyticus.