Kazuhito V. Tabata

Microfabricated arrays of femtoliter chambers allow single molecule enzymology

Precise understanding of biological functions requires tools comparable in size to the basic components of life. Single molecule studies have revealed molecular behaviors usually hidden in the ensemble- and time-averaging of bulk experiments. Although most such approaches rely on sophisticated optical strategies to limit the detection volume, another attractive approach is to perform the assay inside very small containers. We have developed a silicone device presenting a large array of micrometer-sized cavities. We used it to tightly enclose volumes of solution, as low as femtoliters, over long periods of time. The microchip insures that the chambers are uniform and precisely positioned. We demonstrated the feasibility of our approach by measuring the activity of single molecules of β-galactosidase and horseradish peroxidase. The approach should be of interest for many ultrasensitive bioassays at the single-molecule level.

Photo Gel–Sol/Sol–Gel Transition and Its Patterning of a Supramolecular Hydrogel as Stimuli‐Responsive Biomaterials

In a focused library of glycolipid-based hydrogelators bearing fumaric amide as a trans-cis photoswitching module, several new photoresponsive supramolecular hydrogelators were discovered, the gel-sol/sol-gel transition of which was pseudo-reversibly induced by light. Studying the optimal hydrogel by NMR spectroscopy and various microscopy techniques showed that the trans-cis photoisomerization of the double bond of the fumaric amide unit effectively caused assembly or disassembly of the self-assembled supramolecular fibers to yield the macroscopic hydrogel or the corresponding sol, respectively. The entanglement of the supramolecular fibers produced nanomeshes, the void space of which was roughly evaluated to be 250 nm based on confocal laser scanning microscopy observations of the size-dependent Brownian motion of nanobeads embedded in the supramolecular hydrogel. It was clearly shown that such nanomeshes become a physical obstacle that captures submicro- to micrometer-sized substrates such as beads or bacteria. By exploiting the photoresponsive property of the supramolecular nanomeshes, we succeeded in off/on switching of bacterial movement and rotary motion of bead-tethered F(1)-ATPase, a biomolecular motor protein, in the supramolecular hydrogel. Furthermore, by using the photolithographic technique, gel-sol photopatterning was successfully conducted to produce sol spots within the gel matrix. The fabricated gel-sol pattern not only allowed regulation of bacterial motility in a limited area, but also off/on switching of F1-ATPase rotary motion at the single-molecule level. These results demonstrated that the photoresponsive supramolecular hydrogel and the resulting nanomeshes may provide unique biomaterials for the spatiotemporal manipulation of various biomolecules and live bacteria.

Diversity in ATP concentrations in a single bacterial cell population revealed by quantitative single-cell imaging

Recent advances in quantitative single-cell analysis revealed large diversity in gene expression levels between individual cells, which could affect the physiology and/or fate of each cell. In contrast, for most metabolites, the concentrations were only measureable as ensemble averages of many cells. In living cells, adenosine triphosphate (ATP) is a critically important metabolite that powers many intracellular reactions. Quantitative measurement of the absolute ATP concentration in individual cells has not been achieved because of the lack of reliable methods. In this study, we developed a new genetically-encoded ratiometric fluorescent ATP indicator “QUEEN”, which is composed of a single circularly-permuted fluorescent protein and a bacterial ATP binding protein. Unlike previous FRET-based indicators, QUEEN was apparently insensitive to bacteria growth rate changes. Importantly, intracellular ATP concentrations of numbers of bacterial cells calculated from QUEEN fluorescence were almost equal to those from firefly luciferase assay. Thus, QUEEN is suitable for quantifying the absolute ATP concentration inside bacteria cells. Finally, we found that, even for a genetically-identical Escherichia coli cell population, absolute concentrations of intracellular ATP were significantly diverse between individual cells from the same culture, by imaging QUEEN signals from single cells.

Simple Dark-Field Microscopy with Nanometer Spatial Precision and Microsecond Temporal Resolution

Molecular motors such as kinesin, myosin, and F(1)-ATPase are responsible for many important cellular processes. These motor proteins exhibit nanometer-scale, stepwise movements on micro- to millisecond timescales. So far, methods developed to measure these small and fast movements with high spatial and temporal resolution require relatively complicated experimental systems. Here, we describe a simple dark-field imaging system that employs objective-type evanescent illumination to selectively illuminate a thin layer on the coverslip and thus yield images with high signal/noise ratios. Only by substituting the dichroic mirror in conventional objective-type total internal reflection fluorescence microscope with a perforated mirror, were nanometer spatial precision and microsecond temporal resolution simultaneously achieved. This system was applied to the study of the rotary mechanism of F(1)-ATPase. The fluctuation of a gold nanoparticle attached to the gamma-subunit during catalytic dwell and the stepping motion during torque generation were successfully visualized with 9.1-mus temporal resolution. Because of the simple optics, this system will be applicable to various biophysical studies requiring high spatial and temporal resolution in vitro and also in vivo.

Planar lipid bilayer reconstitution with a micro-fluidic system

A planar lipid bilayer which is widely used for the electrophysiological study of membrane proteins in laboratories is reconstituted using a micro-fluidic system, in a manner that is suitable for automated processing. We fabricated micro-channels on both sides of the substrate, which are connected through a 100-200 microm aperture, and showed that the bilayer can be formed at the aperture by flowing the lipid solution and buffer, alternately. Parylene coating is found to be suitable for both bilayer formation and electric noise reduction. Future applications include a high-sensitivity ion sensor chip and a high-throughput drug screening device.

Mechanism of Inhibition by C-terminal α-Helices of the ϵ Subunit of Escherichia coli FoF1-ATP Synthase

The ϵ subunit of bacterial FoF1-ATP synthase (FoF1), a rotary motor protein, is known to inhibit the ATP hydrolysis reaction of this enzyme. The inhibitory effect is modulated by the conformation of the C-terminal α-helices of ϵ, and the “extended” but not “hairpin-folded” state is responsible for inhibition. Although the inhibition of ATP hydrolysis by the C-terminal domain of ϵ has been extensively studied, the effect on ATP synthesis is not fully understood. In this study, we generated an Escherichia coli FoF1 (EFoF1) mutant in which the ϵ subunit lacked the C-terminal domain (FoF1ϵΔC), and ATP synthesis driven by acid-base transition (ΔpH) and the K+-valinomycin diffusion potential (ΔΨ) was compared in detail with that of the wild-type enzyme (FoF1ϵWT). The turnover numbers (kcat) of FoF1ϵWT were severalfold lower than those of FoF1ϵΔC. FoF1ϵWT showed higher Michaelis constants (Km). The dependence of the activities of FoF1ϵWT and FoF1ϵΔC on various combinations of ΔpH and ΔΨ was similar, suggesting that the rate-limiting step in ATP synthesis was unaltered by the C-terminal domain of ϵ. Solubilized FoF1ϵWT also showed lower kcat and higher Km values for ATP hydrolysis than the corresponding values of FoF1ϵΔC. These results suggest that the C-terminal domain of the ϵ subunit of EFoF1 slows multiple elementary steps in both the ATP synthesis/hydrolysis reactions by restricting the rotation of the γ subunit.

Visualization of cargo concentration by COPII minimal machinery in a planar lipid membrane

Selective protein export from the endoplasmic reticulum is mediated by COPII vesicles. Here, we investigated the dynamics of fluorescently labelled cargo and non‐cargo proteins during COPII vesicle formation using single‐molecule microscopy combined with an artificial planar lipid bilayer. Single‐molecule analysis showed that the Sar1p–Sec23/24p‐cargo complex, but not the Sar1p–Sec23/24p complex, undergoes partial dimerization before Sec13/31p recruitment. On addition of a complete COPII mixture, cargo molecules start to assemble into fluorescent spots and clusters followed by vesicle release from the planar membrane. We show that continuous GTPase cycles of Sar1p facilitate cargo concentration into COPII vesicle buds, and at the same time, non‐cargo proteins are excluded from cargo clusters. We propose that the minimal set of COPII components is required not only to concentrate cargo molecules, but also to mediate exclusion of non‐cargo proteins from the COPII vesicles.

Arrayed lipid bilayer chambers allow single-molecule analysis of membrane transporter activity

Nano- to micron-size reaction chamber arrays (femtolitre chamber arrays) have facilitated the development of sensitive and quantitative biological assays, such as single-molecule enzymatic assays, digital PCR and digital ELISA. However, the versatility of femtolitre chamber arrays is limited to reactions that occur in aqueous solutions. Here we report an arrayed lipid bilayer chamber system (ALBiC) that contains sub-million femtolitre chambers, each sealed with a stable 4-μm-diameter lipid bilayer membrane. When reconstituted with a limiting amount of the membrane transporter proteins α-hemolysin or F0F1-ATP synthase, the chambers within the ALBiC exhibit stochastic and quantized transporting activities. This demonstrates that the single-molecule analysis of passive and active membrane transport is achievable with the ALBiC system. This new platform broadens the versatility of femtolitre chamber arrays and paves the way for novel applications aimed at furthering our mechanistic understanding of membrane proteins’ function.

Biased Brownian stepping rotation of FoF1-ATP synthase driven by proton motive force

FoF1-ATP synthase (FoF1) produces most of the ATP in cells, uniquely, by converting the proton motive force (pmf) into ATP production via mechanical rotation of the inner rotor complex. Technical difficulties have hampered direct investigation of pmf-driven rotation, which are crucial to elucidating the chemomechanical coupling mechanism of FoF1. Here we develop a novel supported membrane system for direct observation of the rotation of FoF1 driven by pmf that was formed by photolysis of caged protons. Upon photolysis, FoF1 initiated rotation in the opposite direction to that of the ATP-driven rotation. The step size of pmf-driven rotation was 120°, suggesting that the kinetic bottleneck is a catalytic event on F1 with threefold symmetry. The reaction equilibrium was slightly biased to ATP synthesis like under physiological conditions, and FoF1 showed highly stochastic behaviour, frequently making a 120° backward step. This new experimental system would be applicable to single-molecule study of other membrane proteins.

Acceleration of the ATP-binding rate of F1-ATPase by forcible forward rotation

F1‐ATPase (F1) is a reversible ATP‐driven rotary motor protein. When its rotary shaft is reversely rotated, F1 produces ATP against the chemical potential of ATP hydrolysis, suggesting that F1 modulates the rate constants and equilibriums of catalytic reaction steps depending on the rotary angle of the shaft. Although the chemomechanical coupling scheme of F1 has been determined, it is unclear how individual catalytic reaction steps depend on its rotary angle. Here, we report direct evidence that the ATP‐binding rate of F1 increases upon the forward rotation of the rotor, and its binding affinity to ATP is enhanced by rotation.