Synthesis of ATP from ADP and phosphate, catalyzed by F(0)F(1)-ATP synthases, is the most abundant physiological reaction in almost any cell. F(0)F(1)-ATP synthases are membrane-bound enzymes that use the energy derived from an electrochemical proton gradient for ATP formation. We incorporated double-labeled F(0)F(1)-ATP synthases from Escherichia coli into liposomes and measured single-molecule fluorescence resonance energy transfer (FRET) during ATP synthesis and hydrolysis. The gamma subunit rotates stepwise during proton transport-powered ATP synthesis, showing three distinct distances to the b subunits in repeating sequences. The average durations of these steps correspond to catalytic turnover times upon ATP synthesis as well as ATP hydrolysis. The direction of rotation during ATP synthesis is opposite to that of ATP hydrolysis.
F 0 F 1 -ATP synthases catalyze proton transport-coupled ATP synthesis in bacteria, chloroplasts, and mitochondria. In these complexes, the e-subunit is involved in the catalytic reaction and the activation of the enzyme. Fluorescencelabeled F 0 F 1 from Escherichia coli was incorporated into liposomes. Single-molecule fluorescence resonance energy transfer (FRET) revealed that the e-subunit rotates stepwise showing three distinct distances to the b-subunits in the peripheral stalk. Rotation occurred in opposite directions during ATP synthesis and hydrolysis. Analysis of the dwell times of each FRET state revealed different reactivities of the three catalytic sites that depended on the relative orientation of e during rotation. Proton transport through the enzyme in the absence of nucleotides led to conformational changes of e. When the enzyme was inactive (i.e. in the absence of substrates or without membrane energization), three distances were found again, which differed from those of the active enzyme. The three states of the inactive enzyme were unequally populated. We conclude that the active-inactive transition was associated with a conformational change of e within the central stalk.
The EF 0 F 1 -ATP synthase mutants bQ64C and Q QT106C were labelled selectively with the £uorophores tetramethylrhodamine (TMR) at the b-subunit and with a cyanine (Cy5) at the Q Q-subunit. After reconstitution into liposomes, these double-labelled enzymes catalyzed ATP synthesis at a rate of 33 s 31 . Fluorescence of TMR and Cy5 was measured with a confocal set-up for single-molecule detection. Photon bursts were detected, when liposomes containing one enzyme traversed the confocal volume. Three states with di¡erent £uorescence resonance energy transfer (FRET) e⁄ciencies were observed. In the presence of ATP, repeating sequences of those three FRETstates were identi¢ed, indicating stepwise rotation of the Q Q-subunit of EF 0 F 1 . ß 2002 Federation of European Biochemical Societies. Published by Elsevier Science B.V. All rights reserved.
A new technique combining scanning electrochemical microscopy (SECM) and single-molecule fluorescence spectroscopy was developed to accomplish locally and temporally defined pH adjustments in buffer solutions and on surfaces monitored by fluorescence alteration of pH-sensitive fluorophores in real time. Local pH gradients were created by electrochemical generation of H(+) or OH(-) during redox reactions at ultramicro- or nanoelectrodes with radii from 5 microm to 35 nm. Ratiometric fluorescence measurements were performed with a confocal laser microscope using two detectors for different spectral regions. Time-resolved pH measurements were carried out with freely diffusing SNARF-1-dextran. For pH measurements on surfaces, total internal reflection fluorescence microscopy was used in combination with a CCD camera. The fluorophore SNAFL-succinimidyl ester was bound to amino-terminated octadecylsilane-coated coverslips. Local pH determinations could be accomplished with an accuracy of 0.2 unit. The measured pH profiles showed a strong dependence on the tip diameter, the buffer/mediator concentration ratio, and the tip-surface distance. As an application for bionanotechnology using SECM-induced pH changes on the molecular level, the proton-driven ATP synthesis by single membrane-bound F(0)F(1)-ATP synthases was investigated. ATP synthesis resulted in stepwise subunit rotation within the enzyme that was monitored by single-molecule fluorescence resonance energy transfer.
A novel, custom-made software filter for discrimination between proteinaceous particles and silicone oil droplets in flow-microscopy imaging analysis was successfully developed.
Hepatitis B virus core protein self-assembles into icosahedral, highly immunogenic capsid-like particles (CLPs) that can serve as molecular platforms for heterologous proteins. Insertion into the centrally located c/e1 epitope leads to surface display, fusion to the C terminus to internal disposition of the foreign domains. However, symmetry-defined space restrictions on the surface and particularly inside the CLPs limit the size of usable heterologous fusion partners. Further, CLPs carrying differing foreign domains are desirable for applications such as multivalent vaccines, and for structure probing by distance sensitive interactions like fluorescence resonance energy transfer (FRET). Here, we report an in vitro co-assembly system for such mosaic-CLPs allowing successful CLP formation with a per se assembly-deficient fusion protein, and of CLPs from two different fluoroprotein-carrying fusions that exert FRET in an assembly-status dependent way.
The H+ -ATPsynthase from E. coli was isolated and labelled at the gamma- or epsilon-subunit with tetramethylrhodamine, and at the b-subunits with bisCy5. The double labelled enzymes were incorporated into liposomes. They showed ATP hydrolysis activity, and, after energization of the membrane by DeltapH and Deltavarphi, also ATP synthesis activity was observed. Fluorescence resonance energy transfer (FRET) was used to investigate the movements of either the gamma-subunit or the epsilon-subunit relative to the b-subunits in single membrane-integrated enzymes. The results show that during catalysis, the gamma-epsilon complex rotates stepwise relative to the b-subunit. The direction of rotation during ATP synthesis is opposite to that during ATP hydrolysis. The stepwise motion is characterized by dwell times (docking time of the gamma-epsilon complex to one alphabeta pair) up to several hundred ms, followed by a rapid movement of the gamma- and epsilon-subunit to the next alphabeta pair within 0.2 ms. The same FRET levels (i.e., the same gamma-b and epsilon-b distances) are observed during proton transport-coupled ATP hydrolysis and ATP synthesis, indicating that the reaction proceeds via the same intermediates in both directions. Under non-catalytic conditions, i.e., in the absence of ATP or without energization also, three FRET levels are found, however, the distances differ from those under catalytic conditions. We conclude that this reflects a movement of the epsilon-subunit during active/inactive transition.
The rotary mechanism of ATP synthase requires a strong binding within stator subunits. In this work we studied the binding affinity of the b-subunit to F(1)-ATPase of Escherichia coli. The dimerization of the truncated b-subunit without amino acids 1-33, b(34-156)T62C, was investigated by analytical ultracentrifugation, resulting in a dissociation constant of 1.8 microM. The binding of b-subunit monomeric and dimeric forms to the isolated F(1) part was investigated by fluorescence correlation spectroscopy and steady-state fluorescence. The mutants b(34-156)T62C and EF(1)-gammaT106C were labeled with several fluorophores. Fluorescence correlation spectroscopy was used to measure translational diffusion times of the labeled b-subunit, labeled F(1), and a mixture of the labeled b-subunit with unlabeled F(1). Data analysis revealed a dissociation constant of 0.2 nM of the F(1)b(2) complex, yielding a Gibbs free energy of binding of DeltaG(o)= -55 kJ mol(-1). In steady-state fluorescence resonance energy transfer (FRET) measurements it was found that binding of the b-subunit to EF(1)-gammaT106C-Alexa488 resulted in a fluorescence decrease of one-third of the initial FRET donor fluorescence intensity. The decrease of fluorescence was measured as a function of b-concentration, and data were described by a model including equilibria for dimerization of the b-subunit and binding of b and b(2) to F(1). For a quantitative description of fluorescence decrease we used two different models: the binding of the first and the second b-subunit causes the same fluorescence decrease (model 1) or only the binding of the first b-subunit causes fluorescence decrease (model 2). Data evaluation revealed a dissociation constant for the F(1)b(2) complex of 0.6 nM (model 1) or 14 nM (model 2), giving DeltaG(o)= -52 kJ mol(-1) and DeltaG(o)= -45 kJ mol(-1), respectively. The maximal DeltaG observed for ATP synthesis in cells is approximately DeltaG= 55 kJ mol(-1). Therefore, the binding energy of the b-subunit seems to be too low for models in which the free energy for ATP synthesis is accumulated in the elastic strain between rotor and stator subunits and then transduced to the catalytic site in one single step. Models in which energy transduction takes place in at least two steps are favored.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
hi@scite.ai
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.