It is becoming clear that the bacterial flagellar motor output is important not only for bacterial locomotion but also for mediating the transition from liquid to surface living. The output of the flagellar motor changes with the mechanical load placed on it by the external environment: at a higher load, the motor runs more slowly and produces higher torque. Here we show that the number of torque-generating units bound to the flagellar motor also depends on the external mechanical load, with fewer stators at lower loads. Stalled motors contained at least as many stators as rotating motors at high load, indicating that rotation is unnecessary for stator binding. Mutant stators incapable of generating torque could not be detected around the motor. We speculate that a component of the bacterial flagellar motor senses external load and mediates the strength of stator binding to the rest of the motor.
Most biological processes are performed by multiprotein complexes. Traditionally described as static entities, evidence is now emerging that their components can be highly dynamic, exchanging constantly with cellular pools. The bacterial flagellar motor contains ∼13 different proteins and provides an ideal system to study functional molecular complexes. It is powered by transmembrane ion flux through a ring of stator complexes that push on a central rotor. The Escherichia coli motor switches direction stochastically in response to binding of the response regulator CheY to the rotor switch component FliM. Much is known of the static motor structure, but we are just beginning to understand the dynamics of its individual components. Here we measure the stoichiometry and turnover of FliM in functioning flagellar motors, by using high-resolution fluorescence microscopy of E. coli expressing genomically encoded YPet derivatives of FliM at physiological levels. We show that the ∼30 FliM molecules per motor exist in two discrete populations, one tightly associated with the motor and the other undergoing stochastic turnover. This turnover of FliM molecules depends on the presence of active CheY, suggesting a potential role in the process of motor switching. In many ways the bacterial flagellar motor is as an archetype macromolecular assembly, and our results may have further implications for the functional relevance of protein turnover in other large molecular complexes.chemotaxis | single molecule | total internal reflection fluorescence | in vivo microscopy | molecular motor T he bacterial flagellar motor is one of the most complex biological nanomachines (1), ideal for investigating turnover within a multimeric complex. It is the result of the coordinated, sequential expression of about 50 genes (2) producing a structure that spans the cell membrane and rotates an extracellular filament extending several micrometers from the cell surface, at speed of hundreds of hertz. The motor is about is about 45 nm in diameter and is composed of at least 13 different proteins, all in different copy numbers. It is powered by a transmembrane ion flux (1, 3, 4) and consists of a core rotating against a ring of stator proteins (1, 5-7). The C ring, also called the "switch complex," is part of the rotor and localized to the cytoplasmic motor region. The response regulator CheY-P binds one of the C ring components, FliM, causing the rotor to switch rotational direction, thus making FliM the interface with the chemosensory pathway (8-11).Much is known of the static motor structure (5-7), but the dynamics and interactions of its constituents under natural conditions in living cells are poorly understood. Recent results showed that molecules of the stator protein MotB in the flagellar motor, fused to GFP, exchange with a membrane pool of freely diffusing MotB on a time scale of minutes (12)(13)(14). This observation raised the question of whether protein turnover is a general feature of molecular complexes or is a peculiarity of MotB.To ad...
The injectisome is a membrane complex through which some bacteria can inject effector proteins into host cells. This study reveals that the cytosolic C-ring structure has a dynamic relationship to the rest of the injectisome, with implications for the regulation of secretion.
bThe second messenger cyclic diguanylate (c-di-GMP) plays a critical role in the regulation of motility. In Pseudomonas aeruginosa PA14, c-di-GMP inversely controls biofilm formation and surface swarming motility, with high levels of this dinucleotide signal stimulating biofilm formation and repressing swarming. P. aeruginosa encodes two stator complexes, MotAB and MotCD, that participate in the function of its single polar flagellum. Here we show that the repression of swarming motility requires a functional MotAB stator complex. Mutating the motAB genes restores swarming motility to a strain with artificially elevated levels of c-di-GMP as well as stimulates swarming in the wild-type strain, while overexpression of MotA from a plasmid represses swarming motility. Using point mutations in MotA and the FliG rotor protein of the motor supports the conclusion that MotA-FliG interactions are critical for c-di-GMP-mediated swarming inhibition. Finally, we show that high c-di-GMP levels affect the localization of a green fluorescent protein (GFP)-MotD fusion, indicating a mechanism whereby this second messenger has an impact on MotCD function. We propose that when c-di-GMP level is high, the MotAB stator can displace MotCD from the motor, thereby affecting motor function. Our data suggest a newly identified means of c-di-GMP-mediated control of surface motility, perhaps conserved among Pseudomonas, Xanthomonas, and other organisms that encode two stator systems. Since its discovery in 1987 as an allosteric activator of bacterial cellulose synthesis (1), cyclic diguanylate (c-di-GMP) has been shown to be a remarkably important signaling molecule across diverse bacterial species, controlling a multitude of behaviors and processes, including biofilm formation, motility, virulence, cell cycle progression, and differentiation (2-4). An important feature of c-di-GMP regulation is the ability of this signal to control critical lifestyle transitions, such as motile-sessile transitions (e.g., planktonic to biofilm), which are undertaken by many bacterial species (3, 5, 6). Generally speaking, elevated levels of c-di-GMP promote sessile lifestyles such as biofilm formation; in contrast, low levels of c-di-GMP are associated with motility (3, 6). Intracellular levels of this dinucleotide are controlled by opposing activities of enzymes that synthesize c-di-GMP (GGDEF domaincontaining diguanylate cyclases [DGCs]) and those that cleave this signaling molecule (EAL-or HD-GYP domain-containing phosphodiesterases [PDEs]) (3,4,(7)(8)(9)(10)(11).More recently, studies focused on how cells respond to changing c-di-GMP levels, indicated that this signaling network relies upon proteins or RNA molecules, known as c-di-GMP effectors (or receptors), which bind c-di-GMP and whose output functions are altered due to c-di-GMP-mediated structural changes (3,4,12). A number of distinct effectors have been identified and classified based on their c-di-GMP-binding motif. The PilZ class of c-di-GMP effector proteins is one of the best-studied class...
SummaryThe bacterial flagellar motor, one of the few rotary motors in nature, produces torque to drive the flagellar filament by ion translocation through membranebound stator complexes. We used the light-driven proton pump proteorhodopsin (pR) to control the proton-motive force (PMF) in vivo by illumination. pR excitation was shown to be sufficient to replace native PMF generation, and when excited in cells with intact native PMF generation systems increased motor speed beyond the physiological norm. We characterized the effects of rapid in vivo PMF changes on the flagellar motor. Transient PMF disruption events from loss of illumination caused motors to stop, with rapid recovery of their previous rotation rate after return of illumination. However, extended periods of PMF loss led to stepwise increases in rotation rate upon PMF return as stators returned to the motor. The rate constant for stator binding to a putative single binding site on the motor was calculated to be 0.06 s -1 . Using GFP-tagged MotB stator proteins, we found that transient PMF disruption leads to reversible stator diffusion away from the flagellar motor, showing that PMF presence is necessary for continued motor integrity, and calculated a stator dissociation rate of 0.038 s -1 .
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