Professor Richard Berry D. Phil.

Stoichiometry and turnover in single, functioning membrane protein complexes

Nature 443:7109 (2006) 355-358

Authors:

MC Leake, JH Chandler, GH Wadhams, F Bai, RM Berry, JP Armitage

Abstract:

Many essential cellular processes are carried out by complex biological machines located in the cell membrane. The bacterial flagellar motor is a large membrane-spanning protein complex that functions as an ion-driven rotary motor to propel cells through liquid media. Within the motor, MotB is a component of the stator that couples ion flow to torque generation and anchors the stator to the cell wall. Here we have investigated the protein stoichiometry, dynamics and turnover of MotB with single-molecule precision in functioning bacterial flagellar motors in Escherichia coli. We monitored motor function by rotation of a tethered cell body, and simultaneously measured the number and dynamics of MotB molecules labelled with green fluorescent protein (GFP-MotB) in the motor by total internal reflection fluorescence microscopy. Counting fluorophores by the stepwise photobleaching of single GFP molecules showed that each motor contains ∼22 copies of GFP-MotB, consistent with ∼11 stators each containing two MotB molecules. We also observed a membrane pool of ∼200 GFP-MotB molecules diffusing at ∼0.008 μm2s-1. Fluorescence recovery after photobleaching and fluorescence loss in photobleaching showed turnover of GFP-MotB between the membrane pool and motor with a rate constant of the order of 0.04 s-1: the dwell time of a given stator in the motor is only ∼0.5 min. This is the first direct measurement of the number and rapid turnover of protein subunits within a functioning molecular machine. © 2006 Nature Publishing Group.

Stoichiometry and turnover in single, functioning membrane protein complexes

Nature 443 (2006) 355-358

Authors:

RM Berry, Armitage JP, Chandler JH, Leake MC

The maximum number of torque-generating units in the flagellar motor of Escherichia coli is at least 11

Proceedings of the National Academy of Sciences of the United States of America 103:21 (2006) 8066-8071

Authors:

SW Reid, MC Leake, JH Chandler, CJ Lo, JP Armitage, RM Berry

Abstract:

Torque is generated in the rotary motor at the base of the bacterial flagellum by ion translocating stator units anchored to the peptidoglycan cell wall. Stator units are composed of the proteins MotA and MotB in proton-driven motors, and they are composed of PomA and PomB in sodium-driven motors. Strains of Escherichia coli lacking functional stator proteins produce flagella that do not rotate, and induced expression of the missing proteins leads to restoration of motor rotation in discrete speed increments, a process known as "resurrection." Early work suggested a maximum of eight units. More recent indications that WT motors may contain more than eight units, based on recovery of disrupted motors, are inconclusive. Here we demonstrate conclusively that the maximum number of units in a motor is at least 11. Using back-focal-plane interferometry of 1-μm polystyrene beads attached to flagella, we observed at least 11 distinct speed increments during resurrection with three different combinations of stator proteins in E. coli. The average torques generated by a single unit and a fully induced motor were lower than previous estimates. Speed increments at high numbers of units are smaller than those at low numbers, indicating that not all units in a fully induced motor are equivalent. © 2006 by The National Academy of Sciences of the USA.

The maximum number of torque-generation units in the flagellar motor of Escherichia coli is at least 11

Proceedings of the National Academy of Sciences of the USA 103 (2006) 8066-8071

Authors:

RM Berry, Chandler JH, Leake MC, Reid SW

Controlled delivery of membrane proteins to artificial lipid bilayers by nystatin-ergosterol modulated vesicle fusion.

IEE Proc Nanobiotechnol 153:2 (2006) 21-30

Authors:

MRR de Planque, MRR de Planque, GP Mendes, M Zagnoni, ME Sandison, KH Fisher, RM Berry, A Watts, H Morgan

Abstract:

The study of ion channels and other membrane proteins and their potential use as biosensors and drug screening targets require their reconstitution in an artificial membrane. These applications would greatly benefit from microfabricated devices in which stable artificial lipid bilayers can be rapidly and reliably formed. However, the amount of protein delivered to the bilayer must be carefully controlled. A vesicle fusion technique is investigated where composite ion channels of the polyene antibiotic nystatin and the sterol ergosterol are employed to render protein-carrying vesicles fusogenic. After fusion with an ergosterol-free artificial bilayer, the nystatin-ergosterol channels do not dissociate immediately and thus cause a transient current signal that marks the vesicle fusion event. Experimental pitfalls of this method were identified, the influence of the nystatin and ergosterol concentration on the fusion rate and the shape of the fusion event marker was explored, and the number of different lipid species was reduced. Under these conditions, the -amyloid peptide could be delivered in a controlled manner to a standard planar bilayer. Additionally, electrical recordings were obtained of vesicles fusing with a planar lipid bilayer in a microfabricated device, demonstrating the suitability of nystatin-ergosterol modulated vesicle fusion for protein delivery within microsystems.