Oxford Molecular Motors

Structure and mechanism of the Zorya anti-phage defence system

Nature Nature Research 639:8056 (2024) 1093-1101

Authors:

Haidai Hu, Philipp F Popp, Thomas CD Hughes, Aritz Roa-Eguiara, Nicole R Rutbeek, Freddie JO Martin, Ivo Alexander Hendriks, Leighton J Payne, Yumeng Yan, Dorentina Humolli, Victor Klein-Sousa, Inga Songailiene, Yong Wang, Michael Lund Nielsen, Richard M Berry, Alexander Harms, Marc Erhardt, Simon A Jackson, Nicholas MI Taylor

Abstract:

Zorya is a recently identified and widely distributed bacterial immune system that protects bacteria from viral (phage) infections. Three Zorya subtypes have been identified, each containing predicted membrane-embedded ZorA–ZorB (ZorAB) complexes paired with soluble subunits that differ among Zorya subtypes, notably ZorC and ZorD in type I Zorya systems1, 2. Here we investigate the molecular basis of Zorya defence using cryo-electron microscopy, mutagenesis, fluorescence microscopy, proteomics and functional studies. We present cryo-electron microscopy structures of ZorAB and show that it shares stoichiometry and features of other 5:2 inner membrane ion-driven rotary motors. The ZorA5B2 complex contains a dimeric ZorB peptidoglycan-binding domain and a pentameric α-helical coiled-coil tail made of ZorA that projects approximately 70 nm into the cytoplasm. We also characterize the structure and function of the soluble Zorya components ZorC and ZorD, finding that they have DNA-binding and nuclease activity, respectively. Comprehensive functional and mutational analyses demonstrate that all Zorya components work in concert to protect bacterial cells against invading phages. We provide evidence that ZorAB operates as a proton-driven motor that becomes activated after sensing of phage invasion. Subsequently, ZorAB transfers the phage invasion signal through the ZorA cytoplasmic tail to recruit and activate the soluble ZorC and ZorD effectors, which facilitate the degradation of the phage DNA. In summary, our study elucidates the foundational mechanisms of Zorya function as an anti-phage defence system.

Cryo-EM structures provide insight into how E. coli F1Fo ATP synthase accommodates symmetry mismatch

Nature Communications Springer Nature 11:1 (2020) 2615

Authors:

Meghna Sobti, James L Walshe, Di Wu, Robert Ishmukhametov, Yi C Zeng, Carol V Robinson, Richard M Berry, Alastair G Stewart

Abstract:

F1Fo ATP synthase functions as a biological rotary generator that makes a major contribution to cellular energy production. It comprises two molecular motors coupled together by a central and a peripheral stalk. Proton flow through the Fo motor generates rotation of the central stalk, inducing conformational changes in the F1 motor that catalyzes ATP production. Here we present nine cryo-EM structures of E. coli ATP synthase to 3.1–3.4 Å resolution, in four discrete rotational sub-states, which provide a comprehensive structural model for this widely studied bacterial molecular machine. We observe torsional flexing of the entire complex and a rotational sub-step of Fo associated with long-range conformational changes that indicates how this flexibility accommodates the mismatch between the 3- and 10-fold symmetries of the F1 and Fo motors. We also identify density likely corresponding to lipid molecules that may contribute to the rotor/stator interaction within the Fo motor.

Domain-swap polymerization drives the self-assembly of the bacterial flagellar motor.

Nature structural & molecular biology 23:3 (2016) 197-203

Authors:

MAB Baker, RMG Hynson, LA Ganuelas, NS Mohammadi, CW Liew, AA Rey, AP Duff, AE Whitten, CM Jeffries, NJ Delalez, YV Morimoto, D Stock, JP Armitage, AJ Turberfield, K Namba, RM Berry, LK Lee

Abstract:

Large protein complexes assemble spontaneously, yet their subunits do not prematurely form unwanted aggregates. This paradox is epitomized in the bacterial flagellar motor, a sophisticated rotary motor and sensory switch consisting of hundreds of subunits. Here we demonstrate that Escherichia coli FliG, one of the earliest-assembling flagellar motor proteins, forms ordered ring structures via domain-swap polymerization, which in other proteins has been associated with uncontrolled and deleterious protein aggregation. Solution structural data, in combination with in vivo biochemical cross-linking experiments and evolutionary covariance analysis, revealed that FliG exists predominantly as a monomer in solution but only as domain-swapped polymers in assembled flagellar motors. We propose a general structural and thermodynamic model for self-assembly, in which a structural template controls assembly and shapes polymer formation into rings.

A modular platform for one-step assembly of multi-component membrane systems by fusion of charged proteoliposomes

Nature Communications Nature Publishing Group 7 (2016) 13025

Authors:

Robert Ishmukhametov, Aidan N Russell, Richard M Berry

Abstract:

An important goal in synthetic biology is the assembly of biomimetic cell-like structures, which combine multiple biological components in synthetic lipid vesicles. A key limiting assembly step is the incorporation of membrane proteins into the lipid bilayer of the vesicles. Here we present a simple method for delivery of membrane proteins into a lipid bilayer within 5 min. Fusogenic proteoliposomes, containing charged lipids and membrane proteins, fuse with oppositely charged bilayers, with no requirement for detergent or fusion-promoting proteins, and deliver large, fragile membrane protein complexes into the target bilayers. We demonstrate the feasibility of our method by assembling a minimal electron transport chain capable of adenosine triphosphate (ATP) synthesis, combining Escherichia coli F1Fo ATP-synthase and the primary proton pump bo3-oxidase, into synthetic lipid vesicles with sizes ranging from 100 nm to ∼10 μm. This provides a platform for the combination of multiple sets of membrane protein complexes into cell-like artificial structures.

Conformational spread as a mechanism for cooperativity in the bacterial flagellar switch.

Science 327:5966 (2010) 685-689

Authors:

Fan Bai, Richard W Branch, Dan V Nicolau, Teuta Pilizota, Bradley C Steel, Philip K Maini, Richard M Berry

Abstract:

The bacterial flagellar switch that controls the direction of flagellar rotation during chemotaxis has a highly cooperative response. This has previously been understood in terms of the classic two-state, concerted model of allosteric regulation. Here, we used high-resolution optical microscopy to observe switching of single motors and uncover the stochastic multistate nature of the switch. Our observations are in detailed quantitative agreement with a recent general model of allosteric cooperativity that exhibits conformational spread--the stochastic growth and shrinkage of domains of adjacent subunits sharing a particular conformational state. We expect that conformational spread will be important in explaining cooperativity in other large signaling complexes.