Nicholas L. Bartelli scite author profile

Cytoplasmic domains of transmembrane bacterial chemoreceptors are largely extended four-helix coiled coils. Previous observations suggested the domain was structurally dynamic. We probed directly backbone dynamics of this domain of the transmembrane chemoreceptor Tar from Escherichia coli using site-directed spin labeling and electron paramagnetic resonance (EPR) spectroscopy. Spin labels were positioned on solvent-exposed helical faces because EPR spectra for such positions reflect primarily polypeptide backbone movements. We acquired spectra for spinlabeled, intact receptor homodimers solubilized in detergent or inserted into native E. coli lipid bilayers in Nanodiscs, characterizing 16 positions distributed throughout the cytoplasmic domain and on both helices of its helical hairpins, one amino terminal to the membrane-distal tight turn (N-helix), and the other carboxyl terminal (C-helix). Detergent solubilization increased backbone dynamics for much of the domain, suggesting that loss of receptor activities upon solubilization reflects wide-spread destabilization. For receptors in either condition, we observed an unanticipated difference between the N-and C-helices. For bilayer-inserted receptors, EPR spectra from sites in the membrane-distal protein-interaction region and throughout the C-helix were typical of well-structured helices. In contrast, for approximately two-thirds of the N-helix, from its origin as the AS-2 helix of the membrane-proximal HAMP domain to the beginning of the membrane-distal protein-interaction region, spectra had a significantly mobile component, estimated by spectral deconvolution to average approximately 15%. Differential helical dynamics suggests a four-helix bundle organization with a pair of core scaffold helices and two more dynamic partner helices. This newly observed feature of chemoreceptor structure could be involved in receptor function.

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Bacterial Chemoreceptor Dynamics: Helical Stability in the Cytoplasmic Domain Varies with Functional Segment and Adaptational Modification

Bartelli

Hazelbauer

2016

Journal of Molecular Biology

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Dynamics are thought to be important features of structure and signaling in the cytoplasmic domain of bacterial chemoreceptors. However, little is known about which structural features are dynamic. For this largely helical domain, comprising a four-helix bundle and an extended four-helix coiled coil, functionally important structural dynamics likely involves helical mobility and stability. To investigate, we used continuous wave EPR spectroscopy and site-specific spin labels that directly probed, in essentially physiological conditions, mobility of helical backbones in the cytoplasmic domain of intact chemoreceptor Tar homodimers inserted into lipid bilayers of Nanodiscs. We observed differences among functional regions, between companion helices in helical hairpins of the coiled coil and between receptor conformational states generated by adaptational modification. Increased adaptational modification decreased helical dynamics while preserving dynamics differences among functional regions and between companion helices. In contrast, receptor ligand occupancy did not have a discernable effect on dynamics to which our approach was sensitive, implying that the two sensory inputs alter different chemoreceptor features. Spectral fitting indicated that differences in helical dynamics we observed for ensemble spin-label mobility reflected differences in proportions of a minority receptor population in which the otherwise helical backbone was essentially disordered. We suggest that our measurements provided site-specific snapshots of equilibria between a majority state of well-ordered helix and a minority state of locally disordered polypeptide backbone. Thus, the proportion of polypeptide chain that is locally and presumably transiently disordered is a structural feature of cytoplasmic domain dynamics that varies with functional region and modification-induced signaling state.

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Direct evidence that the carboxyl‐terminal sequence of a bacterial chemoreceptor is an unstructured linker and enzyme tether

Bartelli¹,

Hazelbauer²

2011

Protein Science

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Sensory adaptation in bacterial chemotaxis involves reversible methylation of specific glutamyl residues on chemoreceptors. The reactions are catalyzed by a dedicated methyltransferase and dedicated methylesterase. In Escherichia coli and related organisms, control of these enzymes includes an evolutionarily recent addition of interaction with a pentapeptide activator located at the carboxyl terminus of the receptor polypeptide chain. Effective enzyme activation requires not only the pentapeptide but also a segment of the receptor polypeptide chain between that sequence and the coiled-coil body of the chemoreceptor. This segment has features consistent with a role as a flexible and presumably unstructured linker and enzyme tether, but there has been no direct information about its structure. We used site-directed spin labeling and electron paramagnetic resonance spectroscopy to characterize structural features of the carboxyl-terminal 40 residues of E. coli chemoreceptor Tar. Beginning~35 residues from the carboxyl terminus and continuing to the end of the protein, spectra of spin-labeled Tar embedded in native membranes or in reconstituted proteoliposomes, exhibited mobilities characteristic of unstructured, disordered segments. Binding of methyltransferase substantially reduced mobility for positions in or near the pentapeptide but mobility for the linker sequence remained high, being only modestly reduced in a gradient of decreasing effects for 10-15 residues, a pattern consistent with the linker providing a flexible arm that would allow enzyme diffusion within defined limits. Thus, our data identify that the carboxyl-terminal linker between the receptor body and the pentapeptide is an unstructured, disordered segment that can serve as a flexible arm and enzyme tether.

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Lipidation of Class IV CdiA Effector Proteins Promotes Target Cell Recognition during Contact-Dependent Growth Inhibition

Halvorsen

Garza-Sánchez

Ruhe

et al. 2021

mBio

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