Phosphorylation-Induced Activation of the Response Regulator VraR from Staphylococcus aureus: Insights from Hydrogen Exchange Mass Spectrometry

A two-component system consisting of the histidine kinase vancomycin-resistance-associated sensor and the response regulator vancomycin-resistance-associated regulator (VraR) allows Staphylococcus aureus to sense antibiotic-related cell wall stress and to mount a suitable response. An experimental structure of full-length VraR is not available yet, but previous work points to similarities between VraR and the well-characterized NarL. This work employs hydrogen exchange mass spectrometry to gain insights into the phosphorylation-induced activation of VraR, a process that primes the protein for dimerization and DNA binding. Whereas VraR is highly dynamic, phosphorylated VraR shows less extensive deuteration. This rigidification is most dramatic within the receiver domain, which carries the phosphorylation site D55. Alterations in the DNA-binding domain are much less pronounced. Changes in deuteration within the receiver domain are consistent with a Y-T coupling mechanism. In analogy to NarL, the activation of VraR is thought to involve separation and subsequent reorientation of the two domains, thereby allowing the α8-turn-α9 element to engage in DNA binding. The current work suggests that this structural transition is triggered by a reduction in the effective length of the linker through enhanced hydrogen bonding. In addition, separation of the two domains may be favored by the establishment of noncovalent protein-protein interactions and intradomain contacts at the expense of previously existing interdomain bonds. α9 appears to be packed against the receiver domain in nonactivated VraR. Support is presented for α1 as a dimerization interface in phosphorylated VraR, whereas protein-protein interactions for nonphosphorylated VraR are impeded by extensive disorder in this region.     

The effect of Parkinson's-disease-associated mutations on the deubiquitinating enzyme UCH-L1

The neuronal ubiquitin C-terminal hydrolase (UCH) UCH-L1 has been linked to Parkinson's disease (PD) and other neurodegenerative diseases. Here, we present a study on the structure, stability, unfolding, and dynamics of wild-type and mutant UCH-L1. Fluorescence, far-UV CD, and NMR measurements were used to establish that the unfolding of UCH-L1 is three-state under equilibrium conditions and that an intermediate is populated. S18Y and I93M mutants, which are associated with a decreased risk or an increased risk of PD, respectively, are less stable than wild type. However, while there is minimal structural perturbation in the S18Y mutant, the I93M mutation is more disruptive. In particular, the NMR data suggest that there are local rearrangements around the site of the mutation, which we propose results in the exposure of hydrophobic surface area. This may have two consequences: an increased tendency towards, firstly, aggregation in vivo, and, secondly, aberrant interactions with tubulin and the chaperone-mediated autophagy machinery as observed by other groups, both of which may be involved in neurodegenerative processes.     

Hydrogen deuterium exchange mass spectrometry applied to chaperones and chaperone-assisted protein folding

Introduction: Hydrogen–deuterium exchange (HDX) mass spectrometry (MS) is ideal for monitoring the protein folding and unfolding. The exchange of a deuterium in solution for an amide hydrogen in a protein can be very different depending on the degree of folding and protection of backbone amide positions. Molecular chaperones that assist with protein folding in vivo are necessary for folding of many substrate (client) proteins. HDX MS provides valuable insight into what chaperones are doing in protein folding and how they are doing it.

Areas covered: Application of HDX MS to the protein folding problem was desirable from the outset of the technique, but technical issues prohibited many studies. In the last 20 years, conformational changes of chaperones themselves (e.g., GroEL/GroES, Hsp70, and Hsp90) have been studied. Studies of interactions between chaperones, co-chaperones, and substrate proteins have revealed binding interfaces, allosteric conformational changes, and remodeling of components during various chaperone cycles. Experiments elucidating how chaperones contribute to and enhance the folding pathway of substrate proteins have been demonstrated.

Expert opinion: Technical issues that once prevented the analysis of chaperones have largely been resolved, permitting exciting comprehensive HDX MS studies of folding pathways during chaperone-assisted protein folding.     

Characterization of Elements Involved in Allosteric Light Regulation of Phosphodiesterase Activity by Comparison of Different Functional BlrP1 States

Bacteria have evolved dedicated signaling mechanisms that enable the integration of a range of environmental stimuli and the accordant modulation of metabolic pathways. One central signaling molecule in bacteria is the second messenger cyclic dimeric GMP (c-di-GMP). Complex regulatory mechanisms for modulating c-di-GMP concentrations have evolved, in line with its importance for maintaining bacterial fitness under changing environmental conditions. One interesting example in this context is the blue-light-regulated phosphodiesterase 1 (BlrP1) of Klebsiella pneumoniae. This covalently linked system of a sensor of blue light using FAD (BLUF) and an EAL phosphodiesterase domain orchestrates the light-dependent down-regulation of c-di-GMP levels. To reveal details of light-induced structural changes involved in EAL activity regulation, we extended previous crystallographic studies with hydrogen–deuterium exchange experiments and small-angle X-ray scattering analysis of different functional BlrP1 states. The combination of hydrogen–deuterium exchange and small-angle X-ray scattering allows the integration of local and global structural changes and provides an improved understanding of light signaling via an allosteric communication pathway between the BLUF and EAL domains. This model is supported by results from a mutational analysis of the EAL dimerization region and the analysis of metal-coordination effects of the EAL active site on the dark-state recovery kinetics of the BLUF domain. In combination with structural information from other EAL domains, the observed bidirectional communication points to a general mechanism of EAL activity regulation and suggests that a similar allosteric coupling is maintained in catalytically inactive EAL domains that retain a regulatory function.     

Allosteric signaling in the biotin repressor occurs via local folding coupled to global dampening of protein dynamics

The biotin repressor is an allosterically regulated, site-specific DNA-binding protein. Binding of the small ligand bio-5′-AMP activates repressor dimerization, which is a prerequisite to DNA binding. Multiple disorder-to-order transitions, some of which are known to be important for the functional allosteric response, occur in the vicinity of the ligand-binding site concomitant with effector binding to the repressor monomer. In this work, the extent to which these local changes are coupled to additional changes in the structure/dynamics of the repressor was investigated using hydrogen/deuterium exchange coupled to mass spectrometry. Measurements were performed on the apo-protein and on complexes of the protein bound to four different effectors that elicit a range of thermodynamic responses in the repressor. Global exchange measurements indicate that binding of any effector to the intact protein is accompanied by protection from exchange. Mass spectrometric analysis of pepsin-cleavage products generated from the exchanged complexes reveals that the protection is distributed throughout the protein. Furthermore, the magnitude of the level of protection in each peptide from hydrogen/deuterium exchange correlates with the magnitude of the functional allosteric response elicited by a ligand. These results indicate that local structural changes in the binding site that occur concomitant with effector binding nucleate global dampening of dynamics. Moreover, the magnitude of dampening of repressor dynamics tracks with the magnitude of the functional response to effector binding.     

Using hydrogen deuterium exchange mass spectrometry to engineer optimized constructs for crystallization of protein complexes: Case study of PI4KIIIβ with Rab11

The ability of proteins to bind and interact with protein partners plays fundamental roles in many cellular contexts. X‐ray crystallography has been a powerful approach to understand protein‐protein interactions; however, a challenge in the crystallization of proteins and their complexes is the presence of intrinsically disordered regions. In this article, we describe an application of hydrogen deuterium exchange mass spectrometry (HDX‐MS) to identify dynamic regions within type III phosphatidylinositol 4 kinase beta (PI4KIIIβ) in complex with the GTPase Rab11. This information was then used to design deletions that allowed for the production of diffraction quality crystals. Importantly, we also used HDX‐MS to verify that the new construct was properly folded, consistent with it being catalytically and functionally active. Structures of PI4KIIIβ in an Apo state and bound to the potent inhibitor BQR695 in complex with both GTPγS and GDP loaded Rab11 were determined. This hybrid HDX‐MS/crystallographic strategy revealed novel aspects of the PI4KIIIβ‐Rab11 complex, as well as the molecular mechanism of potency of a PI4K specific inhibitor (BQR695). This approach is widely applicable to protein‐protein complexes, and is an excellent strategy to optimize constructs for high‐resolution structural approaches.     

Hydrogen-Deuterium Exchange Coupled to Top- and Middle-Down Mass Spectrometry Reveals Histone Tail Dynamics before and after Nucleosome Assembly

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Light-Driven Domain Mechanics of a Minimal Phytochrome Photosensory Module Studied by EPR

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A Novel Polar Core and Weakly Fixed C-Tail in Squid Arrestin Provide New Insight into Interaction with Rhodopsin

Photoreceptors of the squid Loligo pealei contain a G-protein-coupled receptor (GPCR) signaling system that activates phospholipase C in response to light. Analogous to the mammalian visual system, signaling of the photoactivated GPCR rhodopsin is terminated by binding of squid arrestin (sArr). sArr forms a light-dependent, high-affinity complex with squid rhodopsin, which does not require prior receptor phosphorylation for interaction. This is at odds with classical mammalian GPCR desensitization where an agonist-bound phosphorylated receptor is needed to break stabilizing constraints within arrestins, the so-called “three-element interaction” and “polar core” network, before a stable receptor–arrestin complex can be established. Biophysical and mass spectrometric analysis of the squid rhodopsin–arrestin complex indicates that in contrast to mammalian arrestins, the sArr C-tail is not involved in a stable three-element interaction. We determined the crystal structure of C-terminally truncated sArr that adopts a basal conformation common to arrestins and is stabilized by a series of weak but novel polar core interactions. Unlike mammalian arrestin-1, deletion of the sArr C-tail does not influence kinetic properties of complex formation of sArr with the receptor. Hydrogen–deuterium exchange studies revealed the footprint of the light-activated rhodopsin on sArr. Furthermore, double electron–electron resonance spectroscopy experiments provide evidence that receptor-bound sArr adopts a conformation different from the one known for arrestin-1 and molecular dynamics simulations reveal the residues that account for the weak three-element interaction. Insights gleaned from studying this system add to our general understanding of GPCR–arrestin interaction.