Rational design to control the trade-off between receptor affinity and cooperativity.

Cooperativity enhances the responsiveness of biomolecular receptors to small changes in the concentration of their target ligand, albeit with a concomitant reduction in affinity. The binding midpoint of a two-site receptor with a Hill coefficient of 1.9, for example, must be at least 19 times higher than the dissociation constant of the higher affinity of its two binding sites. This trade-off can be overcome, however, by the extra binding energy provided by the addition of more binding sites, which can be used to achieve highly cooperative receptors that still retain high affinity. Exploring this experimentally, we have employed an "intrinsic disorder" mechanism to design two cooperative, three-binding-site receptors starting from a single-site-and thus noncooperative-doxorubicin-binding aptamer. The first receptor follows a binding energy landscape that partitions the energy provided by the additional binding event to favor affinity, achieving a Hill coefficient of 1.9 but affinity within a factor of 2 of the parent aptamer. The binding energy landscape of the second receptor, in contrast, partitions more of this energy toward cooperativity, achieving a Hill coefficient of 2.3, but at the cost of 4-fold poorer affinity than that of the parent aptamer. The switch between these two behaviors is driven primarily by the affinity of the receptors' second binding event, which serves as an allosteric "gatekeeper" defining the extent to which the system is weighted toward higher cooperativity or higher affinity.

Paradoxical enhancement of chemoreceptor detection sensitivity by a sensory adaptation enzyme.

A sensory adaptation system that tunes chemoreceptor sensitivity enables motile Escherichia coli cells to track chemical gradients with high sensitivity over a wide dynamic range. Sensory adaptation involves feedback control of covalent receptor modifications by two enzymes: CheR, a methyltransferase, and CheB, a methylesterase. This study describes a CheR function that opposes the signaling consequences of its catalytic activity. In the presence of CheR, a variety of mutant serine chemoreceptors displayed up to 40-fold enhanced detection sensitivity to chemoeffector stimuli. This response enhancement effect did not require the known catalytic activity of CheR, but did involve a binding interaction between CheR and receptor molecules. Response enhancement was maximal at low CheR:receptor stoichiometry and quantitative analyses argued against a reversible binding interaction that simply shifts the ON-OFF equilibrium of receptor signaling complexes. Rather, a short-lived CheR binding interaction appears to promote a long-lasting change in receptor molecules, either a covalent modification or conformation that enhances their response to attractant ligands.

Protein structural and surface water rearrangement constitute major events in the earliest aggregation stages of tau.

Protein aggregation plays a critical role in the pathogenesis of neurodegenerative diseases, and the mechanism of its progression is poorly understood. Here, we examine the structural and dynamic characteristics of transiently evolving protein aggregates under ambient conditions by directly probing protein surface water diffusivity, local protein segment dynamics, and interprotein packing as a function of aggregation time, along the third repeat domain and C terminus of Δtau187 spanning residues 255-441 of the longest isoform of human tau. These measurements were achieved with a set of highly sensitive magnetic resonance tools that rely on site-specific electron spin labeling of Δtau187. Within minutes of initiated aggregation, the majority of Δtau187 that is initially homogeneously hydrated undergoes structural transformations to form partially structured aggregation intermediates. This is reflected in the dispersion of surface water dynamics that is distinct around the third repeat domain, found to be embedded in an intertau interface, from that of the solvent-exposed C terminus. Over the course of hours and in a rate-limiting process, a majority of these aggregation intermediates proceed to convert into stable ß-sheet structured species and maintain their stacking order without exchanging their subunits. The population of ß-sheet structured species is >5% within 5 min of aggregation and gradually grows to 50-70% within the early stages of fibril formation, while they mostly anneal block-wisely to form elongated fibrils. Our findings suggest that the formation of dynamic aggregation intermediates constitutes a major event occurring in the earliest stages of tau aggregation that precedes, and likely facilitates, fibril formation and growth.

Regulatory Role of an Interdomain Linker in the Bacterial Chemotaxis Histidine Kinase CheA.

The histidine kinase CheA plays a central role in signal integration, conversion, and amplification in the bacterial chemotaxis signal transduction pathway. The kinase activity is regulated in chemotaxis signaling complexes formed via the interactions among CheA's regulatory domain (P5), the coupling protein CheW, and transmembrane chemoreceptors. Despite recent advancements in the understanding of the architecture of the signaling complex, the molecular mechanism underlying this regulation remains elusive. An interdomain linker that connects the catalytic (P4) and regulatory domains of CheA may mediate regulatory signals from the P5-CheW-receptor interactions to the catalytic domain. To investigate whether this interdomain linker is capable of both activating and inhibiting CheA, we performed in vivo screens to search for P4-P5 linker mutations that result in different CheA autokinase activities. Several CheA variants were identified with kinase activities ranging from 30% to 670% of the activity of wild-type CheA. All of these CheA variants were defective in receptor-mediated kinase activation, indicating that the natural receptor-mediated signal transmission pathway was simultaneously affected by these mutations. The altered P4-P5 linkers were sufficient for making significant changes in the kinase activity even in the absence of the P5 domain. Therefore, the interdomain linker is an active module that has the ability to impose regulatory effects on the catalytic activity of the P4 domain. These results suggest that chemoreceptors may manipulate the conformation of the P4-P5 linker to achieve CheA regulation in the platform of the signaling complex.IMPORTANCE The molecular mechanism underlying kinase regulation in bacterial chemotaxis signaling complexes formed by the regulatory domain of the histidine kinase CheA, the coupling protein CheW, and chemoreceptors is still unknown. We isolated and characterized mutations in the interdomain linker that connects the catalytic and regulatory domains of CheA and found that the linker mutations resulted in different CheA autokinase activities in the absence and presence of the regulatory domain as well as a defect in receptor-mediated kinase activation. These results demonstrate that the interdomain linker is an active module that has the ability to impose regulatory effects on CheA activity. Chemoreceptors may manipulate the conformation of this interdomain linker to achieve CheA regulation in the platform of the signaling complex.

New Architecture for Reagentless, Protein-Based Electrochemical Biosensors.

Here we demonstrate a new class of reagentless, single-step sensors for the detection of proteins and peptides that is the electrochemical analog of fluorescence polarization (fluorescence anisotropy), a versatile optical approach widely employed to this same end. Our electrochemical sensors consist of a redox-reporter-modified protein (the "receptor") site-specifically anchored to an electrode via a short, flexible polypeptide linker. Interaction of the receptor with its binding partner alters the efficiency with which the reporter approaches the electrode surface, thus causing a change in redox current upon voltammetric interrogation. As our first proof-of-principle we employed the bacterial chemotaxis protein CheY as our receptor. Interaction with either of CheY's two binding partners, the P2 domain of the chemotaxis kinase, CheA, or the 16-residue "target region" of the flagellar switch protein, FliM, leads to easily measurable changes in output current that trace Langmuir isotherms within error of those seen in solution. Phosphorylation of the electrode-bound CheY decreases its affinity for CheA-P2 and enhances its affinity for FliM in a manner likewise consistent with its behavior in solution. As expected given the proposed sensor signaling mechanism, the magnitude of the binding-induced signal change depends on the placement of the redox reporter on the receptor. Following these preliminary studies with CheY, we also developed and characterized additional sensors aimed at the detection of specific antibodies using the relevant protein antigens as the receptor. These exhibit excellent detection limits for their targets without the use of reagents or wash steps. This novel, protein-based electrochemical sensing architecture provides a new and potentially promising approach to sensors for the single-step measurement of specific proteins and peptides.

Spatially Heterogeneous Surface Water Diffusivity around Structured Protein Surfaces at Equilibrium.

Hydration water on the surface of a protein is thought to mediate the thermodynamics of protein-ligand interactions. For hydration water to play a role beyond modulating global protein solubility or stability, the thermodynamic properties of hydration water must reflect on the properties of the heterogeneous protein surface and thus spatially vary over the protein surface. A potent read-out of local variations in thermodynamic properties of hydration water is its equilibrium dynamics spanning picosecond to nanosecond time scales. In this study, we employ Overhauser dynamic nuclear polarization (ODNP) to probe the equilibrium hydration water dynamics at select sites on the surface of Chemotaxis Y (CheY) in dilute solution. ODNP reports on site-specific hydration water dynamics within 5-10 Å of a label tethered to the biomolecular surface on two separate time scales of motion, corresponding to diffusive water (DW) and protein-water coupled motions, referred to as bound water (BW). We find DW dynamics to be highly heterogeneous across the surface of CheY. We identify a significant correlation between DW dynamics and the local hydropathy of the CheY protein surface, empirically determined by molecular dynamics (MD) simulations, and find the more hydrophobic sites to be hydrated with slower diffusing water. Furthermore, we compare the hydration water dynamics on different polypeptides and liposome surfaces and find the DW dynamics on globular proteins to be significantly more heterogeneous than on intrinsically disordered proteins (IDPs), peptides, and liposomes. The heterogeneity in the hydration water dynamics suggests that structured proteins have the capacity to encode information into the surrounding hydration shell.

Solution structure of a minor and transiently formed state of a T4 lysozyme mutant.

Proteins are inherently plastic molecules, whose function often critically depends on excursions between different molecular conformations (conformers). However, a rigorous understanding of the relation between a protein's structure, dynamics and function remains elusive. This is because many of the conformers on its energy landscape are only transiently formed and marginally populated (less than a few per cent of the total number of molecules), so that they cannot be individually characterized by most biophysical tools. Here we study a lysozyme mutant from phage T4 that binds hydrophobic molecules and populates an excited state transiently (about 1 ms) to about 3% at 25 °C (ref. 5). We show that such binding occurs only via the ground state, and present the atomic-level model of the 'invisible', excited state obtained using a combined strategy of relaxation-dispersion NMR (ref. 6) and CS-Rosetta model building that rationalizes this observation. The model was tested using structure-based design calculations identifying point mutants predicted to stabilize the excited state relative to the ground state. In this way a pair of mutations were introduced, inverting the relative populations of the ground and excited states and altering function. Our results suggest a mechanism for the evolution of a protein's function by changing the delicate balance between the states on its energy landscape. More generally, they show that our approach can generate and validate models of excited protein states.

Cavity as a source of conformational fluctuation and high-energy state: high-pressure NMR study of a cavity-enlarged mutant of T4 lysozyme.

Although the structure, function, conformational dynamics, and controlled thermodynamics of proteins are manifested by their corresponding amino acid sequences, the natural rules for molecular design and their corresponding interplay remain obscure. In this study, we focused on the role of internal cavities of proteins in conformational dynamics. We investigated the pressure-induced responses from the cavity-enlarged L99A mutant of T4 lysozyme, using high-pressure NMR spectroscopy. The signal intensities of the methyl groups in the (1)H/(13)C heteronuclear single quantum correlation spectra, particularly those around the enlarged cavity, decreased with the increasing pressure, and disappeared at 200 MPa, without the appearance of new resonances, thus indicating the presence of heterogeneous conformations around the cavity within the ground state ensemble. Above 200 MPa, the signal intensities of >20 methyl groups gradually decreased with the increasing pressure, without the appearance of new resonances. Interestingly, these residues closely matched those sensing a large conformational change between the ground- and high-energy states, at atmospheric pressure. (13)C and (1)H NMR line-shape simulations showed that the pressure-induced loss in the peak intensity could be explained by the increase in the high-energy state population. In this high-energy state, the aromatic side chain of F114 gets flipped into the enlarged cavity. The accommodation of the phenylalanine ring into the efficiently packed cavity may decrease the partial molar volume of the high-energy state, relative to the ground state. We suggest that the enlarged cavity is involved in the conformational transition to high-energy states and in the volume fluctuation of the ground state.

The linker between the dimerization and catalytic domains of the CheA histidine kinase propagates changes in structure and dynamics that are important for enzymatic activity.

The histidine kinase, CheA, couples environmental stimuli to changes in bacterial swimming behavior, converting a sensory signal to a chemical signal in the cytosol via autophosphorylation. The kinase activity is regulated in the platform of chemotaxis signaling complexes formed by CheW, chemoreceptors, and the regulatory domain of CheA. Our previous computational and mutational studies have revealed that two interdomain linkers play important roles in CheA's enzymatic activity. Of the two linkers, one that connects the dimerization and ATP binding domains is essential for both basal autophosphorylation and activation of the kinase. However, the mechanistic role of this linker remains unclear, given that it is far from the autophosphorylation reaction center (the ATP binding site). Here we investigate how this interdomain linker is coupled to CheA's enzymatic activity. Using modern nuclear magnetic resonance (NMR) techniques, we find that by interacting with the catalytic domain, the interdomain linker initiates long-range structural and dynamic changes directed toward the catalytic center of the autophosphorylation reaction. Subsequent biochemical assays define the functional relevance of these NMR-based observations. These findings extend our understanding of the chemotaxis signal transduction pathway.

Conformational coupling between receptor and kinase binding sites through a conserved salt bridge in a signaling complex scaffold protein.

Bacterial chemotaxis is one of the best studied signal transduction pathways. CheW is a scaffold protein that mediates the association of the chemoreceptors and the CheA kinase in a ternary signaling complex. The effects of replacing conserved Arg62 of CheW with other residues suggested that the scaffold protein plays a more complex role than simply binding its partner proteins. Although R62A CheW had essentially the same affinity for chemoreceptors and CheA, cells expressing the mutant protein are impaired in chemotaxis. Using a combination of molecular dynamics simulations (MD), NMR spectroscopy, and circular dichroism (CD), we addressed the role of Arg62. Here we show that Arg62 forms a salt bridge with another highly conserved residue, Glu38. Although this interaction is unimportant for overall protein stability, it is essential to maintain the correct alignment of the chemoreceptor and kinase binding sites of CheW. Computational and experimental data suggest that the role of the salt bridge in maintaining the alignment of the two partner binding sites is fundamental to the function of the signaling complex but not to its assembly. We conclude that a key feature of CheW is to maintain the specific geometry between the two interaction sites required for its function as a scaffold.

The conjugated oligoelectrolyte DSSN+ enables exceptional coulombic efficiency via direct electron transfer for anode-respiring Shewanella oneidensis MR-1-a mechanistic study.

Shewanella oneidensis MR-1 was cultivated on lactate with poised graphite electrode acceptors (E = +0.2 V vs. Ag/AgCl) in order to explore the basis for sustained increases in anodic current output following the addition of the lipid-intercalating conjugated oligoelectrolyte (COE), 4,4'-bis(4'-(N,N-bis(6''-(N,N,N-trimethylammonium)hexyl)amino)-styryl)stilbene tetraiodide (DSSN+). Microbial cultures, which were spiked with DSSN+, exhibit a ∼2.2-fold increase in charge collected, a ∼3.1-fold increase in electrode colonization by S. oneidensis, and a ∼1.7-fold increase in coulombic efficiency from 51 ± 10% to an exceptional 84 ± 7% without obvious toxicity effects. Direct microbial biofilm voltammetry reveals that DSSN+ rapidly and sustainably increases cytochrome-based direct electron transfer and subsequently increases flavin-based mediated electron transfer. Control experiments indicate that DSSN+ does not contribute to the current in the absence of bacteria.

Distal structural elements coordinate a conserved base flipping network.

One of the most dramatic illustrations of enzymatic promotion of a high-energy intermediate is observed in DNA modification and repair enzymes where an individual base is rotated (flipped) 180° around the deoxyribose-phosphate backbone and into the active site. While the end states have been extensively characterized, experimental techniques have yet to yield a full description of the base flipping process and the role played by the enzyme. The C5 cytosine methyltransferase M.HhaI coordinates an ensemble of reciprocal DNA and enzyme rearrangements to efficiently flip the target cytosine from the DNA helix. We sought to understand the role of individual amino acids during base flipping. Our results demonstrate that M.HhaI initiates base flipping before closure of the catalytic loop and utilizes the conserved serine 85 in the catalytic loop to accelerate flipping and maintain distortion of the DNA backbone. Serine 87, which forms specific contacts within the DNA helix after base flipping, is not involved in the flipping process or in maintaining the catalytically competent complex. At the base of the catalytic loop, glycine 98 acts as a hinge to allow conformational dynamism of the loop and mutation to alanine inhibits stabilization of the closed loop. Our results illustrate how an enzyme utilizes numerous, distal residues in concert to transform substrate recognition into catalysis.

Enzyme-promoted base flipping controls DNA methylation fidelity.

A quantitative understanding of how conformational transitions contribute to enzyme catalysis and specificity remains a fundamental challenge. A suite of biophysical approaches was used to reveal several transient states of the enzyme-substrate complexes of the model DNA cytosine methyltransferase M.HhaI. Multidimensional, transverse relaxation-optimized nuclear magnetic resonance (NMR) experiments show that M.HhaI has the same conformation with noncognate and cognate DNA sequences. The high-affinity cognatelike mode requires the formation of a subset of protein-DNA interactions that drive the flipping of the target base from the helix to the active site. Noncognate substrates lacking these interactions undergo slow base flipping, and fluorescence tracking of the catalytic loop corroborates the NMR evidence of a loose, nonspecific binding mode prior to base flipping and subsequent closure of the catalytic loop. This slow flipping transition defines the rate-limiting step for the methylation of noncognate sequences. Additionally, we present spectroscopic evidence of an intermediate along the base flipping pathway that has been predicted but never previously observed. These findings provide important details of how conformational rearrangements are used to balance specificity with catalytic efficiency.

Structure of flagellar motor proteins in complex allows for insights into motor structure and switching.

The flagellar motor is one type of propulsion device of motile bacteria. The cytoplasmic ring (C-ring) of the motor interacts with the stator to generate torque in clockwise and counterclockwise directions. The C-ring is composed of three proteins, FliM, FliN, and FliG. Together they form the "switch complex" and regulate switching and torque generation. Here we report the crystal structure of the middle domain of FliM in complex with the middle and C-terminal domains of FliG that shows the interaction surface and orientations of the proteins. In the complex, FliG assumes a compact conformation in which the middle and C-terminal domains (FliG(MC)) collapse and stack together similarly to the recently published structure of a mutant of FliG(MC) with a clockwise rotational bias. This intramolecular stacking of the domains is distinct from the intermolecular stacking seen in other structures of FliG. We fit the complex structure into the three-dimensional reconstructions of the motor and propose that the cytoplasmic ring is assembled from 34 FliG and FliM molecules in a 1:1 fashion.

Structural insights into the interaction between the bacterial flagellar motor proteins FliF and FliG.

The binding of the soluble cytoplasmic protein FliG to the transmembrane protein FliF is one of the first interactions in the assembly of the bacterial flagellum. Once established, this interaction is integral in keeping the flagellar cytoplasmic ring, responsible for both transmission of torque and control of the rotational direction of the flagellum, anchored to the central transmembrane ring on which the flagellum is assembled. Here we isolate and characterize the interaction between the N-terminal domain of Thermotoga maritima FliG (FliG(N)) and peptides corresponding to the conserved C-terminal portion of T. maritima FliF. Using nuclear magnetic resonance (NMR) and other techniques, we show that the last ~40 amino acids of FliF (FliF(C)) interact strongly (upper bound K(d) in the low nanomolar range) with FliG(N). The formation of this complex causes extensive conformational changes in FliG(N). We find that T. maritima FliG(N) is homodimeric in the absence of the FliF(C) peptide but forms a heterodimeric complex with the peptide, and we show that this same change in oligomeric state occurs in full-length T. maritima FliG, as well. We relate previously observed phenotypic effects of FliF(C) mutations to our direct observation of binding. Lastly, on the basis of NMR data, we propose that the primary interaction site for FliF(C) is located on a conserved hydrophobic patch centered along helix 1 of FliG(N). These results provide new detailed information about the bacterial flagellar motor and support efforts to understand the cytoplasmic ring's precise molecular structure and mechanism of rotational switching.

Solution structure of a complex of the histidine autokinase CheA with its substrate CheY.

In the bacterial chemotaxis two-component signaling system, the histidine-containing phosphotransfer domain (the "P1" domain) of CheA receives a phosphoryl group from the catalytic domain (P4) of CheA and transfers it to the cognate response regulator (RR) CheY, which is docked by the P2 domain of CheA. Phosphorylated CheY then diffuses into the cytoplasm and interacts with the FliM moiety of the flagellar motors, thereby modulating the direction of flagellar rotation. Structures of various histidine phosphotransfer domains (HPt) complexed with their cognate RR domains have been reported. Unlike the Escherichia coli chemotaxis system, however, these systems lack the additional domains dedicated to binding to the response regulators, and the interaction of an HPt domain with an RR domain in the presence of such a domain has not been examined on a structural basis. In this study, we used modern nuclear magnetic resonance techniques to construct a model for the interaction of the E. coli CheA P1 domain (HPt) and CheY (RR) in the presence of the CheY-binding domain, P2. Our results indicate that the presence of P2 may lead to a slightly different relative orientation of the HPt and RR domains versus those seen in such complex structures previously reported.

Computational and experimental analyses reveal the essential roles of interdomain linkers in the biological function of chemotaxis histidine kinase CheA.

A two-component signal transduction pathway underlies the phenomenon of bacterial chemotaxis that allows bacteria to modulate their swimming behavior in response to environmental stimuli. The dimeric five-domain histidine kinase, CheA, plays a central role in the pathway, converting sensory signals to a chemical signal via trans-autophosphorylation between the P1 and P4 domains. This autophosphorylation is regulated via the networked interactions among the P5 domain of CheA, CheW, and chemoreceptors. Despite a wealth of structural information about these components and their interactions, the key question of how the kinase activity of the catalytic P4 domain is regulated by the signal received from the regulatory P5 domain remains poorly understood. We performed replica exchange molecular dynamics simulations on the CheA kinase core and found that while individual domains maintained their structural fold, these domains exhibited a variety of interdomain orientations due to two interdomain linkers. A partially populated conformation that adopts an interdomain arrangement is suitable for building a functional ternary complex. An allosteric network derived from this structural model implies critical roles for two linkers in CheA's activity. The biochemical and biological functions of these linkers were assigned via a series of biochemical and genetic assays that show the P4-P5 linker controls the activation of CheA and the P3-P4 linker controls both the basal autophosphorylation activity and the activation of CheA. These results reveal the functional dependence between the two linkers and the essential role of the linkers in passing signal information from one domain to another.

Proteolytic processing induces a conformational switch required for antibacterial toxin delivery.

Many Gram-negative bacteria use CdiA effector proteins to inhibit the growth of neighboring competitors. CdiA transfers its toxic CdiA-CT region into the periplasm of target cells, where it is released through proteolytic cleavage. The N-terminal cytoplasm-entry domain of the CdiA-CT then mediates translocation across the inner membrane to deliver the C-terminal toxin domain into the cytosol. Here, we show that proteolysis not only liberates the CdiA-CT for delivery, but is also required to activate the entry domain for membrane translocation. Translocation function depends on precise cleavage after a conserved VENN peptide sequence, and the processed ∆VENN entry domain exhibits distinct biophysical and thermodynamic properties. By contrast, imprecisely processed CdiA-CT fragments do not undergo this transition and fail to translocate to the cytoplasm. These findings suggest that CdiA-CT processing induces a critical structural switch that converts the entry domain into a membrane-translocation competent conformation.

Determinants of precatalytic conformational transitions in the DNA cytosine methyltransferase M.HhaI.

The DNA methyltransferase M.HhaI is an excellent model for understanding how recognition of a nucleic acid substrate is translated into site-specific modification. In this study, we utilize direct, real-time monitoring of the catalytic loop position via engineered tryptophan fluorescence reporters to dissect the conformational transitions that occur in both enzyme and DNA substrate prior to methylation of the target cytosine. Using nucleobase analogues in place of the target and orphan bases, the kinetics of the base flipping and catalytic loop closure rates were determined, revealing that base flipping precedes loop closure as the rate-determining step prior to methyl transfer. To determine the mechanism by which individual specific hydrogen bond contacts at the enzyme-DNA interface mediate these conformational transitions, nucleobase analogues lacking hydrogen bonding groups were incorporated into the recognition sequence to disrupt the major groove recognition elements. The consequences of binding, loop closure, and catalysis were determined for four contacts, revealing large differences in the contribution of individual hydrogen bonds to DNA recognition and conformational transitions on the path to catalysis. Our results describe how M.HhaI utilizes direct readout contacts to accelerate extrication of the target base that offer new insights into the evolutionary history of this important class of enzymes.