Your search keyword '"Dahlquist Fw"' showing total 203 results

1. Access of ligands to cavities within the core of a protein is rapid.

Author

Feher, VA, Baldwin, EP, and Dahlquist, FW

Subjects

Benzene, Indoles, Muramidase, Proteins, Recombinant Proteins, Magnetic Resonance Spectroscopy, Binding Sites, Energy Transfer, Protein Conformation, Models, Molecular, Biophysics, Developmental Biology, Medical and Health Sciences, Chemical Sciences, Biological Sciences

Abstract

We have investigated the magnitude and timescale of fluctuations within the core of a protein using the exchange kinetics of indole and benzene binding to engineered hydrophobic cavities in T4 lysozyme. The crystal structures of variant-benzene complexes suggest that relatively large scale fluctuations (1-2 angstrom) of backbone atoms are required for entry of these ligands into the core. Nonetheless, these ligands enter the cavities rapidly, with bimolecular rate constants of approximately 10(6)-10(7) M(-1) s(-1) and a low activation barrier, 2-5 kcal mol(-1). These results suggest that protein cores undergo substantial fluctuations on the millisecond to microsecond timescale and that entry of small molecules into protein interiors is not strongly limited by steric occlusion.

Published

1996

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

Author

Lai, R-Z, Han, X-S, Dahlquist, FW, and Parkinson, JS

Subjects

bacterial chemotaxis, dynamic-bundle model, receptor methyltransferase, signaling conformation, nonequilibrium mechanism

Abstract

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.

Published

2017

3. Signaling complexes control the chemotaxis kinase by altering its apparent rate constant of autophosphorylation

Author

Pan, W, Dahlquist, FW, and Hazelbauer, GL

Subjects

Histidine Kinase, Amino Acid Motifs, Biophysics, Gene Expression, Methyl-Accepting Chemotaxis Proteins, Ligands, Substrate Specificity, Bacterial Proteins, Protein Domains, bacterial chemoreceptors, enzyme kinetics, Receptors, Escherichia coli, Phosphorylation, Other Information and Computing Sciences, Aspartic Acid, Binding Sites, Escherichia coli Proteins, Chemotaxis, Nanodiscs, Computation Theory and Mathematics, Recombinant Proteins, bacterial chemotaxis, Kinetics, Cell Surface, bacteria, Biochemistry and Cell Biology, Protein Multimerization, Signal Transduction, Protein Binding

Abstract

Autophosphorylating histidine kinase CheA is central to signaling in bacterial chemotaxis. The kinase donates its phosphoryl group to two response regulators, CheY that controls flagellar rotation and thus motility and CheB, crucial for sensory adaptation. As measured by coupled CheY phosphorylation, incorporation into signaling complexes activates the kinase ∼1000-fold and places it under control of chemoreceptors. By the same assay, receptors modulate kinase activity ∼100-fold as a function of receptor ligand occupancy and adaptational modification. These changes are the essence of chemotactic signaling. Yet, the enzymatic properties affected by incorporation into signaling complexes, by chemoreceptor ligand binding or by receptor adaptational modification are largely undefined. To investigate, we performed steady-state kinetic analysis of autophosphorylation using a liberated kinase phosphoryl-accepting domain, characterizing kinase alone, in isolated core signaling complexes and in small arrays of core complexes assembled in vitro with receptors contained in isolated native membranes. Autophosphorylation in signaling complexes was measured as a function of ligand occupancy and adaptational modification. Activation by incorporation into signaling complexes and modulation in complexes by ligand occupancy and adaptational modification occurred largely via changes in the apparent catalytic rate constant (kcat ). Changes in the autophosphorylation kcat accounted for most of the ∼1000-fold kinase activation in signaling complexes observed for coupled CheY phosphorylation, and the ∼100-fold inhibition by ligand occupancy or modulation by adaptational modification. Our results indicate no more than a minor role in kinase control for simple sequestration of the autophosphorylation substrate. Instead they indicate direct effects on the active site.

Published

2017

4. Heterodimerization of the Yeast Homeodomain Transcriptional Regulators .alpha.2 and a1: Secondary Structure Determination of the a1 Homeodomain and Changes Produced by .alpha.2 Interactions

Author

Dahlquist Fw, Baxter Sm, Phillips Cl, Roth Af, and Gontrum Dm

Subjects

Magnetic Resonance Spectroscopy, Receptors, Peptide, Macromolecular Substances, Stereochemistry, Molecular Sequence Data, Cooperativity, Saccharomyces cerevisiae, Biochemistry, Protein Structure, Secondary, Turn (biochemistry), chemistry.chemical_compound, Gene Expression Regulation, Fungal, Amino Acid Sequence, Protein secondary structure, Homeodomain Proteins, chemistry.chemical_classification, Chemistry, Hydrogen Bonding, Nuclear magnetic resonance spectroscopy, NKX-homeodomain factor, Molecular biology, Recombinant Proteins, Amino acid, Receptors, Mating Factor, Helix, DNA, Protein Binding, Transcription Factors

Abstract

The homeodomain proteins, a1 and alpha 2, act cooperatively to regulate cell-type specific genes in yeast. The basis of this cooperativity is an interaction between the two proteins, forming a heterodimer that binds DNA tightly and specifically. A fragment containing the homeodomain of a1, a1(66-126), has been studied by NMR spectroscopy to gain secondary structure information and to characterize the changes in a1 upon heterodimerization with alpha 2. Heteronuclear (1H-15N) NMR methods were used to assign backbone resonances of the 61 amino acid fragment. The a1(66-126) secondary structure was determined using NOE connectivities, 3JHN alpha coupling constants and hydrogen exchange kinetic data. NMR data identify three helical segments separated by a loop and a tight turn that are the characteristic structural elements of homeodomain proteins. The a1 fragment was titrated with alpha 2(128-210), the homeodomain-containing fragment of alpha 2, to study changes in a1(66-126) spectra produced by alpha 2 binding. The a1(66-126) protein was labeled with 15N and selectively observed using isotope-edited NMR experiments. NMR spectra of bound a1(66-126) indicate that residues in helix 1, helix 2, and the loop connecting them are directly involved in the binding of the alpha 2 fragment. Relatively minor effects on the resonances from residues in helix 3, the putative DNA-binding helix, were noted upon alpha 2 binding. We have thus located a region of the a1 homeodomain important for specific protein recognition.

Published

1994

5. Membrane protein conformational change dependent on the hydrophobic environment

Author

Wilson Ml and Dahlquist Fw

Subjects

chemistry.chemical_classification, Conformational change, Magnetic Resonance Spectroscopy, Protein Conformation, Stereochemistry, Peripheral membrane protein, Enthalpy, Spin–lattice relaxation, Membrane Proteins, Hydrogen-Ion Concentration, Coliphages, Biochemistry, Micelle, Viral Proteins, Crystallography, Viral Envelope Proteins, chemistry, Escherichia coli, Thermodynamics, Tyrosine, Non-covalent interactions, Spin Labels, Conformational isomerism, Entropy (order and disorder)

Abstract

Two conformational states of the coat protein of the filamentous bacteriophage M13 have been detected in detergent solution by using magnetic resonance techniques. When 3-fluorotyrosine is incorporated in place of the two tyrosine residues in the protein, four 19F nuclear magnetic resonance signals are observed, two for each conformer of the protein. The equilibrium between the two forms can be modulated by pH, temperature, and detergent structure. The rate of interconversion of the isomers is rapid on the minutes time scale but is slow relative to the T1 relaxation time of the fluorine resonances of approximately 50 ms. The conformational change between the conformers results in the perturbation of a basic residue in the protein such that this group has a pKa of approximately 9.5 in one state which shifts to 10.5 or more in the other conformational state. The temperature dependence of the equilibrium suggests an enthalpy difference of about 10 kcal/mol which is offset by entropy to give nearly zero free energy difference between the states at pH 8.3 in deoxycholate solution at room temperature. This suggests a substantial reorganization of the noncovalent interactions defining the two conformational states. The conformational equilibrium is strongly dependent on detergent structure and the presence of phospholipid in the detergent micelle. The results are not consistent with a strong, specific lipid binding to the protein but appear to be consistent with a more general effect of the overall micelle structure on the conformational state of the protein.

Published

1985

6. Biphasic transient kinetics are a property of a single site in horse liver alcohol dehydrogenase

Author

Anderson Dc and Dahlquist Fw

Subjects

Macromolecular Substances, Stereochemistry, Dimer, Kinetics, Biochemistry, chemistry.chemical_compound, Animals, Reactivity (chemistry), Horses, Ternary complex, Alcohol dehydrogenase, chemistry.chemical_classification, Binding Sites, biology, Alcohol Dehydrogenase, Trifluoroethanol, NAD, Alcohol Oxidoreductases, Enzyme, Liver, chemistry, Catalytic cycle, biology.protein, Pyrazoles, NAD+ kinase, Mathematics

Abstract

The transient kinetics under single turnover conditions of the dimeric enzyme horse liver alcohol dehydrogenase (LADH) are often biphasic with nearly equal amplitudes in the fast and slow components of the reaction. These observations have been the basis for the suggestion that this enzyme displays half of the sites reactivity or kinetic site-site interactions in its catalytic cycle [Bernhard, S.A., Dunn, M.F., Luisi, P.L., & Shack, P. (1970) Biochemistry 9, 185]. Alternatively, the biphasic kinetics could be the result of a complex mechanistic path at a single site with no kinetic interactions between the active sites [Kvassman, J., & Pettersson, G. (1976) Eur. J. Biochem. 62, 279; Kvassman, J., & Pettersson, G. (1978) Eur. J. Biochem. 87, 417]. To resolve this question, we have prepared LADH in which one of the two active sites is occupied by the strongly bound, slowly exchanging ternary complex inhibitors NAD with trifluoroethanol or NAD with pyrazole. These half-inhibited dimers show essentially the same biphasic transient kinetics as the native enzyme. These results strongly support mechanisms in which the observed kinetics are a property of each independently functioning site of the dimer. The possibility of half of the sites reactivity or kinetic site-site interaction appears to be ruled out.

Published

1982

7. Evidence for induced interactions in the anticooperative binding of nicotinamide adenine dinucleotide to sturgeon muscle glyceraldehyde-3-phosphate dehydrogenase

Author

Dahlquist Fw and Long Jw

Subjects

Binding Sites, Magnetic Resonance Spectroscopy, biology, Muscles, Fishes, Glyceraldehyde-3-Phosphate Dehydrogenases, Nicotinamide adenine dinucleotide, NAD, Biochemistry, Cofactor, chemistry.chemical_compound, Apoenzymes, Spectrometry, Fluorescence, Sturgeon, chemistry, biology.protein, Animals, Glyceraldehyde 3-phosphate dehydrogenase, Protein Binding

Published

1977

8. [13] The meaning of scatchard and hill plots

Author

Dahlquist Fw

Subjects

Set (abstract data type), symbols.namesake, Scatchard plot, symbols, Curve fitting, Cooperative binding, Nernst equation, Statistical physics, Meaning (existential), Plot (graphics), Interpretation (model theory), Mathematics

Abstract

Publisher Summary A number of interesting macromolecular questions are directly concerned with the binding of ligands to macromolecules. As a result, there has been a great increase in the number of publications primarily concerned with the measurement of such binding and its interpretation. A number of methods for graphical and computer-assisted analysis of the binding data have been employed. This chapter considers two commonly used graphical methods: the Scatchard plot and the Hill plot. The Hill plot, log [sites bound]/[sites free] versus log [free ligand], is also known as the “Sips plot” in the immunological literature. When redox equilibria are considered as the binding of electrons, the Hill plot and Nernst plot are fully equivalent as well. the chapter relates these common methods of data presentation to each other. It is clear that a given set of binding data contains the same information independent of the particular method used to interpret it. However, certain graphical methods show some aspects of this information more clearly than others. The chapter demonstrates the quantitative relationships that allow directly converting from one method to the others. It also demonstrates the way parameters for a number of models for apparent cooperative binding behavior may be extracted from the two plots without the need for extensive computer-dependent curve fitting.

Published

1978

9. A nuclear magnetic resonance study of enzyme-inhibitor association. The use of pH and temperature effects to probe the binding environments

Author

Dahlquist Fw and Raftery Ma

Subjects

Binding Sites, Magnetic Resonance Spectroscopy, biology, Chemistry, Kinetics, Temperature, Nuclear magnetic resonance spectroscopy, Hydrogen-Ion Concentration, Biochemistry, Nuclear magnetic resonance, Enzyme inhibitor, biology.protein, Muramidase, Binding site, Pyrans

Published

1968

10. Some properties of contiguous binding subsites on lysozyme as determined by proton magnetic resonance spectroscopy

Author

Dahlquist Fw and Raftery Ma

Subjects

Binding Sites, Magnetic Resonance Spectroscopy, Chemical Phenomena, Light, Rotation, Oligosaccharides, Chitin, Disaccharides, Biochemistry, Amides, Proton magnetic resonance, chemistry.chemical_compound, Chemistry, Nuclear magnetic resonance, chemistry, Muramidase, Glycosides, Lysozyme, Spectroscopy

Published

1969

11. Author Correction: Proteolytic processing induces a conformational switch required for antibacterial toxin delivery.

Author

Bartelli NL, Passanisi VJ, Michalska K, Song K, Nhan DQ, Zhou H, Cuthbert BJ, Stols LM, Eschenfeldt WH, Wilson NG, Basra JS, Cortes R, Noorsher Z, Gabraiel Y, Poonen-Honig I, Seacord EC, Goulding CW, Low DA, Joachimiak A, Dahlquist FW, and Hayes CS

Published

2022

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

Author

Bartelli NL, Passanisi VJ, Michalska K, Song K, Nhan DQ, Zhou H, Cuthbert BJ, Stols LM, Eschenfeldt WH, Wilson NG, Basra JS, Cortes R, Noorsher Z, Gabraiel Y, Poonen-Honig I, Seacord EC, Goulding CW, Low DA, Joachimiak A, Dahlquist FW, and Hayes CS

Subjects

Anti-Bacterial Agents metabolism, Anti-Bacterial Agents pharmacology, Escherichia coli metabolism, Membrane Proteins metabolism, Proteolysis, Escherichia coli Proteins metabolism

Abstract

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., (© 2022. The Author(s).)

Published

2022

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

Author

Ortega G, Mariottini D, Troina A, Dahlquist FW, Ricci F, and Plaxco KW

Subjects

Binding Sites, Doxorubicin chemistry, Doxorubicin metabolism, Kinetics, Ligands, Protein Binding, Receptors, Cell Surface metabolism, Receptors, Cell Surface chemistry

Abstract

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., Competing Interests: The authors declare no competing interest.

Published

2020

14. The Cytoplasm-Entry Domain of Antibacterial CdiA Is a Dynamic α-Helical Bundle with Disulfide-Dependent Structural Features.

Author

Bartelli NL, Sun S, Gucinski GC, Zhou H, Song K, Hayes CS, and Dahlquist FW

Subjects

Amino Acid Sequence, Anti-Bacterial Agents metabolism, Bacterial Toxins chemistry, Bacterial Toxins metabolism, Contact Inhibition, Crystallography, X-Ray, Cysteine, Disulfides metabolism, Escherichia coli Proteins genetics, Escherichia coli Proteins metabolism, Membrane Proteins genetics, Membrane Proteins metabolism, Protein Conformation, alpha-Helical, Protein Structure, Secondary, Protein Transport, Type V Secretion Systems, Anti-Bacterial Agents chemistry, Cytoplasm metabolism, Disulfides chemistry, Escherichia coli metabolism, Escherichia coli Proteins chemistry, Membrane Proteins chemistry, Protein Domains

Abstract

Many Gram-negative bacterial species use contact-dependent growth inhibition (CDI) systems to compete with neighboring cells. CDI + strains express cell-surface CdiA effector proteins, which carry a toxic C-terminal region (CdiA-CT) that is cleaved from the effector upon transfer into the periplasm of target bacteria. The released CdiA-CT consists of two domains. The C-terminal domain is typically a nuclease that inhibits cell growth, and the N-terminal "cytoplasm-entry" domain mediates toxin translocation into the target-cell cytosol. Here, we use NMR and circular dichroism spectroscopic approaches to probe the structure, stability, and dynamics of the cytoplasm-entry domain from Escherichia coli STEC_MHI813. Chemical shift analysis reveals that the CdiA-CT MHI813 entry domain is composed of a C-terminal helical bundle and a dynamic N-terminal region containing two disulfide linkages. Disruption of the disulfides by mutagenesis or chemical reduction destabilizes secondary structure over the N-terminus, but has no effect on the C-terminal helices. Although critical for N-terminal structure, the disulfides have only modest effects on global thermodynamic stability, and the entry domain exhibits characteristics of a molten globule. We find that the disulfides form in vivo as the entry domain dwells in the periplasm of inhibitor cells prior to target-cell recognition. CdiA-CT MHI813 variants lacking either disulfide still kill target bacteria, but disruption of both bonds abrogates growth inhibition activity. We propose that the entry domain's dynamic structural features are critical for function. In its molten globule-like state, the domain resists degradation after delivery, yet remains pliable enough to unfold for membrane translocation., (Copyright © 2019. Published by Elsevier Ltd.)

Published

2019

15. Expanding the Scope of Protein-Detecting Electrochemical DNA "Scaffold" Sensors.

Author

Kang D, Parolo C, Sun S, Ogden NE, Dahlquist FW, and Plaxco KW

Subjects

Biosensing Techniques methods, Electrochemical Techniques instrumentation, Equipment Design, Escherichia coli Proteins chemistry, Green Fluorescent Proteins chemistry, Green Fluorescent Proteins metabolism, HIV Core Protein p24 analysis, Histidine Kinase chemistry, Limit of Detection, Methyl-Accepting Chemotaxis Proteins chemistry, Molecular Weight, Nitrilotriacetic Acid chemistry, Proteins chemistry, Proteins metabolism, Biosensing Techniques instrumentation, DNA chemistry, Electrochemical Techniques methods, Proteins analysis

Abstract

The ability to measure the levels of diagnostically relevant proteins, such as antibodies, directly at the point of care could significantly impact healthcare. Thus motivated, we explore here the E-DNA "scaffold" sensing platform, a rapid, convenient, single-step means to this end. These sensors comprise a rigid nucleic acid "scaffold" attached via a flexible linker to an electrode and modified on its distal end with a redox reporter and a protein binding "recognition element". The binding of a targeted protein reduces the efficiency with which the redox reporter approaches the electrode, resulting in an easily measured signal change when the sensor is interrogated voltammetrically. Previously we have demonstrated scaffold sensors employing a range of low molecular weight haptens and linear peptides as their recognition elements. Expanding on this here we have characterized sensors employing much larger recognition elements (up to and including full length proteins) in order to (1) define the range of recognition elements suitable for use in the platform; (2) better characterize the platform's signaling mechanism to aid its design and optimization; and (3) demonstrate the analytical performance of sensors employing full-length proteins as recognition elements. In doing so we have enlarged the range of molecular targets amenable to this rapid and convenient sensing platform.

Published

2018

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

Author

Ding X, He Q, Shen F, Dahlquist FW, and Wang X

Subjects

Escherichia coli genetics, Escherichia coli Proteins genetics, Histidine Kinase genetics, Methyl-Accepting Chemotaxis Proteins genetics, Models, Molecular, Phosphorylation, Signal Transduction, Chemotaxis, Escherichia coli enzymology, Escherichia coli Proteins chemistry, Gene Expression Regulation, Histidine Kinase chemistry, Methyl-Accepting Chemotaxis Proteins chemistry

Abstract

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., (Copyright © 2018 American Society for Microbiology.)

Published

2018

17. The Bacterial Flagellar Motor Continues to Amaze.

Author

Dahlquist FW

Subjects

Fluorescence Polarization, Organothiophosphorus Compounds, Bacteria, Escherichia coli

Published

2018

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

Author

Barnes R, Sun S, Fichou Y, Dahlquist FW, Heyden M, and Han S

Subjects

Diffusion, Escherichia coli Proteins, Hydrophobic and Hydrophilic Interactions, Molecular Dynamics Simulation, Methyl-Accepting Chemotaxis Proteins chemistry, Thermodynamics, Water chemistry

Abstract

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.

Published

2017

19. New Architecture for Reagentless, Protein-Based Electrochemical Biosensors.

Author

Kang D, Sun S, Kurnik M, Morales D, Dahlquist FW, and Plaxco KW

Subjects

Escherichia coli Proteins, Indicators and Reagents chemistry, Methyl-Accepting Chemotaxis Proteins analysis, Biosensing Techniques, Electrochemical Techniques instrumentation, Methyl-Accepting Chemotaxis Proteins chemistry

Abstract

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.

Published

2017

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

Author

Lai RZ, Han XS, Dahlquist FW, and Parkinson JS

Subjects

Bacterial Proteins metabolism, Catalysis, Escherichia coli metabolism, Escherichia coli Proteins metabolism, Ligands, Membrane Proteins metabolism, Methyltransferases metabolism, Serine metabolism, Signal Transduction physiology, Adaptation, Biological physiology, Chemoreceptor Cells metabolism

Abstract

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., Competing Interests: The authors declare no conflict of interest.

Published

2017

21. Signaling complexes control the chemotaxis kinase by altering its apparent rate constant of autophosphorylation.

Author

Pan W, Dahlquist FW, and Hazelbauer GL

Subjects

Amino Acid Motifs, Bacterial Proteins genetics, Binding Sites, Chemotaxis physiology, Escherichia coli genetics, Escherichia coli Proteins genetics, Gene Expression, Histidine Kinase genetics, Kinetics, Ligands, Methyl-Accepting Chemotaxis Proteins genetics, Phosphorylation, Protein Binding, Protein Domains, Protein Multimerization, Receptors, Cell Surface genetics, Recombinant Proteins genetics, Recombinant Proteins metabolism, Signal Transduction, Substrate Specificity, Aspartic Acid metabolism, Bacterial Proteins metabolism, Escherichia coli enzymology, Escherichia coli Proteins metabolism, Histidine Kinase metabolism, Methyl-Accepting Chemotaxis Proteins metabolism, Receptors, Cell Surface metabolism

Abstract

Autophosphorylating histidine kinase CheA is central to signaling in bacterial chemotaxis. The kinase donates its phosphoryl group to two response regulators, CheY that controls flagellar rotation and thus motility and CheB, crucial for sensory adaptation. As measured by coupled CheY phosphorylation, incorporation into signaling complexes activates the kinase ∼1000-fold and places it under control of chemoreceptors. By the same assay, receptors modulate kinase activity ∼100-fold as a function of receptor ligand occupancy and adaptational modification. These changes are the essence of chemotactic signaling. Yet, the enzymatic properties affected by incorporation into signaling complexes, by chemoreceptor ligand binding or by receptor adaptational modification are largely undefined. To investigate, we performed steady-state kinetic analysis of autophosphorylation using a liberated kinase phosphoryl-accepting domain, characterizing kinase alone, in isolated core signaling complexes and in small arrays of core complexes assembled in vitro with receptors contained in isolated native membranes. Autophosphorylation in signaling complexes was measured as a function of ligand occupancy and adaptational modification. Activation by incorporation into signaling complexes and modulation in complexes by ligand occupancy and adaptational modification occurred largely via changes in the apparent catalytic rate constant (k cat ). Changes in the autophosphorylation k cat accounted for most of the ∼1000-fold kinase activation in signaling complexes observed for coupled CheY phosphorylation, and the ∼100-fold inhibition by ligand occupancy or modulation by adaptational modification. Our results indicate no more than a minor role in kinase control for simple sequestration of the autophosphorylation substrate. Instead they indicate direct effects on the active site., (© 2017 The Protein Society.)

Published

2017

22. Co-Folding of a FliF-FliG Split Domain Forms the Basis of the MS:C Ring Interface within the Bacterial Flagellar Motor.

Author

Lynch MJ, Levenson R, Kim EA, Sircar R, Blair DF, Dahlquist FW, and Crane BR

Subjects

Amino Acid Motifs, Bacterial Proteins genetics, Bacterial Proteins metabolism, Binding Sites, Biomechanical Phenomena, Cell Membrane ultrastructure, Cloning, Molecular, Crystallography, X-Ray, Escherichia coli genetics, Escherichia coli metabolism, Flagella ultrastructure, Gene Expression, Membrane Proteins genetics, Membrane Proteins metabolism, Models, Molecular, Protein Binding, Protein Conformation, alpha-Helical, Protein Folding, Protein Interaction Domains and Motifs, Protein Structure, Tertiary, Recombinant Fusion Proteins chemistry, Recombinant Fusion Proteins genetics, Recombinant Fusion Proteins metabolism, Thermotoga maritima ultrastructure, Bacterial Proteins chemistry, Cell Membrane chemistry, Flagella chemistry, Membrane Proteins chemistry, Thermotoga maritima chemistry

Abstract

The interface between the membrane (MS) and cytoplasmic (C) rings of the bacterial flagellar motor couples torque generation to rotation within the membrane. The structure of the C-terminal helices of the integral membrane protein FliF (FliF C ) bound to the N terminal domain of the switch complex protein FliG (FliG N ) reveals that FliG N folds around FliF C to produce a topology that closely resembles both the middle and C-terminal domains of FliG. The interface is consistent with solution-state nuclear magnetic resonance, small-angle X-ray scattering, in vivo interaction studies, and cellular motility assays. Co-folding with FliF C induces substantial conformational changes in FliG N and suggests that FliF and FliG have the same stoichiometry within the rotor. Modeling the FliF C :FliG N complex into cryo-electron microscopy rotor density updates the architecture of the middle and upper switch complex and shows how domain shuffling of a conserved interaction module anchors the cytoplasmic rotor to the membrane., (Copyright © 2017 Elsevier Ltd. All rights reserved.)

Published

2017

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

Author

Pavlova A, Cheng CY, Kinnebrew M, Lew J, Dahlquist FW, and Han S

Subjects

Computer Simulation, Cryoelectron Microscopy, Electron Spin Resonance Spectroscopy, Humans, Kinetics, Magnetic Resonance Spectroscopy, Mutant Proteins chemistry, Protein Structure, Secondary, Protein Subunits chemistry, Spin Labels, Time Factors, tau Proteins ultrastructure, Protein Aggregates, Water chemistry, tau Proteins chemistry

Abstract

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 β-sheet structured species and maintain their stacking order without exchanging their subunits. The population of β-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.

Published

2016

24. Inter-aromatic distances in Geobacter sulfurreducens pili relevant to biofilm charge transport.

Author

Yan H, Chuang C, Zhugayevych A, Tretiak S, Dahlquist FW, and Bazan GC

Subjects

Amino Acid Sequence, Bacterial Proteins chemistry, Electron Transport, Models, Molecular, Molecular Sequence Data, Protein Structure, Secondary, Semiconductors, Biofilms, Fimbriae, Bacterial chemistry, Fimbriae, Bacterial physiology, Geobacter chemistry, Geobacter physiology

Published

2015

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

Author

Maeno A, Sindhikara D, Hirata F, Otten R, Dahlquist FW, Yokoyama S, Akasaka K, Mulder FA, and Kitahara R

Subjects

Carbon Isotopes, Computer Simulation, Hydrophobic and Hydrophilic Interactions, Models, Molecular, Muramidase genetics, Mutation, Nuclear Magnetic Resonance, Biomolecular, Pressure, Protein Conformation, Proton Magnetic Resonance Spectroscopy, Recombinant Proteins chemistry, Recombinant Proteins genetics, Viral Proteins genetics, Water chemistry, Bacteriophage T4, Muramidase chemistry, Viral Proteins chemistry

Abstract

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., (Copyright © 2015 Biophysical Society. Published by Elsevier Inc. All rights reserved.)

Published

2015

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

Author

Kirchhofer ND, Chen X, Marsili E, Sumner JJ, Dahlquist FW, and Bazan GC

Subjects

Electron Transport, Energy Transfer physiology, Equipment Design, Equipment Failure Analysis, Static Electricity, Bioelectric Energy Sources microbiology, Electrodes microbiology, Electrolytes chemistry, Shewanella physiology

Abstract

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.

Published

2014

27. 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.

Author

Wang X, Vallurupalli P, Vu A, Lee K, Sun S, Bai WJ, Wu C, Zhou H, Shea JE, Kay LE, and Dahlquist FW

Subjects

Catalytic Domain, Enzyme Activation, Histidine Kinase, Models, Molecular, Phosphorylation, Protein Multimerization, Bacterial Proteins chemistry, Protein Kinases chemistry, Thermotoga maritima metabolism

Abstract

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.

Published

2014

28. Enzyme-promoted base flipping controls DNA methylation fidelity.

Author

Matje DM, Zhou H, Smith DA, Neely RK, Dryden DT, Jones AC, Dahlquist FW, and Reich NO

Subjects

Bacterial Proteins chemistry, Bacterial Proteins genetics, Bacterial Proteins metabolism, Binding Sites, Catalytic Domain genetics, DNA-Cytosine Methylases genetics, Kinetics, Mutagenesis, Site-Directed, Nuclear Magnetic Resonance, Biomolecular, Protein Conformation, Spectrometry, Fluorescence, Substrate Specificity, DNA chemistry, DNA metabolism, DNA Methylation physiology, DNA-Cytosine Methylases chemistry, DNA-Cytosine Methylases metabolism

Abstract

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.

Published

2013

29. Distal structural elements coordinate a conserved base flipping network.

Author

Matje DM, Krivacic CT, Dahlquist FW, and Reich NO

Subjects

Amino Acid Sequence, Animals, Bacterial Proteins chemistry, Bacterial Proteins genetics, Bacterial Proteins metabolism, Catalytic Domain genetics, Conserved Sequence, DNA (Cytosine-5-)-Methyltransferases genetics, DNA-Cytosine Methylases chemistry, DNA-Cytosine Methylases genetics, DNA-Cytosine Methylases metabolism, Haemophilus enzymology, Haemophilus genetics, Humans, Kinetics, Models, Molecular, Molecular Sequence Data, Mutagenesis, Site-Directed, Nucleic Acid Conformation, Protein Conformation, Sequence Homology, Amino Acid, DNA chemistry, DNA metabolism, DNA (Cytosine-5-)-Methyltransferases chemistry, DNA (Cytosine-5-)-Methyltransferases metabolism

Abstract

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.

Published

2013

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

Author

Ortega DR, Mo G, Lee K, Zhou H, Baudry J, Dahlquist FW, and Zhulin IB

Subjects

Binding Sites, Chemotaxis, Molecular Dynamics Simulation, Mutation, Protein Conformation, Protein Unfolding, Reproducibility of Results, Escherichia coli Proteins chemistry, Escherichia coli Proteins metabolism

Abstract

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.

Published

2013

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

Author

Vartanian AS, Paz A, Fortgang EA, Abramson J, and Dahlquist FW

Subjects

Bacterial Proteins genetics, Crystallography, X-Ray, Flagella chemistry, Flagella genetics, Multiprotein Complexes genetics, Protein Structure, Quaternary, Protein Structure, Tertiary, Salmonella typhimurium genetics, Bacterial Proteins chemistry, Multiprotein Complexes chemistry, Salmonella typhimurium chemistry

Abstract

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.

Published

2012

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

Author

Wang X, Wu C, Vu A, Shea JE, and Dahlquist FW

Subjects

Bacterial Proteins genetics, Membrane Proteins genetics, Methyl-Accepting Chemotaxis Proteins, Mutagenesis, Phosphorylation, Point Mutation, Protein Structure, Tertiary, Bacterial Proteins chemistry, Bacterial Proteins metabolism, Chemotaxis, Membrane Proteins chemistry, Membrane Proteins metabolism, Molecular Dynamics Simulation

Abstract

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.

Published

2012

33. CheA-receptor interaction sites in bacterial chemotaxis.

Author

Wang X, Vu A, Lee K, and Dahlquist FW

Subjects

Bacterial Proteins metabolism, Binding Sites, Chemotaxis, Escherichia coli enzymology, Escherichia coli metabolism, Escherichia coli Proteins chemistry, Escherichia coli Proteins metabolism, Histidine Kinase, Membrane Proteins chemistry, Membrane Proteins metabolism, Methyl-Accepting Chemotaxis Proteins, Nuclear Magnetic Resonance, Biomolecular, Protein Kinases metabolism, Thermotoga maritima metabolism, Bacterial Proteins chemistry, Protein Kinases chemistry, Thermotoga maritima enzymology

Abstract

In bacterial chemotaxis, transmembrane chemoreceptors, the CheA histidine kinase, and the CheW coupling protein assemble into signaling complexes that allow bacteria to modulate their swimming behavior in response to environmental stimuli. Among the protein-protein interactions in the ternary complex, CheA-CheW and CheW-receptor interactions were studied previously, whereas CheA-receptor interaction has been less investigated. Here, we characterize the CheA-receptor interaction in Thermotoga maritima by NMR spectroscopy and validate the identified receptor binding site of CheA in Escherichia coli chemotaxis. We find that CheA interacts with a chemoreceptor in a manner similar to that of CheW, and the receptor binding site of CheA's regulatory domain is homologous to that of CheW. Collectively, the receptor binding sites in the CheA-CheW complex suggest that conformational changes in CheA are required for assembly of the CheA-CheW-receptor ternary complex and CheA activation., (Copyright © 2012 Elsevier Ltd. All rights reserved.)

Published

2012

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

Author

Levenson R, Zhou H, and Dahlquist FW

Subjects

Amino Acid Sequence, Bacterial Proteins genetics, Bacterial Proteins metabolism, Caulobacter crescentus chemistry, Flagella genetics, Flagella metabolism, Membrane Proteins genetics, Membrane Proteins metabolism, Molecular Motor Proteins genetics, Molecular Motor Proteins metabolism, Molecular Sequence Data, Protein Binding, Thermotoga maritima chemistry, Bacterial Proteins chemistry, Flagella chemistry, Membrane Proteins chemistry, Molecular Motor Proteins chemistry

Abstract

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.

Published

2012

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

Author

Mo G, Zhou H, Kawamura T, and Dahlquist FW

Subjects

Escherichia coli Proteins, Histidine Kinase, Kinetics, Methyl-Accepting Chemotaxis Proteins, Models, Molecular, Nuclear Magnetic Resonance, Biomolecular, Protein Structure, Tertiary physiology, Spectrometry, Fluorescence, Bacterial Proteins chemistry, Bacterial Proteins metabolism, Membrane Proteins chemistry, Membrane Proteins metabolism, Protein Kinases chemistry

Abstract

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.

Published

2012

36. The receptor-CheW binding interface in bacterial chemotaxis.

Author

Vu A, Wang X, Zhou H, and Dahlquist FW

Subjects

Binding Sites, Models, Biological, Models, Molecular, Nuclear Magnetic Resonance, Biomolecular, Protein Binding, Protein Structure, Quaternary, Protein Structure, Secondary, Thermotoga maritima genetics, Thermotoga maritima metabolism, Thermotoga maritima physiology, Bacterial Proteins chemistry, Bacterial Proteins metabolism, Chemotaxis genetics, Chemotaxis physiology, Protein Interaction Domains and Motifs physiology, Receptors, Chemokine chemistry, Receptors, Chemokine metabolism

Abstract

The basic structural unit of the signaling complex in bacterial chemotaxis consists of the chemotaxis kinase CheA, the coupling protein CheW, and chemoreceptors. These complexes play an important role in regulating the kinase activity of CheA and in turn controlling the rotational bias of the flagellar motor. Although individual three-dimensional structures of CheA, CheW, and chemoreceptors have been determined, the interaction between chemoreceptor and CheW is still unclear. We used nuclear magnetic resonance to characterize the interaction modes of chemoreceptor and CheW from Thermotoga maritima. We find that chemoreceptor binding surface is located near the highly conserved tip region of the N-terminal helix of the receptor, whereas the binding interface of CheW is placed between the β-strand 8 of domain 1 and the β-strands 1 and 3 of domain 2. The receptor-CheW complex shares a similar binding interface to that found in the "trimer-of-dimers" oligomer interface seen in the crystal structure of cytoplasmic domains of chemoreceptors from Escherichia coli. Based on the association constants inferred from fast exchange chemical shifts associated with receptor-CheW titrations, we estimate that CheW binds about four times tighter to its first binding site of the receptor dimer than to its second binding site. This apparent anticooperativity in binding may reflect the close proximity of the two CheW binding surfaces near the receptor tip or further, complicating the events at this highly conserved region of the receptor. This work describes the first direct observation of the interaction between chemoreceptor and CheW., (Copyright © 2011 Elsevier Ltd. All rights reserved.)

Published

2012

37. The structure and dynamic properties of the complete histidine phosphotransfer domain of the chemotaxis specific histidine autokinase CheA from Thermotoga maritima.

Author

Vu A, Hamel DJ, Zhou H, and Dahlquist FW

Subjects

Chemotaxis, Methyl-Accepting Chemotaxis Proteins, Models, Molecular, Protein Conformation, Structure-Activity Relationship, Bacterial Proteins chemistry, Histidine chemistry, Membrane Proteins chemistry, Thermotoga maritima enzymology

Abstract

The bacterial histidine autokinase CheA contains a histidine phosphotransfer (Hpt) domain that accepts a phosphate from the catalytic domain and donates the phosphate to either target response regulator protein, CheY or CheB. The Hpt domain forms a helix-bundle structure with a conserved four-helix bundle motif and a variable fifth helix. Observation of two nearly equally populated conformations in the crystal structure of a Hpt domain fragment of CheA from Thermotoga maritima containing only the first four helices suggests more mobility in a tightly packed helix bundle structure than previously thought. In order to examine how the structures of Hpt domain homologs may differ from each other particularly in the conformation of the last helix, and whether an alternative conformation exists in the intact Hpt domain in solution, we have solved a high-resolution, solution structure of the CheA Hpt from T. maritima and characterized the backbone dynamics of this protein. The structure contains a four-helix bundle characteristic of histidine phosphotransfer domains. The position and orientation of the fifth helix resembles those in known Hpt domain crystal and solution structures in other histidine kinases. The alternative conformation that was reported in the crystal structure of the CheA Hpt from T. maritima missing the fifth helix is not detected in the solution structure, suggesting a role for the fifth helix in providing stabilizing forces to the overall structure.

Published

2011

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

Author

Bouvignies G, Vallurupalli P, Hansen DF, Correia BE, Lange O, Bah A, Vernon RM, Dahlquist FW, Baker D, and Kay LE

Subjects

Evolution, Molecular, Hydrophobic and Hydrophilic Interactions, Ligands, Protein Binding, Temperature, Bacteriophage T4 enzymology, Bacteriophage T4 genetics, Models, Molecular, Muramidase chemistry, Muramidase genetics, Mutation

Abstract

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.

Published

2011

39. The design involved in PapI and Lrp regulation of the pap operon.

Author

Kawamura T, Vartanian AS, Zhou H, and Dahlquist FW

Subjects

Base Sequence, Binding Sites genetics, Escherichia coli Proteins genetics, Leucine-Responsive Regulatory Protein genetics, Protein Binding, Repressor Proteins genetics, Escherichia coli Proteins metabolism, Gene Expression Regulation, Bacterial, Leucine-Responsive Regulatory Protein metabolism, Operon genetics, Repressor Proteins metabolism, Uropathogenic Escherichia coli genetics

Abstract

The uropathogenic Escherichia coli colonize the host body by attaching themselves to the epithelial cells through the pyelonephritis-associated pili (pap). The expression of the papBA operon is regulated under a reversible phase-variation mechanism, which partitions the population of cells into those that express the pap and others that do not. The two phases of pap expression are the direct consequences of the two distinct DNA-binding modes exhibited by leucine-responsive regulatory protein (Lrp) in the pap promoter region. In the phase-OFF cells, Lrp occupies the binding sites proximal to the transcription start, blocking transcription initiation. In the phase-ON cells, Lrp occupies the binding sites distal to the transcription start and is thought to promote the CAP (catabolite gene activation protein)-directed transcription initiation. Lrp binds to the proximal binding sites more tightly than to the distal sites, and the switching from phase-OFF to phase-ON requires a local co-regulator, PapI. Here, we used PapI and an isolated DNA-binding domain construct of Lrp to show that there is a DNA co-recognition mechanism by which both proteins acquire enhanced affinity to the distal pap site DNA, to which neither of them binds to an appreciable extent without the other. Also, examination of the binding properties of the Lrp DNA-binding domain presented here led us to propose a new sequence alignment of the six pap Lrp-binding sites. New insights into the design of sequences regulating the pap phase variation as revealed by the pap Lrp-binding site sequences are thus defined and discussed., (Copyright © 2011 Elsevier Ltd. All rights reserved.)

Published

2011

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

Author

Matje DM, Coughlin DF, Connolly BA, Dahlquist FW, and Reich NO

Subjects

Amino Acid Sequence, DNA, Bacterial, Escherichia coli, Gene Expression Regulation, Bacterial physiology, Models, Molecular, Protein Conformation, Bacterial Proteins chemistry, Bacterial Proteins metabolism, DNA-Cytosine Methylases chemistry, DNA-Cytosine Methylases metabolism

Abstract

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.

Published

2011

41. No difference in kinetics of tau or histone phosphorylation by CDK5/p25 versus CDK5/p35 in vitro.

Author

Peterson DW, Ando DM, Taketa DA, Zhou H, Dahlquist FW, and Lew J

Subjects

Blotting, Western, Escherichia coli, Humans, In Vitro Techniques, Kinetics, Magnetic Resonance Spectroscopy, Phosphorylation, Histones metabolism, Nerve Tissue Proteins metabolism, Neurons metabolism, tau Proteins metabolism

Abstract

CDK5/p35 is a cyclin-dependent kinase essential for normal neuron function. Proteolysis of the p35 subunit in vivo results in CDK5/p25 that causes neurotoxicity associated with a number of neurodegenerative diseases. Whereas the mechanism by which conversion of p35 to p25 leads to toxicity is unknown, there is common belief that CDK5/p25 is catalytically hyperactive compared to CDK5/p35. Here, we have compared the steady-state kinetic parameters of CDK5/p35 and CDK5/p25 towards both histone H1, the best known substrate for both enzymes, and the microtubule-associated protein, tau, a physiological substrate whose in vivo phosphorylation is relevant to Alzheimer's disease. We show that the kinetics of both enzymes are the same towards either substrate in vitro. Furthermore, both enzymes display virtually identical kinetics towards individual phosphorylation sites in tau monitored by NMR. We conclude that conversion of p35 to p25 does not alter the catalytic efficiency of the CDK5 catalytic subunit by using histone H1 or tau as substrates, and that neurotoxicity associated with CDK5/p25 is unlikely attributable to CDK5 hyperactivation, as measured in vitro.

Published

2010

42. Structural basis for the localization of the chemotaxis phosphatase CheZ by CheAS.

Author

Hao S, Hamel D, Zhou H, and Dahlquist FW

Subjects

Binding Sites, Dimerization, Escherichia coli genetics, Escherichia coli Proteins, Histidine Kinase, Magnetic Resonance Spectroscopy, Methyl-Accepting Chemotaxis Proteins, Models, Molecular, Nitrogen Isotopes, Phosphorylation, Protein Binding, Protein Structure, Tertiary, Protons, Signal Transduction, Bacterial Proteins chemistry, Bacterial Proteins metabolism, Chemotaxis genetics, Escherichia coli metabolism, Membrane Proteins chemistry, Membrane Proteins metabolism

Abstract

CheA-short interacts with CheZ to localize CheZ to cell poles. The fifth helical region (residues 112 to 133) from the phosphotransfer domain of CheA interacts with CheZ and becomes ordered and helical, although it lacks a stable fold in the CheA fragment comprising residues 98 to 150 alone. One CheA molecule binds to one CheZ dimer.

Published

2009

43. The recognition pathway for the DNA cytosine methyltransferase M.HhaI.

Author

Zhou H, Purdy MM, Dahlquist FW, and Reich NO

Subjects

Base Sequence, Catalysis, Catalytic Domain genetics, Crystallography, X-Ray, DNA Methylation genetics, DNA, Bacterial chemistry, DNA, Bacterial genetics, DNA-Binding Proteins chemistry, DNA-Binding Proteins genetics, DNA-Cytosine Methylases genetics, Enzyme Stability genetics, Haemophilus genetics, Protein Binding genetics, Substrate Specificity genetics, DNA-Cytosine Methylases chemistry, Haemophilus enzymology

Abstract

Enzymatic sequence-specific DNA modification involves multiple poorly understood intermediates. DNA methyltransferases like M.HhaI initially bind nonspecific DNA and then selectively bind and modify a unique sequence. High-resolution NMR was used to map conformational changes occurring in M.HhaI upon binding nonspecific DNA, a one base pair altered noncognate DNA sequence, and both hemimethylated and unmethylated cognate DNA sequences. Comparisons with previous NMR studies of the apoenzyme and enzyme-cofactor complex provide snapshots of the pathway to sequence-specific complex formation. Dramatic chemical shift perturbations reaching many distal sites within the protein are detected with cognate DNA, while much smaller changes are observed upon nonspecific and noncognate DNA binding. A cooperative rather than stepwise transition from a nonspecific to a cognate complex is revealed. Furthermore, switching from unmethylated to hemimethylated cognate DNA involves detectable protein conformational changes 20-30 A away from the methyl group, indicating high protein sensitivity and plasticity to DNA modification.

Published

2009

44. Site-specific dynamic nuclear polarization of hydration water as a generally applicable approach to monitor protein aggregation.

Author

Pavlova A, McCarney ER, Peterson DW, Dahlquist FW, Lew J, and Han S

Subjects

Amino Acid Substitution genetics, Amyloid chemistry, Humans, Peptide Fragments chemistry, Peptide Fragments genetics, Protein Binding, Protein Isoforms chemistry, Protein Isoforms genetics, Recombinant Proteins chemistry, Recombinant Proteins genetics, Spin Labels, tau Proteins chemistry, tau Proteins genetics, Electron Spin Resonance Spectroscopy methods, Proteins chemistry, Water chemistry

Abstract

We present a generally applicable approach for monitoring protein aggregation by detecting changes in surface hydration water dynamics and the changes in solvent accessibility of specific protein sites, as protein aggregation proceeds in solution state. This is made possible through the Overhauser dynamic nuclear polarization (DNP) of water interacting with stable nitroxide spin labels tethered to specific proteins sites. This effect is highly localized due to the magnetic dipolar nature of the electron-proton spin interaction, with >80% of their interaction occurring within 5 A between the unpaired electron of the spin label and the proton of water. We showcase our tool on the aggregation of tau proteins, whose fibrillization is linked to neurodegenerative disease pathologies known as taupathies. We demonstrate that the DNP approach to monitor local changes in hydration dynamics with residue specificity and local contrast can distinguish specific and neat protein-protein packing leading to fibers from non-specific protein agglomeration or precipitation. The ability to monitor tau assembly with local, residue-specific, resolution, under ambient conditions and in solution state will help unravel the mechanism and structural characteristics of the gradual process of tau aggregation into amyloid fibers, which remains unclear to this day.

Published

2009

45. A molecular mechanism of bacterial flagellar motor switching.

Author

Dyer CM, Vartanian AS, Zhou H, and Dahlquist FW

Subjects

Bacterial Proteins metabolism, Binding Sites, Membrane Proteins metabolism, Models, Molecular, Nuclear Magnetic Resonance, Biomolecular, Protein Structure, Secondary, Bacterial Proteins chemistry, Membrane Proteins chemistry

Abstract

The high-resolution structures of nearly all the proteins that comprise the bacterial flagellar motor switch complex have been solved; yet a clear picture of the switching mechanism has not emerged. Here, we used NMR to characterize the interaction modes and solution properties of a number of these proteins, including several soluble fragments of the flagellar motor proteins FliM and FliG, and the response-regulator CheY. We find that activated CheY, the switch signal, binds to a previously unidentified region of FliM, adjacent to the FliM-FliM interface. We also find that activated CheY and FliG bind with mutual exclusivity to this site on FliM, because their respective binding surfaces partially overlap. These data support a model of CheY-driven motor switching wherein the binding of activated CheY to FliM displaces the carboxy-terminal domain of FliG (FliGC) from FliM, modulating the FliGC-MotA interaction, and causing the motor to switch rotational sense as required for chemotaxis.

Published

2009

46. A soluble oligomer of tau associated with fiber formation analyzed by NMR.

Author

Peterson DW, Zhou H, Dahlquist FW, and Lew J

Subjects

Alzheimer Disease pathology, Amino Acid Sequence, Humans, Isotope Labeling, Magnetic Resonance Imaging, Magnetic Resonance Spectroscopy, Models, Molecular, Molecular Sequence Data, Nerve Fibers pathology, Neurofibrillary Tangles pathology, Nitrogen Isotopes, Peptide Fragments chemistry, Protein Conformation, Nerve Fibers physiology, tau Proteins chemistry

Abstract

Alzheimer's disease (AD) is characterized by the intracellular accumulation of the neurofibrillary tangles comprised mainly of the microtubule-associated protein, tau. A critical aspect of understanding tangle formation is to understand the transition of soluble monomeric tau into mature fibrils by characterizing the structure of intermediates along the aggregation pathway. We have carried out multidimensional NMR studies on a C-terminal fragment of human tau (tau (187)) to gain structural insight into the aggregation process. To specifically monitor intermolecular interaction between tau molecules in solution, we combined (15)N- and (14)N-labeled tau, the latter of which was modified with a paramagnetic nitroxide spin label (MTSL). Paramagnetic relaxation enhancement (PRE) of (15)N-tau by interaction with MTSL- (14)N-tau allowed identification of low molecular weight oligomers of tau (187) that formed in response to heparin-induced aggregation. Two regions, VQIINK (280) and VQIVYK (311), were exclusively broadened by MTSL located at varied positions in the tau molecule. We propose that soluble oligomers of tau (187) are generated via intermolecular interactions at these motifs triggered by heparin addition. However, the associated line broadening at these motifs cannot be due to interaction between tau (187) and heparin directly. Instead, these specific interactions necessarily occur between tau molecules and are intermolecular in nature. Our data support the idea that VQIINK (280) and VQIVYK (311) are the major, if not sole, critical regions that directly mediate intermolecular contact between tau molecules during the early phases of aggregation.

Published

2008

47. Protein-DNA chimeras for single molecule mechanical folding studies with the optical tweezers.

Author

Cecconi C, Shank EA, Dahlquist FW, Marqusee S, and Bustamante C

Subjects

Computer Simulation, Models, Chemical, Models, Molecular, Molecular Probe Techniques, Protein Conformation, Stress, Mechanical, DNA chemistry, DNA ultrastructure, DNA-Binding Proteins chemistry, DNA-Binding Proteins ultrastructure, Micromanipulation methods, Optical Tweezers, Protein Folding

Abstract

Here we report on a method that extends the study of the mechanical behavior of single proteins to the low force regime of optical tweezers. This experimental approach relies on the use of DNA handles to specifically attach the protein to polystyrene beads and minimize the non-specific interactions between the tethering surfaces. The handles can be attached to any exposed pair of cysteine residues. Handles of different lengths were employed to mechanically manipulate both monomeric and polymeric proteins. The low spring constant of the optical tweezers enabled us to monitor directly refolding events and fluctuations between different molecular structures in quasi-equilibrium conditions. This approach, which has already yielded important results on the refolding process of the protein RNase H (Cecconi et al. in Science 309: 2057-2060, 2005), appears robust and widely applicable to any protein engineered to contain a pair of reactive cysteine residues. It represents a new strategy to study protein folding at the single molecule level, and should be applicable to a range of problems requiring tethering of protein molecules.

Published

2008

48. A theory of protein dynamics to predict NMR relaxation.

Author

Caballero-Manrique E, Bray JK, Deutschman WA, Dahlquist FW, and Guenza MG

Subjects

Computer Simulation, Kinetics, Protein Conformation, Algorithms, Crystallography methods, Magnetic Resonance Spectroscopy methods, Models, Chemical, Models, Molecular, Proteins chemistry, Proteins ultrastructure

Abstract

We present a theoretical, site-specific, approach to predict protein subunit correlation times, as measured by NMR experiments of (1)H-(15)N nuclear Overhauser effect, spin-lattice relaxation, and spin-spin relaxation. Molecular dynamics simulations are input to our equation of motion for protein dynamics, which is solved analytically to produce the eigenvalues and the eigenvectors that specify the NMR parameters. We directly compare our theoretical predictions to experiments and to simulation data for the signal transduction chemotaxis protein Y (CheY), which regulates the swimming response of motile bacteria. Our theoretical results are in good agreement with both simulations and experiments, without recourse to adjustable parameters. The theory is general, since it allows calculations of any dynamical property of interest. As an example, we present theoretical calculations of NMR order parameters and x-ray Debye-Waller temperature factors; both quantities show good agreement with experimental data.

Published

2007

49. Simultaneous high gain and wide dynamic range in a model of bacterial chemotaxis.

Author

Park MJ, Dahlquist FW, and Doyle FJ 3rd

Subjects

Computer Simulation, Escherichia coli Proteins, Histidine Kinase, Methyl-Accepting Chemotaxis Proteins, Bacterial Proteins metabolism, Chemotactic Factors metabolism, Chemotaxis physiology, Escherichia coli physiology, Membrane Proteins metabolism, Models, Biological

Abstract

Mathematical modelling and sensitivity analysis of the signal transduction pathway underlying chemotaxis in Escherichia coli suggests a mechanism for high sensitivity over a dynamic range of five orders of magnitude. The analysis reveals that the enhancement in sensing ability occurs in the signal receiving module that is comprised of ligand binding, change of occupancy and change of receptor activities. The clustering of receptors contributes to the signal capability by exploiting interactions between receptors for the activity change. The role of the autophosphorylation of the histidine kinase CheA and the phosphotransfer to the response regulator protein CheY is to relay the signal to the cell's motor apparatus at little expense to the sensitivity at low stimuli. The results also provide insight on the values of kinetic parameters that maximise the efficiency of the signalling pathway.

Published

2007

50. The role of high affinity non-specific DNA binding by Lrp in transcriptional regulation and DNA organization.

Author

Peterson SN, Dahlquist FW, and Reich NO

Subjects

Amino Acid Sequence, Binding Sites, Conserved Sequence, DNA, Bacterial chemistry, DNA, Bacterial genetics, Escherichia coli Proteins genetics, Leucine metabolism, Molecular Sequence Data, Repressor Proteins genetics, Repressor Proteins metabolism, Sequence Alignment, Transcription Factors genetics, Transcription Factors metabolism, Transcription, Genetic, DNA, Bacterial metabolism, Escherichia coli Proteins chemistry, Escherichia coli Proteins metabolism, Gene Expression Regulation, Bacterial, Leucine-Responsive Regulatory Protein chemistry, Leucine-Responsive Regulatory Protein metabolism

Abstract

Transcriptional regulatory proteins typically bind specific DNA sequences with approximately 10(3)-10(7)-fold higher affinity than non-specific DNA and this discrimination is essential for their in vivo function. Here we show that the bacterial leucine-responsive regulatory protein (Lrp) does not follow this trend and has a approximately 20-400-fold binding discrimination between specific and non-specific DNA sequences. We suggest that the dual function of Lrp to regulate genes and to organize DNA utilizes this unique property. A approximately 20-fold decrease in binding affinity from specific DNA is dependent upon cryptic binding sites, including the sequence GN(2-3)TTT and A-tracts. Removal of these sites still results in high binding affinity, only approximately 70-fold weaker than that of specific sites. Similar to Lrp's binding of specific sites in the pap and ilvIH promoters, Lrp binds cooperatively to non-specific DNA; thus, protein/protein interactions are important for both specific and non-specific DNA binding. When considering this cooperativity of Lrp binding, the binding selectivity to specific sites may increase to a maximum of approximately 400-fold. Neither leucine nor the pap-specific local regulator PapI alter Lrp's non-specific binding affinity or cooperative binding of non-specific DNA. We hypothesize that Lrp combines low sequence discrimination and relatively high intracellular protein concentrations to ensure its ability to regulate the transcription of specific genes while also functioning as a nucleoid-associated protein. Modeling of Lrp binding data and comparison to other proteins with regulatory and nucleoid-associated properties suggests similar mechanisms.

Published

2007