Your search keyword '"Crane BR"' showing total 44 results

1. Dissecting the Interaction between Cryptochrome and Timeless Reveals Underpinnings of Light-Dependent Recognition.

Author

Schneps CM, Dunleavy R, and Crane BR

Abstract

Circadian rhythms are determined by cell-autonomous transcription-translation feedback loops that entrain to environmental stimuli. In the model circadian clock of Drosophila melanogaster , the clock is set by the light-induced degradation of the core oscillator protein timeless (TIM) by the principal light-sensor cryptochrome (CRY). The cryo-EM structure of CRY bound to TIM revealed that within the extensive CRY:TIM interface, the TIM N-terminus binds into the CRY FAD pocket, in which FAD and the associated phosphate-binding loop (PBL) undergo substantial rearrangement. The TIM N-terminus involved in CRY binding varies in isoforms that facilitate the adaptation of flies to different light environments. Herein, we demonstrate, through peptide binding assays and pulsed-dipolar electron spin resonance (ESR) spectroscopy, that the TIM N-terminal peptide alone exhibits light-dependent binding to CRY and that the affinity of the interaction depends on the initiating methionine residue. Extensions to the TIM N-terminus that mimic less light-sensitive variants have substantially reduced interactions with CRY. Substitutions of CRY residues that couple to the flavin rearrangement in the CRY:TIM complex have dramatic effects on CRY light activation. CRY residues Arg237 on α8, Asn253, and Gln254 on the PBL are critical for the release of the CRY autoinhibitory C-terminal tail (CTT) and subsequent TIM binding. These key light-responsive elements of CRY are well conserved throughout Type I cryptochromes of invertebrates but not by cryptochromes of chordates and plants, which likely utilize a distinct light-activation mechanism.

Published

2024

2. Enzymatic Spin-Labeling of Protein N- and C-Termini for Electron Paramagnetic Resonance Spectroscopy.

Author

Dunleavy R, Chandrasekaran S, and Crane BR

Abstract

Electron paramagnetic resonance (EPR) spectroscopy is a powerful tool for investigating the structure and dynamics of proteins. The introduction of paramagnetic moieties at specific positions in a protein enables precise measurement of local structure and dynamics. This technique, termed site-directed spin-labeling, has traditionally been performed using cysteine-reactive radical-containing probes. However, large proteins are more likely to contain multiple cysteine residues and cysteine labeling at specific sites may be infeasible or impede function. To address this concern, we applied three peptide-ligating enzymes (sortase, asparaginyl endopeptidase, and inteins) for nitroxide labeling of N- and C-termini of select monomeric and dimeric proteins. Continuous wave and pulsed EPR (double electron electron resonance) experiments reveal specific attachment of nitroxide probes to ether N-termini (OaAEP1) or C-termini (sortase and intein) across three test proteins (CheY, CheA, and iLOV), thereby enabling a straightforward, highly specific, and general method for protein labeling. Importantly, the linker length (3, 5, and 9 residues for OaAEP1, intein, and sortase reactions, respectively) between the probe and the target protein has a large impact on the utility of distance measurements by pulsed EPR, with longer linkers leading to broader distributions. As these methods are only dependent on accessible N- and C-termini, we anticipate application to a wide range of protein targets for biomolecular EPR spectroscopy.

Published

2023

3. Interdomain Linkers Regulate Histidine Kinase Activity by Controlling Subunit Interactions.

Author

Maschmann Z, Chandrasekaran S, Chua TK, and Crane BR

Subjects

Histidine Kinase metabolism, Methyl-Accepting Chemotaxis Proteins genetics, Methyl-Accepting Chemotaxis Proteins chemistry, Models, Molecular, Thermotoga maritima metabolism, Chemotaxis, Bacterial Proteins chemistry, Escherichia coli Proteins chemistry

Abstract

Bacterial chemoreceptors regulate the cytosolic multidomain histidine kinase CheA through largely unknown mechanisms. Residue substitutions in the peptide linkers that connect the P4 kinase domain to the P3 dimerization and P5 regulatory domain affect CheA basal activity and activation. To understand the role that these linkers play in CheA activity, the P3-to-P4 linker (L3) and P4-to-P5 linker (L4) were extended and altered in variants of Thermotoga maritima ( Tm ) CheA. Flexible extensions of the L3 and L4 linkers in CheA-LV1 (linker variant 1) allowed for a well-folded kinase domain that retained wild-type (WT)-like binding affinities for nucleotide and normal interactions with the receptor-coupling protein CheW. However, CheA-LV1 autophosphorylation activity registered ∼50-fold lower compared to WT. Neither a WT nor LV1 dimer containing a single P4 domain could autophosphorylate the P1 substrate domain. Autophosphorylation activity was rescued in variants with extended L3 and L4 linkers that favor helical structure and heptad spacing. Autophosphorylation depended on linker spacing and flexibility and not on sequence. Pulse-dipolar electron-spin resonance (ESR) measurements with spin-labeled adenosine 5'-triphosphate (ATP) analogues indicated that CheA autophosphorylation activity inversely correlated with the proximity of the P4 domains within the dimers of the variants. Despite their separation in primary sequence and space, the L3 and L4 linkers also influence the mobility of the P1 substrate domains. In all, interactions of the P4 domains, as modulated by the L3 and L4 linkers, affect domain dynamics and autophosphorylation of CheA, thereby providing potential mechanisms for receptors to regulate the kinase.

Published

2022

4. Why Do Most Aromatics Fail to Support Hole Hopping in the Cytochrome c Peroxidase-Cytochrome c Complex?

Author

Ru X, Crane BR, Zhang P, and Beratan DN

Subjects

Cytochromes c genetics, Cytochromes c metabolism, Electron Transport, Kinetics, Oxidation-Reduction, Cytochrome-c Peroxidase genetics, Cytochrome-c Peroxidase metabolism

Abstract

Electron transport through aromatic species (especially tryptophan and tyrosine) plays a central role in water splitting, redox signaling, oxidative damage protection, and bioenergetics. The cytochrome c peroxidase (CcP)-cytochrome c (Cc) complex (CcP:Cc) is used widely to study interprotein electron transfer (ET) mechanisms. Tryptophan 191 (Trp191) of CcP supports hole hopping charge recombination in the CcP:Cc complex. Experimental studies find that when Trp191 is substituted by tyrosine, phenylalanine, or redox-active aniline derivatives bound in the W191G cavity, enzymatic activity and charge recombination rates both decrease. Theoretical analysis of these CcP:Cc complexes finds that the ET kinetics depend strongly on the chemistry of the modified Trp site. The computed electronic couplings in the W191F and W191G species are orders of magnitude smaller than in the native protein, due largely to the absence of a hopping intermediate and the large tunneling distance. Small molecules bound in the W191G cavity are weakly coupled electronically to the Cc heme, and the structural disorder of the guest molecule in the binding pocket may contribute further to the lack of enzymatic activity. The couplings in W191Y are not substantially weakened compared to the native species, but the redox potential difference for tyrosine vs tryptophan oxidation accounts for the slower rate in the Tyr mutant. Thus, theoretical analysis explains why only the native Trp supports rapid hole hopping in the CcP:Cc complex. Favorable free energies and electronic couplings are essential for establishing an efficient hole hopping relay in this protein-protein complex.

Published

2021

5. Dph3 Enables Aerobic Diphthamide Biosynthesis by Donating One Iron Atom to Transform a [3Fe-4S] to a [4Fe-4S] Cluster in Dph1-Dph2.

Author

Zhang Y, Su D, Dzikovski B, Majer SH, Coleman R, Chandrasekaran S, Fenwick MK, Crane BR, Lancaster KM, Freed JH, and Lin H

Subjects

Dithionite metabolism, Histidine biosynthesis, Iron chemistry, Iron-Sulfur Proteins chemistry, Peptide Elongation Factor 2 metabolism, Repressor Proteins chemistry, S-Adenosylmethionine metabolism, Saccharomyces cerevisiae enzymology, Saccharomyces cerevisiae Proteins chemistry, Histidine analogs & derivatives, Iron-Sulfur Proteins metabolism, Repressor Proteins metabolism, Saccharomyces cerevisiae Proteins metabolism

Abstract

All radical S -adenosylmethionine (radical-SAM) enzymes, including the noncanonical radical-SAM enzyme diphthamide biosynthetic enzyme Dph1-Dph2, require at least one [4Fe-4S](Cys) 3 cluster for activity. It is well-known in the radical-SAM enzyme community that the [4Fe-4S](Cys) 3 cluster is extremely air-sensitive and requires strict anaerobic conditions to reconstitute activity in vitro. Thus, how such enzymes function in vivo in the presence of oxygen in aerobic organisms is an interesting question. Working on yeast Dph1-Dph2, we found that consistent with the known oxygen sensitivity, the [4Fe-4S] cluster is easily degraded into a [3Fe-4S] cluster. Remarkably, the small iron-containing protein Dph3 donates one Fe atom to convert the [3Fe-4S] cluster in Dph1-Dph2 to a functional [4Fe-4S] cluster during the radical-SAM enzyme catalytic cycle. This mechanism to maintain radical-SAM enzyme activity in aerobic environments is likely general, and Dph3-like proteins may exist to keep other radical-SAM enzymes functional in aerobic environments.

Published

2021

6. Peripheral Methionine Residues Impact Flavin Photoreduction and Protonation in an Engineered LOV Domain Light Sensor.

Author

Yee EF, Oldemeyer S, Böhm E, Ganguly A, York DM, Kottke T, and Crane BR

Abstract

Proton-coupled electron transfer reactions play critical roles in many aspects of sensory phototransduction. In the case of flavoprotein light sensors, reductive quenching of flavin excited states initiates chemical and conformational changes that ultimately transmit light signals to downstream targets. These reactions generally require neighboring aromatic residues and proton-donating side chains for rapid and coordinated electron and proton transfer to flavin. Although photoreduction of flavoproteins can produce either the anionic (ASQ) or neutral semiquinone (NSQ), the factors that favor one over the other are not well understood. Here we employ a biologically active variant of the light-oxygen-voltage (LOV) domain protein VVD devoid of the adduct-forming Cys residue (VVD-III) to probe the mechanism of flavin photoreduction and protonation. A series of isosteric and conservative residue replacements studied by rate measurements, fluorescence quantum yields, FTIR difference spectroscopy, and molecular dynamics simulations indicate that tyrosine residues facilitate charge recombination reactions that limit sustained flavin reduction, whereas methionine residues facilitate radical propagation and quenching and also gate solvent access for flavin protonation. Replacement of a single surface Met residue with Leu favors formation of the ASQ over the NSQ and desensitizes photoreduction to oxidants. In contrast, increasing site hydrophilicity by Gln substitution promotes rapid NSQ formation and weakens the influence of the redox environment. Overall, the photoreactivity of VVD-III can be understood in terms of redundant electron donors, internal hole quenching, and coupled proton transfer reactions that all depend upon protein conformation, dynamics, and solvent penetration.

Published

2021

7. Tuning Radical Relay Residues by Proton Management Rescues Protein Electron Hopping.

Author

Yee EF, Dzikovski B, and Crane BR

Subjects

Amino Acid Substitution, Hydrogen Bonding, Oxidation-Reduction, Saccharomyces cerevisiae enzymology, Cytochrome-c Peroxidase chemistry, Protons, Saccharomyces cerevisiae Proteins chemistry, Tyrosine chemistry

Abstract

Transient tyrosine and tryptophan radicals play key roles in the electron transfer (ET) reactions of photosystem (PS) II, ribonucleotide reductase (RNR), photolyase, and many other proteins. However, Tyr and Trp are not functionally interchangeable, and the factors controlling their reactivity are often unclear. Cytochrome c peroxidase (CcP) employs a Trp191 •+ radical to oxidize reduced cytochrome c ( Cc ). Although a Tyr191 replacement also forms a stable radical, it does not support rapid ET from Cc . Here we probe the redox properties of CcP Y191 by non-natural amino acid substitution, altering the ET driving force and manipulating the protic environment of Y191. Higher potential fluorotyrosine residues increase ET rates marginally, but only addition of a hydrogen bond donor to Tyr191 • (via Leu232His or Glu) substantially alters activity by increasing the ET rate by nearly 30-fold. ESR and ESEEM spectroscopies, crystallography, and pH-dependent ET kinetics provide strong evidence for hydrogen bond formation to Y191 • by His232/Glu232. Rate measurements and rapid freeze quench ESR spectroscopy further reveal differences in radical propagation and Cc oxidation that support an increased Y191 • formal potential of ∼200 mV in the presence of E232. Hence, Y191 inactivity results from a potential drop owing to Y191 •+ deprotonation. Incorporation of a well-positioned base to accept and donate back a hydrogen bond upshifts the Tyr • potential into a range where it can effectively oxidize Cc . These findings have implications for the Y Z /Y D radicals of PS II, hole-hopping in RNR and cryptochrome, and engineering proteins for long-range ET reactions.

Published

2019

8. Design, Validation, and Application of an Enzyme-Coupled Hydrogen Sulfide Detection Assay.

Author

Lynch MJ and Crane BR

Subjects

Research Design, Treponema denticola enzymology, Bacterial Proteins metabolism, Cysteine analysis, Cysteine Synthase metabolism, Enzyme Assays instrumentation, Enzyme Assays methods, Escherichia coli Proteins metabolism, Fluorescence, Hydrogen Sulfide analysis

Abstract

Hydrogen sulfide (H 2 S) is a key metabolite in biosynthesis and is increasingly being recognized as an essential gasotransmitter. Owing to its diffusible and reactive nature, H 2 S can be difficult to quantify, particularly in situ. Although several detection schemes are available, they have drawbacks. In efforts to quantify sulfide release in the cross-linking reaction of the flagellar protein FlgE, we developed an enzyme-coupled sulfide detection assay using the Escherichia coli O-acetylserine sulfhydrylase enzyme CysM. Conversion of HS - to l-cysteine via CysM followed by derivatization with the thiol-specific fluorescent dye 7-diethylamino-3-(4-maleimidophenyl)-4-methylcoumarin enables for facile detection and quantification of H 2 S by fluorescent HPLC. The assay was validated by comparison to the well-established methylene blue sulfide detection assay and the robustness demonstrated by interference assays in the presence of common thiols such as glutathione, 2-mercaptoethanol, dithiothreitol, and l-methionine, as well as a range of anions. We then applied the assay to the aforementioned lysinoalanine cross-linking by the Treponema denticola flagellar hook protein FlgE. Overall, unlike previously reported H 2 S detection methods, the assay provides a biologically compatible platform to accurately and specifically measure hydrogen sulfide in situ, even when it is produced on long time scales.

Published

2019

9. Site-Specific Incorporation of a Cu 2+ Spin Label into Proteins for Measuring Distances by Pulsed Dipolar Electron Spin Resonance Spectroscopy.

Author

Merz GE, Borbat PP, Muok AR, Srivastava M, Bunck DN, Freed JH, and Crane BR

Subjects

Bacterial Proteins chemistry, Bacterial Proteins genetics, Bacterial Proteins isolation & purification, Bacterial Proteins metabolism, Binding Sites, Cyclic N-Oxides chemistry, Electron Spin Resonance Spectroscopy methods, Escherichia coli genetics, Green Fluorescent Proteins chemistry, Green Fluorescent Proteins genetics, Histidine Kinase chemistry, Histidine Kinase genetics, Histidine Kinase isolation & purification, Histidine Kinase metabolism, Mesylates chemistry, Methyl-Accepting Chemotaxis Proteins chemistry, Methyl-Accepting Chemotaxis Proteins genetics, Methyl-Accepting Chemotaxis Proteins isolation & purification, Methyl-Accepting Chemotaxis Proteins metabolism, Proof of Concept Study, Protein Binding, Protein Domains, Pyrazoles chemical synthesis, Thermotoga maritima chemistry, Thermotoga maritima genetics, Tyrosine chemical synthesis, Tyrosine genetics, Copper chemistry, Pyrazoles chemistry, Spin Labels, Tyrosine analogs & derivatives

Abstract

Pulsed dipolar electron spin resonance spectroscopy (PDS) is a powerful tool for measuring distances in solution-state macromolecules. Paramagnetic metal ions, such as Cu 2+ , are used as spin probes because they can report on metalloprotein features and can be spectroscopically distinguished from traditional nitroxide (NO)-based labels. Here, we demonstrate site-specific incorporation of Cu 2+ into non-metalloproteins through the use of a genetically encodable non-natural amino acid, 3-pyrazolyltyrosine (PyTyr). We first incorporate PyTyr in cyan fluorescent protein to measure Cu 2+ -to-NO distances and examine the effects of solvent conditions on Cu 2+ binding and protein aggregation. We then apply the method to characterize the complex formed by the histidine kinase CheA and its target response regulator CheY. The X-ray structure of CheY-PyTyr confirms Cu labeling at PyTyr but also reveals a secondary Cu site. Cu 2+ -to-NO and Cu 2+ -to-Cu 2+ PDS measurements of CheY-PyTyr with nitroxide-labeled CheA provide new insights into the conformational landscape of the phosphotransfer complex and have implications for kinase regulation.

Published

2018

10. Glutamine Amide Flip Elicits Long Distance Allosteric Responses in the LOV Protein Vivid.

Author

Ganguly A, Thiel W, and Crane BR

Subjects

Allosteric Regulation, Amides chemistry, Fungal Proteins chemistry, Glutamine chemistry, Molecular Conformation, Molecular Dynamics Simulation, Thermodynamics, Amides metabolism, Fungal Proteins metabolism, Glutamine metabolism

Abstract

Light-oxygen-voltage (LOV) domains sense blue light through the photochemical formation of a cysteinyl-flavin covalent adduct. Concurrent protonation at the flavin N5 position alters the hydrogen bonding interactions of an invariant Gln residue that has been proposed to flip its amide side chain as a critical step in the propagation of conformational change. Traditional molecular dynamics (MD) and replica-exchange MD (REMD) simulations of the well-characterized LOV protein Vivid (VVD) demonstrate that the Gln182 amide indeed reorients by ∼180° in response to either adduct formation or reduction of the isoalloxazine ring to the neutral semiquinone, both of which involve N5 protonation. Free energy simulations reveal that the relative free energies of the flipped Gln conformation and the flipping barrier are significantly lower in the light-adapted state. The Gln182 flip stabilizes an important hinge-bβ region between the PAS β-sheet and the N-terminal cap helix that in turn destabilizes an N-terminal latch region against the PAS core. Release of the latch, observed both experimentally and in the simulations, is known to mediate light-induced VVD dimerization. This computational study of a LOV protein, unprecedented in its agreement with experiment, provides an atomistic view of long-range allosteric coupling in a photoreceptor.

Published

2017

11. Constraints on the Radical Cation Center of Cytochrome c Peroxidase for Electron Transfer from Cytochrome c.

Author

Payne TM, Yee EF, Dzikovski B, and Crane BR

Subjects

Amino Acid Substitution, Binding Sites genetics, Cations chemistry, Crystallography, X-Ray, Cytochrome-c Peroxidase genetics, Electron Transport, Free Radicals chemistry, Kinetics, Ligands, Models, Molecular, Mutagenesis, Site-Directed, Photochemical Processes, Protein Conformation, Recombinant Proteins chemistry, Recombinant Proteins genetics, Recombinant Proteins metabolism, Cytochrome-c Peroxidase chemistry, Cytochrome-c Peroxidase metabolism, Cytochromes c chemistry, Cytochromes c metabolism

Abstract

The tryptophan 191 cation radical of cytochrome c peroxidase (CcP) compound I (Cpd I) mediates long-range electron transfer (ET) to cytochrome c (Cc). Here we test the effects of chemical substitution at position 191. CcP W191Y forms a stable tyrosyl radical upon reaction with peroxide and produces spectral properties similar to those of Cpd I but has low reactivity toward reduced Cc. CcP W191G and W191F variants also have low activity, as do redox ligands that bind within the W191G cavity. Crystal structures of complexes between Cc and CcP W191X (X = Y, F, or G), as well as W191G with four bound ligands reveal similar 1:1 association modes and heme pocket conformations. The ligands display structural disorder in the pocket and do not hydrogen bond to Asp235, as does Trp191. Well-ordered Tyr191 directs its hydroxyl group toward the porphyrin ring, with no basic residue in the range of interaction. CcP W191X (X = Y, F, or G) variants substituted with zinc-porphyrin (ZnP) undergo photoinduced ET with Cc(III). Their slow charge recombination kinetics that result from loss of the radical center allow resolution of difference spectra for the charge-separated state [ZnP(+), Cc(II)]. The change from a phenyl moiety at position 191 in W191F to a water-filled cavity in W191G produces effects on ET rates much weaker than the effects of the change from Trp to Phe. Low net reactivity of W191Y toward Cc(II) derives either from the inability of ZnP(+) or the Fe-CcP ferryl to oxidize Tyr or from the low potential of the resulting neutral Tyr radical.

Published

2016

12. Preformed Soluble Chemoreceptor Trimers That Mimic Cellular Assembly States and Activate CheA Autophosphorylation.

Author

Greenswag AR, Li X, Borbat PP, Samanta D, Watts KJ, Freed JH, and Crane BR

Subjects

Bacterial Proteins genetics, Bacterial Proteins metabolism, Escherichia coli genetics, Escherichia coli metabolism, Escherichia coli Proteins genetics, Escherichia coli Proteins metabolism, Histidine Kinase, Membrane Proteins genetics, Membrane Proteins metabolism, Methyl-Accepting Chemotaxis Proteins, Methyltransferases chemistry, Methyltransferases genetics, Methyltransferases metabolism, Protein Structure, Quaternary, Protein Structure, Tertiary, Receptors, Cell Surface genetics, Receptors, Cell Surface metabolism, Bacterial Proteins chemistry, Escherichia coli chemistry, Escherichia coli Proteins chemistry, Membrane Proteins chemistry, Protein Multimerization, Receptors, Cell Surface chemistry

Abstract

Bacterial chemoreceptors associate with the histidine kinase CheA and coupling protein CheW to form extended membrane arrays that receive and transduce environmental signals. A receptor trimers-of-dimers resides at each vertex of the hexagonal protein lattice. CheA is fully activated and regulated when it is integrated into the receptor assembly. To mimic these states in solution, we have engineered chemoreceptor cytoplasmic kinase-control modules (KCMs) based on the Escherichia coli aspartate receptor Tar that are covalently fused and trimerized by a foldon domain (Tar(FO)). Small-angle X-ray scattering, multi-angle light scattering, and pulsed-dipolar electron spin resonance spectroscopy of spin-labeled proteins indicate that the Tar(FO) modules assemble into homogeneous trimers wherein the protein interaction regions closely associate at the end opposite to the foldon domains. The Tar(FO) variants greatly increase the saturation levels of phosphorylated CheA (CheA-P), indicating that the association with a trimer of receptor dimers changes the fraction of active kinase. However, the rate constants for CheA-P formation with the Tar variants are low compared to those for autophosphorylation by free CheA, and net phosphotransfer from CheA to CheY does not increase commensurately with CheA autophosphorylation. Thus, the Tar variants facilitate slow conversion to an active form of CheA that then undergoes stable autophosphorylation and is capable of subsequent phosphotransfer to CheY. Free CheA is largely incapable of phosphorylation but contains a small active fraction. Addition of Tar(FO) to CheA promotes a planar conformation of the regulatory domains consistent with array models for the assembly state of the ternary complex and different from that observed with a single inhibitory receptor. Introduction of Tar(FO) into E. coli cells activates endogenous CheA to produce increased clockwise flagellar rotation, with the effects increasing in the presence of the chemotaxis methylation system (CheB/CheR). Overall, the Tar(FO) modules demonstrate that trimerized signaling tips self-associate, bind CheA and CheW, and facilitate conversion of CheA to an active conformation.

Published

2015

13. Enzymatic and cryoreduction EPR studies of the hydroxylation of methylated N(ω)-hydroxy-L-arginine analogues by nitric oxide synthase from Geobacillus stearothermophilus.

Author

Davydov R, Labby KJ, Chobot SE, Lukoyanov DA, Crane BR, Silverman RB, and Hoffman BM

Subjects

Animals, Arginine chemistry, Arginine metabolism, Bacterial Proteins chemistry, Bacterial Proteins genetics, Citrulline chemistry, Citrulline metabolism, Cold Temperature, Electron Spin Resonance Spectroscopy, Hydrogen Peroxide chemistry, Hydroxylation, Isomerism, Kinetics, Methylation, Mice, Nitric Oxide chemistry, Nitric Oxide metabolism, Nitric Oxide Synthase chemistry, Nitric Oxide Synthase genetics, Nitric Oxide Synthase Type II chemistry, Nitric Oxide Synthase Type II genetics, Nitric Oxide Synthase Type II metabolism, Oxidation-Reduction, Protein Stability, Recombinant Proteins chemistry, Recombinant Proteins metabolism, Substrate Specificity, Arginine analogs & derivatives, Bacterial Proteins metabolism, Biocatalysis, Geobacillus stearothermophilus enzymology, Models, Molecular, Nitric Oxide Synthase metabolism

Abstract

Nitric oxide synthase (NOS) catalyzes the conversion of L-arginine to L-citrulline and NO in a two-step process involving the intermediate N(ω)-hydroxy-L-arginine (NHA). It was shown that Cpd I is the oxygenating species for L-arginine; the hydroperoxo ferric intermediate is the reactive intermediate with NHA. Methylation of the N(ω)-OH and N(ω)-H of NHA significantly inhibits the conversion of NHA into NO and L-citrulline by mammalian NOS. Kinetic studies now show that N(ω)-methylation of NHA has a qualitatively similar effect on H₂O₂-dependent catalysis by bacterial gsNOS. To elucidate the effect of methylating N(ω)-hydroxy L-arginine on the properties and reactivity of the one-electron-reduced oxy-heme center of NOS, we have applied cryoreduction/annealing/EPR/ENDOR techniques. Measurements of solvent kinetic isotope effects during 160 K cryoannealing cryoreduced oxy-gsNOS/NHA confirm the hydroperoxo ferric intermediate as the catalytically active species of step two. Product analysis for cryoreduced samples with methylated NHA's, NHMA, NMOA, and NMMA, annealed to 273 K, show a correlation of yields of L-citrulline with the intensity of the g 2.26 EPR signal of the peroxo ferric species trapped at 77 K, which converts to the reactive hydroperoxo ferric state. There is also a correlation between the yield of L-citrulline in these experiments and k(obs) for the H₂O₂-dependent conversion of the substrates by gsNOS. Correspondingly, no detectable amount of cyanoornithine, formed when Cpd I is the reactive species, was found in the samples. Methylation of the NHA guanidinium N(ω)-OH and N(ω)-H inhibits the second NO-producing reaction by favoring protonation of the ferric-peroxo to form unreactive conformers of the ferric-hydroperoxo state. It is suggested that this is caused by modification of the distal-pocket hydrogen-bonding network of oxy gsNOS and introduction of an ordered water molecule that facilitates delivery of the proton(s) to the one-electron-reduced oxy-heme moiety. These results illustrate how variations in the properties of the substrate can modulate the reactivity of a monooxygenase.

Published

2014

14. Distance-independent charge recombination kinetics in cytochrome c-cytochrome c peroxidase complexes: compensating changes in the electronic coupling and reorganization energies.

Author

Jiang N, Kuznetsov A, Nocek JM, Hoffman BM, Crane BR, Hu X, and Beratan DN

Subjects

Cytochrome-c Peroxidase chemistry, Cytochromes c chemistry, Cytochromes c genetics, Electron Transport, Electrons, Heme chemistry, Kinetics, Models, Molecular, Quantum Theory, Solvents chemistry, Thermodynamics, Zinc chemistry, Cytochrome-c Peroxidase metabolism, Cytochromes c metabolism

Abstract

Charge recombination rate constants vary no more than 3-fold for interprotein ET in the Zn-substituted wild type (WT) cytochrome c peroxidase (CcP):cytochrome c (Cc) complex and in complexes with four mutants of the Cc protein (i.e., F82S, F82W, F82Y, and F82I), despite large differences in the ET distance. Theoretical analysis indicates that charge recombination for all complexes involves a combination of tunneling and hopping via Trp191. For three of the five structures (WT and F82S(W)), the protein favors hopping more than that in the other two structures that have longer heme → ZnP distances (F82Y(I)). Experimentally observed biexponential ET kinetics is explained by the complex locking in alternative coupling pathways, where the acceptor hole state is either primarily localized on ZnP (slow phase) or on Trp191 (fast phase). The large conformational differences between the CcP:Cc interface for the F82Y(I) mutants compared to that the WT and F82S(W) complexes are predicted to change the reorganization energies for the CcP:Cc ET reactions because of changes in solvent exposure and interprotein ET distances. Since the recombination reaction is likely to occur in the inverted Marcus regime, an increased reorganization energy compensates the decreased role for hopping recombination (and the longer transfer distance) in the F82Y(I) mutants. Taken together, coupling pathway and reorganization energy effects for the five protein complexes explain the observed insensitivity of recombination kinetics to donor-acceptor distance and docking pose and also reveals how hopping through aromatic residues can accelerate long-range ET.

Published

2013

15. Defining a key receptor-CheA kinase contact and elucidating its function in the membrane-bound bacterial chemosensory array: a disulfide mapping and TAM-IDS Study.

Author

Piasta KN, Ulliman CJ, Slivka PF, Crane BR, and Falke JJ

Subjects

Alanine genetics, Disulfides chemistry, Escherichia coli genetics, Escherichia coli metabolism, Escherichia coli Proteins, Histidine Kinase, Methyl-Accepting Chemotaxis Proteins, Models, Chemical, Molecular Docking Simulation, Protein Structure, Tertiary, Signal Transduction, Tryptophan genetics, Adaptor Proteins, Signal Transducing chemistry, Bacterial Proteins chemistry, Chemotaxis physiology, Membrane Proteins chemistry, Protein Kinases chemistry

Abstract

The three core components of the ubiquitous bacterial chemosensory array - the transmembrane chemoreceptor, the histidine kinase CheA, and the adaptor protein CheW - assemble to form a membrane-bound, hexagonal lattice in which receptor transmembrane signals regulate kinase activity. Both the regulatory domain of the kinase and the adaptor protein bind to overlapping sites on the cytoplasmic tip of the receptor (termed the protein interaction region). Notably, the kinase regulatory domain and the adaptor protein share the same fold constructed of two SH3-like domains. The present study focuses on the structural interface between the receptor and the kinase regulatory domain. Two models have been proposed for this interface: Model 1 is based on the crystal structure of a homologous Thermotoga complex between a receptor fragment and the CheW adaptor protein. This model has been used in current models of chemosensory array architecture to build the receptor-CheA kinase interface. Model 2 is based on a newly determined crystal structure of a homologous Thermotoga complex between a receptor fragment and the CheA kinase regulatory domain. Both models present unique strengths and weaknesses, and current evidence is unable to resolve which model best describes contacts in the native chemosensory arrays of Escherichia coli, Salmonella typhimurium, and other bacteria. Here we employ disulfide mapping and tryptophan and alanine mutation to identify docking sites (TAM-IDS) to test Models 1 and 2 in well-characterized membrane-bound arrays formed from E. coli and S. typhimurium components. The results reveal that the native array interface between the receptor protein interaction region and the kinase regulatory domain is accurately described by Model 2, but not by Model 1. In addition, the results show that the interface possesses both a structural function that contributes to stable CheA kinase binding in the array and a regulatory function central to transmission of the activation signal from receptor to CheA kinase. On-off switching alters the disulfide formation rates of specific Cys pairs at the interface, but not most Cys pairs, indicating that signaling perturbs localized regions of the interface. The findings suggest a simple model for the rearrangement of the interface triggered by the attractant signal and for longer range transmission of the signal in the chemosensory array.

Published

2013

16. The 3.2 Å resolution structure of a receptor: CheA:CheW signaling complex defines overlapping binding sites and key residue interactions within bacterial chemosensory arrays.

Author

Li X, Fleetwood AD, Bayas C, Bilwes AM, Ortega DR, Falke JJ, Zhulin IB, and Crane BR

Subjects

Adaptor Proteins, Signal Transducing genetics, Amino Acid Sequence, Bacterial Proteins genetics, Binding Sites, Computer Simulation, Crystallization, Crystallography, X-Ray, Histidine Kinase, Membrane Proteins genetics, Methyl-Accepting Chemotaxis Proteins, Models, Molecular, Protein Engineering, Protein Structure, Quaternary, Protein Structure, Secondary, Protein Structure, Tertiary, Structure-Activity Relationship, Thermotoga maritima genetics, Thermotoga maritima metabolism, Adaptor Proteins, Signal Transducing chemistry, Bacterial Proteins chemistry, Membrane Proteins chemistry, Protein Kinases chemistry

Abstract

Bacterial chemosensory arrays are composed of extended networks of chemoreceptors (also known as methyl-accepting chemotaxis proteins, MCPs), the histidine kinase CheA, and the adaptor protein CheW. Models of these arrays have been developed from cryoelectron microscopy, crystal structures of binary and ternary complexes, NMR spectroscopy, mutational, data and biochemical studies. A new 3.2 Å resolution crystal structure of a Thermotoga maritima MCP protein interaction region in complex with the CheA kinase-regulatory module (P4-P5) and adaptor protein CheW provides sufficient detail to define residue contacts at the interfaces formed among the three proteins. As in a previous 4.5 Å resolution structure, CheA-P5 and CheW interact through conserved hydrophobic surfaces at the ends of their β-barrels to form pseudo 6-fold symmetric rings in which the two proteins alternate around the circumference. The interface between P5 subdomain 1 and CheW subdomain 2 was anticipated from previous studies, whereas the related interface between CheW subdomain 1 and P5 subdomain 2 has only been observed in these ring assemblies. The receptor forms an unexpected structure in that the helical hairpin tip of each subunit has "unzipped" into a continuous α-helix; four such helices associate into a bundle, and the tetramers bridge adjacent P5-CheW rings in the lattice through interactions with both P5 and CheW. P5 and CheW each bind a receptor helix with a groove of conserved hydrophobic residues between subdomains 1 and 2. P5 binds the receptor helix N-terminal to the tip region (lower site), whereas CheW binds the same helix with inverted polarity near the bundle end (upper site). Sequence comparisons among different evolutionary classes of chemotaxis proteins show that the binding partners undergo correlated changes at key residue positions that involve the lower site. Such evolutionary analyses argue that both CheW and P5 bind to the receptor tip at overlapping positions. Computational genomics further reveal that two distinct CheW proteins in Thermotogae utilize the analogous recognition motifs to couple different receptor classes to the same CheA kinase. Important residues for function previously identified by mutagenesis, chemical modification and biophysical approaches also map to these same interfaces. Thus, although the native CheW-receptor interaction is not observed in the present crystal structure, the bioinformatics and previous data predict key features of this interface. The companion study of the P5-receptor interface in native arrays (accompanying paper Piasta et al. (2013) Biochemistry, DOI: 10.1021/bi400385c) shows that, despite the non-native receptor fold in the present crystal structure, the local helix-in-groove contacts of the crystallographic P5-receptor interaction are present in native arrays and are essential for receptor regulation of kinase activity.

Published

2013

17. Light-induced subunit dissociation by a light-oxygen-voltage domain photoreceptor from Rhodobacter sphaeroides.

Author

Conrad KS, Bilwes AM, and Crane BR

Subjects

Amino Acid Sequence, Bacterial Proteins genetics, Crystallography, X-Ray, Flavins metabolism, Light, Models, Molecular, Molecular Sequence Data, Oxygen metabolism, Point Mutation, Protein Conformation, Protein Multimerization, Protein Structure, Tertiary, Protein Subunits chemistry, Protein Subunits genetics, Protein Subunits metabolism, Rhodobacter sphaeroides genetics, Sequence Homology, Bacterial Proteins chemistry, Bacterial Proteins metabolism, Rhodobacter sphaeroides chemistry, Rhodobacter sphaeroides metabolism

Abstract

Light-oxygen-voltage (LOV) domains bind a flavin chromophore to serve as blue light sensors in a wide range of eukaryotic and prokaryotic proteins. LOV domains are associated with a variable effector domain or a separate protein signaling partner to execute a wide variety of functions that include regulation of kinases, generation of anti-sigma factor antagonists, and regulation of circadian clocks. Here we present the crystal structure, photocycle kinetics, association properties, and spectroscopic features of a full-length LOV domain protein from Rhodobacter sphaeroides (RsLOV). RsLOV exhibits N- and C-terminal helical extensions that form an unusual helical bundle at its dimer interface with some resemblance to the helical transducer of sensory rhodopsin II. The blue light-induced conformational changes of RsLOV revealed from a comparison of light- and dark-state crystal structures support a shared signaling mechanism of LOV domain proteins that originates with the light-induced formation of a flavin-cysteinyl photoadduct. Adduct formation disrupts hydrogen bonding in the active site and propagates structural changes through the LOV domain core to the N- and C-terminal extensions. Single-residue variants in the active site and dimer interface of RsLOV alter photoadduct lifetimes and induce structural changes that perturb the oligomeric state. Size exclusion chromatography, multiangle light scattering, small-angle X-ray scattering, and cross-linking studies indicate that RsLOV dimerizes in the dark but, upon light excitation, dissociates into monomers. This light-induced switch in oligomeric state may prove to be useful for engineering molecular associations in controlled cellular settings.

Published

2013

18. Azurin as a protein scaffold for a low-coordinate nonheme iron site with a small-molecule binding pocket.

Author

McLaughlin MP, Retegan M, Bill E, Payne TM, Shafaat HS, Peña S, Sudhamsu J, Ensign AA, Crane BR, Neese F, and Holland PL

Subjects

Azides chemistry, Binding Sites, Coordination Complexes chemistry, Crystallography, X-Ray, Cyanides chemistry, Magnetic Resonance Spectroscopy, Molecular Structure, Oxidation-Reduction, Azurin chemistry, Iron chemistry, Nonheme Iron Proteins chemistry, Quantum Theory

Abstract

The apoprotein of Pseudomonas aeruginosa azurin binds iron(II) to give a 1:1 complex, which has been characterized by electronic absorption, Mössbauer, and NMR spectroscopies, as well as X-ray crystallography and quantum-chemical computations. Despite potential competition by water and other coordinating residues, iron(II) binds tightly to the low-coordinate site. The iron(II) complex does not react with chemical redox agents to undergo oxidation or reduction. Spectroscopically calibrated quantum-chemical computations show that the complex has high-spin iron(II) in a pseudotetrahedral coordination environment, which features interactions with side chains of two histidines and a cysteine as well as the C═O of Gly45. In the (5)A(1) ground state, the d(z(2)) orbital is doubly occupied. Mutation of Met121 to Ala leaves the metal site in a similar environment but creates a pocket for reversible binding of small anions to the iron(II) center. Specifically, azide forms a high-spin iron(II) complex and cyanide forms a low-spin iron(II) complex.

Published

2012

19. Heme binding to the Mammalian circadian clock protein period 2 is nonspecific.

Author

Airola MV, Du J, Dawson JH, and Crane BR

Subjects

Amino Acid Sequence, Animals, Chromatography, Gel, Circular Dichroism, Heme chemistry, Humans, Iron metabolism, Mammals metabolism, Models, Biological, Models, Molecular, Molecular Sequence Data, Mutagenesis, Site-Directed, Mutant Proteins chemistry, Mutant Proteins metabolism, Mutant Proteins physiology, Period Circadian Proteins chemistry, Period Circadian Proteins genetics, Protein Binding, Protein Interaction Domains and Motifs genetics, Protein Interaction Domains and Motifs physiology, Protein Multimerization genetics, Protein Structure, Tertiary genetics, Sequence Homology, Amino Acid, Substrate Specificity, Heme metabolism, Period Circadian Proteins metabolism

Abstract

The mammalian circadian clock synchronizes physical and metabolic activity with the diurnal cycle through a transcriptional-posttranslational feedback loop. An additional feedback mechanism regulating clock timing has been proposed to involve oscillation in heme availability. Period 2 (PER2), an integral component in the negative feedback loop that establishes circadian rhythms in mammals, has been identified as a heme-binding protein. However, the majority of evidence for heme binding is based upon in vitro heme-binding assays. We sought to ascertain if these largely spectral assays could distinguish between specific and nonspecific heme interactions. Heme-binding properties by a number of other well-characterized proteins, all with no known biological role involving heme interaction, corresponded to those displayed by PER2. Site-directed mutants of putative heme-binding residues identified by MCD were unable to locate a specific heme-binding site on PER2. Protein film electrochemistry also indicates that heme binds PER2 nonspecifically on the protein surface. Our results establish the inability of qualitative in vitro assays to easily distinguish between specific and nonspecific heme binding. We conclude that heme binding to PER2 is likely to be nonspecific and does not involve the hydrophobic pocket within the PER2 PAS domains that in other PAS proteins commonly recognizes cofactors. These findings also question the significance of in vivo studies that implicate heme interactions with the clock proteins PER2 and nPAS2 in biological function.

Published

2010

20. Structure of the ternary complex formed by a chemotaxis receptor signaling domain, the CheA histidine kinase, and the coupling protein CheW as determined by pulsed dipolar ESR spectroscopy.

Author

Bhatnagar J, Borbat PP, Pollard AM, Bilwes AM, Freed JH, and Crane BR

Subjects

Bacterial Proteins genetics, Electron Spin Resonance Spectroscopy, Histidine Kinase, Kinetics, Membrane Proteins genetics, Methyl-Accepting Chemotaxis Proteins, Molecular Conformation, Multiprotein Complexes genetics, Protein Binding, Protein Conformation, Protein Kinases genetics, Thermotoga maritima chemistry, Thermotoga maritima genetics, Bacterial Proteins chemistry, Chemotaxis, Membrane Proteins chemistry, Multiprotein Complexes chemistry, Protein Kinases chemistry, Thermotoga maritima enzymology

Abstract

The signaling apparatus that controls bacterial chemotaxis is composed of a core complex containing chemoreceptors, the histidine autokinase CheA, and the coupling protein CheW. Site-specific spin labeling and pulsed dipolar ESR spectroscopy (PDS) have been applied to investigate the structure of a soluble ternary complex formed by Thermotoga maritima CheA (TmCheA), CheW, and receptor signaling domains. Thirty-five symmetric spin-label sites (SLSs) were engineered into the five domains of the CheA dimer and CheW to provide distance restraints within the CheA:CheW complex in the absence and presence of a soluble receptor that inhibits kinase activity (Tm14). Additional PDS restraints among spin-labeled CheA, CheW, and an engineered single-chain receptor labeled at six different sites allow docking of the receptor structure relative to the CheA:CheW complex. Disulfide cross-linking between selectively incorporated Cys residues finds two pairs of positions that provide further constraints within the ternary complex: one involving Tm14 and CheW and another involving Tm14 and CheA. The derived structure of the ternary complex indicates a primary site of interaction between CheW and Tm14 that agrees well with previous biochemical and genetic data for transmembrane chemoreceptors. The PDS distance distributions are most consistent with only one CheW directly engaging one dimeric Tm14. The CheA dimerization domain (P3) aligns roughly antiparallel to the receptor-conserved signaling tip but does not interact strongly with it. The angle of the receptor axis with respect to P3 and the CheW-binding P5 domains is bound by two limits differing by approximately 20 degrees . In one limit, Tm14 aligns roughly along P3 and may interact to some extent with the hinge region near the P3 hairpin loop. In the other limit, Tm14 tilts to interact with the P5 domain of the opposite subunit in an interface that mimics that observed with the P5 homologue CheW. The time domain ESR data can be simulated from the model only if orientational variability is introduced for the P5 and, especially, P3 domains. The Tm14 tip also binds beside one of the CheA kinase domains (P4); however, in both bound and unbound states, P4 samples a broad range of distributions that are only minimally affected by Tm14 binding. The CheA P1 domains that contain the substrate histidine are also broadly distributed in space under all conditions. In the context of the hexagonal lattice formed by trimeric transmembrane chemoreceptors, the PDS structure is best accommodated with the P3 domain in the center of a honeycomb edge.

Published

2010

21. EPR and ENDOR characterization of the reactive intermediates in the generation of NO by cryoreduced oxy-nitric oxide synthase from Geobacillus stearothermophilus.

Author

Davydov R, Sudhamsu J, Lees NS, Crane BR, and Hoffman BM

Subjects

Arginine analogs & derivatives, Arginine metabolism, Bacterial Proteins chemistry, Bacterial Proteins metabolism, Catalytic Domain, Citrulline metabolism, Electron Spin Resonance Spectroscopy, Ferrous Compounds chemistry, Ferrous Compounds metabolism, Heme chemistry, Heme metabolism, Models, Molecular, Nitric Oxide chemistry, Nitric Oxide Synthase antagonists & inhibitors, Nitric Oxide Synthase chemistry, Nuclear Magnetic Resonance, Biomolecular, Oxidation-Reduction, Geobacillus stearothermophilus enzymology, Nitric Oxide biosynthesis, Nitric Oxide Synthase metabolism

Abstract

Cryoreduction EPR/ENDOR/step-annealing measurements with substrate complexes of oxy-gsNOS (3; gsNOS is nitric oxide synthase from Geobacillus stearothermophilus) confirm that Compound I (6) is the reactive heme species that carries out the gsNOS-catalyzed (Stage I) oxidation of L-arginine to N-hydroxy-L-arginine (NOHA), whereas the active species in the (Stage II) oxidation of NOHA to citrulline and HNO/NO(-) is the hydroperoxy-ferric form (5). When 3 is reduced by tetrahydrobiopterin (BH4), instead of an externally supplied electron, the resulting BH4(+) radical oxidizes HNO/NO(-) to NO. In this report, radiolytic one-electron reduction of 3 and its complexes with Arg, Me-Arg, and NO(2)Arg was shown by EPR and (1)H and (14,15)N ENDOR spectroscopies to generate 5; in contrast, during cryoreduction of 3/NOHA, the peroxo-ferric-gsNOS intermediate (4/NOHA) was trapped. During annealing at 145 K, ENDOR shows that 5/Arg and 5/Me-Arg (but not 5/NO(2)Arg) generate a Stage I primary product species in which the OH group of the hydroxylated substrate is coordinated to Fe(III), characteristic of 6 as the active heme center. Analysis shows that hydroxylation of Arg and Me-Arg is quantitative. Annealing of 4/NOHA at 160 K converts it first to 5/NOHA and then to the Stage II primary enzymatic product. The latter contains Fe(III) coordinated by water, characteristic of 5 as the active heme center. It further contains quantitative amounts of citrulline and HNO/NO(-); the latter reacts with the ferriheme to form the NO-ferroheme upon further annealing. Stage I delivery of the first proton of catalysis to the (unobserved) 4 formed by cryoreduction of 3 involves a bound water that may convey a proton from L-Arg, while the second proton likely derives from the carboxyl side chain of Glu 248 or the heme carboxylates; the process also involves proton delivery by water(s). In the Stage II oxidation of NOHA, the proton that converts 4/NOHA to 5/NOHA likely is derived from NOHA itself, a conclusion supported by the pH invariance of the process. The present results illustrate how the substrate itself modulates the nature and reactivity of intermediates along the monooxygenase reaction pathway.

Published

2009

22. Relaxation dynamics of Pseudomonas aeruginosa Re(I)(CO)3(alpha-diimine)(HisX)+ (X = 83, 107, 109, 124, 126)Cu(II) azurins.

Author

Blanco-Rodríguez AM, Busby M, Ronayne K, Towrie M, Grădinaru C, Sudhamsu J, Sýkora J, Hof M, Zális S, Di Bilio AJ, Crane BR, Gray HB, and Vlcek A Jr

Subjects

Absorption, Anisotropy, Azurin chemistry, Binding Sites, Electron Transport, Electrons, Models, Molecular, Protein Conformation, Quantum Theory, Rhenium metabolism, Spectroscopy, Fourier Transform Infrared, Surface Properties, Time Factors, Azurin metabolism, Organometallic Compounds metabolism, Pseudomonas aeruginosa

Abstract

Photoinduced relaxation processes of five structurally characterized Pseudomonas aeruginosa Re(I)(CO)(3)(alpha-diimine)(HisX) (X = 83, 107, 109, 124, 126)Cu(II) azurins have been investigated by time-resolved (ps-ns) IR spectroscopy and emission spectroscopy. Crystal structures reveal the presence of Re-azurin dimers and trimers that in two cases (X = 107, 124) involve van der Waals interactions between interdigitated diimine aromatic rings. Time-dependent emission anisotropy measurements confirm that the proteins aggregate in mM solutions (D(2)O, KP(i) buffer, pD = 7.1). Excited-state DFT calculations show that extensive charge redistribution in the Re(I)(CO)(3) --> diimine (3)MLCT state occurs: excitation of this (3)MLCT state triggers several relaxation processes in Re-azurins whose kinetics strongly depend on the location of the metallolabel on the protein surface. Relaxation is manifested by dynamic blue shifts of excited-state nu(CO) IR bands that occur with triexponential kinetics: intramolecular vibrational redistribution together with vibrational and solvent relaxation give rise to subps, approximately 2, and 8-20 ps components, while the approximately 10(2) ps kinetics are attributed to displacement (reorientation) of the Re(I)(CO)(3)(phen)(im) unit relative to the peptide chain, which optimizes Coulombic interactions of the Re(I) excited-state electron density with solvated peptide groups. Evidence also suggests that additional segmental movements of Re-bearing beta-strands occur without perturbing the reaction field or interactions with the peptide. Our work demonstrates that time-resolved IR spectroscopy and emission anisotropy of Re(I) carbonyl-diimine complexes are powerful probes of molecular dynamics at or around the surfaces of proteins and protein-protein interfacial regions.

Published

2009

23. The structure of a soluble chemoreceptor suggests a mechanism for propagating conformational signals.

Author

Pollard AM, Bilwes AM, and Crane BR

Subjects

Bacterial Proteins genetics, Bacterial Proteins metabolism, Crystallography, X-Ray, Disulfides chemistry, Hydrogen Bonding, Membrane Proteins genetics, Membrane Proteins metabolism, Methyl-Accepting Chemotaxis Proteins, Models, Molecular, Protein Structure, Secondary, Recombinant Proteins chemistry, Recombinant Proteins isolation & purification, Recombinant Proteins metabolism, Thermotoga maritima chemistry, Thermotoga maritima genetics, Thermotoga maritima metabolism, Bacterial Proteins chemistry, Membrane Proteins chemistry, Protein Conformation, Signal Transduction

Abstract

Transmembrane chemoreceptors, also known as methyl-accepting chemotaxis proteins (MCPs), translate extracellular signals into intracellular responses in the bacterial chemotaxis system. MCP ligand binding domains control the activity of the CheA kinase, situated approximately 200 A away, across the cytoplasmic membrane. The 2.17 A resolution crystal structure of a Thermotoga maritima soluble receptor (Tm14) reveals distortions in its dimeric four-helix bundle that provide insight into the conformational states available to MCPs for propagating signals. A bulge in one helix generates asymmetry between subunits that displaces the kinase-interacting tip, which resides more than 100 A away. The maximum bundle distortion maps to the adaptation region of transmembrane MCPs where reversible methylation of acidic residues tunes receptor activity. Minor alterations in coiled-coil packing geometry translate the bulge distortion to a >25 A movement of the tip relative to the bundle stalks. The Tm14 structure discloses how alterations in local helical structure, which could be induced by changes in methylation state and/or by conformational signals from membrane proximal regions, can reposition a remote domain that interacts with the CheA kinase.

Published

2009

24. Substrate-ligand interactions in Geobacillus stearothermophilus nitric oxide synthase.

Author

Kabir M, Sudhamsu J, Crane BR, Yeh SR, and Rousseau DL

Subjects

Absorption, Arginine chemistry, Arginine metabolism, Biopterins chemistry, Biopterins metabolism, Carbon Monoxide metabolism, Coenzymes metabolism, Iron metabolism, Ligands, Nitric Oxide Synthase chemistry, Oxygen metabolism, Protein Binding, Spectrum Analysis, Raman, Sulfur metabolism, Bacillaceae enzymology, Nitric Oxide Synthase metabolism

Abstract

Nitric oxide synthase (NOS) generates NO via a sequential two-step reaction [l-arginine (l-Arg) --> N-hydroxy-l-arginine (NOHA) --> l-citrulline + NO]. Each step of the reaction follows a distinct mechanism defined by the chemical environment introduced by each substrate bound to the heme active site. The dioxygen complex of the NOS enzyme from a thermophilic bacterium, Geobacillus stearothermophilus (gsNOS), is unusually stable; hence, it provides a unique model for the studies of the mechanistic differences between the two steps of the NOS reaction. By using CO as a structural probe, we found that gsNOS exhibits two conformations in the absence of substrate, as indicated by the presence of two sets of nu(Fe-CO)/nu(C-O) modes in the resonance Raman spectra. In the nu(Fe-CO) versus nu(C-O) inverse correlation plot, one set of data falls on the correlation line characterized by mammalian NOSs (mNOS), whereas the other set of data lies on a new correlation line defined by a bacterial NOS from Bacillus subtilis (bsNOS), reflecting a difference in the proximal Fe-Cys bond strength in the two conformers of gsNOS. The addition of l-Arg stabilizes the conformer associated with the mNOS correlation line, whereas NOHA stabilizes the conformer associated with the bsNOS correlation line, although both substrates introduce a positive electrostatic potential into the distal heme pocket. To assess how substrate binding affects Fe-Cys bond strength, the frequency of the Fe-Cys stretching mode of gsNOS was monitored by resonance Raman spectroscopy with 363.8 nm excitation. In the substrate-free form, the Fe-Cys stretching mode was detected at 342.5 cm(-1), similar to that of bsNOS. The binding of l-Arg and NOHA brings about a small decrease and increase in the Fe-Cys stretching frequency, respectively. The implication of these unique structural features with respect to the oxygen chemistry of NOS is discussed.

Published

2008

25. Time-resolved dimerization of a PAS-LOV protein measured with photocoupled small angle X-ray scattering.

Author

Lamb JS, Zoltowski BD, Pabit SA, Crane BR, and Pollack L

Subjects

Dimerization, Fungal Proteins metabolism, Oxygen chemistry, Oxygen metabolism, Photochemistry, Scattering, Small Angle, X-Ray Diffraction, Fungal Proteins chemistry

Abstract

Time-resolved small-angle X-ray scattering (SAXS) has been used to probe photoexcitation of the blue-light signal transduction protein Vivid (VVD). Laser excitation of sample in a continuous flow cell enables time-resolved measurement of the initial response of VVD to illumination. Good signal-to-noise is achieved without relying on multiple exposures of the same sample or limiting exposure times to prevent radiation damage. The SAXS data demonstrate that VVD dimerizes within tens of milliseconds of light-state activation. Time-resolved SAXS in a flow cell format is a general method for connecting chemical changes in photoreceptors to conformationally driven output signals.

Published

2008

26. Light activation of the LOV protein vivid generates a rapidly exchanging dimer.

Author

Zoltowski BD and Crane BR

Subjects

Amino Acid Sequence, Chromatography, Gel, Crystallography, X-Ray, Dimerization, Fungal Proteins chemistry, Kinetics, Models, Molecular, Molecular Sequence Data, Mutant Proteins chemistry, Mutant Proteins metabolism, Mutation genetics, Protein Structure, Secondary, Sequence Alignment, Fungal Proteins metabolism, Fungal Proteins radiation effects, Light, Neurospora crassa metabolism, Neurospora crassa radiation effects

Abstract

The fungal photoreceptor Vivid (VVD) plays an important role in the adaptation of blue-light responses in Neurospora crassa. VVD, an FAD-binding LOV (light, oxygen, voltage) protein, couples light-induced cysteinyl adduct formation at the flavin ring to conformational changes in the N-terminal cap (Ncap) of the VVD PAS domain. Size-exclusion chromatography (SEC), equilibrium ultracentrifugation, and static and dynamic light scattering show that these conformational changes generate a rapidly exchanging VVD dimer, with an expanded hydrodynamic radius. A three-residue N-terminal beta-turn that assumes two different conformations in a crystal structure of a VVD C71V variant is essential for light-state dimerization. Residue substitutions at a critical hinge between the Ncap and PAS core can inhibit or enhance dimerization, whereas a Tyr to Trp substitution at the Ncap-PAS interface stabilizes the light-state dimer. Cross-linking through engineered disulfides indicates that the light-state dimer differs considerably from the dark-state dimer found in VVD crystal structures. These results verify the role of Ncap conformational changes in gating the photic response of N. crassa and indicate that LOV-LOV homo- or heterodimerization may be a mechanism for regulating light-activated gene expression.

Published

2008

27. Crystal structure and mechanism of tryptophan 2,3-dioxygenase, a heme enzyme involved in tryptophan catabolism and in quinolinate biosynthesis.

Author

Zhang Y, Kang SA, Mukherjee T, Bale S, Crane BR, Begley TP, and Ealick SE

Subjects

Binding Sites, Crystallography, X-Ray, Glycine genetics, Glycine metabolism, Indoleamine-Pyrrole 2,3,-Dioxygenase chemistry, Indoleamine-Pyrrole 2,3,-Dioxygenase metabolism, Models, Molecular, Mutagenesis, Site-Directed, Oxidation-Reduction, Protein Folding, Ralstonia classification, Ralstonia enzymology, Structure-Activity Relationship, Substrate Specificity, Heme metabolism, Quinolinic Acid metabolism, Tryptophan metabolism, Tryptophan Oxygenase chemistry, Tryptophan Oxygenase metabolism

Abstract

The structure of tryptophan 2,3-dioxygenase (TDO) from Ralstonia metallidurans was determined at 2.4 A. TDO catalyzes the irreversible oxidation of l-tryptophan to N-formyl kynurenine, which is the initial step in tryptophan catabolism. TDO is a heme-containing enzyme and is highly specific for its substrate l-tryptophan. The structure is a tetramer with a heme cofactor bound at each active site. The monomeric fold, as well as the heme binding site, is similar to that of the large domain of indoleamine 2,3-dioxygenase, an enzyme that catalyzes the same reaction except with a broader substrate tolerance. Modeling of the putative (S)-tryptophan hydroperoxide intermediate into the active site, as well as substrate analogue and mutagenesis studies, are consistent with a Criegee mechanism for the reaction.

Published

2007

28. Comparison of intra- vs intermolecular long-range electron transfer in crystals of ruthenium-modified azurin.

Author

Gradinaru C and Crane BR

Subjects

Crystallization, Hydrogen-Ion Concentration, Ligands, Models, Chemical, Models, Molecular, Molecular Conformation, Photochemistry, Pseudomonas aeruginosa metabolism, Spectrophotometry, Azurin chemistry, Chemistry, Physical methods, Copper chemistry, Electrons, Proteins chemistry, Ruthenium chemistry

Abstract

Selective metal-ion incorporation and ligand substitution are employed to control whether electrons tunnel over intra- or intermolecular separations in crystals of P. aeruginosa azurin modified with Ru-polypyridine complexes. Cu(1+)-to-Ru3+ electron transfer (ET) across a specific protein-protein interface in the crystal lattice has a time constant 5-10 times longer than ET between the same donor and acceptor within a single protein (tauET = 5 vs 0.5-1.0 micros). Slower intermolecular ET agrees well with a longer distance between redox centers across the inter-protein (18.9 A) compared to the intra-protein separation (17.0 A) and indicates that the closest donor/acceptor pair dominates crystal ET. Lowering the crystal pH accelerates inter-protein ET (tauET = 1.0 micros) but not intra-protein ET. Faster inter-protein ET likely results from a pH-induced peptide bond flip that perturbs hydrogen bonding in the path between Ru and Cu centers on adjacent molecules.

Published

2006

29. Excited-state dynamics of structurally characterized [ReI(CO)3(phen)(HisX)]+ (X = 83, 109) Pseudomonas aeruginosa azurins in aqueous solution.

Author

Blanco-Rodríguez AM, Busby M, Gradinaru C, Crane BR, Di Bilio AJ, Matousek P, Towrie M, Leigh BS, Richards JH, Vlcek A Jr, and Gray HB

Subjects

Metalloproteins chemistry, Models, Molecular, Peptides chemistry, Phenanthrolines chemistry, Protein Conformation, Pseudomonas aeruginosa chemistry, Solutions, Spectrophotometry, Infrared, Water chemistry, Azurin chemistry, Rhenium chemistry

Abstract

The triplet metal-to-ligand charge transfer ((3)MLCT) dynamics of two structurally characterized Re(I)(CO)(3)(phen)(HisX)-modified (phen = 1,10-phenanthroline; X = 83, 109) Pseudomonas aeruginosa azurins have been investigated by picosecond time-resolved infrared (TRIR) spectroscopy in aqueous (D(2)O) solution. The (3)MLCT relaxation dynamics exhibited by the two Re(I)-azurins are very different from those of the sensitizer [Re(I)(CO)(3)(phen)(im)](+) (im = imidazole). Whereas the Re(I)(CO)(3) intramolecular vibrational relaxation in Re(I)(CO)(3)(phen)(HisX)Az (4 ps) is similar to that of [Re(I)(CO)(3)(phen)(im)](+) (2 ps), the medium relaxation is much slower ( approximately 250 vs 9.5 ps); the 250-ps relaxation is attributable to reorientation of D(2)O molecules as well as structural reorganization of the rhenium chromophore and nearby polar amino acids in each of the modified proteins.

Published

2006

30. Nitrosyl-heme structures of Bacillus subtilis nitric oxide synthase have implications for understanding substrate oxidation.

Author

Pant K and Crane BR

Subjects

Arginine analogs & derivatives, Arginine chemistry, Arginine metabolism, Bacillus subtilis metabolism, Binding Sites, Catalysis, Crystallography, X-Ray, Ferric Compounds chemistry, Ferric Compounds metabolism, Ferrous Compounds chemistry, Ferrous Compounds metabolism, Hemoglobins chemistry, Nitric Oxide chemistry, Nitric Oxide metabolism, Nitric Oxide Synthase metabolism, Oxidoreductases metabolism, Oxygen metabolism, Protein Structure, Tertiary, Substrate Specificity, Bacillus subtilis chemistry, Heme chemistry, Nitric Oxide Synthase chemistry, Oxidation-Reduction

Abstract

The crystal structures of nitrosyl-heme complexes of a prokaryotic nitric oxide synthase (NOS) from Bacillus subtilis (bsNOS) reveal changes in active-site hydrogen bonding in the presence of the intermediate N(omega)-hydroxy-l-arginine (NOHA) compared to the substrate l-arginine (l-Arg). Correlating with a Val-to-Ile residue substitution in the bsNOS heme pocket, the Fe(II)-NO complex with both l-Arg and NOHA is more bent than the Fe(II)-NO, l-Arg complex of mammalian eNOS [Li, H., Raman, C. S., Martasek, P., Masters, B. S. S., and Poulos, T. L. (2001) Biochemistry 40, 5399-5406]. Structures of the Fe(III)-NO complex with NOHA show a nearly linear nitrosyl group, and in one subunit, partial nitrosation of bound NOHA. In the Fe(II)-NO complexes, the protonated NOHA N(omega) atom forms a short hydrogen bond with the heme-coordinated NO nitrogen, but active-site water molecules are out of hydrogen bonding range with the distal NO oxygen. In contrast, the l-Arg guanidinium interacts more weakly and equally with both NO atoms, and an active-site water molecule hydrogen bonds to the distal NO oxygen. This difference in hydrogen bonding to the nitrosyl group by the two substrates indicates that interactions provided by NOHA may preferentially stabilize an electrophilic peroxo-heme intermediate in the second step of NOS catalysis.

Published

2006

31. Solvent isotope effects on interfacial protein electron transfer in crystals and electrode films.

Author

Kang SA, Hoke KR, and Crane BR

Subjects

Crystallization, Crystallography, X-Ray, Deuterium Oxide chemistry, Electrochemistry, Electrodes, Kinetics, Models, Molecular, Protein Conformation, Cytochrome-c Peroxidase chemistry, Cytochromes c chemistry, Metalloporphyrins chemistry, Saccharomyces cerevisiae Proteins chemistry, Zinc chemistry

Abstract

D(2)O-grown crystals of yeast zinc porphyrin substituted cytochrome c peroxidase (ZnCcP) in complex with yeast iso-1-cytochrome c (yCc) diffract to higher resolution (1.7 A) and pack differently than H(2)O-grown crystals (2.4-3.0 A). Two ZnCcP's bind the same yCc (porphyrin-to-porphyrin separations of 19 and 29 A), with one ZnCcP interacting through the same interface found in the H(2)O crystals. The triplet excited-state of at least one of the two unique ZnCcP's is quenched by electron transfer (ET) to Fe(III)yCc (k(e) = 220 s(-1)). Measurement of thermal recombination ET between Fe(II)yCc and ZnCcP+ in the D(2)O-treated crystals has both slow and fast components that differ by 2 orders of magnitude (k(eb)(1) = 2200 s(-1), k(eb)(2) = 30 s(-1)). Back ET in H(2)O-grown crystals is too fast for observation, but soaking H(2)O-grown crystals in D(2)O for hours generates slower back ET, with kinetics similar to those of the D(2)O-grown crystals (k(eb)(1) = 7000 s(-1), k(eb)(2) = 100 s(-1)). Protein-film voltammetry of yCc adsorbed to mixed alkanethiol monolayers on gold electrodes shows slower ET for D(2)O-grown yCc films than for H(2)O-grown films (k(H) = 800 s(-1); k(D) = 540 s(-1) at 20 degrees C). Soaking H(2)O- or D(2)O-grown films in the counter solvent produces an immediate inverse isotope effect that diminishes over hours until the ET rate reaches that found in the counter solvent. Thus, D(2)O substitution perturbs interactions and ET between yCc and either CcP or electrode films. The effects derive from slow exchanging protons or solvent molecules that in the crystal produce only small structural changes.

Published

2006

32. Electron transfer between cytochrome c and cytochome c peroxidase in single crystals.

Author

Kang SA, Marjavaara PJ, and Crane BR

Subjects

Animals, Electrons, Horses, Kinetics, Metalloporphyrins chemistry, Metalloporphyrins metabolism, Models, Molecular, Oxidation-Reduction, Yeasts enzymology, Zinc chemistry, Zinc metabolism, Cytochrome-c Peroxidase chemistry, Cytochrome-c Peroxidase metabolism, Cytochromes c chemistry, Cytochromes c metabolism

Abstract

Cytochrome c (Cc) and cytochrome c peroxidase (CcP) form an important redox pair for understanding interprotein electron transfer (ET). Measurements of ET rates from photoexcited CcP substituted with Zn porphyrin to either yeast Fe(III)Cc or horse Fe(III)Cc in crystals reveal that the molecular associations found in the respective crystal structures determine solution reactivity. Similar forward rates for yeast isozyme-1 Cc (yCc) and yCc homologue horse Cc (hCc), despite different orientations relative to CcP, suggest small-amplitude conformational gating of ET even in the crystalline state; faster back ET in the yCc compared to the hCc complex agrees with the relative coupling between redox sites predicted by the structures.

Published

2004

33. Subunit exchange by CheA histidine kinases from the mesophile Escherichia coli and the thermophile Thermotoga maritima.

Author

Park SY, Quezada CM, Bilwes AM, and Crane BR

Subjects

Amino Acid Sequence, Bacterial Proteins antagonists & inhibitors, Bacterial Proteins metabolism, Chemotaxis, Dimerization, Enzyme Stability, Escherichia coli growth & development, Escherichia coli Proteins antagonists & inhibitors, Escherichia coli Proteins metabolism, Histidine Kinase, Kinetics, Membrane Proteins antagonists & inhibitors, Membrane Proteins metabolism, Methyl-Accepting Chemotaxis Proteins, Models, Chemical, Molecular Sequence Data, Protein Folding, Protein Kinase Inhibitors, Protein Kinases metabolism, Protein Subunits antagonists & inhibitors, Protein Subunits metabolism, Structural Homology, Protein, Temperature, Thermodynamics, Thermotoga maritima growth & development, Bacterial Proteins chemistry, Escherichia coli enzymology, Escherichia coli Proteins chemistry, Membrane Proteins chemistry, Protein Kinases chemistry, Protein Subunits chemistry, Thermotoga maritima enzymology

Abstract

Dimerization of the chemotaxis histidine kinase CheA is required for intersubunit autophosphorylation [Swanson, R. V., Bourret, R. B., and Simon, M. I. (1993) Mol. Microbiol. 8, 435-441]. Here we show that CheA dimers exchange subunits by the rate-limiting dissociation of a central four-helix bundle association domain (P3), despite the high stability of P3 versus unfolding. P3 alone determines the stability and exchange properties of the CheA dimer. For CheA proteins from the mesophile Escherichia coli and the thermophile Thermotoga maritima, subunit dissociation activates at temperatures where the respective organisms live (37 and 80 degrees C). Under destabilizing conditions, P3 dimer dissociation is cooperative with unfolding. Chemical denaturation is reversible for both EP3 and TP3. Aggregation accompanies thermal unfolding for both proteins under most conditions, but thermal unfolding is reversible and two-state for EP3 at low protein concentrations. Residue differences within interhelical loops may account for the contrasted thermodynamic properties of structurally similar EP3 and TP3 (41% sequence identity). Under stabilizing conditions, greater correlation between activation energy for dimer dissociation and P3 stability suggests more unfolding in the dissociation of EP3 than TP3. Furthermore, destabilization of extended conformations by glycerol slows relative dissociation rates more for EP3 than for TP3. Nevertheless, at physiological temperatures, neither protein likely unfolds completely during subunit exchange. EP3 and TP3 will not exchange subunits with each other. The receptor coupling protein CheW reduces the subunit dissociation rate of the T. maritima CheA dimer by interacting with the regulatory domain P5.

Published

2004

34. Spectroscopy and reactivity of a photogenerated tryptophan radical in a structurally defined protein environment.

Author

Miller JE, Grădinaru C, Crane BR, Di Bilio AJ, Wehbi WA, Un S, Winkler JR, and Gray HB

Subjects

Azurin analogs & derivatives, Azurin metabolism, Copper chemistry, Electron Spin Resonance Spectroscopy, Free Radicals chemistry, Free Radicals metabolism, Phenanthrolines chemistry, Photochemistry, Pseudomonas aeruginosa chemistry, Pseudomonas aeruginosa metabolism, Rhenium chemistry, Zinc chemistry, Azurin chemistry, Tryptophan chemistry

Abstract

Near-UV irradiation of structurally characterized [Re(I)(CO)3(1,10-phenanthroline)(Q107H)](W48F/Y72F/H83Q/Y108W)AzM(II) [Az = Pseudomonas aeruginosa azurin, M = Cu, Zn]/[Co(NH3)5Cl]Cl2 produces a tryptophan radical (W108*) with unprecedented kinetic stability. After rapid formation (k = 2.8 x 106 s-1), the radical persists for more than 5 h at room temperature in the folded ReAzM(II) structure. The absorption spectrum of ReAz(W108*)M(II) exhibits maxima at 512 and 536 nm. Oxidation of K4[Mo(CN)8] by ReAz(W108*)Zn(II) places the W108*/W108 reduction potential in the protein above 0.8 V vs NHE.

Published

2003

35. Tetrahydrobiopterin radical enzymology.

Author

Wei CC, Crane BR, and Stuehr DJ

Subjects

Binding Sites, Catalysis, Electron Transport, Free Radicals chemistry, Free Radicals metabolism, Models, Molecular, Molecular Structure, Nitric Oxide Synthase metabolism, Biopterins analogs & derivatives, Biopterins chemistry, Biopterins metabolism, Enzymes metabolism

Published

2003

36. Structure of a nitric oxide synthase heme protein from Bacillus subtilis.

Author

Pant K, Bilwes AM, Adak S, Stuehr DJ, and Crane BR

Subjects

Amino Acid Sequence, Animals, Bacterial Proteins metabolism, Binding Sites, Cattle, Crystallography, X-Ray, Dimerization, Enzyme Stability, Heme chemistry, Hemeproteins metabolism, Humans, Mice, Molecular Sequence Data, Nitric Oxide metabolism, Nitric Oxide Synthase metabolism, Pterins chemistry, Substrate Specificity, Surface Properties, Bacillus subtilis enzymology, Bacterial Proteins chemistry, Hemeproteins chemistry, Nitric Oxide Synthase chemistry

Abstract

Eukaryotic nitric oxide synthases (NOSs) produce nitric oxide to mediate intercellular signaling and protect against pathogens. Recently, proteins homologous to mammalian NOS oxygenase domains have been found in prokaryotes and one from Bacillus subtilis (bsNOS) has been demonstrated to produce nitric oxide [Adak, S., Aulak, K. S., and Stuehr, D. J. (2002) J. Biol. Chem. 277, 16167-16171]. We present structures of bsNOS complexed with the active cofactor tetrahydrofolate and the substrate L-arginine (L-Arg) or the intermediate N(omega)-hydroxy-L-arginine (NHA) to 1.9 or 2.2 A resolution, respectively. The bsNOS structure is similar to those of the mammalian NOS oxygenase domains (mNOS(ox)) except for the absence of an N-terminal beta-hairpin hook and zinc-binding region that interact with pterin and stabilize the mNOS(ox) dimer. Changes in patterns of residue conservation between bacterial and mammalian NOSs correlate to different binding modes for pterin side chains. Residue conservation on a surface patch surrounding an exposed heme edge indicates a likely interaction site for reductase proteins in all NOSs. The heme pockets of bsNOS and mNOS(ox) recognize L-Arg and NHA similarly, although a change from Val to Ile beside the substrate guanidinium may explain the 10-20-fold slower dissociation of product NO from the bacterial enzyme. Overall, these structures suggest that bsNOS functions naturally to produce nitrogen oxides from L-Arg and NHA in a pterin-dependent manner, but that the regulation and purpose of NO production by NOS may be quite different in B. subtilis than in mammals.

Published

2002

37. Electron tunneling in single crystals of Pseudomonas aeruginosa azurins.

Author

Crane BR, Di Bilio AJ, Winkler JR, and Gray HB

Subjects

Azurin metabolism, Binding Sites, Copper chemistry, Copper metabolism, Crystallization, Crystallography, X-Ray, Electron Transport, Models, Molecular, Osmium chemistry, Osmium metabolism, Oxidation-Reduction, Protein Conformation, Pseudomonas aeruginosa chemistry, Rhenium chemistry, Rhenium metabolism, Ruthenium chemistry, Ruthenium metabolism, Azurin chemistry, Pseudomonas aeruginosa metabolism

Abstract

Rates of reduction of Os(III), Ru(III), and Re(I) by Cu(I) in His83-modified Pseudomonas aeruginosa azurins (M-Cu distance approximately 17 A) have been measured in single crystals, where protein conformation and surface solvation are precisely defined by high-resolution X-ray structure determinations: 1.7(8) x 10(6) s(-1) (298 K), 1.8(8) x 10(6) s(-1) (140 K), [Ru(bpy)2(im)(3+)-]; 3.0(15) x 10(6) s(-1) (298 K), [Ru(tpy)(bpy)(3+)-]; 3.0(15) x 10(6) s(-1) (298 K), [Ru(tpy)(phen)(3+)-]; 9.0(50) x 10(2) s(-1) (298 K), [Os(bpy)2(im)(3+)-]; 4.4(20) x 10(6) s(-1) (298 K), [Re(CO)3(phen)(+)] (bpy = 2,2'-bipyridine; im = imidazole; tpy = 2,2':6',2' '-terpyridine; phen = 1,10-phenanthroline). The time constants for electron tunneling in crystals are roughly the same as those measured in solution, indicating very similar protein structures in the two states. High-resolution structures of the oxidized (1.5 A) and reduced (1.4 A) states of Ru(II)(tpy)(phen)(His83)Az establish that very small changes in copper coordination accompany reduction but reveal a shorter axial interaction between copper and the Gly45 peptide carbonyl oxygen [2.6 A for Cu(II)] than had been recognized previously. Although Ru(bpy)2(im)(His83)Az is less solvated in the crystal, the reorganization energy for Cu(I) --> Ru(III) electron transfer falls in the range (0.6-0.8 eV) determined experimentally for the reaction in solution. Our work suggests that outer-sphere protein reorganization is the dominant activation component required for electron tunneling.

Published

2001

38. Properties of photogenerated tryptophan and tyrosyl radicals in structurally characterized proteins containing rhenium(I) tricarbonyl diimines.

Author

Di Bilio AJ, Crane BR, Wehbi WA, Kiser CN, Abu-Omar MM, Carlos RM, Richards JH, Winkler JR, and Gray HB

Subjects

Free Radicals chemistry, Free Radicals radiation effects, Imines radiation effects, Photochemistry, Proteins radiation effects, Rhenium radiation effects, Tryptophan radiation effects, Tyrosine radiation effects, Imines chemistry, Proteins chemistry, Rhenium chemistry, Tryptophan chemistry, Tyrosine chemistry

Published

2001

39. Structures of the N(omega)-hydroxy-L-arginine complex of inducible nitric oxide synthase oxygenase dimer with active and inactive pterins.

Author

Crane BR, Arvai AS, Ghosh S, Getzoff ED, Stuehr DJ, and Tainer JA

Subjects

Animals, Arginine chemistry, Arginine metabolism, Binding Sites, Biopterins chemistry, Catalysis, Crystallography, X-Ray, Dimerization, Heme metabolism, Hydrogen Bonding, Iron metabolism, Mice, Models, Chemical, Models, Molecular, Molecular Sequence Data, Nitric Oxide Synthase Type II, Oxidation-Reduction, Oxygen metabolism, Oxygenases chemistry, Protein Conformation, Structure-Activity Relationship, Arginine analogs & derivatives, Biopterins analogs & derivatives, Biopterins metabolism, Nitric Oxide Synthase chemistry, Nitric Oxide Synthase metabolism, Oxygenases metabolism

Abstract

Nitric oxide synthases (NOSs) catalyze two mechanistically distinct, tetrahydrobiopterin (H(4)B)-dependent, heme-based oxidations that first convert L-arginine (L-Arg) to N(omega)-hydroxy-L-arginine (NHA) and then NHA to L-citrulline and nitric oxide. Structures of the murine inducible NOS oxygenase domain (iNOS(ox)) complexed with NHA indicate that NHA and L-Arg both bind with the same conformation adjacent to the heme iron and neither interacts directly with it nor with H(4)B. Steric restriction of dioxygen binding to the heme in the NHA complex suggests either small conformational adjustments in the ternary complex or a concerted reaction of dioxygen with NHA and the heme iron. Interactions of the NHA hydroxyl with active center beta-structure and the heme ring polarize and distort the hydroxyguanidinium to increase substrate reactivity. Steric constraints in the active center rule against superoxo-iron accepting a hydrogen atom from the NHA hydroxyl in their initial reaction, but support an Fe(III)-peroxo-NHA radical conjugate as an intermediate. However, our structures do not exclude an oxo-iron intermediate participating in either L-Arg or NHA oxidation. Identical binding modes for active H(4)B, the inactive quinonoid-dihydrobiopterin (q-H(2)B), and inactive 4-amino-H(4)B indicate that conformational differences cannot explain pterin inactivity. Different redox and/or protonation states of q-H(2)B and 4-amino-H(4)B relative to H(4)B likely affect their ability to electronically influence the heme and/or undergo redox reactions during NOS catalysis. On the basis of these structures, we propose a testable mechanism where neutral H(4)B transfers both an electron and a 3,4-amide proton to the heme during the first step of NO synthesis.

Published

2000

40. Structures of the siroheme- and Fe4S4-containing active center of sulfite reductase in different states of oxidation: heme activation via reduction-gated exogenous ligand exchange.

Author

Crane BR, Siegel LM, and Getzoff ED

Subjects

Binding Sites, Crystallization, Crystallography, X-Ray, Electron Spin Resonance Spectroscopy, Electrophoresis, Polyacrylamide Gel, Fourier Analysis, Heme chemistry, Heme metabolism, Iron-Sulfur Proteins metabolism, Kinetics, Ligands, Models, Molecular, Oxidation-Reduction, Oxidoreductases Acting on Sulfur Group Donors metabolism, Phosphates metabolism, Protein Binding, Reducing Agents, Solutions, Heme analogs & derivatives, Iron-Sulfur Proteins chemistry, Oxidoreductases Acting on Sulfur Group Donors chemistry

Abstract

The active center of the Escherichia coli sulfite reductase hemoprotein (SiRHP) is exquisitely designed to catalyze the six-electron reductions of sulfite to sulfide and nitrite to ammonia. Refined high-resolution crystallographic structures of oxidized, two-electron reduced, and intermediately reduced states of SiRHP, monitored by single-crystal electron paramagnetic resonance (EPR) spectroscopy, reveal that a bridging cysteine thiolate supplied by the protein always covalently links the siroheme (iron isobacteriochlorin) to the Fe4S4 cluster, facilitating their ability to transfer electrons to substrate. The reduction potential and reactivity of the cluster are tuned by association with the siroheme, accessibility to solvent, and hydrogen bonds supplied by the protein loops containing the four cluster-ligating cysteines. The distorted conformation of the siroheme recognized by the protein potentially destabilizes the electronic conjugation of the isobacteriochlorin ring and produces axial configurations for some propionate side chains that promote interactions with exogenous ligands and active-site residues. An extensive hydrogen-bond network of positively charged side chains, ordered water molecules, and siroheme carboxylates coordinates, polarizes, and influences the protonation state of anionic ligands. In the oxidized (siroheme Fe3+, Fe4S42+) SiRHP crystal structure, the high density of positive charges in the binding pocket is stabilized by the siroheme's sixth axial ligand-an exogenous phosphate anion. Binding assays with H32PO42- demonstrate that oxidized SiRHP binds phosphate in solution with a dissociation constant of 14 microM at pH 7.7, suggesting that phosphate anions play an important role in stabilizing and sequestering the active-site of the oxidized enzyme in vivo. Reduction of the cofactors couples changes in siroheme iron coordination geometry to changes in active-site protein conformation, leading to phosphate release both in the crystal and in solution. An intermediately reduced enzyme, where the siroheme is mainly ferrous (+2) and the cluster cubane is mainly oxidized (+2), appears to have the lowest affinity for phosphate in the crystal. Reduction-gated release of phosphate from the substrate-binding site may explain the 10(5)-fold increase in rates of ligand association that accompany reduction of SiRHP.

Published

1997

41. Probing the catalytic mechanism of sulfite reductase by X-ray crystallography: structures of the Escherichia coli hemoprotein in complex with substrates, inhibitors, intermediates, and products.

Author

Crane BR, Siegel LM, and Getzoff ED

Subjects

Binding Sites, Carbon Monoxide chemistry, Catalysis, Crystallography, X-Ray, Cyanides chemistry, Heme analogs & derivatives, Heme chemistry, Ligands, Nitrates chemistry, Nitrites chemistry, Oxidation-Reduction, Oxidoreductases Acting on Sulfur Group Donors metabolism, Substrate Specificity drug effects, Sulfites chemistry, Escherichia coli enzymology, Hemeproteins chemistry, Oxidoreductases Acting on Sulfur Group Donors antagonists & inhibitors, Oxidoreductases Acting on Sulfur Group Donors chemistry

Abstract

To further understand the six-electron reductions of sulfite and nitrite catalyzed by the Escherichia coli sulfite reductase hemoprotein (SiRHP), we have determined crystallographic structures of the enzyme in complex with the inhibitors phosphate, carbon monoxide, and cyanide, the substrates sulfite and nitrite, the intermediate nitric oxide, the product sulfide (or, most likely, an oxidized derivative thereof), and an oxidized nitrogen species (probably nitrate). A hydrogen-bonded cage of ligand-binding arginine and lysine side chains, ordered water molecules, and siroheme carboxylates provides preferred locations for recognizing the common functional groups of these ligands and accommodates their varied sizes, shapes, and charged without requiring substantial structural changes. The coordination geometries presented here suggest that the successively deoxygenated sulfur and nitrogen species produced during catalysis need not alter their orientation in the active site to adopt new stable coordination states. Strong pi-acid ligands decrease the bond length between the siroheme and the proximal cysteine thiolate shared with the iron-sulfur cluster, emphasizing the ability of the coupled cofactors to promote electron tranfer into substrate. On binding the siroheme, the substrate sulfite provides an oxygen atom in a unique location of the binding site compared to all other ligands studied, induces a spin transition in the siroheme iron, flips an active-site arginine, and orders surrounding active-center loops. The loop that coalesces over the active center shields the positively charged ligand-coordinating residues from solvent, enhancing their ability to polarize the substrate. Hydrogen bonds supplied by active-site arginine and lysine residues facilitate charge transfer into the substrate from the electron-rich cofactors, activate S-O bonds for reductive cleavage, and provide potential proton sources for the formation of favorable aquo leaving groups on the substrate. Strong interactions between sulfite and ordered water molecules also implicate solvent as a source of protons for generating product water. From the structures reported here, we propose a series of key structural states of ligated SiRHP in the catalytic reduction of sulfite to sulfide.

Published

1997

42. Mutagenesis of acidic residues in the oxygenase domain of inducible nitric-oxide synthase identifies a glutamate involved in arginine binding.

Author

Gachhui R, Ghosh DK, Wu C, Parkinson J, Crane BR, and Stuehr DJ

Subjects

Alanine, Amino Acid Sequence, Animals, Antioxidants metabolism, Biopterins analogs & derivatives, Biopterins metabolism, Cattle, Chromatography, Gel, Heme metabolism, Humans, Mice, Molecular Sequence Data, Mutagenesis, Site-Directed, Nitric Oxide Synthase genetics, Oxygenases genetics, Oxygenases metabolism, Rats, Structure-Activity Relationship, Arginine metabolism, Glutamic Acid metabolism, Nitric Oxide Synthase metabolism

Abstract

The oxygenase domain of the mouse cytokine-inducible nitric-oxide synthase (iNOSox, amino acids 1-498) binds heme, tetrahydrobiopterin, and the substrate Arg and is the domain responsible for catalyzing nitric oxide synthesis and maintaining the enzyme's active dimeric structure. To further understand iNOSox structure-function, we carried out alanine point mutagenesis on 15 conserved acidic residues located within a region of iNOSox (amino acids 352-473) that shares sequence homology with the pterin-binding module in dihydrofolate reductases and may be important for iNOSox subunit dimerization and/or Arg binding. Five point mutants were identical or nearly identical to wild-type, while 10 exhibited a range of defects that included low heme content (2), heme ligand instability (2), defective dimerization (2), and poor Arg and/or tetrahydrobiopterin binding (4). Mutations that caused defective tetrahydrobiopterin binding were also associated with other defects. In contrast, two mutants (E371A and D376A) exhibited an exclusive defect in Arg binding. These mutants were dimeric, indicating that dimerization of iNOSox in Escherichia coli does not require Arg. In one case (E371A), the defect in Arg binding was absolute, as assessed by spectral perturbation, radioligand binding, and catalytic studies. We conclude that mutagenesis of conserved acidic residues within this region of iNOSox can lead to exclusive defects in dimerization and in Arg binding. Modeling considerations predict that the E371 carboxylate may participate in Arg binding by interacting with its guanidine moiety.

Published

1997

43. Unusual trigonal-planar copper configuration revealed in the atomic structure of yeast copper-zinc superoxide dismutase.

Author

Ogihara NL, Parge HE, Hart PJ, Weiss MS, Goto JJ, Crane BR, Tsang J, Slater K, Roe JA, Valentine JS, Eisenberg D, and Tainer JA

Subjects

Crystallography, X-Ray, Electron Spin Resonance Spectroscopy, Fourier Analysis, Oxidation-Reduction, Protein Conformation, Saccharomyces cerevisiae enzymology, Superoxide Dismutase chemistry

Abstract

The three-dimensional structure of yeast copper-zinc superoxide dismutase (CuZnSOD) has been determined in a new crystal form in space group R32 and refined against X-ray diffraction data using difference Fourier and restrained crystallographic refinement techniques. The unexpected result is that the copper ion has moved approximately 1 angstrom from its position in previously reported CuZnSOD models, the copper-imidazolate bridge is broken, and a roughly trigonal planar ligand geometry characteristic of Cu(I) rather than Cu(II) is revealed. Final R values for the two nearly identical room temperature structures are 18.6% for all 19 149 reflections in the 10.0-1.7 angstrom resolution range and 18. 2% for 17 682 reflections (F > 2 sigma) in the 10.0-1.73 angstrom resolution range. A third structure has been determined using X-ray data collected at -180 degrees C. The final R value for this structure is 19.0% (R(free) = 22.9%) for all 24 356 reflections in the 10.0-1.55 angstrom resolution range. Virtually no change in the positions of the ligands to the zinc center is observed in these models. The origin of the broken bridge and altered Cu-ligand geometry is discussed.

Published

1996

44. Proton uptake accompanies formation of the ternary complex of citrate synthase, oxaloacetate, and the transition-state analog inhibitor, carboxymethyl-CoA. Evidence that a neutral enol is the activated form of acetyl-CoA in the citrate synthase reaction.

Author

Kurz LC, Shah S, Crane BR, Donald LJ, Duckworth HW, and Drysdale GR

Subjects

Allosteric Regulation, Animals, Circular Dichroism, Escherichia coli enzymology, Hydrogen-Ion Concentration, Isoelectric Point, Magnetic Resonance Spectroscopy, Myocardium enzymology, Potassium Chloride pharmacology, Swine, Acetyl Coenzyme A metabolism, Acyl Coenzyme A metabolism, Citrate (si)-Synthase metabolism, Oxaloacetates metabolism, Protons

Abstract

Citrate synthase complexes with the transition-state analog inhibitor, carboxymethyl-CoA (CM-CoA), are believed to mimic those with the activated form of acetyl-CoA. The X-ray structure [Karpusas, M., Branchaud, B., & Remington, S.J. (1990) Biochemistry 29, 2213] of the ternary complex of the enzyme, oxaloacetate, and CMCoA has been used as the basis for a proposal that a neutral enol of acetyl-CoA is that activated form. Since the inhibitor carboxyl has a pKa of 3.90, analogy with an enolic acetyl-CoA intermediate leads to the prediction that a proton should be taken up from solution upon formation of the analog complex so that the transition-state analog carboxyl is protonated when bound. We have obtained evidence in solution for this proposal by comparing the isoelectric points and the pH dependence of the dissociation constants of the ternary complexes of the pig heart enzyme with the neutral ground-state analog inhibitor, acetonyl-CoA (KCoA), and the anionic transition-state analog inhibitor (CMCoA) and by studying the NMR spectra of the transition-state analog complexes of allosteric (Escherichia coli) and nonallosteric (pig heart) enzymes. The pH dependence of the dissociation constant of the ground-state analog indicates no proton uptake, while that for the transition-state analog indicates that 0.55 +/- 0.04 proton is taken up when the analog binds to the citrate synthase-oxaloacetate binary complex. The overall charges of ternary complexes of the pig heart enzyme with the transition-state and ground-state analog inhibitors are the same, as monitored by their isoelectric points.(ABSTRACT TRUNCATED AT 250 WORDS)

Published

1992