Thermodynamic studies of the mechanism of metal binding to the Escherichia coli zinc transporter YiiP

Sequence homology of the Escherichia coli YiiP places it within the family of cation diffusion facilitators, a family of membrane transporters that play a central role in regulating cellular zinc homeostasis. Here we describe the first thermodynamic and mechanistic studies of metal binding to a cation diffusion facilitator. Isothermal titration calorimetric analyses of the purified YiiP and binding competitions among Zn(2+), Cd(2+), and Hg(2+) revealed a mutually competitive binding site common to three metal ions and a set of noncompetitive binding sites, including one Cd(2+) site, one Hg(2+) site, and at least one Zn(2+) site, to which the binding of Zn(2+) exhibited partial inhibitions of both Cd(2+) and Hg(2+) bindings. Lowering the pH from 7.0 to 5.5 inhibited binding of Zn(2+) and Cd(2+) to the common site. Further, the enthalpy change of the Cd(2+) binding to the common site was found to be related linearly to the ionization enthalpy of the pH buffer with a slope corresponding to the release of 1.23 H(+) for each Cd(2+) binding. These H(+) effects are consistent with a coupled deprotonation process upon binding of Zn(2+) and Cd(2+). Modification of histidine residues by diethyl pyrocarbonate specifically inhibited Zn(2+) binding to the common binding site, indicating that the mechanism of binding-deprotonation coupling involves a histidine residue(s).     

Oligomeric state of the Escherichia coli metal transporter YiiP

YiiP is a 32.9-kDa metal transporter found in the plasma membrane of Escherichia coli (Chao, Y., and Fu, D. (2004) J. Biol. Chem. 279, 17173-17180). Here we report the determination of the YiiP oligomeric state in detergent-lipid micelles and in membranes. Molecular masses of YiiP solubilized with dodecyl-, undecyl-, decyl-, or nonyl-beta-d-maltoside were measured directly using size-exclusion chromatography coupled with laser light-scattering photometry, yielding a mass distribution of YiiP homo-oligomers within a narrow range (68.0-68.8 kDa) that equals the predicted mass of a YiiP dimer within experimental error. The detergent-lipid masses associated with YiiP in the mixed micelles were found to increase from 135.5 to 232.6 kDa, with an apparent correlation with the alkyl chain length of the maltoside detergents. Cross-linking the detergent-solubilized YiiP with 1-ethyl-3-[3-dimethylaminopropyl] carbodiimide hydrochloride (EDC) resulted in a dimeric cross-linked product in an EDC concentration-dependent manner. The oligomeric state of the purified YiiP in reconstituted membranes was determined by electron microscopic analysis of two-dimensional YiiP crystals in negative stain. A projection structure calculated from measurable optical diffractions to 25 A revealed a pseudo-2-fold symmetry within a molecular boundary of approximately 75 x 40 A, indicative of the presence of YiiP dimers in membranes. These data provide direct structural evidence for a dimeric association of YiiP both in detergent-lipid micelles and in the reconstituted lipid bilayer. The functional relevance of the dimeric association in YiiP is discussed.     

Binding and transport of metal ions at the dimer interface of the Escherichia coli metal transporter YiiP

YiiP is a representative member of the cation diffusion facilitator (CDF) family, a class of ubiquitous metal transporters that play an essential role in metal homeostasis. Recently, a pair of Zn2+/Cd2+-selective binding sites has been localized to two highly conserved aspartyl residues (Asp157), each in a 2-fold-symmetry-related transmembrane segment 5 (TM5) of a YiiP homodimer. Here we report the functional and structural interactions between Asp157 and yet another highly conserved Asp49 in the TM2. Calorimetric binding analysis indicated that Asp49 and Asp157 contribute to a common Cd2+ binding site in each subunit. Copper phenanthroline oxidation of YiiP(D49C), YiiP(D157C), and YiiP(D49C/D157C) yielded inter- and intra-subunit cross-links among Cys49 and Cys157, consistent with the spatial proximity of two (Asp49-Asp157) sites at the dimer interface. Hg2+ binding to YiiP(D49C) or YiiP(D49C/D157C) also yielded a Cys49-Hg2+-Cys49 biscysteinate complex across the dimer interface, further establishing the interfacial location of a (Asp49-Asp157)2 bimetal binding center. Two bound Cd2+ ions were found transported cooperatively with a sigmoidal dependence on the Cd2+ concentration (n = 1.4). The binding affinity, transport cooperativity, and rate were modestly reduced by either a D49C or D157C mutation, but greatly diminished when all the bidentate aspartate O-ligands in (Asp49-Asp157)2 were replaced by the monodentate cysteine S-ligands. The functional significance of these findings is discussed based on the unique coordination chemistry of aspartyl residues and a model for the translocation pathway of metal ions at the YiiP dimer interface.     

Mutations in the aspartate receptor of Escherichia coli which affect aspartate binding

The effects of five mutations at arginines 64, 69, and 73 of the Tar protein were analyzed using swarm assays, aspartate binding in purified membranes, and methylation both in vitro and in vivo. The defects in the responses of these mutant receptors to aspartate were shown to be directly attributable to reduced binding of aspartate to the receptor rather than to defects in their signaling characteristics. Mutations at residues 64, 69, and 73 reduced aspartate binding by factors of greater than 10(-4), 10(-3), and 10(-2), respectively. Once aspartate was bound, the mutants exhibited normal signaling properties. No cooperativity was observed in the coupling of aspartate binding to methylation, indicating that the monomers of the receptor dimer act independently. The in vitro methylation system was thus shown to be an effective way of measuring aspartate binding constants and examining the functional integrity of the proteins. The maltose responses of the receptor proteins were affected slightly, or not at all, in an in vivo methylation assay. Two models for the roles of these arginine residues in receptor function are discussed.     

Structure and metal binding properties of ZnuA, a periplasmic zinc transporter from Escherichia coli

ZnuA is the periplasmic Zn²⁺-binding protein associated with the high-affinity ATP-binding cassette ZnuABC transporter from Escherichia coli. Although several structures of ZnuA and its homologs have been determined, details regarding metal ion stoichiometry, affinity, and specificity as well as the mechanism of metal uptake and transfer remain unclear. The crystal structures of E. coli ZnuA (Eco-ZnuA) in the apo, Zn²⁺-bound, and Co²⁺-bound forms have been determined. ZnZnuA binds at least two metal ions. The first, observed previously in other structures, is coordinated tetrahedrally by Glu59, His60, His143, and His207. Replacement of Zn²⁺ with Co²⁺ results in almost identical coordination geometry at this site. The second metal binding site involves His224 and several yet to be identified residues from the His-rich loop that is unique to Zn²⁺ periplasmic metal binding receptors. Electron paramagnetic resonance and X-ray absorption spectroscopic data on CoZnuA provide additional insight into possible residues involved in this second site. The second site is also detected by metal analysis and circular dichroism (CD) titrations. Eco-ZnuA binds Zn²⁺ (estimated K _d < 20 nM), Co²⁺, Ni²⁺, Cu²⁺, Cu⁺, and Cd²⁺, but not Mn²⁺. Finally, conformational changes upon metal binding observed in the crystal structures together with fluorescence and CD data indicate that only Zn²⁺ substantially stabilizes ZnuA and might facilitate recognition of ZnuB and subsequent metal transfer. Electronic supplementary material The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Free energy simulations of ligand binding to the aspartate transporter Glt(Ph)

Glutamate/Aspartate transporters cotransport three Na⁺ and one H⁺ ions with the substrate and countertransport one K⁺ ion. The binding sites for the substrate and two Na⁺ ions have been observed in the crystal structure of the archeal homolog Glt_Ph, while the binding site for the third Na⁺ ion has been proposed from computational studies and confirmed by experiments. Here we perform detailed free energy simulations of Glt_Ph, giving a comprehensive characterization of the substrate and ion binding sites, and calculating their binding free energies in various configurations. Our results show unequivocally that the substrate binds after the binding of two Na⁺ ions. They also shed light into Asp/Glu selectivity of Glt_Ph, which is not observed in eukaryotic glutamate transporters.     

3D model of the Escherichia coli multidrug transporter MdfA reveals an essential membrane-embedded positive charge

MdfA is an Escherichia coli multidrug transporter of the major facilitator superfamily (MFS) of secondary transporters. Although several aspects of multidrug recognition by MdfA have been characterized, better understanding the detailed mechanism of its function requires structural information. Previous studies have modeled the 3D structures of MFS proteins, based on the X-ray structure of LacY and GlpT. However, because of poor sequence homology, between LacY, GlpT, and MdfA additional constraints were required for a reliable homology modeling. Using an algorithm that predicts the angular orientation of each transmembrane helix (TM) (kPROT), we obtained a remarkably similar pattern for the 12 TMs of MdfA and those of GlpT and LacY, suggesting that they all have similar helix packing. Consequently, a 3D model was constructed for MdfA by structural alignment with LacY and GlpT, using the kPROT results as an additional constraint. Further refinement and a preliminary evaluation of the model were achieved by correlated mutation analysis and the available experimental data. Surprisingly, in addition to the previously characterized membrane-embedded glutamate at position 26, the model suggests that Asp34 and Arg112 are located within the membrane, on the same face of the cavity as Glu26. Importantly, Arg112 is evolutionarily conserved in secondary drug transporters, and here we show that a positive charge at this position is absolutely essential for multidrug transport by MdfA.     

Effectors of Escherichia coli aspartate transcarbamoylase differentially perturb aspartate binding rather than the T-R transition

New systematic methods developed for equilibrium isotope exchange kinetics have been used to analyze the effects of activator ATP and inhibitor CTP with Escherichia coli aspartate transcarbamoylase. This indepth approach requires (a) variation of [modifier] with fixed subsaturating levels of substrates, and (b) variation of at least three combinations of reactant-product pairs in constant ratio at equilibrium: [A,B,P,Q], [A,P], and [B,Q] with the co-substrates held constant, in the presence and absence of added modifier. Both ATP and CTP had much stronger effects on the [14C]Asp in equilibrium C-Asp exchange rate than on [32P]C-P in equilibrium Pi. The bisubstrate analog N-phosphonacetyl-L-aspartate activated, then inhibited, Asp in equilibrium C-Asp more strongly than C-P in equilibrium Pi. N-Phosphonacetyl-L-aspartate gave complete (100%) inhibition, whereas CTP inhibition of either exchange was only partial. Substrate saturation curves in the presence and absence of effectors indicate that ATP and CTP perturb the observed values of Rmax and S0.5 in different fashions without appreciably changing the observed Hill number. Computer simulations indicate that the primary site of ATP and CTP action is the association rate for Asp, not the allosteric T-R transition. This finding is substantiated by previous studies in which modified aspartate transcarbamoylase had lost cooperative Asp binding without loss of sensitivity to effectors, or in which sensitivity to one effector could be deleted selectively. The present results, with newly devised computer simulation and analysis methods, illustrate the usefulness of equilibrium isotope exchange kinetic probes for providing unique insights to enzyme regulatory mechanisms, to define exactly which steps are altered in a given kinetic mechanism.     

A membrane-embedded glutamate is required for ligand binding to the multidrug transporter EmrE

EmrE is an Escherichia coli multidrug transporter that confers resistance to a variety of toxins by removing them in exchange for hydrogen ions. The detergent-solubilized protein binds tetraphenylphosphonium (TPP(+)) with a K(D) of 10 nM. One mole of ligand is bound per approximately 3 mol of EmrE, suggesting that there is one binding site per trimer. The steep pH dependence of binding suggests that one or more residues, with an apparent pK of approximately 7.5, release protons prior to ligand binding. A conservative Asp replacement (E14D) at position 14 of the only membrane-embedded charged residue shows little transport activity, but binds TPP(+) at levels similar to those of the wild-type protein. The apparent pK of the Asp shifts to <5.0. The data are consistent with a mechanism requiring Glu14 for both substrate and proton recognition. We propose a model in which two of the three Glu14s in the postulated trimeric EmrE homooligomer deprotonate upon ligand binding. The ligand is released on the other face of the membrane after binding of protons to Glu14.     

Role of aspartate 27 in the binding of methotrexate to dihydrofolate reductase from Escherichia coli

Dihydrofolate reductase from wild-type Escherichia coli (WT-ECDHFR) and from a mutant enzyme in which aspartate 27 is replaced by asparagine have been compared with respect to the binding of the inhibitor methotrexate (MTX). Although the Asp27----Asn substitution causes only small changes in the association rate constants (kon) for the formation of binary and ternary (with NADPH) complexes, the dissociation rate constants for these complexes (koff) are increased for the mutant enzyme by factors of about 5- and 100-fold, respectively, at pH 7.65. In binding experiments, the initial MTX binary and ternary complexes of the mutant enzyme were found to undergo relatively rapid isomerization (kobs approximately 17 and 145 s-1, respectively). Although such rapid isomerization of complexes of WT-ECDHFR could not be detected in binding experiments, evidence of a slow isomerization (k = 4 x 10(-3) s-1) of the ternary WT-ECDHFR.MTX.NADPH complex was obtained from progress of inhibition experiments. This slow isomerization increases binding of MTX to WT-ECDHFR only 2.4-fold (much less than previously estimated). From presently available data, we could not determine the contribution of the rapid isomerization of complexes to the binding of MTX to the mutant enzyme. The Asp27----Asn substitution increases the overall dissociation constant (KD) 9-fold for the binary complex and 85-fold for the ternary complex. When it is also taken into account that a proton ultimately derived from the solvent must be added to MTX bound to the WT enzyme, but not to MTX bound to the mutant enzyme, these increases in KD for the mutant enzyme correspond to decreases in binding energy for MTX of 3.9 and 5.2 kcal/mol at pH 7.65 for the binary and ternary complexes, respectively.     

Identification of the Escherichia coli K-12 Nramp orthologue (MntH) as a selective divalent metal ion transporter

The Escherichia coli mntH (formerly yfeP) gene encodes a putative membrane protein (MntH) highly similar to members of the eukaryotic Nramp family of divalent metal ion transporters. To determine the function of E. coli MntH, a null mutant was created and MntH was overexpressed both in wild-type E. coli and in the metal-dependent mutant hflB1(Ts). At the restrictive temperature 42 degrees C, the mntH null mutation reduces the suppression of hflB1(Ts) thermosensitivity by exogenous divalent metals. Conversely, overexpression of MntH restores growth at 42 degrees C, increases suppression of the ts phenotype by Fe(II) and Ni(II) and renders hflB1(Ts) cells hypersensitive to Mn(II). Transport studies in intact cells show that MntH selectively facilitates uptake of 54Mn(II) and 55Fe(II) in a temperature-, time- and proton-dependent manner. Competition studies in uptake assays and growth inhibition experiments in hflB1(Ts) mutants together indicate that MntH is a divalent metal cation transporter of broad substrate specificity. The functional characteristics of MntH suggest that it corresponds to the previously described manganese transporter of E. coli. This study indicates that proton-dependent divalent metal ion uptake has been preserved in the Nramp family from bacteria to humans.     

A bacterial glutathione transporter (Escherichia coli CydDC) exports reductant to the periplasm

Glutathione (GSH), a major biological antioxidant, maintains redox balance in prokaryotes and eukaryotic cells and forms exportable conjugates with compounds of pharmacological and agronomic importance. However, no GSH transporter has been characterized in a prokaryote. We show here that a heterodimeric ATP-binding cassette-type transporter, CydDC, mediates GSH transport across the Escherichia coli cytoplasmic membrane. In everted membrane vesicles, GSH is imported via an ATP-driven, protonophore-insensitive, orthovanadate-sensitive mechanism, equating with export to the periplasm in intact cells. GSH transport and cytochrome bd quinol oxidase assembly are abolished in the cydD1 mutant. Glutathione disulfide (GSSG) was not transported in either Cyd(+) or Cyd(-) strains. Exogenous GSH restores defective swarming motility and benzylpenicillin sensitivity in a cydD mutant and also benzylpenicillin sensitivity in a gshA mutant defective in GSH synthesis. Overexpression of the cydDC operon in dsbD mutants defective in disulfide bond formation restores dithiothreitol tolerance and periplasmic cytochrome b assembly, revealing redundant pathways for reductant export to the periplasm. These results identify the first prokaryotic GSH transporter and indicate a key role for GSH in periplasmic redox homeostasis.     

Mutations that affect ligand binding to the Escherichia coli aspartate receptor: implications for transmembrane signaling

Three arginine residues of the binding site of the Escherichia coli aspartate receptor contribute to its high affinity for aspartate (K(d) approximately 3 microm). Site-directed mutations at residue 64 had the greatest effect on aspartate binding. No residue could substitute for the native arginine; all changes resulted in an apparent K(d) of approximately 35 mm. These mutations had little impact on maltose responses. At residue Arg-69, a lysine substitution was least disruptive, conferring an apparent K(d) of 0.3 mm for aspartate. Results obtained for an alanine mutant were similar to those with cysteine and histidine mutants (K(d) approximately 5 mm) indicating that side chain size was not an important factor here. Proline and aspartate caused more severe defects, presumably for reasons related to conformation and charge. The impact of residue 69 mutations on the maltose response was small. Mutations at Arg-73 had similar effects on aspartate binding (K(d) 0.3-7 mm) but more severe consequences for maltose responses. Larger side chains resulted in the best aspartate binding, implying steric considerations are important here. Signaling in the mutant proteins was surprisingly robust. Given aspartate binding, signaling occurred with essentially wild-type efficiency. These results were evaluated in the context of available structural data.     

Zn(II) binding to Escherichia coli 70S ribosomes

Escherichia coli 70S ribosomes tightly bind 8 equiv of Zn(II), and EXAFS spectra indicate that Zn(II) may be protein-bound. Ribosomes were incubated with EDTA and Zn(II), and after dialysis, the resulting ribosomes bound 5 and 11 equiv of Zn(II), respectively. EXAFS studies show that the additional Zn(II) in the zinc-supplemented ribosomes binds in part to the phosphate backbone of the ribosome. Lastly, in vitro translation studies demonstrate that EDTA-treated ribosomes do not synthesize an active Zn(II)-bound metalloenzyme, while the as-isolated ribosomes do. These studies demonstrate that the majority of intracellular Zn(II) resides in the ribosome.     

Three residues involved in binding and catalysis in the carbamyl phosphate binding site of Escherichia coli aspartate transcarbamylase

Site-directed mutagenesis was used to create four mutant versions of Escherichia coli aspartate transcarbamylase at three positions in the catalytic chain of the enzyme. The location of all the amino acid substitutions was near the carbamyl phosphate binding site as previously determined by X-ray crystallography. Arg-54, which interacts with both the anhydride oxygen and a phosphate oxygen of carbamyl phosphate, was replaced by alanine. This mutant enzyme was approximately 17,000-fold less active than the wild type, although the binding of substrates and substrate analogues was not altered substantially. Arg-105, which interacts with both the carbonyl oxygen and a phosphate oxygen of carbamyl phosphate, was replaced by alanine. This mutant enzyme exhibited an approximate 1000-fold loss of activity, while the activity of catalytic subunit isolated from this mutant enzyme was reduced by 170-fold compared to the wild-type catalytic subunit. The KD of carbamyl phosphate and the inhibition constants for acetyl phosphate and N-(phosphono-acetyl)-L-aspartate (PALA) were increased substantially by this amino acid substitution. Furthermore, this loss in substrate and substrate analogue binding can be correlated with the large increases in the aspartate and carbamyl phosphate concentrations at half of the maximum observed specific activity, [S]0.5. Gln-137, which interacts with the amino group of carbamyl phosphate, was replaced by both asparagine and alanine. The asparagine mutant exhibited only a small reduction in activity while the alanine mutant was approximately 50-fold less active than the wild type. The catalytic subunits of both these mutant enzymes were substantially more active than the corresponding holoenzymes.(ABSTRACT TRUNCATED AT 250 WORDS)     

Puromycin binding to the donor (P-) site of Escherichia coli ribosomes

Puromycin inhibits the interaction of peptidyl-tRNA analogues AcPhe-tRNA_ox-red^Phe, AcPhe-tRNA^Phe and fMet-tRNA_f^Met with the donor (P-) site of Escherichia coli ribosomes. affects almost equally both the rate of the binding and the equilibrium of the system. This means that the effect is due to direct competition for the P-site, but not due to the indirect influence via the acceptor (A-) site. The inhibition was observed also in 30 S ribosomal subunits, therefore the puromycin binding site is situated far from the peptidyl transferase center. Quantitative measurements show that the affinity of puromycin for its new ribosomal binding site is similar to its affinity for the acceptor site of the peptidyl transferase center.     

Function of threonine-55 in the carbamoyl phosphate binding site of Escherichia coli aspartate transcarbamoylase

Carbamoyl phosphate is held in the active site of Escherichia coli aspartate transcarbamoylase by a variety of interactions with specific side chains of the enzyme. In particular, the carbonyl group of carbamoyl phosphate interacts with Thr-55, Arg-105, and His-134. Site-specific mutagenesis was used to create a mutant version of the enzyme in which Thr-55 was replaced by alanine in order to help define the role of this residue in the catalytic mechanism. The Thr-55----Ala holoenzyme exhibits a 4.7-fold reduction in maximal observed specific activity, no alteration in aspartate cooperativity, and a small reduction in carbamoyl phosphate cooperativity. The mutation also causes 14-fold and 35-fold increases in the carbamoyl phosphate and aspartate concentrations required for half the maximal observed specific activity, respectively. Circular dichroism spectroscopy has shown that saturating carbamoyl phosphate does not induce a conformational change in the Thr-55----Ala holoenzyme as it does for the wild-type holoenzyme. The kinetic properties of the Thr-55----Ala catalytic subunit are altered to a greater extent than the mutant holoenzyme. The mutant catalytic subunit cannot be saturated by either substrate under the experimental conditions. Furthermore, as opposed to the wild-type catalytic subunit, the Thr-55----Ala catalytic subunit shows cooperativity for aspartate and can be activated by N-(phosphonoacetyl)-L-aspartate in the presence of low concentrations of aspartate and high concentrations of carbamoyl phosphate. As deduced by circular dichroism spectroscopy, the conformation of the Thr-55----Ala catalytic subunit in the absence of active-site ligands is distinctly different from the wild-type catalytic subunit.(ABSTRACT TRUNCATED AT 250 WORDS)     

The metal permease ZupT from Escherichia coli is a transporter with a broad substrate spectrum

The Escherichia coli zupT (formerly ygiE) gene encodes a cytoplasmic membrane protein (ZupT) related to members of the eukaryotic ZIP family of divalent metal ion transporters. Previously, ZupT was shown to be responsible for uptake of zinc. In this study, we show that ZupT is a divalent metal cation transporter of broad substrate specificity. An E. coli strain with a disruption in all known iron uptake systems could grow in the presence of chelators only if zupT was expressed. Heterologous expression of Arabidopsis thaliana ZIP1 could also alleviate iron deficiency in this E. coli strain, as could expression of indigenous mntH or feoABC. Transport studies with intact cells showed that ZupT facilitates uptake of 55Fe2+ similarly to uptake of MntH or Feo. Other divalent cations were also taken up by ZupT, as shown using 57Co2+. Expression of zupT rendered E. coli cells hypersensitive to Co2+ and sensitive to Mn2+. ZupT did not appear to be metal regulated: expression of a Phi(zupT-lacZ) operon fusion indicated that zupT is expressed constitutively at a low level.