Copper uptake proteins (CTRs), mediate cellular acquisition of the essential metal copper in all eukaryotes. Here, we report the structure of the human CTR1 protein solved by electron crystallography to an in plane resolution of 7 Å. Reminiscent of the design of traditional ion channels, trimeric hCTR1 creates a pore that stretches across the membrane bilayer at the interface between the subunits. Assignment of the helices identifies the second transmembrane helix as the key element lining the pore, and reveals how functionally important residues on this helix could participate in Cu(I)-coordination during transport. Aligned with and sealing both ends of the pore, extracellular and intracellular domains of hCTR1 appear to provide additional metal binding sites. Consistent with the existence of distinct metal binding sites, we demonstrate that hCTR1 stably binds 2 Cu(I)-ions through 3-coordinate Cu-S bonds, and that mutations in one of these putative binding sites results in a change of coordination chemistry.copper homeostasis ͉ electron crystallography ͉ EXAFS ͉ membrane protein
X-ray absorption spectroscopy has been used to probe the local coordination of the copper centers in the oxidized and reduced states of the peptidylglycine monooxygenase catalytic core (PHMcc) in both the resting and substrate-bound forms of the enzyme. The results indicate that reduction causes significant changes in coordination number and geometry of both Cu centers (CuH and CuM). The CuH center changes from 4- or 5-coordinate tetragonal to a 2-coordinate configuration, with one of the three histidine ligands becoming undetectable by EXAFS (suggesting that it has moved away from the CuH by at least 0.3 A). The CuM center changes from 4- or 5-coordinate tetragonal to a trigonal or tetrahedral configuration, with an estimated 0.3-0.5 A movement of the M314 S ligand. Reduction also leads to loss of coordinated water from both of the coppers. Substrate binding has little or no effect on the local environment of the Cu centers in either oxidation state. These findings bring into question whether direct electron transfer between CuH and CuM via a tunneling mechanism can be fast enough to support the observed catalytic rate, and suggest that some other mechanism for electron transfer, such as superoxide channeling, should be considered.
The temperature dependence of the primary and secondary intrinsic isotope effects for the C-H bond cleavage catalyzed by peptidylglycine alpha-hydroxylating monooxygenase has been determined. Analysis of the magnitude and Arrhenius behavior of the intrinsic isotope effects provides strong evidence for the use of tunneling as a primary catalytic strategy for this enzyme. Modeling of the isotope effect data allows for a comparison to the hydrogen transfer catalyzed by soybean lipoxygenase in terms of environmental reorganization energy and frequency of the protein vibration that controls the hydrogen transfer.
Peptidylglycine monooxygenase (PHM) carries out the hydroxylation of the alpha-C atom of glycine-extended propeptides, the first step in the amidation of peptide hormones by the bifunctional enzyme peptidyl-alpha-amidating monooxygenase (PAM). Since PHM is a copper-containing monooxygenase, a study of the interaction between the reduced enzyme and carbon monoxide has been carried out as a probe of the interaction of the Cu(I) sites with O(2). The results show that, in the absence of peptide substrate, reduced PHM binds CO with a stoichiometry of 0.5 CO/Cu(I), indicating that only one of the two copper centers, Cu(B), forms a Cu(I)-carbonyl. FTIR spectroscopy shows a single band in the 2200-1950 cm(-)(1) energy region with nu(CO) = 2093 cm(-)(1) assigned to the intraligand C-O stretch via isotopic labeling with (13)CO. A His242Ala mutant of PHM, which deletes the Cu(B) site by replacing one of its histidine ligands, completely eliminates CO binding. EXAFS spectroscopy is consistent with binding of a single CO ligand with a Cu-C distance of 1.82 +/- 0.03 A. The Cu-S(met) distance increases from 2.23 +/- 0. 02 A in the reduced unliganded enzyme to 2.33 +/- 0.01 A in the carbonylated enzyme, suggesting that the methionine-containing Cu(B) center is the site of CO binding. The binding of the peptide substrate N-Ac-tyr-val-gly perturbs the CO ligand environment, eliciting an IR band at 2062 cm(-)(1) in addition to the 2093 cm(-)(1) band. (13)CO isotopic substitution assigns both frequencies as C-O stretching bands. The CO:Cu binding stoichiometry and peptide/CO FTIR titrations indicate that the 2062 cm(-)(1) band is due to binding of CO at a second site, most likely at the Cu(A) center. This suggests that peptide binding may activate the Cu(A) center toward O(2) binding and reduction to superoxide. As a result of these findings, a new mechanism is proposed involving channeling of superoxide across the 11 A distance between the two copper centers.
Peptidylglycine alpha-hydroxylating monooxygenase (PHM) is a copper, ascorbate, and molecular oxygen dependent enzyme that plays a key role in the biosynthesis of many peptides. Using site-directed mutagenesis, the catalytic core of PHM was found not to extend beyond Asp359. Shorter PHM proteins were eliminated intracellularly, suggesting that they failed to fold correctly. A set of mutant PHM proteins whose design was based on the structural and mechanistic similarities of PHM and dopamine beta-monooxygenase (D beta M) was characterized. Mutation of Tyr79, the residue equivalent to a p-cresol target in D beta M, to Phe79 altered the kinetic parameters of PHM. Disruption of either His-rich cluster contained within the PHM/D beta M homology domain eliminated activity, while deletion of a third His-rich cluster unique to PHM failed to affect activity; the catalytically inactive mutant PHM proteins still bound to a peptidylglycine substrate affinity resin. EPR and EXAFS studies of oxidized PHM indicate that the active site contains type 2 copper in a tetragonal environment; the copper is coordinated to two to three His and one to two additional O/N ligands, probably solvent, again supporting the structural homology of PHM and D beta M. Mutation of the Met residues common to PHM and D beta M to Ile identified Met314 as critical for catalytic activity.
Gram-negative bacteria utilize dual membrane resistance nodulation division-type efflux systems to export a variety of substrates. These systems contain an essential periplasmic component that is important for assembly of the protein complex. We show here that the periplasmic protein CusB from the Cus copper/silver efflux system has a critical role in Cu(I) and Ag(I) binding. Isothermal titration calorimetry experiments demonstrate that one Ag(I) ion is bound per CusB molecule with high affinity. X-ray absorption spectroscopy data indicate that the metal environment is an all-sulfur 3-coordinate environment. Candidates for the metal-coordinating residues were identified from sequence analysis, which showed four conserved methionine residues. Mutations of three of these methionine residues to isoleucine resulted in significant effects on CusB metal binding in vitro. Cells containing these CusB variants also show a decrease in their ability to grow on copper-containing plates, indicating an important functional role for metal binding by CusB. Gel filtration chromatography demonstrates that upon binding metal, CusB undergoes a conformational change to a more compact structure. Based on these structural and functional effects of metal binding, we propose that the periplasmic component of resistance nodulation division-type efflux systems plays an active role in export through substrate-linked conformational changes.Efflux systems of the resistance nodulation division (RND) 2 family are key players in the intrinsic and acquired antibiotic resistance of Gram-negative bacteria (1). These systems confer resistance to otherwise lethal concentrations of drugs and metal ions, and they also mediate efflux of bacterial products such as siderophores, peptides, and quorum-sensing signals (2, 3). With antibiotic-resistant pathogens representing a growing threat to human health, understanding these efflux systems is of significant importance.RND-type efflux systems form a transenvelope complex comprised of three fundamental components: an energy-utilizing inner membrane protein (4), an outer membrane factor, and a periplasmic component (5). The inner membrane components are proton-substrate antiporters of the RND protein superfamily, which are subclassified on the basis of their exported substrate (4). Members of the heavy metal efflux subfamily of RND transport systems are highly substrate-specific, with the ability to differentiate between monovalent and divalent ions (4). In contrast, the hydrophobe/amphiphile efflux (HAE) subfamily of RND protein systems has significantly broader substrate recognition. Members of the HAE-RND systems transport a wide range of structurally unrelated molecules, including antibiotics, dyes, detergents, bile salts, organic solvents, and antimicrobial peptides (6).Insights into the functions of the three fundamental components of RND efflux systems have been gathered from studies of a variety of RND systems. By far, the most information at the structural and biochemical levels is known for the inn...
The bifunctional peptidylglycine alpha-amidating enzyme catalyzes the C-terminal amidation of glycine-extended peptides. The first enzyme activity, peptidylglycine alpha-hydroxylating monooxygenase, catalyzes the oxygen-, ascorbate-, and copper-dependent formation of alpha-hydroxyglycine derivatives. These are substrates for the second enzyme activity, peptidylamidoglycolate lyase, which catalyzes their breakdown to the corresponding C-terminal amidated peptide and glyoxylate as final products. Kinetic and isotope effect studies were carried out with N-benzoylglycine as a substrate at pH 6.0 using monofunctional and bifunctional monooxygenase activities. Kinetic data indicate an equilibrium ordered mechanism, with hippuric acid binding first followed by oxygen. A potentially important difference between the two monooxygenase activities is that product release occurs more slowly from the bifunctional enzyme, indicating an influence of the lyase domain on release of alpha-hydroxyglycine product to solution. Intrinsic isotope effects for the C-H bond cleavage were measured for the monofunctional form of the enzyme using a double-label tracer method, yielding 10.6 +/- 0.8 and 1.20 +/- 0.03 for the primary and alpha-secondary deuterium intrinsic isotope effects, respectively. These values are identical to previous measurements for the analogous enzyme system, dopamine beta-monooxygenase [Miller, S. M., and Klinman, J. P. (1985) Biochemistry 24, 2114-2127]. The identity of intrinsic isotope effects for peptidylglycine alpha-hydroxylating monooxygenase and dopamine beta-monooxygenase with substrates of comparable reactivity (N-benzoylglycine and dopamine, respectively) extends similarities between the two enzymes significantly beyond sequence homology and cofactor requirements.
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