Methionine-rich motifs have an important role in copper trafficking factors, including the CusF protein. Here we show that CusF uses a new metal recognition site wherein Cu(I) is tetragonally displaced from a Met 2 His ligand plane toward a conserved tryptophan. Spectroscopic studies demonstrate that both thioether ligation and strong cation-π interactions with tryptophan stabilize metal binding. This novel active site chemistry affords mechanisms for control of adventitious metal redox and substitution chemistry.In recent years, metal-specific gene regulatory and cation-trafficking proteins have been isolated and demonstrate metal binding motifs with unprecedented coordination chemistry tailored to their function 1 . For example, the CXXC sequence, found in cytosolic copper chaperones and trafficking proteins, provides for facile Cu(I) transfer via low-coordinationnumber anionic intermediates 1,2 . Extracellular or periplasmic copper trafficking domains, however, function in environments that are more oxidizing than the cytosol and frequently have less well understood methionine-rich sequences 3-8 . The cus operon encodes a bacterial copper homeostasis system with several methionine-motif proteins 5,9,10 , including the periplasmic protein CusF, which is thought to serve as copper chaperone or regulator 5,6 . CusF binds Cu(I) in vitro 11 , and a methionine-rich Cu(I) site was proposed 6 based on an apo-CusF structure and NMR chemical shift data. Here we show that metal recognition in CusF involves a strong interaction between a cationic Cu(I)-thioether/imidazole center and the aromatic ring of tryptophan. To our knowledge, such cation-π interactions have not been reported for transition metal receptors or metalloenzyme active sites.Correspondence should be addressed to T.V.O. (t-ohalloran@northwestern.edu). 6 These authors contributed equally to this work.Published online at http://www.nature.com/naturechemicalbiology Reprints and permissions information is available online at
In humans, cystathionine β-synthase (CBS) is a hemeprotein, which catalyzes a pyridoxal phosphate (PLP)-dependent condensation reaction. Changes in the heme environment are communicated to the active site, which is ~20 Å away. In this study, we have examined the role of H67 and R266, which are in the second coordination sphere of the heme ligands, H65 and C52 respectively, in modulating the heme's electronic properties and in transmitting information between the heme and active sites. While the H67A mutation is comparable to wild-type CBS, interesting differences are revealed by mutations at the R266 site. The pathogenic mutant, R266K, is moderately PLP-responsive while the R266M mutation shows dramatic differences in the ferrous state. The electrostatic interaction between C52 and R266 is critical for stabilizing the ferrous heme and its disruption leads to the facile formation of a 424 nm (C-424) absorbing ferrous species, which is inactive, compared to the active 449 nm ferrous species for wild-type CBS. Resonance Raman studies on the R266M mutant reveal that the kinetics of C52 rebinding after Fe-CO photolysis are comparable to that of wild-type CBS. EXAFS studies on C-424 CBS are consistent with the presence of two axial N/O low Z scatters with only one being a rigid unit of a histidine residue while the other could be a solvent molecule, an oxygen atom from the peptide backbone or a side chain nitrogen. The redox potential for the heme in full-length CBS is −350 ± 4 mV and is substantially lower than the value of −287 ± 2 mV determined for truncated CBS. A redox-regulated ligand change has the potential to serve as an allosteric on/off switch in human CBS and the second sphere ligand, R266, plays an important role in this transition.
Lantibiotics are peptide-derived antimicrobial agents that are ribosomally synthesized and posttranslationally modified by a multienzyme complex to their biologically active forms. Nisin has attracted much attention recently due to its novel mechanism of action including specific binding to the bacterial cell wall precursor lipid II, followed by membrane permeabilization. Nisin has been commercially used as a food preservative, while other lantibiotics show promising activity against bacterial infections. The posttranslational modifications are believed to be carried out by a multienzyme complex. At present the enzymes catalyzing the formation of the lantibiotic signature structural motifs, dehydroalanine (Dha), dehydrobutyrine (Dhb), lanthionine (Ln), and methyllanthionine (MeLn), are poorly characterized. In an effort to gain insight into the mechanism by which lantibiotics are biosynthesized, the cyclase enzymes involved in the synthesis of nisin and subtilin (NisC and SpaC, respectively) have been cloned, expressed, and purified. Both proteins exist as monomers in solution and contain a stoichiometric zinc atom. EXAFS data on SpaC and a C349A mutant are in line with two cysteine ligands to the metal in the wild-type enzyme with possibly two additional histidines. The two cysteine ligands are likely Cys303 and Cys349 on the basis of sequence alignments and EXAFS data. The metal may function to activate the cysteine thiol of the peptide substrate toward intramolecular Michael addition to the dehydroalanine and dehydrobutyrine residues in the peptide.
Heme-copper/dioxygen adduct formation relevant to cytochrome c oxidase: spectroscopic characterization of [(6L)FeIII-(O22?)-CuII]+
In the further development and understanding of heme-copper dioxygen reactivity relevant to cytochrome c oxidase O(2)-reduction chemistry, we describe a high-spin, five-coordinate dioxygen (peroxo) adduct of an iron(II)-copper(I) complex, [((6)L)Fe(II)Cu(I)](BArF(20)) (1), where (6)L is a tetraarylporphyrinate with a tethered tris(2-pyridylmethyl)amine chelate for copper. Reaction of 1 with O(2) in MeCN affords a remarkably stable [t(1/2) (rt; MeCN) approximately 60 min] adduct, [((6)L)Fe(III)-(O(2) (2-))-Cu(II)](+) (2) [EPR silent; lambda(max)=418 (Soret), 561 nm], formulated as a peroxo complex based on manometry (1:O(2)=1:1; spectrophotometric titration, -40 degrees C, MeCN), mass spectrometry {MALDI-TOF-MS: (16)O(2), m/z 1191 ([((6)L)Fe(III)-((16)O(2) (2-))-Cu(II)](+)); (18)O(2), m/z 1195}, and resonance Raman spectroscopy (nu((O-O))=788 cm(-1); Delta(16)O(2)/(18)O(2)=44 cm(-1); Delta(16)O(2)/(16/18)O(2)=22 cm(-1)). (1)H and (2)H NMR spectroscopy (-40 degrees C, MeCN) reveals that 2 is the first heme-copper peroxo complex which is high-spin, with downfield-shifted pyrrole resonances (delta(pyrrole)=75 ppm, s, br) and upfield shifted peaks at delta= -22, -35, and -40 ppm, similar to the pattern observed for the mu-oxo complex [((6)L)Fe(III)-O-Cu(II)](BAr(F)) (3) (known S=2 system, antiferromagnetically coupled high-spin Fe(III) and Cu(II)). The corresponding magnetic moment measurement (Evans method, CD(3)CN, -40 degrees C) also confirms the S=2 spin state, with mu(B)=4.9. Structural insights were obtained from X-ray absorption spectroscopy, showing Fe-O (1.83 A) and Cu-O (1.882 A) bonds, and an Fe...Cu distance of 3.35(2) A, suggestive of a mu-1,2-peroxo ligand present in 2. The reaction of 2 with cobaltocene gives 3, differing from the observed full reduction seen with other heme-Cu peroxo complexes. Finally, thermal decomposition of 2 yields 3, with concomitant release of 0.5 mol O(2) per mol 2, as confirmed quantitatively by an alkaline pyrogallol dioxygen scavenging solution.
Copper binding to the human copper chaperone for superoxide dismutase (hCCS) has been investigated by X-ray absorption spectroscopy. Stoichiometry measurements on the dialyzed, as-isolated protein indicated that up to 3.5 Cu ions bound per hCCS molecule. Reduction with either sodium dithionite or dithiothreitol decreased the copper binding ratio to 2 coppers per hCCS monomer. Analysis of the as-isolated EXAFS data indicated coordination of Cu by a mixture of S and N backscatterers, suggestive of heterogeneous binding of copper between Cu-cysteine binding sites of domain I or III and copper-histidine SOD1-like metal binding sites of domain II. The best fit was obtained with 1.6 Cu-S (cysteine) at 2.24 A (2sigma(2) = 0.011 A(2)) and 1.1 N (histidine) at 1.98 A (2sigma(2) = 0.005 A(2)). A peak of variable intensity in the Fourier transform (FT) of the as-isolated protein at 2.7 A was suggestive of the presence of a heavy atom scatterer such as Cu. Analysis of the dithionite- and DTT-reduced derivatives indicated that copper was lost from the histidine coordinating sites, resulting in a S-only environment with copper coordinated to three S backscatterers at 2. 26 A. The heavy atom scatterer peak was now prominent in the FT and could be well fit by a Cu-Cu interaction at 2.72 A. The data were best interpreted by a dinuclear mu(2)()-bridged cluster with doubly bridging cysteine ligands similar to the cluster proposed to exist in the cytochrome c oxidase chaperone COX17. Analysis of primary sequence and X-ray structural information on yeast CCS strongly suggests that this cluster bridges between domains I and III in hCCS. A mechanism for copper translocation is briefly discussed.
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