The crystal structure of the CopC protein from Pseudomonas fluorescens reveals amended classifications for the CopC protein family.

The bacterial CopC family of proteins are periplasmic copper binding proteins that act in copper detoxification. These proteins contain Cu(I) and/or Cu(II) binding sites, with the family that binds Cu(II) only the most prevalent, based on sequence analyses. Here we present three crystal structures of the CopC protein from Pseudomonas fluorescens (Pf-CopC) that include the wild type protein bound to Cu(II) and two variant proteins, where Cu(II) coordinating ligands were mutated, in Cu-free states. We show that the Cu(II) atom in Pf-CopC is coordinated by two His residues, an Asp residue and the N-terminus of the protein (therefore a 3N + O site). This coordination structure is consistent with all structurally characterized proteins from the CopC family to date. Structural and sequence analyses of the CopC family allow a relationship between protein sequence and the Cu(II) binding affinity of these proteins to be proposed.

Copper ATPase CopA from Escherichia coli: Quantitative Correlation between ATPase Activity and Vectorial Copper Transport.

Cu-ATPases are membrane copper transporters present in all kingdoms of life. They play a central role in Cu homeostasis by pumping Cu ions across cell membranes with energy derived from ATP hydrolysis. In this work, the Cu-ATPase CopA from Escherichia coli was expressed and purified in fully functional form and demonstrated to bind Cu(I) with subfemtomolar affinity. It was incorporated into the lipid membrane of giant unilamellar vesicles (GUVs) whose dimensions match those of eukaryotic cells. An 1H NMR approach provided a quantitative ATPase activity assay for the enzyme either dissolved in detergent or embedded in GUV membranes. The activity varied with the Cu(I) availability in an optimized assay solution for either environment, demonstrating a direct correlation between ATPase activity and Cu(I) transport. Quantitative analysis of the Cu content trapped by the GUVs is consistent with a Cu:ATP turnover ratio of 1.

Evaluation of employing poly-lysine tags versus poly-histidine tags for purification and characterization of recombinant copper-binding proteins.

Quantitative characterization of metalloproteins at molecular and atomic levels generally requires tens of milligrams of highly purified samples, a situation frequently challenged by problems in generating unmodified native forms. A variety of affinity tags, such as the popular poly-histidine tag, have been developed to facilitate purification but they generally rely on expensive affinity resins and their presence may interfere with protein characterization. This paper documents that addition of a poly-lysine tag to the C-terminus enables, for the copper-binding proteins examined, ready purification in large scale via cost-effective cation-exchange chromatography. The tag may be removed readily by the enzyme carboxypeptidase B to generate the native protein with no extra residues. However, this cleavage step is normally not necessary since the poly-lysine tag is shown to have no detectable affinity for either Cu(I) or Cu(II) and imposes no interference to the copper binding properties of the target proteins. In contrast, the poly-histidine tag possesses a sub-picomolar affinity for Cu(I) and -nanomolar affinity for Cu(II) and may need to be removed for reliable characterization of the target proteins. These conclusions may be extended to the study of other metallo-proteins and metallo-enzymes.

A set of robust fluorescent peptide probes for quantification of Cu(ii) binding affinities in the micromolar to femtomolar range.

Reliable quantification of copper binding affinities and identification of the binding sites provide a molecular basis for an understanding of the nutritional roles and toxic effects of copper ions. Sets of chromophoric probes are now available that can quantify Cu(i) binding affinities from nanomolar to attomolar concentrations on a unified scale under in vitro conditions. Equivalent probes for Cu(ii) are lacking. This work reports development of a set of four fluorescent dansyl peptide probes (DP1-4) that can quantify Cu(ii) binding affinities from micromolar to femtomolar concentrations, also on a unified scale. The probes were constructed by conjugation of a dansyl group to four short peptides of specific design. Each was characterised by its dissociation constant KD, its pH dependence and the nature of its binding site. One equivalent of Cu(ii) is bound by the individual probes that display different and well-separated affinities at pH 7.4 (log KD = -8.1, -10.1, -12.3 and -14.1, respectively). Intense fluorescence is emitted at λmax ∼ 550 nm upon excitation at ∼330 nm. Binding of Cu(ii) quenches the fluorescence intensity linearly until one equivalent of Cu(ii) is bound. Multiple approaches and multiple affinity standards were employed to ensure reliability. Selected examples of application to well-characterised Cu(ii) binding peptides and proteins are presented. These include Aß16 peptides, two naturally occurring Cu(ii)-chelating motifs in human serum and cerebrospinal fluid with sequences GHK and DAHK and two copper binding proteins, CopC from Pseudomonas syringae and PcoC from Escherichia coli. Previously reported affinities are reproduced, demonstrating that peptides DP1-4 form a set of robust and reliable probes for Cu(ii) binding to peptides and protein targets.

CopC protein from Pseudomonas fluorescens SBW25 features a conserved novel high-affinity Cu(II) binding site.

Copper homeostasis in the bacterium Pseudomonas fluorescens SBW25 appears to be mediated mainly via chromosomal cue and cop systems. Under elevated copper levels that induce stress, the cue system is activated for expression of a P1B-type ATPase to remove excess copper from the cytosol. Under copper-limiting conditions, the cop system is activated to express two copper uptake proteins, Pf-CopCD, to import this essential nutrient. Pf-CopC is a periplasmic copper chaperone that may donate copper to the inner membrane transporter Pf-CopD for active copper importation. A database search revealed that Pf-CopC belongs to a new family of CopC proteins (designated Type B in this work) that differs significantly from the known CopC proteins of Type A that possess two separated binding sites specific for Cu(I) and Cu(II). This article reports the isolation and characterization of Pf-CopC and demonstrates that it lacks a Cu(I) binding site and possesses a novel Cu(II) site that binds Cu(II) with 100 times stronger affinity than do the Type A proteins. Presumably, this is a requirement for a copper uptake role under copper-limiting conditions. The Cu(II) site incorporates a highly conserved amino terminal copper and nickel (ATCUN) binding motif, NH2-Xxx-Xxx-His, but the anticipated ATCUN binding mode is prevented by a thermodynamically more favorable binding mode comprising His1 as a key bidentate ligand and His3 and His85 as co-ligands. However, upon His1 mutation, the ATCUN binding mode is adopted. This work demonstrates how a copper chaperone may fine tune its copper binding site to meet new challenges to its function.