ATP7A-dependent copper sequestration contributes to termination of ß-CATENIN signaling during early adipogenesis.

OBJECTIVES: Adipocyte fate determination is tightly regulated by extrinsic signaling pathways and intrinsic metabolic and morphologic changes that maintain adipose tissue function. Copper (Cu) homeostasis is required for the normal metabolism of mature adipocytes, whereas the role of Cu in adipogenesis is unclear. METHODS: To determine the role of Cu is adipocytes differentiation, we used 3T3-L1 adipocytes, immunocytochemistry, X-ray fluorescence, mass-spectrometry, pharmacological treatments, and manipulations of copper levels. RESULTS: In differentiating 3T3-L1 cells, adipogenic stimuli trigger the upregulation and trafficking of the Cu transporter Atp7a, thus causing Cu redistribution from the cytosol to vesicles. Disrupting Cu homeostasis by the deletion of Atp7a results in Cu elevation and inhibition of adipogenesis. The upregulation of C/EBPß, an initial step of adipogenesis, is not affected in Atp7a-/- cells, whereas the subsequent upregulation of PPARγ is inhibited. Comparison of changes in the Atp7a-/- and wild type cells proteomes during early adipogenesis revealed stabilization of ß-catenin, a negative regulator of adipogenesis. Cu chelation, or overexpression of the Cu transporter ATP7B in Atp7a-/- cells, restored ß-catenin down-regulation and intracellular targeting. CONCLUSIONS: Cu buffering during early adipogenesis contributes to termination of ß-catenin signaling. Abnormal upregulation of ß-catenin was also observed in vivo in the livers of Atp7b-/- mice, which accumulate Cu, suggesting a tissue-independent crosstalk between Cu homeostasis and the Wnt/ß-catenin pathway. These results point to a new regulatory role of Cu in adipocytes and contribute to better understanding of human disorders of Cu misbalance.

In vivo and in vitro analyses of amygdalar function reveal a role for copper.

Mice with a single copy of the peptide amidating monooxygenase (Pam) gene (PAM(+/-)) are impaired in contextual and cued fear conditioning. These abnormalities coincide with deficient long-term potentiation (LTP) at excitatory thalamic afferent synapses onto pyramidal neurons in the lateral amygdala. Slice recordings from PAM(+/-) mice identified an increase in GABAergic tone (Gaier ED, Rodriguiz RM, Ma XM, Sivaramakrishnan S, Bousquet-Moore D, Wetsel WC, Eipper BA, Mains RE. J Neurosci 30: 13656-13669, 2010). Biochemical data indicate a tissue-specific deficit in Cu content in the amygdala; amygdalar expression of Atox-1 and Atp7a, essential for transport of Cu into the secretory pathway, is reduced in PAM(+/-) mice. When PAM(+/-) mice were fed a diet supplemented with Cu, the impairments in fear conditioning were reversed, and LTP was normalized in amygdala slice recordings. A role for endogenous Cu in amygdalar LTP was established by the inhibitory effect of a brief incubation of wild-type slices with bathocuproine disulfonate, a highly selective, cell-impermeant Cu chelator. Interestingly, bath-applied CuSO4 had no effect on excitatory currents but reversibly potentiated the disynaptic inhibitory current. Bath-applied CuSO4 was sufficient to potentiate wild-type amygdala afferent synapses. The ability of dietary Cu to affect signaling in pathways that govern fear-based behaviors supports an essential physiological role for Cu in amygdalar function at both the synaptic and behavioral levels. This work is relevant to neurological and psychiatric disorders in which disturbed Cu homeostasis could contribute to altered synaptic transmission, including Wilson's, Menkes, Alzheimer's, and prion-related diseases.

Major changes in copper coordination accompany reduction of peptidylglycine monooxygenase: implications for electron transfer and the catalytic mechanism.

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.

Domains I and III of the human copper chaperone for superoxide dismutase interact via a cysteine-bridged Dicopper(I) cluster.

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.

Spectroscopic analysis of the trinuclear cluster in the Fet3 protein from yeast, a multinuclear copper oxidase.

The Fet3 protein (Fet3p) is a multinuclear copper oxidase essential for high-affinity iron uptake in yeast. Fet3p contains one type 1, one type 2, and a strongly antiferromagnetically coupled binuclear Cu(II)-Cu(II) type 3 copper. The type 2 and type 3 sites constitute a structurally distinct trinuclear cluster at which dioxygen is reduced to water. In Fet3p, as in ceruloplasmin, Fe(II) is oxidized to Fe(III) at the type 1 copper; this is the ferroxidase reaction that is fundamental to the physiologic function of these two enzymes. Using site-directed mutagenesis, we have generated type 1-depleted (T1D), type 2-depleted (T2D), and T1D/T2D mutants. None were active in the essential ferroxidase reaction catalyzed by Fet3p. However, the spectroscopic signatures of the remaining Cu(II) sites in any one of the three mutants were indistinguishable from those exhibited by the wild type. Although the native protein and the T1D mutant were isolated in the completely oxidized Cu(II) form, the T2D and T1D/T2D mutants were found to be completely reduced. This result is consistent with the essential role of the type 2 copper in dioxygen turnover, and with the suggestions that cuprous ion is the valence state of intracellular copper. Although stable to dioxygen, the Cu(I) sites in both proteins were readily oxidized by hydrogen peroxide. The double mutant was extensively analyzed by X-ray absorption spectroscopy. Edge and near-edge features clearly distinguished the oxidized from the reduced form of the binuclear cluster. EXAFS was strongly consistent with the expected coordination of each type 3 copper by three histidine imidazoles. Also, copper scattering was observed in the oxidized cluster along with scattering from a ligand corresponding to a bridging oxygen. The data derived from the reduced cluster indicated that the bridge was absent in this redox state. In the reduced form of the double mutant, an N/O ligand was apparent that was not seen in the reduced form of the T1D protein. This ligand in T1D/T2D could be either the remaining type 2 copper imidazole ligand (from His416) or a water molecule that could be stabilized at the type 3 cluster by H-bonding to this side chain. If present in the native protein, this H(2)O could provide acid catalysis of dioxygen reduction at the reduced trinuclear center.

Selenomethionine-substituted Thermus thermophilus cytochrome ba3: characterization of the CuA site by Se and Cu K-EXAFS.

We have designed a gene that encodes a polypeptide corresponding to amino acids 44-168 of the Thermus thermophilus cytochrome ba3 subunit II [Keightley et al. (1995) J. Biol. Chem. 270, 20345-20358]. The resulting ba3-CuAt10 protein separated into two fractions (A and B) during cation exchange chromatography which were demonstrated to differ only by N-terminal acetylation in fraction A. When the gene was expressed in an Escherichia coli strain that is auxotrophic for methionine and grown in the presence of selenomethionine (Se(Met)), the single methionine of the CuAt10 protein was quantitatively replaced with Se(Met). Native (S(Met)) and Se(Met)-substituted proteins were characterized by electrospray mass, optical absorption, and EPR spectroscopies and by electrochemical analysis; they were found to have substantially identical properties. The Se(Met)-containing protein was further characterized by Se and Cu K-EXAFS which revealed Cu-Se bond lengths of 2.55 A in the mixed-valence form and 2.52 A in the fully reduced form of CuA. Further analysis of the Se- and Cu-EXAFS spectra yielded the Se-S(thiolate) distances and thereby information on the Se-Cu-Cu and Se-Cu-S(thiolate) angles. An expanded EXAFS structural model is presented.

Coordination of CuB in reduced and CO-liganded states of cytochrome bo3 from Escherichia coli. Is chloride ion a cofactor?

The ubiquinol oxidase cytochrome bo3 from Escherichia coli is one of the respiratory heme-copper oxidases which catalyze the reduction of O2 to water linked to translocation of protons across the bacterial or mitochondrial membrane. We have studied the structure of the CuB site in the binuclear heme-copper center of O2 reduction by EXAFS spectroscopy in the fully reduced state of this enzyme, as well as in the reduced CO-liganded states where CO is bound either to the heme iron or to CuB. We find that, in the reduced enzyme, CuB is coordinated by one weakly bound and two strongly bound histidine imidazoles at Cu-N distances of 2.10 and 1.92 A, respectively, and that an additional feature at 2.54 A is due to a highly ordered water molecule that might be weakly associated with the copper. Unexpectedly, the binding of CO to heme iron is found to result in a major conformational change at CuB, which now binds only two equidistant histidine imidazoles at 1.95 A and a chloride ion at 2. 25 A, with elimination of the water molecule and one of the histidines. Attempts to remove the chloride from the enzyme by extensive dialysis did not change this finding, nor did substitution of chloride with bromide. Photolysis of CO bound to the heme iron is known to cause the CO to bind to CuB in a very fast reaction and to remain bound to CuB at low temperatures. In this state, we indeed find the CO to be bound to CuB at a Cu-C distance of 1.85 A, with chloride still bound at 2.25 A and the two histidine imidazoles at a Cu-N distance of 2.01 A. These results suggest that reduction of the binuclear site weakens the bond between CuB and one of its three histidine imidazole ligands, and that binding of CO to the reduced binuclear site causes a major structural change in CuB in which one histidine ligand is lost and replaced by a chloride ion. Whether chloride is a cofactor in this enzyme is discussed.