SummaryThe Spx protein is indispensable for survival of Bacillus subtilis under disulphide stress. Its interaction with the a a a a -subunit of RNA polymerase is required for transcriptional induction of genes that function in thiol homeostasis, such as thioredoxin ( trxA ) and thioredoxin reductase ( trxB ). The N-terminal end of Spx contains a Cys-X-X-Cys (CXXC) motif, which is a likely target for redox-sensitive control. We show here that Spx directly activates trxA and -B transcription by interacting with the RNA polymerase a a a a -subunit, but it does so only under an oxidized condition. The transcriptional activation by Spx requires formation of an intramolecular disulphide bond between two cysteine residues that reside in the CXXC motif. The mechanism of Spx-dependent transcriptional activation is unique in that it does not involve initial Spx-DNA interaction.
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.
Copper is essential for human physiology, but in excess it causes the severe metabolic disorder Wilson disease. Elevated copper is thought to induce pathological changes in tissues by stimulating the production of reactive oxygen species that damage multiple cell targets. To better understand the molecular basis of this disease, we performed genome-wide mRNA profiling as well as protein and metabolite analysis for Atp7b ؊/؊ mice, an animal model of Wilson disease. We found that at the presymptomatic stages of the disease, copper-induced changes are inconsistent with widespread radical-mediated damage, which is likely due to the sequestration of cytosolic copper by metallothioneins that are markedly up-regulated in Atp7b ؊/؊ livers. Instead, copper selectively up-regulates molecular machinery associated with the cell cycle and chromatin structure and down-regulates lipid metabolism, particularly cholesterol biosynthesis. Specific changes in the transcriptome are accompanied by distinct metabolic changes. Biochemical and mass spectroscopy measurements revealed a 3.6-fold decrease of very low density lipoprotein cholesterol in serum and a 33% decrease of liver cholesterol, indicative of a marked decrease in cholesterol biosynthesis. Consistent with low cholesterol levels, the amount of activated sterol regulatory-binding protein 2 (SREBP-2) is increased in Atp7b ؊/؊ nuclei. However, the SREBP-2 target genes are dysregulated suggesting that elevated copper alters SREBP-2 function rather than its processing or re-localization. Thus, in Atp7b ؊/؊ mice elevated copper affects specific cellular targets at the transcription and/or translation levels and has distinct effects on liver metabolic function, prior to appearance of histopathological changes. The identification of the network of specific copper-responsive targets facilitates further mechanistic analysis of human disorders of copper misbalance.
Significance
Copper is essential for normal growth and development because it serves roles in catalysis, signaling, and structure. Cells acquire copper through the copper transporter 1 (Ctr1) protein, a copper transporter that localizes to the cell membrane and intracellular vesicles. Both copper and the anticancer drug cisplatin are imported by Ctr1 by virtue of an extracellular domain rich in metal-binding amino acids. In this report we demonstrate that a protein structurally related to Ctr1, called Ctr2, plays a role in the generation or stability of a truncated form of Ctr1 lacking a large portion of the extracellular domain. Retention of this domain in mice or cells lacking Ctr2 enhances copper and cisplatin uptake, thereby establishing Ctr2 as a regulator of Ctr1 function.
Expressed protein ligation was used to replace the axial methionine of the blue copper protein azurin from Pseudomonas aeruginosa with unnatural amino acids. The highly conserved methionine121 residue was replaced with the isostructural amino acids norleucine (Nle) and selenomethionine (SeM). The UV-visible absorption, X- and Q-band EPR, and Cu EXAFS spectra of the variants are slightly perturbed from WT. All variants have a predominant S(Cys) to Cu(II) charge transfer band around 625 nm and narrow EPR hyperfine splittings. The Se EXAFS of the M121SeM variant is also reported. In contrast to the small spectral changes, the reduction potentials of M121SeM, M121Leu, and M121Nle are 25, 135, and 140 mV, respectively, higher than that of WT azurin. The use of unnatural amino acids allowed deconvolution of different factors affecting the reduction potentials of the blue copper center. A careful analysis of the WT azurin and its variants obtained in this work showed the large reduction potential variation was linearly correlated with the hydrophobicity of the axial ligand side chains. Therefore, hydrophobicity is the dominant factor in tuning the reduction potentials of blue copper centers by axial ligands.
The human copper chaperone HAH1 transports copper to the Menkes and Wilson proteins, which are copper-translocating P-type ATPases located in the transGolgi apparatus and believed to provide copper for important enzymes such as ceruloplasmin, tyrosinase, and peptidylglycine monooxygenase. Although a substantial amount of structural data exist for HAH1 and its yeast and bacterial homologues, details of the copper coordination remain unclear and suggest the presence of two protein-derived cysteine ligands and a third exogenous thiol ligand. Here we report the preparation and reconstitution of HAH1 with Cu(I) using a protocol that minimizes the use of thiol reagents believed to be the source of the third ligand. We show by x-ray absorption spectroscopy that this reconstitution protocol generates an occupied Cu(I) binding site with linear biscysteinate coordination geometry, as evidenced by (i) an intense edge absorption centered at 8982.5 eV, with energy and intensity identical to the rigorously linear twocoordinate model complex bis-2,3,5,6-tetramethylbenzene thiolate Cu(I) and (ii) an EXAFS spectrum that could be fit to two Cu-S interactions at 2.16 Å, a distance typical of digonal Cu(I) coordination. Binding of exogenous ligands (GSH, dithiothreitol, and tris-(2-carboxyethyl)-phosphine) to the Cu(I) was investigated. When GSH or dithiothreitol was added to the chaperone during the reconstitution procedure, the resulting Cu(I)-HAH1 remained two-coordinate, whereas the addition of the phosphine during reconstitution elicited a threecoordinate species. When the exogenous ligands were titrated into the Cu(I)-HAH1, all formed three-coordinate adducts but with differing affinities. Thus, GSH and dithiothreitol showed weaker binding, with estimated K D values in the range 10 -25 mM, whereas tris-(2-carboxyethyl)-phosphine showed stronger affinity, with a K D value of <5 mM. The implications of these findings for mechanisms of copper transport are discussed.
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