Tetrathiomolybdate inhibition of the Enterococcus hirae CopB copper ATPase.

Tetrathiomolybdate (TTM) avidly interacts with copper and has recently been employed to reduce excess copper in patients with Wilson disease. We found that TTM inhibits the purified Enterococcus hirae CopB copper ATPase with an IC(50) of 34 nM. Dithiomolybdate and trithiomolybdate, which commonly contaminate TTM, inhibited the copper ATPases with similar potency. Inhibition could be reversed by copper or silver, suggesting inhibition by substrate binding. These findings for the first time allowed an estimate of the high affinity of CopB for copper and silver. TTM is a new tool for the study of copper ATPases.

Interaction of the CopZ copper chaperone with the CopA copper ATPase of Enterococcus hirae assessed by surface plasmon resonance.

Intracellular copper routing in Enterococcus hirae can be accomplished by the CopZ metallochaperone. Using surface plasmon resonance analysis, we show here that CopZ interacts with the CopA copper ATPase. The binding affinity of CopZ for CopA was increased in the presence of copper, due to a 15-fold lower dissociation rate constant. Mutating the N-terminal copper binding motif of CopA from CxxC to SxxS abolished this copper-induced effect. Moreover, CopZ failed to show an interaction with an unrelated copper binding protein used as a control. These results show that (i) the CopA copper ATPase specifically interacts with the CopZ chaperone, (ii) this interaction is based on protein-protein interaction, and (iii) surface plasmon resonance is a novel tool for quantitative analysis of metallochaperone-target interactions.

Expression of the human Menkes ATPase in Xenopus laevis oocytes.

Menkes disease is an X-linked disorder of copper metabolism that is usually fatal. The affected gene has recently been cloned and encodes one of the two human copper ATPases. If the Menkes ATPase is defective, copper is trapped in the intestinal mucosa, leading to systemic copper deficiency. In order to study copper transport by this ATPase and the effects of disease mutations on its function, we developed a Xenopus laevis oocyte expression system. Wild-type Menkes ATPase cDNA and a fusion of this gene with the green fluorescent protein (GFP) gene was transcribed in vitro and the mRNA injected into oocytes. Expression in oocytes was analyzed by Western blotting and fluorescence microscopy. The Menkes ATPase-GFP chimera appeared to localize primarily to the plasma membrane as assessed by confocal microscopy. This system should thus provide an interesting new tool to study the function of the Menkes ATPase.

Structure-function analysis of purified Enterococcus hirae CopB copper ATPase: effect of Menkes/Wilson disease mutation homologues.

The Enterococcus hirae CopB ATPase (EC 3.6.1.3) confers copper resistance to the organism by expelling excess copper. Two related human ATPase genes, ATP7A (EC 3.6.1.36) and ATP7B (EC 3.6.1.36), have been cloned as the loci of mutations causing Menkes and Wilson diseases, diseases of copper metabolism. Many mutations in these genes have been identified in patients. Since it has not yet been possible to purify the human copper ATPases, it has proved difficult to test the impact of mutations on ATPase function. Some mutations occur in highly conserved sequence motifs, suggesting that their effect on function can be tested with a homologous enzyme. Here, we used the E. hirae CopB ATPase to investigate the impact of such mutations on enzyme function in vivo and in vitro. The Menkes disease mutation of Cys-1000-->Arg, changing the conserved Cys-Pro-Cys ('CPC') motif, was mimicked in CopB. The corresponding Cys-396-->Ser CopB ATPase was unable to restore copper resistance in a CopB knock-out mutant in vivo. The purified mutant ATPase still formed an acylphosphate intermediate, but possessed no detectable ATP hydrolytic activity. The most frequent Wilson disease mutation, His-1069-->Gln, was introduced into CopB as His-480-->Gln (H480Q). This mutant CopB also failed to confer copper resistance to a CopB knock-out strain. Purified H480Q CopB formed an acylphosphate intermediate and retained a small, but significant, ATPase activity. Our results reveal that Cys-396 and His-480 of CopB are key residues for ATPase function, and similar roles are suggested for Cys-1000 and His-1069 of Menkes and Wilson ATPases respectively.

Epidermal growth factor is decreased in liver of rats with biliary cirrhosis but does not act as paracrine growth factor immediately after hepatectomy.

BACKGROUND/AIMS: Epidermal growth factor, a potent mitogen for hepatocytes and cholangiocytes, is thought to act as an immediate-early gene after partial hepatectomy. Since regeneration is impaired in cirrhosis, we explored the expression of epidermal growth factor in cirrhotic rat liver immediately after partial hepatectomy. METHODS: Cirrhosis was induced by bile duct ligation (n=21); sham-operated animals served as controls (n=21). Twenty-five days after initial surgery animals were subjected to 70% partial hepatectomy or sham operation; the liver was sampled before surgery and 20, 40 and 90 min thereafter. Epidermal growth factor mRNA levels were assessed by quantitative reverse transcription polymerase chain reaction. Protein expression was estimated by immunohistochemistry using a polyclonal antibody against epidermal growth factor. RESULTS: Before hepatectomy, epidermal growth factor mRNA averaged 70.3+/-39.9 pg/microg of total RNA in controls; this was markedly decreased to 21.9+/-12.7 pg/microg RNA in bile duct ligation (p<0.01). Epidermal growth factor mRNA did not increase after partial hepatectomy in either group, with the exception of sham-operated controls. Immunohistochemistry revealed that partial hepatectomy had no effect on epidermal growth factor expression. Hepatocytes showed uniformly cytosolic epidermal growth factor in controls, while in bile duct ligation immunostaining was faint or absent. Cholangiocytes exhibited a strong cytosolic staining in all experimental groups. CONCLUSIONS: The present study shows that epidermal growth factor is reduced in the cirrhotic liver. This could contribute to the loss of parenchymal liver tissue observed in cirrhosis. The lack of up-regulation after PH sheds doubt on the role of epidermal growth factor as an immediate-early gene in hepatic regeneration. Further, we demonstrate that epidermal growth factor accumulates in cholangiocytes. This observation is strong evidence for involvement of the mitogen epidermal growth factor in the proliferation of bile ducts during cirrhogenesis.

[How (deficient) copper causes illness]. / Wie (kein) Kupfer krank macht.

Copper is an essential cofactor in all cells. However, it remains largely unknown how cells deal with this element, which is essential yet toxic. Through the study of microbial model systems on the one hand, and the investigation of inherited diseases in copper metabolism on the other, important insights into the way cells deal with copper can be gained. Two key new elements of copper metabolism have emerged from these studies: ATP-driven copper pumps and intracellular copper transport proteins, the copper chaperones.