Brain copper content and cuproenzyme activity do not vary with prion protein expression level.

Prion diseases are neurodegenerative disorders that result from conformational transformation of a normal cell surface glycoprotein, PrP(C), into a pathogenic isoform, PrP(Sc). Although the normal physiological function of PrP(C) has remained enigmatic, the recent observation that the protein binds copper ions with micromolar affinity suggests a possible role in brain copper metabolism. In this study, we have used mice that express 0, 1, and 10 times the normal level of PrP to assess the effect of PrP expression level on the amount of brain copper and on the properties of two brain cuproenzymes. Using mass spectrometry, we find that the amount of ionic copper in subcellular fractions from brain is similar in all three lines of mice. In addition, the enzymatic activities of Cu-Zn superoxide dismutase and cytochrome c oxidase in brain extracts are similar in these groups of animals, as is the incorporation of (64)Cu into Cu-Zn superoxide dismutase both in cultured cerebellar neurons and in vivo. Our results differ from those of another set of published studies, and they require a re-evaluation of the role of PrP(C) in copper metabolism.

Intracellular pathways of copper trafficking in yeast and humans.

In the bakers yeast S. cerevisiae, there at least four intracellular targets requiring copper ions-1) Ccc2p and Fet3p in the secretory pathway (homologues to Menkes/Wilson proteins and ceruloplasmin); 2) cytochrome oxidase in the mitochondria; 3) copper transcription factors in the nucleus; and 4) Cu/Zn superoxide dismutase (SOD1) in the cytosol. We have discovered a small soluble copper carrier that specifically delivers copper ions to the secretory pathway. This 8.2 kDa factor known as Atx1p, exhibits striking homology to the MERp mercury carrier of bacteria and contains a single MTCXXC metal binding site also found in the Menkes/Wilson family of copper transporting ATPases. Our studies show that Atx1p is cytosolic and facilitates the delivery of copper ions from the cell surface copper transporter to Ccc2p and Fet3p in the secretory pathway; furthermore, it is not involved in the delivery of copper ions to the mitochondria, the nucleus or cytosolic SOD1, implicating specific signals directing Atx1p to the secretory pathway. Homologues to Atx1p have been found in invertebrates, plants and humans, and the human gene is abundantly expressed in all tissues. In addition to Atx1p, we have recently uncovered an additional metal trafficking protein that appears to specifically deliver copper ions to SOD1. Mutants in the corresponding gene (lys7) are defective for SOD1 activity, and are unable to incorporate copper into SOD1, while there is no obvious impairment in copper delivery to cytochrome oxidase of Fet3p. The encoded 27 kDa protein contains a single MHCXXC consensus copper binding sequence and close homologues have been identified in a wide array of eukaryotic species including humans.

The copper chaperone CCS directly interacts with copper/zinc superoxide dismutase.

Dominantly inherited mutations in the gene encoding copper/zinc superoxide dismutase (SOD1) result in the fatal motor neuron disease familial amyotrophic lateral sclerosis (FALS). These mutations confer a gain-of-function to SOD1 with neuronal degeneration resulting from enhanced free radical generating activity of the copper present in the mutant enzyme. The delivery of copper to SOD1 is mediated through a soluble factor identified as the copper chaperone for SOD1 (CCS). Amino acid sequence alignment of SOD1 and CCS reveals a striking homology with conservation of the amino acids essential for mediating SOD1 homodimerization. Here we demonstrate that CCS and SOD1 directly interact in vitro and in vivo and that this interaction is mediated via the homologous domains in each protein. Importantly, CCS interacts not only with wild-type SOD1 but also with SOD1 containing the common missense mutations resulting in FALS. Our findings therefore reveal a common mechanism whereby different SOD1 FALS mutants may result in neuronal injury and suggest a novel therapeutic approach in patients affected by this fatal disease.

HAH1 is a copper-binding protein with distinct amino acid residues mediating copper homeostasis and antioxidant defense.

HAH1 is a 68-amino acid protein originally identified as a human homologue of Atx1p, a multi-copy suppressor of oxidative injury in sod1 delta yeast. Molecular modeling of HAH1 predicts a protein structure of two alpha-helices overlaying a four-stranded antiparallel beta-sheet with a potential metal binding site involving two conserved cysteine residues. Consistent with this model, in vitro studies with recombinant HAH1 directly demonstrated binding of Cu(I), and site-directed mutagenesis identified these cysteine residues as copper ligands. Expression of wild type and mutant HAH1 in atx1 delta yeast revealed the essential role of these cysteine residues in copper trafficking to the secretory compartment in vivo, as expression of a Cys-12/Cys-15 double mutant abrogated copper incorporation into the multicopper oxidase Fet3p. In contrast, mutation of the highly conserved lysine residues in the carboxyl terminus of HAH1 had no effect on copper trafficking to the secretory pathway but eliminated the antioxidant function of HAH1 in sod1 delta yeast. Taken together, these data support the concept of a unique copper coordination environment in HAH1 that permits this protein to function as an intracellular copper chaperone mediating distinct biological processes in eucaryotic cells.

The copper chaperone for superoxide dismutase.

Copper is distributed to distinct localizations in the cell through diverse pathways. We demonstrate here that the delivery of copper to copper/zinc superoxide dismutase (SOD1) is mediated through a soluble factor identified as Saccharomyces cerevisiae LYS7 and human CCS (copper chaperone for SOD). This factor is specific for SOD1 and does not deliver copper to proteins in the mitochondria, nucleus, or secretory pathway. Yeast cells containing a lys7Delta null mutation have normal levels of SOD1 protein, but fail to incorporate copper into SOD1, which is therefore devoid of superoxide scavenging activity. LYS7 and CCS specifically restore the biosynthesis of holoSOD1 in vivo. Elucidation of the CCS copper delivery pathway may permit development of novel therapeutic approaches to human diseases that involve SOD1, including amyotrophic lateral sclerosis.