Protein kinase-dependent phosphorylation of the Menkes copper P-type ATPase

The Menkes copper-translocating P-type ATPase (ATP7A; MNK) is a key regulator of copper homeostasis in humans. It has a dual role in supplying copper to essential cuproenzymes in the trans-Golgi network (TGN) and effluxing copper from the cell. These functions are achieved through copper-regulated trafficking of MNK between the TGN and the plasma membrane. However, the exact mechanism(s) which regulate the localisation and biochemical functions of MNK are still unknown. Here we investigated copper-dependent phosphorylation of MNK by a putative protein kinase(s). We found that in the presence of elevated copper there was a substantial increase in phosphorylation of the wild-type MNK in vivo. The majority of copper-dependent phosphorylation was on serine residues in two phosphopeptides. In contrast, there was no up-regulation of phosphorylation of a non-trafficking MNK mutant with mutated cytosolic copper-binding sites. Our findings suggest a potentially important role of kinase-dependent phosphorylation in the regulation of function of the MNK protein.     

Mutational analysis of the Menkes copper P-type ATPase (ATP7A)

The Menkes protein (ATP7A; MNK) is a ubiquitous human copper-translocating P-type ATPase and it has a key role in regulating copper homeostasis. Previously we characterised fundamental steps in the catalytic cycle of the Menkes protein. In this study we analysed the role of several conserved regions of the Menkes protein, particularly within the putative cytosolic ATP-binding domain. The results of catalytic studies have indicated an important role of 1086His in catalysis. Our findings provide a biochemical explanation for the most common Wilson disease-causing mutation (H1069Q in the homologous Wilson copper-translocating P-type ATPase). Furthermore, we have identified a unique role of 1230Asp, within the DxxK motif, in coupling ATP binding and acylphosphorylation with copper translocation. Finally, we found that the Menkes protein mutants with significantly reduced catalytic activity can still undergo copper-regulated exocytosis, suggesting that only the complete loss of catalytic activity prevents copper-regulated trafficking of the Menkes protein.     

Phosphorylation regulates copper-responsive trafficking of the Menkes copper transporting P-type ATPase

The Menkes copper-translocating P-type ATPase (ATP7A) is a critical copper transport protein functioning in systemic copper absorption and supply of copper to cuproenzymes in the secretory pathway. Mutations in ATP7A can lead to the usually lethal Menkes disease. ATP7A function is regulated by copper-responsive trafficking between the trans-Golgi Network and the plasma membrane. We have previously reported basal and copper-responsive kinase phosphorylation of ATP7A but the specific phosphorylation sites had not been identified. As copper stimulates both trafficking and phosphorylation of ATP7A we aimed to identify all the specific phosphosites and to determine whether trafficking and phosphorylation are linked. We identified twenty in vivo phosphorylation sites in the human ATP7A and eight in hamster, all clustered within the N- and C-terminal cytosolic domains. Eight sites were copper-responsive and hence candidates for regulating copper-responsive trafficking or catalytic activity. Mutagenesis of the copper-responsive phosphorylation site Serine-1469 resulted in mislocalization of ATP7A in the presence of added copper in both polarized (Madin Darby canine kidney) and non-polarized (Chinese Hamster Ovary) cells, strongly suggesting that phosphorylation of specific serine residues is required for copper-responsive ATP7A trafficking to the plasma membrane. A constitutively phosphorylated site, Serine-1432, when mutated to alanine also resulted in mislocalization in the presence of added copper in polarized Madin Darby kidney cells. These studies demonstrate that phosphorylation of specific serine residues in ATP7A regulates its sub-cellular localization and hence function and will facilitate identification of the kinases and signaling pathways involved in regulating this pivotal copper transporter.     

A comparison of the mutation spectra of Menkes disease and Wilson disease

The genes for two copper-transporting ATPases, ATP7A and ATP7B, are defective in the heritable disorders of copper imbalance, Menkes disease (MNK) and Wilson disease (WND), respectively. A comparison of the two proteins shows extensive conservation in the signature domains, with amino acid identities outside of the conserved domains being limited. The mutation spectra of MNK and WND were compared to confirm and refine further regions critical for normal function. Mutations were found to be relatively widespread; however, the majority was concentrated within defined functional domains and membrane-spanning segments, reinforcing the importance of these regions for protein function. Of the total published point mutations in ATP7A, 23.0% are splice-site, 20.7% nonsense, 17.2% missense, and 39.1% small insertions/deletions. There is a high prevalence (58.2%) of missense mutations in ATP7B. For the other mutations in ATP7B, 7.4% are splice-site, 7.4% nonsense, and 27.0% small insertions/deletions. A region of possible importance is the intervening sequence between the last copper-binding domain and the first transmembrane helix, as this region has a high percentage of MNK mutations. Similarly, the region containing the ATP-binding domain has 24.6% of all WND mutations. The study of mutation locations is useful for defining critical regions or residues and for efficient molecular diagnosis.Electronic Supplementary Material Supplementary material is available for this article if you access the article at .     

Copper-regulated trafficking of the Menkes disease copper ATPase is associated with formation of a phosphorylated catalytic intermediate

The Menkes protein (MNK; ATP7A) is a copper-transporting P-type ATPase that is defective in the copper deficiency disorder, Menkes disease. MNK is localized in the trans-Golgi network and transports copper to enzymes synthesized within secretory compartments. However, in cells exposed to excessive copper, MNK traffics to the plasma membrane where it functions in copper efflux. A conserved feature of all P-type ATPases is the formation of an acyl-phosphate intermediate, which occurs as part of the catalytic cycle during cation transport. In this study we investigated the effect of mutations within conserved catalytic regions of MNK on intracellular localization and trafficking from the trans-Golgi network (TGN). Our findings suggest that mutations that block formation of the phosphorylated catalytic intermediate also prevent copper-induced relocalization of MNK from the TGN. Furthermore, mutations in the phosphatase domain, which resulted in hyperphosphorylation of MNK, caused constitutive trafficking from the TGN to the plasma membrane. A similar effect on trafficking was observed with a phosphatase mutation in the closely related copper ATPase, ATP7B, affected in Wilson disease. These findings suggest that the copper-induced trafficking of the Menkes and Wilson disease copper ATPases is associated with the phosphorylated intermediate that is formed during the catalysis of these pumps. Our findings describe a novel mechanism for regulating the subcellular location of a transport protein involving the recognition of intermediate conformations during catalysis.     

A single PDZ domain protein interacts with the Menkes copper ATPase, ATP7A. A new protein implicated in copper homeostasis

The homeostatic regulation of essential elements such as copper requires many proteins whose activities are often mediated and tightly coordinated through protein-protein interactions. This regulation ensures that cells receive enough copper without intracellular concentrations reaching toxic levels. To date, only a small number of proteins implicated in copper homeostasis have been identified, and little is known of the protein-protein interactions required for this process. To identify other proteins important for copper homeostasis, while also elucidating the protein-protein interactions that are integral to the process, we have utilized a known copper protein, the copper ATPase ATP7A, as a bait in a yeast two-hybrid screen of a human cDNA library to search for interacting partners. One of the ATP7A-interacting proteins identified is a novel protein with a single PDZ domain. This protein was recently identified to interact with the plasma membrane calcium ATPase b-splice variants. We propose a change in name for this protein from PISP (plasma membrane calcium ATPase-interacting single-PDZ protein) to AIPP1 (ATPase-interacting PDZ protein) and suggest that it represents the protein that interacts with the class I PDZ binding motif identified at the ATP7A C terminus. The interaction in mammalian cells was confirmed and an additional splice variant of AIPP1 was identified. This study represents an essential step forward in identifying the proteins and elucidating the network of protein-protein interactions involved in maintaining copper homeostasis and validates the use of the yeast two-hybrid approach for this purpose.     

Structure and metal binding studies of the second copper binding domain of the Menkes ATPase

Biological utilisation of copper requires that the metal, in its ionic forms, be meticulously transported, inserted into enzymes and regulatory proteins, and excess be excreted. To understand the trafficking process, it is crucial that the structures of the proteins involved in the varied processes be resolved. To investigate copper binding to a family of structurally related copper-binding proteins, we have characterised the second Menkes N-terminal domain (MNKr2). The structure, determined using 1H and 15N heteronuclear NMR, of the reduced form of MNKr2 has revealed two alpha-helices lying over a single beta-sheet and shows that the binding site, a Cys(X)2Cys pair, is located on an exposed loop. 1H-15N HSQC experiments demonstrate that binding of Cu(I) causes changes that are localised to conserved residues adjacent to the metal binding site. Residues in this area are important to the delivery of copper by the structurally related Cu(I) chaperones. Complementary site-directed mutagenesis of the adjacent residues has been used to probe the structural roles of conserved residues.     

Correction of the copper transport defect of Menkes patient fibroblasts by expression of two forms of the sheep Wilson ATPase

The Wilson disease (WD) protein (ATP7B) is a copper-transporting P-type ATPase that is responsible for the efflux of hepatic copper into the bile, a process that is essential for copper homeostasis in mammals. Compared with other mammals, sheep have a variant copper phenotype and do not efficiently excrete copper via the bile, often resulting in excessive copper accumulation in the liver. To investigate the function of sheep ATP7B and its potential role in the copper-accumulation phenotype, cDNAs encoding the two forms of ovine ATP7B were transfected into immortalised fibroblast cell lines derived from a Menkes disease patient and a normal control. Both forms of ATP7B were able to correct the copper-retention phenotype of the Menkes cell line, demonstrating each to be functional copper-transporting molecules and suggesting that the accumulation of copper in the sheep liver is not due to a defect in the copper transport function of either form of sATP7B.     

Menkes copper-translocating P-type ATPase (ATP7A): biochemical and cell biology properties,and role in Menkes disease

The Menkes copper-translocating P-type ATPase (ATP7A; MNK) is a ubiquitous protein that regulates the absorption of copper in the gastrointestinal tract. Inside cells the protein has a dual function: it delivers copper to cuproenzymes in the Golgi compartment and effluxes excess copper. The latter property is achieved through copper-dependent vesicular trafficking of the Menkes protein to the plasma membrane of the cell. The trafficking mechanism and catalytic activity combine to facilitate absorption and intercellular transport of copper. The mechanism of catalysis and copper-dependent trafficking of the Menkes protein are the subjects of this review. Menkes disease, a systemic copper deficiency disorder, is caused by mutations in the gene encoding the Menkes protein. The effect of these mutations on the catalytic cycle and the cell biology of the Menkes protein, as well as predictions of the effect of particular mutant MNKs on observed Menkes disease symptoms will also be discussed.     

Application of a copper blotting method to the study of Menkes disease

Menkes disease is an X-linked recessive disorder of copper metabolism. Deficient quantity or functional activity of a molecule involved in intracellular copper transport is believed to represent the basic defect. We applied an in vitro copper binding assay (copper blotting) to tissue proteins from Menkes patients and controls to evaluate differences in copper-binding. Proteins were separated by SDS-PAGE, electrotransferred to nitrocellulose, and probed with⁶⁷CuCl₂. Copper-binding polypeptides were visualized by autoradiography. No major differences were observed between a Menkes patient and control subjects in copper blots of post-mortem liver, kidney, or brain—tissues affected clinically by the disturbance of copper metabolism in Menkes disease. We also applied the copper blotting technique to fibroblast proteins from an affected female in whom the gene responsible for Menkes disease is interrupted by a chromosomal translocation, and detected no differences in copper-binding proteins relative to normal controls. These experiments suggest that the gene product defective in Menkes disease is not detectable in copper blots, either because normal tissue levels are below the limits of detection of this method, or because the molecule involved does not bind copper under these conditions.     

Structural basis for copper transfer by the metallochaperone for the Menkes/Wilson disease proteins

The Hah1 metallochaperone protein is implicated in copper delivery to the Menkes and Wilson disease proteins. Hah1 and the N-termini of its target proteins belong to a family of metal binding domains characterized by a conserved MT/HCXXC sequence motif. The crystal structure of Hah1 has been determined in the presence of Cu(I), Hg(II), and Cd(II). The 1.8 A resolution structure of CuHah1 reveals a copper ion coordinated by Cys residues from two adjacent Hah1 molecules. The CuHah1 crystal structure is the first of a copper chaperone bound to copper and provides structural support for direct metal ion exchange between conserved MT/HCXXC motifs in two domains. The structures of HgHah1 and CdHah1, determined to 1.75 A resolution, also reveal metal ion coordination by two MT/HCXXC motifs. An extended hydrogen bonding network, unique to the complex of two Hah1 molecules, stabilizes the metal binding sites and suggests specific roles for several conserved residues. Taken together, the structures provide models for intermediates in metal ion transfer and suggest a detailed molecular mechanism for protein recognition and metal ion exchange between MT/HCXXC containing domains.     

Correction of a mouse model of Menkes disease by the human Menkes gene

The brindled mouse is an accurate model of the fatal human X-linked copper deficiency disorder, Menkes disease. Males carrying the mutant allele of the Menkes gene orthologue Atp7a die in the second week of life. To determine whether the genetic defect in the brindled mice could be corrected by expression of the human Menkes gene, male transgenic mice expressing ATP7A from the chicken beta-actin composite promoter (CAG) were mated with female carriers of the brindled mutation (Atp7a(Mo-br)). Mutant males carrying the transgene survived and were fertile but the copper defect was not completely corrected. Unexpectedly males corrected with one transgenic line (T25#5) were mottled and resembled carrier females, this effect appeared to be caused by mosaic expression of the transgene. In contrast, males corrected with another line (T22#2) had agouti coats. Copper concentrations in tissues of the rescued mutants also resembled those of the heterozygous females, with high levels in kidney (84.6+/-4.9 microg/g in corrected males vs. 137.0+/-44.3 microg/g in heterozygotes) and small intestine (15.6+/-2.5 microg/g in corrected males vs. 15.7+/-2.8 microg/g in heterozygotes). The results show that the Menkes defect in mice is corrected by the human Menkes gene and that adequate correction is obtained even when the transgene expression does not match that of the endogenous gene.     

A Neurospora crassa Arp1 mutation affecting cytoplasmic dynein and dynactin localization

Of the actin-related proteins, Arp1 is the most similar to conventional actin, and functions solely as a component of the multisubunit complex dynactin. Dynactin has been identified as an activator of the microtubule-associated motor cytoplasmic dynein. The role of Arp1 within dynactin is two-fold: (1) it serves as a structural scaffold protein for other dynactin subunits; and (2) it has been proposed to link dynactin, and thereby dynein, with membranous cargo via interaction with spectrin. Using the filamentous fungus Neurospora crassa, we have identified genes encoding subunits of cytoplasmic dynein and dynactin. In this study, we describe a genetic screen for N. crassa Arp1 (ro-4) mutants that are defective for dynactin function. We report that the ro-4(E8) mutant is unusual in that it shows alterations in the localization of cytoplasmic dynein and dynactin and in microtubule organization. In the mutant, dynein/dynactin complexes co-localize with bundled microtubules at hyphal tips. Given that dynein transports membranous cargo from hyphal tips to distal regions, the cytoplasmic dynein and dynactin complexes that accumulate along microtubule tracts at hyphal tips in the ro-4(E8) mutant may have either reduced motor activity or be delayed for activation of motor activity following cargo binding.     

Cooperative binding of copper(I) to the metal binding domains in Menkes disease protein.

We have optimised the overexpression and purification of the N-terminal end of the Menkes disease protein expressed in Escherichia coli, containing one, two and six metal binding domains (MBD), respectively. The domain(s) have been characterised using circular dichroism (CD) and fluorescence spectroscopy, and their copper(I) binding properties have been determined. Structure prediction derived from far-UV CD indicates that the secondary structure is similar in the three proteins and dominated by beta-sheet. The tryptophan fluorescence maximum is blue-shifted in the constructs containing two and six MBDs relative to the monomer, suggesting more structurally buried tryptophan(s), compared to the single MBD construct. Copper(I) binding has been studied by equilibrium dialysis under anaerobic conditions. We show that the copper(I) binding to constructs containing two and six domains is cooperative, with Hill coefficients of 1.5 and 4, respectively. The apparent affinities are described by K(0.5), determined to be 65 microM and 19 microM for constructs containing two and six domains, respectively. Our data reveal a unique regulation of Menkes protein upon a change in copper(I) concentration. The regulation does not occur as an 'all-or-none' cooperativity, suggesting that the copper(I) binding domains have a basal low affinity for binding and release of copper(I) at low concentrations but are able to respond to higher copper levels by increasing the affinity, thereby contributing to prevent the copper concentration from reaching toxic levels in the cell.     

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.     

A core mutation affecting the folding properties of a soluble domain of the ATPase protein CopA from Bacillus subtilis

The two N-terminal domains of the P-type copper ATPase, CopAa and CopAb, from Bacillus subtilis differ in their folding capabilities in vitro. Whereas CopAb has the typical betaalphabetabetaalphabeta structure and is a rigid protein, CopAa is found to be largely unfolded. A sequence analysis of the two and of orthologue homologous proteins indicates that Ser46 in CopAa may destabilise the hydrophobic core, as also confirmed through a bioinformatic energy study. CopAb has a Val in the corresponding position. The S46V and S46A mutants are found to be folded, although the latter displays multiple conformations. S46VCopAa, in both apo and copper(I) loaded forms, has very similar structural and dynamic properties with respect to CopAb, besides a different length of strand beta2 and beta4. It is intriguing that the oxygen of Thr16 is found close, though at longer than bonding distance, to copper in both domains, as it also occurs in a human orthologue domain. This study contributes to understanding the behaviour of proteins that do not properly fold in vitro. A possible biological significance of the peculiar folding behaviour of this domain is discussed.     

A temperature-sensitive mutation affecting the mammalian 60 S ribosome.

A temperature-sensitive Chinese hamster cell mutant, ts14, is unable to synthesize protein in tissue culture at 39 degrees. That mutant's protein biosynthetic machinery has been characterized in cell-free, biologically active extracts. Similar to the mutant's phenotype in tissue culture, ts14 extracts cease protein synthesis in vitro within 15 min at 40 degrees. In contrast, at 25 degrees both ts14 and wild type extracts synthesize protein for more than 2 hours. Fractionation of mutant extracts and complementation with comparable wild type preparations indicate that ts14 possesses a thermolabile component associated with its polyribosomes. In preparation of ts14 ribosomes that are free of mRNA and bound protein factors, the defective factor is complemented functionally only by 60 S ribosomal subunits prepared from the wild type parent. Sedimentation analyses in sucrose gradients demonstrate that ts14's mutation specifically affects stability of the mutant's 60 S ribosome. Treatment with high ionic strength buffers preferentially disrupts the mutant's 60 S ribosomal subunit and results in preparations of mutant ribosomes that contain biologically active 40 S subunits only. These studies demonstrate the applicability of a genetic approach to analyzing structure-function relationships in the eukaryotic ribosome.