Endosomal trafficking of the Menkes copper ATPase ATP7A is mediated by vesicles containing the Rab7 and Rab5 GTPase proteins.

The Cu-ATPase ATP7A (MNK) is localized in the trans-Golgi network (TGN) and relocalizes in the plasma membrane via vesicle-mediated traffic following exposure of the cells to high concentrations of copper. Rab proteins are organelle-specific GTPases, markers of different endosomal compartments; their role has been recently reviewed (Trends Cell Biol. 11(2001) 487). In this article we analyze the endosomal pathway of trafficking of the MNK protein in stably transfected clones of CHO cells, expressing chimeric Rab5-myc or Rab7-myc proteins, markers of early or late endosome compartments, respectively. We demonstrate by immunofluorescence and confocal and electron microscopy techniques that the increase in the concentration of copper in the medium (189 microM) rapidly induces a redistribution of the MNK protein from early sorting endosomes, positive for Rab5-myc protein, to late endosomes, containing the Rab7-myc protein. Cell fractionation experiments confirm these results; i.e., the MNK protein is recruited to the endosomal fraction on copper stimulation and colocalizes with Rab5 and Rab7 proteins. These findings allow the first characterization of the vesicles involved in the intracellular routing of the MNK protein from the TGN to the plasma membrane, a key mechanism allowing appropriate efflux of copper in cells grown in high concentrations of the metal.

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.

Functional studies on the Wilson copper P-type ATPase and toxic milk mouse mutant.

The Wilson protein (WND; ATP7B) is an essential component of copper homeostasis. Mutations in the ATP7B gene result in Wilson disease, which is characterised by hepatotoxicity and neurological disturbances. In this paper, we provide the first direct biochemical evidence that the WND protein functions as a copper-translocating P-type ATPase in mammalian cells. Importantly, we have shown that the mutation of the conserved Met1386 to Val, in the Atp7B for the mouse model of Wilson disease, toxic milk (tx), caused a loss of Cu-translocating activity. These investigations provide strong evidence that the toxic milk mouse is a valid model for Wilson disease and demonstrate a link between the loss of catalytic function of WND and the Wilson disease phenotype.

Intracellular localization and loss of copper responsiveness of Mnk, the murine homologue of the Menkes protein, in cells from blotchy (Mo blo) and brindled (Mo br) mouse mutants.

Menkes disease is an X-linked copper deficiency disorder that results from mutations in the ATP7A ( MNK ) gene. A wide range of disease-causing mutations within ATP7A have been described, which lead to a diversity of phenotypes exhibited by Menkes patients. The mottled locus ( Mo, Atp7a, Mnk ) represents the murine homologue of the ATP7A gene, and the mottled mutants exhibit a diversity of phenotypes similar to that observed among Menkes patients. Therefore, these mutants are valuable models for studying Menkes disease. Two of the mottled mutants are brindled and blotchy and their phenotypes resemble classical Menkes disease and occipital horn syndrome (OHS) in humans, respectively. That is, the brindled mutant and patients with classical Menkes disease are severely copper deficient and have profound neurological problems, while OHS patients and the blotchy mouse have a much milder phenotype with predominantly connective tissue defects. In this study, in an attempt to understand the basis for the brindled and blotchy phenotypes, the copper transport characteristics and intracellular distribution of the Mnk protein were assessed in cultured cells from these mutants. The results demonstrated that the abnormal copper metabolism of brindled and blotchy cells may be related to a number of factors, which include the amount of Mnk protein, the intracellular location of the protein and the ability of Mnk to redistribute in elevated copper. The data also provide evidence for a relationship between the copper transport function and copper-dependent trafficking of Mnk.

The role of GMXCXXC metal binding sites in the copper-induced redistribution of the Menkes protein.

The Menkes protein (MNK or ATP7A) is a transmembrane, copper-transporting CPX-type ATPase, a subgroup of the extensive family of P-type ATPases. A striking feature of the protein is the presence of six metal binding sites (MBSs) in the N-terminal region with the highly conserved consensus sequence GMXCXXC. MNK is normally located in the trans-Golgi network (TGN) but has been shown to relocalize to the plasma membrane when cells are cultured in media containing high concentrations of copper. The experiments described in this report test the hypothesis that the six MBSs are required for this copper-induced trafficking of MNK. Site-directed mutagenesis was used to convert both cysteine residues in the conserved MBS motifs to serines. Mutation of MBS 1, MBS 6, and MBSs 1-3 resulted in a molecule that appeared to relocalize normally with copper, but when MBSs 4-6 or MBSs 1-6 were mutated, MNK remained in the TGN, even when cells were exposed to 300 microM copper. Furthermore, the ability of the MNK variants to relocalize corresponded well with their ability to confer copper resistance. To further define the critical motifs, MBS 5 and MBS 6 were mutated, and these changes abolished the response to copper. The region from amino acid 8 to amino acid 485 was deleted, resulting in mutant MNK that lacked 478 amino acids from the N-terminal region, including the first four MBSs. This truncated molecule responded normally to copper. Moreover, when either one of the remaining MBS 5 and MBS 6 was mutated to GMXSXXS, the resulting proteins were localized to the TGN in low copper and relocalized in response to elevated copper. These experiments demonstrated that the deleted N-terminal region from amino acid 8 to amino acid 485 was not essential for copper-induced trafficking and that one MBS close to the membrane channel of MNK was necessary and sufficient for the copper-induced redistribution.

Correction of the copper transport defect of Menkes patient fibroblasts by expression of the Menkes and Wilson ATPases.

Menkes' disease is a fatal, X-linked, copper deficiency disorder that results from defective copper efflux from intestinal cells and inadequate copper delivery to other tissues, leading to deficiencies of critical copper-dependent enzymes. Wilson's disease is an autosomally inherited, copper toxicosis disorder resulting from defective biliary excretion of copper, which leads to copper accumulation in the liver. The ATP7A and ATP7B genes that are defective in patients with Menkes' and Wilson's diseases, respectively, encode transmembrane, P-type ATPase proteins (ATP7A or MNK and ATP7B or WND, respectively) that function to translocate copper across cellular membranes. In this study, the cDNAs derived from a normal human ATP7A gene and the murine ATP7B homologue, Atp7b, were separately transfected into an immortalized fibroblast cell line obtained from a Menkes' disease patient. Both MNK and WND expressed from plasmid constructs were able to correct the copper accumulation and copper retention phenotype of these cells. However, the two proteins responded differently to elevated extracellular copper levels. Although MNK showed copper-induced trafficking from the trans-Golgi network to the plasma membrane, in the same cell line the intracellular location of WND did not appear to be affected by elevated copper.

Functional analysis and intracellular localization of the human menkes protein (MNK) stably expressed from a cDNA construct in Chinese hamster ovary cells (CHO-K1).

The Menkes protein (MNK or ATP7A) is an important component of the mammalian copper transport pathway and is defective in Menkes disease, a fatal X-linked disorder of copper transport. To study the structure and function of this protein and to elucidate its role in cellular copper homeostasis, a cDNA construct encoding the full-length MNK protein was cloned into a mammalian expression vector under the control of the CMV promoter. Transfection of this plasmid construct into CHO-K1 cells yielded clones that expressed MNK at varying levels. Detailed characterization of four clones showed that an increase in MNK protein expression led to a corresponding increase in the level of copper resistance of the cells. Subcellular localization studies showed that in the parental CHO-K1 and the transfected cell lines, MNK was located in a post-Golgi compartment which, based on immunogold electron microscopic analyses, most likely represented the trans -Golgi network (TGN). When the extracellular copper concentration was increased, MNK in the clones as well as in CHO-K1 cells was redistributed to the cytoplasm and plasma membrane, but returned to the TGN under basal, low copper conditions. This report presents the first ultrastructural evidence for the association of MNK with vesicles within the cell and with the TGN and plasma membrane. It also demonstrates the stable expression of a functional MNK protein from a cDNA construct in mammalian cells, as well as the copper-induced redistribution of MNK in a cell line (CHO-K1) that was not selected for copper resistance or overexpression of MNK.

Physical and genetic map of the chromosome of Dichelobacter nodosus strain A198.

A physical map of the chromosome of Dichelobacter nodosus strain A198 was constructed using the restriction endonucleases EagI and StuI. Mapping data indicated the presence of a single, circular chromosome of 1.54 Mb. The three rRNA operons and the virulence related locus (vrl) were precisely positioned at the junctions of EagI and StuI fragments, and their transcriptional orientations were also determined. Other D. nodosus genes were assigned to specific EagI and StuI fragments. Analysis of the resultant map revealed that the putative virulence genes were not clustered on the chromosome which suggests that the D. nodosus virulence determinants have been acquired gradually and that virulence in D. nodosus is an evolving trait.

Detection of Dichelobacter nodosus using species-specific oligonucleotides as PCR primers.

Dichelobacter nodosus is an essential causative agent of ovine footrot, a disease of major economic significance. Four oligonucleotides complementary to variable regions of the 16S rRNA of D. nodosus were identified, synthesized and tested for their specificity and sensitivity as probes for the detection of D. nodosus. In hybridization reactions using total RNA as the target nucleic acid, three probes were found to be both sensitive and species-specific. When these probes were used as primers in PCR reactions, on both purified D. nodosus DNA and whole cells, the sensitivity of detection was increased by several orders of magnitude. Using PCR, it was possible to detect the presence of D. nodosus by direct examination of lesion material from footrot infected sheep.

Transfer of Kingella indologenes (Snell and Lapage 1976) to the genus Suttonella gen. nov. as Suttonella indologenes comb. nov.; transfer of Bacteroides nodosus (Beveridge 1941) to the genus Dichelobacter gen. nov. as Dichelobacter nodosus comb. nov.; and assignment of the genera Cardiobacterium, Dichelobacter, and Suttonella to Cardiobacteriaceae fam. nov. in the gamma division of Proteobacteria on the basis of 16S rRNA sequence comparisons.

The 16S rRNA sequences of Kingella indologenes, Cardiobacterium hominis, and Bacteroides nodosus were determined by direct RNA sequencing, using a modified Sanger method. Sequence comparisons indicated that these three species represent a novel family in the gamma division of Proteobacteria. On the basis of these data, K. indologenes and B. nodosus cannot retain their current generic status as they are not closely related to other members of their assigned genera. Therefore, we propose transfer of K. indologenes to the new genus Suttonella as Suttonella indologenes and transfer of B. nodosus to the new genus Dichelobacter as Dichelobacter nodosus and assign the genera Cardiobacterium, Suttonella, and Dichelobacter to a new family, Cardiobacteriaceae, in the gamma division of Proteobacteria.

Evidence that Bacteroides nodosus belongs in subgroup gamma of the class Proteobacteria, not in the genus Bacteroides: partial sequence analysis of a B. nodosus 16S rRNA gene.

The taxonomic status of the anaerobe Bacteroides nodosus has for some time been uncertain. To resolve this uncertainty, the distal portion of a 16S rRNA gene from this important ovine pathogen was cloned, mapped, and sequenced. A comparison of the sequence with the sequences of 16S rRNA molecules from other bacteria indicated that B. nodosus is more closely related to Escherichia coli and other members of the class Proteobacteria than to Bacteroides fragilis or the bacteroides-flavobacterium-cytophaga phylum. The evidence from the comparison of sequence signatures suggests that B. nodosus is not a member of the genus Bacteroides but that it belongs in subgroup gamma of the class Proteobacteria.