Refinement of the PARK3 locus on chromosome 2p13 and the analysis of 14 candidate genes.

Parkinson's disease (PD) is a common neurodegenerative disorder with clinical features of bradykinesia, rigidity, resting tremor and postural instability resulting from the deficiency of dopamine in the nigrostriatal system. Previously we mapped a susceptibility gene for an autosomal dominant form of PD to a 10.6 cM region of chromosome 2p (PARK3; OMIM 602404). A common haplotype shared by two North American kindreds (Families B and C) genealogically traced to Southern Denmark and Northern Germany suggested a founder effect. Here we report progress in the refinement of the PARK3 locus and sequence analysis of candidate genes within the region. Members of families B and C were genotyped using polymorphic markers, reducing the minimum common haplotype to eight markers spanning a physical distance of 2.5 Mb. Analysis of 14 genes within the region did not reveal any potentially pathogenic mutations segregating with the disease, implying that none of these genes are likely candidates for PARK3.

Identification of the copper chaperone SAH in Ovis aries: expression analysis and in vitro interaction of SAH with ATP7B.

A clone encoding the putative copper chaperone protein Sheep Atx1 Homologue (SAH) was isolated from a sheep liver cDNA library. The 466-bp cDNA encoded a predicted protein of 68 amino acids, with 44 and 81% amino acid identity to the yeast Atx1 and human Atox1 copper chaperone proteins, respectively. The characteristic MTCxxC and KTGK motifs were conserved in SAH. Northern blot analysis revealed an abundant 0.5-kb mRNA in all tissues examined. Elevated hepatic copper content did not affect the level of SAH mRNA in the liver. Analysis of SAH mRNA in the developing liver revealed low levels of expression in the foetal period, with a steady increase to adult levels occurring during development. In vitro two-hybrid analysis demonstrated SAH interacted with the amino terminal portion of the sheep Wilson's disease protein (ATP7B). The extent of this interaction was significantly reduced by the addition of the copper chelator bathocuproine disulfonic acid to the media. These results suggest SAH is a functional copper chaperone that is able to interact with ATP7B in a copper-dependent manner to facilitate copper transport into the secretory pathway.

Cloning and expression analysis of the sheep ceruloplasmin cDNA.

The cDNA encoding sheep ceruloplasmin (sCP) was isolated from a sheep liver cDNA library. The cDNA contig was 3530 nucleotides in length and encoded a protein of 1048 amino acids. The deduced amino acid sequence showed a high degree of conservation (87%) when compared to the human ceruloplasmin (hCP) sequence. Northern blot analysis of sheep tissue revealed that the sheep ceruloplasmin gene (sCP) was expressed primarily in the liver, but low levels of mRNA were detected in the hypothalamus, spleen and uterus. No sCP mRNA was detected in the cortex, heart, intestine or kidney. Expression was not significantly affected by hepatic copper content. Northern blot analysis of sheep liver during development demonstrated little sCP expression during fetal life, but significant levels of mRNA were observed after birth. Significantly, the developmental expression pattern of sCP was closely correlated with that of the sheep Wilson disease gene (sATP7B), suggesting that the expression of the two genes may be coordinated to ensure that copper is supplied to apoceruloplasmin. Overall, the structure and expression of sCP appeared similar to other mammals, suggesting that abnormalities in CP were not responsible for the unusual sheep copper 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.

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.