Publications (3)18.68 Total impact
-
Article: Evidence that translation reinitiation leads to a partially functional Menkes protein containing two copper-binding sites.
[show abstract] [hide abstract]
ABSTRACT: Menkes disease (MD) is an X-linked recessive disorder of copper metabolism. It is caused by mutations in the ATP7A gene encoding a copper-translocating P-type ATPase, which contains six N-terminal copper-binding sites (CBS1-CBS6). Most patients die in early childhood. We investigated the functional effect of a large frameshift deletion in ATP7A (including exons 3 and 4) identified in a patient with MD with unexpectedly mild symptoms and long survival. The mutated transcript, ATP7A(Delta ex3+ex4), contains a premature termination codon after 46 codons. Although such transcripts are generally degraded by nonsense-mediated mRNA decay (NMD), it was established by real-time PCR quantification that the ATP7A(Delta ex3+ex4) transcript was protected from degradation. A combination of in vitro translation, recombinant expression, and immunocytochemical analysis provided evidence that the ATP7A(Delta ex3+ex4) transcript was protected from degradation because of reinitiation of protein translation. Our findings suggest that reinitiation takes place at two downstream internal codons. The putative N-terminally truncated proteins contain only CBS5 and CBS6. Cellular localization and copper-dependent trafficking of the major part of endogenous and recombinant ATP7A(Delta ex3+ex4) proteins were similar to the wild-type ATP7A protein. Furthermore, the ATP7A(Delta ex3+ex4) cDNA was able to rescue a yeast strain lacking the homologous gene, CCC2. In summary, we propose that reinitiation of the NMD-resistant ATP7A(Delta ex3+ex4) transcript leads to the synthesis of N-terminally truncated and at-least-partially functional Menkes proteins missing CBS1-CBS4. This finding--that a mutation that would have been assumed to be null is not--highlights the need to examine the biochemical phenotype of patients to deduce the efficacy of copper therapy.The American Journal of Human Genetics 09/2006; 79(2):214-29. · 10.60 Impact Factor -
Article: Homozygosity for a gross partial gene deletion of the C-terminal end of ATP7B in a Wilson patient with hepatic and no neurological manifestations.
[show abstract] [hide abstract]
ABSTRACT: We identified a partial gene deletion of ATP7B in a patient with Wilson disease with hepatic onset. The deletion covered exon 20 including major parts of the flanking introns. The breakpoints were identified and the size of the deletion determined to be 2144 bp. The deletion is predicted to lead to a mutated protein product containing 45 aberrant amino acids after transmembrane domain 7, and lacking the transmembrane domain 8 as well as the entire C-terminal cytoplasmic tail. This is the first time a partial gene deletion has been demonstrated in ATP7B. The patient presented at age 10 with hepatic manifestations, including severe jaundice, hepato-splenomegaly, ascites, and spider naevi. The liver biopsy showed fibrosis and early signs of cirrhosis. There was a Kayser-Fleischer ring but no neurological manifestations. All symptoms disappeared with penicillamine therapy. This suggests that the C-terminal cytoplasmatic tail of ATP7B, is not essential for its neurological function. Large deletions in ATP7B may be an overlooked cause of Wilson disease. Patients that are homozygotes for deletions may be valuable for the understanding of the function of various regions of the ATP7B protein.American Journal of Medical Genetics Part A 12/2005; 138(4):340-3. · 2.39 Impact Factor -
Article: Identification and analysis of 21 novel disease-causing amino acid substitutions in the conserved part of ATP7A.
[show abstract] [hide abstract]
ABSTRACT: ATP7A encodes a copper-translocating ATPase that belongs to the large family of P-type ATPases. Eight conserved regions define the core of the P-type ATPase superfamily. We report here the identification of 21 novel missense mutations in the conserved part of ATP7A that encodes the residues p.V842-p.S1404. Using the coordinates of X-ray crystal structures of the sarcoplasmic reticulum Ca(2+)-ATPase, as determined in the presence and absence of Ca(2+), we created structural homology models of ATP7A. By mapping the substituted residues onto the models, we found that these residues are more clustered three-dimensionally than expected from the primary sequence. The location of the substituted residues in conserved regions supports the functional similarities between the two types of P-type ATPases. An immunofluorescence analysis of Menkes fibroblasts suggested that the localization of a large number of the mutated ATP7A protein variants was correct. In the absence of copper, they were located in perinuclear regions of the cells, just like the wild type. However, two of the mutated ATP7A variants showed only partly correct localization, and in five cultures no ATP7A protein could be detected. These findings suggest that although a disease-causing mutation may indicate a functional significance of the affected residue, this is not always the case.Human Mutation 09/2005; 26(2):84-93. · 5.69 Impact Factor
