Glutathione-S-transferase pull-down experiments, co-immunoprecipitations, immunofluorescence microscopy, site-directed mutagenesis, and biosynthetic labeling experiments were performed to characterize the interaction between COMMD1 and ATP7B and the effects of WD causing mutations.
The distinct functional properties of the nucleotide-binding domain of ATP7B, the human copper-transporting ATPase: analysis of the Wilson disease mutations E1064A, H1069Q, R1151H, and C1104F.
The phenotypic expression of WD was compared between patients with different types of mutations in ATP7B, detected by direct sequencing of exons 1-21 of the gene.
The present study was intended to estimate the frequencies of the most common mutations (R778L, R778W, R778G, I1102T and H1069Q) of ATP7B in Indian Wilson disease (WD) population and to explore the correlation between genotype/phenotype and copper ATPase activity.
The results produced in this paper indicate that the best strategy for mutation detection in Yugoslavian patients with WD is an SSCP analysis of exons 14, 8, 5, and 13, where most of the defects (73.1%) lie, followed by mutation analysis of the remaining exons in ATP7B in patients in whom the mutation was not detected by the finitial screening.
The results show (i) the vast majority of mutations lead to the amino-acid distribution probability increase in mutant ATP7As and decrease in ATP7Bs, and (ii) the probability that a mutation causes Menkes/Wilson disease is about nine tenth.
These results indicated that the human ATP7B product compensated for the deficiency of the endogenous rattus protein and did function in intrahepatic copper transport by secreting copper into the plasma via incorporation into ceruloplasmin and by the excretion of copper into the bile, and that ATP7B is critical to hepatic dysfunctions in WD.
We have sequenced the 5' UTR and promoter region of ATP7B in 37 unrelated WND patients in whom partial sequencing of the coding region and intron/exon boundaries of the gene had failed to identify one or both disease-causing mutations.