Inherited copper toxicosis with emphasis on copper toxicosis in Bedlington terriers

Canine copper toxicosis is an important inherited disease in Bedlington terriers, because of its high prevalence rate and similarity to human copper storage disease. It can lead to chronic liver disease and occasional haemolytic anaemia due to impaired copper excretion. The responsible gene for copper toxicosis in Bedlington terriers has been recently identified and was found not to be related to human Wilson’s disease gene ATP7B. Although our understanding of copper metabolism in mammals has improved through genetic molecular technology, the diversity of gene mutation related to copper metabolism in animals will help identify the responsible genes for non-Wilsonian copper toxicoses in human. This review paper discusses our knowledge of normal copper metabolism and the pathogenesis, molecular genetics and current research into copper toxicosis in Bedlington terriers, other animals and humans.     

The copper chaperone Atox1 in canine copper toxicosis in Bedlington terriers

Copper toxicosis, resulting in liver disease, commonly occurs in Bedlington terriers. This recessively inherited disorder, similar in many respects to Wilson disease, is of particular interest because the canine Atp7b gene, homologous to ATP7B defective in Wilson disease, is not responsible for canine copper toxicosis as has been expected. Atox1, a copper chaperone delivering copper to Atp7b, therefore became a potential candidate. We cloned canine Atox1, which shows conserved motifs of the copper-binding domain (MTCXXC) and of the lysine-rich region (KTGK), and showed 88, 80, and 41% amino acid sequence identity with the orthologous mouse, human, and yeast proteins. No gross deletions of Atox1 could be identified in the affected Bedlington terriers by Southern blot analysis of genomic DNA. The canine Atox1 gene spans about 4 kb, with a 204-bp open reading frame cDNA contained within two exons. Sequence analysis of the coding regions, including intron/exon boundaries, showed no mutations in Atox1 from genomic DNA of an affected dog. We have also identified an apparently nontranscribed canine Atox1 pseudogene, with 12 sequence changes and no intron. Mapping of Atox1 and a marker closely linked to the canine copper toxicosis locus indicated lack of synteny. Atox1 is therefore excluded as a candidate gene for canine copper toxicosis, indicating that some other unidentified gene must be responsible for this copper storage disease in dogs and also suggesting the possibility of a similar gene responsible for a copper storage disease in humans.     

Evaluation of the present breeding programme against copper toxicosis in Danish Bedlington terriers

A breeding programme to eradicate copper toxicosis in Danish Bedlington terriers has been established based on a DNA marker test. Genotyping of both parents is compulsory and after 1 January 2000, only homozygous non-carriers are used for breeding. In this study, two groups of Bedlington terriers were genotyped at 18 microsatellite loci. One group represented the original population of Bedlington terriers before introducing the breeding programme (n = 23); the other represented a group of homozygous non-carriers (n = 24) available for breeding after year 2000. Allele numbers, allele frequencies, observed heterozygosities (Ho), expected heterozygosities (He), locus-specific coefficients of inbreeding (Fl) and Nei's genetic distance (D) was calculated. Individual coefficients of inbreeding (Fi) were calculated from the pedigrees and an assignment test was performed. Four rare alleles were lost in the group of homozygous non-carriers. No significant differences were observed between the mean values of allele numbers, Ho, He, Fl and Fi of the two populations of dogs. Nei's genetic distance between the two populations was 0.06 and 88% of the homozygous non-carriers were assigned correctly in the assignment test. The overall diversity of the breed was low (Ho = 0.41) and the breeders were advised to include the heterozygous carriers again.     

Indirect molecular diagnosis of copper toxicosis in Bedlington terriers is complicated by haplotype diversity

Positional cloning recently identified the mutation causing copper toxicosis (CT) in Bedlington terriers. Isolation of the MURR1 gene will be of great value in developing a reliable diagnostic test for the breeding of a copper toxicosis-free stock. It will replace the current diagnostic test using the CT-linked marker, C04107, which is located in intron 1 of the MURR1 gene with a distance of approximately 8 kb from the exon 2 deletion. Despite the short distance between C04107 and the CT mutation, possible recombinant dogs have been reported with C04107. Although these dogs have a normal phenotype, they carry the C04107 allele 2, which is associated with CT. To study the origin of this possible recombination event we collected a pedigree consisting of two unaffected American Bedlington terriers and their litter of four pups, which were all homozygous for the C04107 2,2 genotype. Mutation analysis showed that two dogs were heterozygous for the CT exon 2 deletion mutation, whereas four dogs were homozygous for the wild-type (WT) allele. Haplotype analysis was performed using two DNA markers in the MURR1 gene and four DNA markers flanking the gene and spanning a region of approximately 600 kb. Surprisingly, we identified a new haplotype (haplotype C) that contains allele 2 of marker C04107 in combination with the WT MURR1 allele. Analysis of the flanking markers suggests there are different genetic backgrounds in the Bedlington terrier population.     

Characterization of the COMMD1 (MURR1) mutation causing copper toxicosis in Bedlington terriers

Copper toxicosis is an autosomal recessive disorder affecting Bedlington terriers, characterized by elevated liver copper levels and early death of affected dogs. Genetic linkage mapping studies initially identified linkage between the disease and the microsatellite marker C04107. Subsequently, the deletion of exon 2 of the copper metabolism domain containing 1 (COMMD1) gene (formerly MURR1) was shown to be the major cause of copper toxicosis, although the deletion breakpoints were not defined. In this investigation, polymerase chain reaction (PCR)-based techniques and sequencing were used to isolate the deletion breakpoints, utilizing the newly available dog genome sequence. The breakpoints were positioned at 65.3091 and 65.3489 Mb of dog chromosome 10, in intron 1 and intron 2 of COMMD1 respectively, a deletion of 39.7 kb. The two breakpoints share sequence homology suggesting that homologous recombination may have been responsible for the deletion. Using this information, a genomic diagnostic test for the COMMD1 deletion was developed and compared with microsatellite C04107 genotypes of 40 Bedlington terriers. Results from the 40 samples showed allele 2 of C04107 to be in linkage disequilibrium with the COMMD1 deletion.     

Diagnostic value of a microsatellite DNA marker for copper toxicosis in West-European Bedlington terriers and incidence of the disease

Recently, linkage of a DNA microsatellite marker to inherited copper toxicosis has been reported in American Bedlington terrier families. Due to the fact that there is little exchange of breeding stock between the USA and Europe, it remains to be investigated whether in Europe the marker is informative and is linked with the disease. We have therefore examined the diagnostic value of the microsatellite marker in the European Bedlington. In 130 dogs at least one year of age (62 from The Netherlands, 35 from Belgium, and 33 from Germany) histo- or cytochemical staining of copper was done in liver biopsies. Based on liver histo- or cytochemistry, 51 dogs were obligate carriers, and 25 dogs had copper toxicosis. The inferred genotypes of these 76 dogs were compared with the marker genotypes. All dogs with the disease were homozygous for the 167 bp marker allele. All obligate carriers were heterozygotes with the 167 bp and a 163-bp alleles. All phenotypically healthy dogs were either homozygous for the 163 bp allele or heterozygous. Thus, the marker was in complete linkage disequilibrium with the putative copper toxicosis gene with the 167 bp allele in phase with the disease allele. The frequencies of the 167 bp and the 163 bp allele, respectively, were 0.33 and 0.67 in Dutch dogs, 0.31 and 0.69 in German dogs, and 0.57 and 0.43 in Belgian dogs. We have confirmed the utility of this marker for diagnosis of inherited copper toxicosis in European Bedlington terriers.     

Copper toxicosis in non-COMMD1 Bedlington terriers is associated with metal transport gene ABCA12

Wilson’s disease, caused by a mutation in the ATP-ase 7B gene, is the only genetically characterised human disease with inhibition of biliary copper excretion and toxic copper accumulation in liver and occasionally brain. A similar copper toxicosis occurs in Bedlington terriers (CT) with liver damage only. Although CT has been associated with a defect in the COMMD1 gene (COMMD1 ^del/del), Bedlington terriers with CT and lacking this mutation are also recognised (non-COMMD1 ^del/del).A study was designed to identify any other gene polymorphisms associated with copper toxicity in Bedlington terriers employing genome wide association studies (GWAS) followed by deep sequencing of the candidate region. Blood for DNA analysis and liver for confirmation of the diagnosis was obtained from 30 non-COMMD1 ^del/del Bedlington terriers comprising equal numbers of CT-affected dogs and controls. DNA was initially subjected to GWAS screening and then further sequencing to target the putative mutant gene.The study has identified a significant disease association with a region on chromosome 37 containing identified SNP’s which are highly significantly associated with non-COMMD1 ^del/del Bedlington terrier CT. This region contains the ABCA12 gene which bears a close functional relationship to ATP-ase 7B responsible for Wilson’s disease in man.     

Duplicated DQ haplotypes increase the complexity of restriction element usage in cattle

The MHC of cattle encodes two distinct isotypes of class II molecules, DR and DQ. Unlike humans, cattle lack the DP locus and about half the common haplotypes express duplicated DQ genes. The number and frequency of DQA and DQB alleles means that most cattle are heterozygous. If inter- and/or intrahaplotype pairing of DQA and DQB molecules occurs, cattle carrying DQ-duplicated haplotypes may express more restriction elements than would be predicted by the number of expressed alleles. We are investigating whether duplicated haplotypes cause differences in immune response, particularly in terms of generating protective immunity. We have analyzed the Ag-presenting function of DQ molecules in two heterozygous animals, one of which carries a duplicated haplotype. We compared the class II isotype specificity of T cell clones recognizing a putative vaccinal peptide from foot-and-mouth disease virus (FMDV15). We show for the first time that bovine T cells can recognize Ag in the context of DQ molecules. We also present evidence that interhaplotype pairings of DQA and DQB molecules form functional restriction elements. Both animals showed distinct biases to usage of particular restriction elements. Mainly DQ-restricted clones were derived from the animal with duplicated DQ genes, whereas the majority of clones from the animal with a single DQ gene pair were DR restricted. Furthermore, haplotype bias was observed with both animals. These experiments show that understanding of class II chain pairing in addition to knowledge of the genotype may be important in vaccine design where effective epitope selection is essential.     

XIAP Is a copper binding protein deregulated in Wilson's disease and other copper toxicosis disorders

X-linked inhibitor of apoptosis (XIAP), known primarily for its caspase inhibitory properties, has recently been shown to interact with and regulate the levels of COMMD1, a protein associated with a form of canine copper toxicosis. Here, we describe a role for XIAP in copper metabolism. We find that XIAP levels are greatly reduced by intracellular copper accumulation in Wilson's disease and other copper toxicosis disorders and in cells cultured under high copper conditions. Elevated copper levels result in a profound, reversible conformational change in XIAP due to the direct binding of copper to XIAP, which accelerates its degradation and significantly decreases its ability to inhibit caspase-3. This results in a lowering of the apoptotic threshold, sensitizing the cell to apoptosis. These data provide an unsuspected link between copper homeostasis and the regulation of cell death through XIAP and may contribute to the pathophysiology of copper toxicosis disorders.     

Refined genetic and comparative physical mapping of the canine copper toxicosis locus

Recently, the copper toxicosis (CT) locus in Bedlington terriers was assigned to canine chromosome region CFA10q26, which is homologous to human chromosome region HSA2p13-21. A comparative map between CFA10q21-26 and HSA2p13-21 was constructed by using genes already localized to HSA2p13-21. A high-resolution radiation map of CFA10q21-26 was constructed to facilitate positional cloning of the CT gene. For this map, seven Type I and eleven Type II markers were mapped. Using homozygosity mapping, the CT locus could be confined to a 42.3 cR₃₀₀₀ region, between the FH2523 and C10.602 markers. On the basis of a partial BAC contig, it was estimated that 1-cR₃₀₀₀ is equivalent to approximately 210 kb, implying that the CT candidate region is therefore estimated to be about 9 Mb. Received: 16 December 1999 / Accepted: 23 February 2000     

A study of the role of metallothionein in the inherited copper toxicosis of dogs.

The role of metallothionein (MT) was assessed in the copper-loading disease prevalent in Bedlington terriers. Fractionation of tissue supernatants over Sephadex G-75 showed that most of the additional cytosolic copper present in liver tissue of these dogs was bound to MT, and that substantially more MT-bound copper could be solubilized by detergent plus mercaptoethanol. Zinc contents were only slightly raised, although most of the extra zinc was associated with a 4000-Mr ligand. Ion-exchange chromatography revealed two isoproteins, MT1 and MT2, in all the dog liver samples examined. In Bedlington terrier liver, copper associated with both isoproteins was increased, although the increase for MT2 was greater than for MT1. The content of MT protein was also raised, although cell-free translations and RNA blots of total liver RNA showed that this increase was not associated with a rise in MT mRNA. The significance of these results to the mechanism of copper accumulation in the Bedlington terrier disorder is discussed.     

Sponge cell aggregation: checkpoints in development indicate a high level of organismal complexity

Studies of regeneration provide insight across many scales of animal biology from the processes of cellular communication to the ecology of whole populations. Sponges are highly regenerative animals, with studies showing adults can both recover large portions of their body after predation or damage due to storms, and even reform whole individuals, via an aggregation stage, from dissociated tissues. While sponges are clearly highly regenerative, few studies actually show dissociated cells forming functional individuals. As sponges often serve as model organisms for studying the development and function of traits in metazoans, determining the universality and mechanics of their regeneration potential is important. We tested the capacity of members of seven sponge species from temperate freshwater and marine environments, from a range of taxonomic positions, and with different habits, to form functional sponges after dissociation. Development to a functional sponge progressed through a series of checkpoints: the sorting of cells and removal of debris; adhesion to a substrate and differentiation of cells; organization of cells into tissues; and regionalization of tissues. Two of the seven species tested, Spongilla lacustris and Haliclona cf. permollis, progressed through all four checkpoints, while the remaining five species progressed to various levels of development before aggregates disintegrated. Our findings highlight three important conclusions: (1) The ability of aggregates to differentiate into functional sponges is not as widespread as previously thought; (2) The species‐specific ability of aggregates to develop to functional sponges appears to be an adaptive trait; and (3) The progression of development in aggregates through checkpoints, which in later development involves formation of tissues and regionalization of tissues, highlights the complexity of the sponge body plan and suggests fundamental rules in development shared across metazoans.     

The copper toxicosis gene product Murr1 directly interacts with the Wilson disease protein

Copper toxicosis in Bedlington terriers is an autosomal recessive disorder characterized by excessive hepatic copper accumulation in association with a marked decrease in biliary copper excretion. Recent genetic data have revealed that MURR1, a single copy gene on dog chromosome 10q26, is mutated in this disorder. This gene encodes a 190-amino acid open reading frame of unknown function that is highly conserved in vertebrate species. The Wilson disease protein is a copper transporting ATPase shown to play a critical role in biliary copper excretion. Here we demonstrate that the Wilson disease protein directly interacts with the human homologue of Murr1 in vitro and in vivo and that this interaction is mediated via the copper binding, amino terminus of this ATPase. Importantly, this interaction is specific for this copper transporter, a finding consistent with the observation that impaired copper homeostasis in affected terriers is confined to the liver. Our findings reveal involvement of Murr1 in the defined pathway of hepatic biliary copper excretion, suggest a potential mechanism for Murr1 function in this process, and provide biochemical evidence in support of the proposed role of the MURR1 gene in hepatic copper toxicosis.     

New founder haplotypes at the myotonic dystrophy locus in southern Africa.

The association between normal alleles at the CTG repeat and two nearby polymorphisms in the myotonin protein kinase gene, the Alu insertion/deletion polymorphism and the myotonic dystrophy kinase (DMK)(G/T) intron 9/HinfI polymorphism, has been analyzed in South African Negroids, a population in which myotonic dystrophy (DM) has not been described. South African Negroids have a CTG allelic distribution that is significantly different from that in Caucasoids and Japanese: the CTG repeat lengths of > or = 19 are very rare. The striking linkage disequilibrium between specific alleles at the Alu polymorphism (Alu(ins) and Alu(del)), the HinfI polymorphism (HinfI-1 and HinfI-2), and the CTG repeat polymorphism seen in Caucasoid (Europeans and Canadians) populations was also found in the South African Negroid population. Numerous haplotypes, not previously described in Europeans, were, however, found. It thus seems likely that only a small number of these "African" chromosomes were present in the progenitors of all non-African peoples. These data provide support for the "out of Africa" model for the origin of modern humans and suggest that the rare ancestral DM mutation event may have occurred after the migration from Africa, hence the absence of DM in sub-Saharan Negroid peoples.     

Mapping the mutation causing lens luxation in several terrier breeds

Primary lens luxation (PLL), a painful and blinding inherited condition, is common in several breeds of terrier. Here we have examined the Veterinary Medical Database of patient encounters and Canine Eye Registration Foundation (CERF) cases records for the last 10 years and found the diagnosis recorded in 85 breeds. We have performed association analysis using a genome-wide microsatellite screen to map mutations underlying the condition in miniature bull terriers and Lancashire heelers. These studies show microsatellite alleles in disequilibrium with disease status with highest support in a 6.3-Mbp region in the central part of chromosome 3 (-log P(max) = 6.4). The same region also shows an association to the disease in Tibetan terriers. Tight junction protein-1 (TJP1) is a positional candidate to contain the PLL mutation. All recognized exons and splice junctions of TJP1 have been sequenced from affected, obligate carrier and control Lancashire heeler dogs. Several polymorphisms have been found, but these are not likely to cause the disease.     

Functional consequences of RNA interference targeting COMMD1 in a canine hepatic cell line in relation to copper toxicosis

A deletion in the copper metabolism (Murr1) domain containing 1 (COMMD1) gene is associated with hepatic copper toxicosis in dogs, yet evidence of copper retention in COMMD1-depleted hepatic cells has not been shown. In a dog hepatic cell line, we analysed the copper metabolic functions after an 80% (mRNA and protein) COMMD1 reduction with COMMD1-targeting siRNAs. Exposure to 64Cu resulted in a significant increase in copper retention in COMMD1-depleted cells. COMMD1-depleted cells were almost three times more sensitive to high extracellular copper concentrations. Copper-mediated regulation of metallothionein gene expression was enhanced in COMMD1-depleted cells. Based on the increased copper accumulation and enhanced cellular copper responses upon COMMD1 reduction, we conclude that COMMD1 has a major regulatory function for intracellular copper levels in hepatic cells.     

ATP6H, a subunit of vacuolar ATPase involved in metal transport: evaluation in canine copper toxicosis

Copper toxicosis (CT), resulting in liver disease, occurs commonly in Bedlington terriers. Canine CT is of particular interest because identification of the causative gene may lead to the discovery of another important gene in the copper transport pathway possibly related to human copper diseases not yet identified. Homologs of the copper transporting ATPase ATP7B, defective in Wilson disease, and the copper chaperone ATOX1 were potential candidates, but both have been excluded. The CT locus in Bedlington terriers has been mapped to canine chromosome region CFA10q26, which has a syntenic human chromosome region, HAS2p13-21. The gene ATP6H, for human vacuolar proton-ATPase subunit M9.2, is associated with copper and iron transport in yeast and has been mapped to HAS2p21 and suggested as a candidate gene for CT. We cloned canine ATP6H, which encodes a predicted protein with 99% amino acid sequence identity to the orthologous human protein. Canine ATP6H shows a conserved potential metal binding site, CSVCC, and a glycosylation site, NET. The canine ATP6H is organized into four exons, with a 246-bp open reading frame. Sequence analysis of the coding regions showed no mutations in ATP6H from genomic DNA of an affected dog. We have also identified two, apparently non-transcribed canine ATP6H pseudogenes. Mapping of the true ATP6H gene and a marker closely linked to the CT locus on a canine radiation hybrid panel indicted lack of close physical association. We have therefore excluded canine ATP6H as a candidate gene for canine copper toxicosis, indicating that some other unidentified gene is responsible for this copper storage disease. Received: 8 February 2001 / Accepted: 12 April 2001     

Stable isotope ratios indicate diet and habitat use in New World monkeys

This paper demonstrates the use of stable isotope ratios of carbon and nitrogen in animal tissues for indicating aspects of species behavioral strategy. We analyzed hair from individuals representing four species of New World monkeys (Alouatta palliata, the mantled howler; Ateles geoffroyi, the spider monkey; Cebus capucinus, the capuchin; and Brachyteles arachnoides, the woolly-spider monkey or muriqui) for δ¹³C and δ¹⁵N using previously developed methods. There are no significant differences in either carbon or nitrogen ratios between sexes, sampling year, or year of analysis. Seasonal differences in δ¹³C reached a low level of significance but do not affect general patterns. Variation within species was similar to that recorded previously within single individuals. The δ¹³C data show a bimodal distribution with significant difference between the means. The two monkey populations living in an evergreen forest were similar to each other and different from the other two monkey populations that inhabited dry, deciduous forests. This bimodal distribution is independent of any particular species' diet and reflects the level of leaf cover in the two types of forest. The δ¹⁵N data display three significantly different modes. The omnivorous capuchins were most positive reflecting a trophic level offset. The spider monkeys and the muriquis were similar to one another and significantly more positive than the howlers. This distribution among totally herbivorous species correlates with the ingestion of legumes by the howler monkey population. In combination, these data indicate that museum-curated primate material can be analyzed to yield information on forest cover and diet in populations and species lacking behavioral data. Am. J. Phys. Anthropol. 103:69–83, 1997. © 1997 Wiley-Liss, Inc.     

Mitochondrial DNA haplotypes indicate two postglacial re‐colonization routes of the spruce bark beetle Ips typographus through northern Europe to Scandinavia

Species in northern Europe re‐colonized the region after the last glacial maximum via several routes, which could have lingering signatures in current intraspecific trait variation. The spruce bark beetle, Ips typographus, occurs across Europe, and biological differences have been found between southern and northern Scandinavian populations. However, the postglacial history of I. typographus in Scandinavia has not been previously studied at a fine geographical scale. Therefore, we collected specimens across northern Europe and analysed the genetic variation in a quite large mitochondrial fragment (698 bp). A high genetic diversity was found in some of the most northern populations, in the Baltic States, Gotland and central Europe. Detected genetic and phylogeographic structures suggest that I. typographus re‐colonized Scandinavia via two pathways, one from the northeast and one from the south. These findings are consistent with the re‐colonization history of its host plant, Picea abies. However, we observed low haplotype and nucleotide diversity in southern Scandinavian populations of I. typographus, indicating that (unlike P. abies) it did not disperse across the Baltic Sea in multiple events. Further, the divergence among Scandinavian populations was shallow, conflicting with a scenario where I. typographus expanded concurrently with its host plant from a ‘cryptic refugium’ in the northwest.