Assignment of the human tyrosine aminotransferase gene to chromosome 16

Summary The liver enzyme tyrosine aminotransferase (TAT; EC 2.6.1.5) catalyzes the rate-limiting step in the catabolic pathway of tyrosine. Deficiency in TAT enzyme activity underlies the autosomally inherited disorder tyrosinemia II (Richner-Hanhart syndrome). Using a human TAT cDNA clone as hybridization probe, we have determined the chromosomal location of the TAT structural gene by Southern blot analysis of DNAs from a series of human x rodent somatic cell hybrids. The results assign the TAT gene to human chromosome 16.     

Tyrosine aminotransferase deficiency in mink (Mustela vision): A model for human tyrosinemia II

Mink pseudodistemper, a recessive disease associated with high blood tyrosinelevels, is an animal analogue of the human inborn error of metabolism, tyrosinemia II. Affected mink and man have eye and skin lesions. Affected mink have no hepatic tyrosine aminotransferase (TAT) activity, as measured immunologically and biochemically. Hepatic mitochondrial aspartate aminotransferase is increased to 188% of control. This new genetic animal model of TAT deficiency should allow new studies of tyrosine metabolism.Supported by NIH Grants AM-17253 (LAG), 5T32-AM-07093 (LAG), and RCDA AM-0008 (LAG), grants from the Wisconsin State Mink Advisory Board, and a BRSG grant for the Graduate School of the University of Wisconsin, Madison, Publication No. 82 of the dermatology research laboratories of Duke University Medical Center.     

The mink proopiomelanocortin gene: characterization of cDNA and chromosomal localization

A cDNA library from the mink pituitary was screened using as probe a synthetic oligodeoxyribonucleotide, 5'-TTCATGACCTCCGA-3', corresponding to the endorphin region of bovine proopiomelanocortin (POMC) cDNA. As a result, several clones containing inserts complementary to POMC mRNA were identified. The sequence of one of the fragments (585 bp, 65% of the total length of mRNA) was determined. A high degree of homology (over 80%) among the primary structures of sequences from mink, man, and bovine cDNA POMC was established. With the cloned mink cDNA fragment as probe, the DNAs from mink-Chinese hamster hybrid clones were studied. The results of segregation analysis of mink POMC sequences and mink chromosomes in the mink-Chinese hamster panel allowed us to assign the POMC gene to mink chromosome 11.     

Inherited and de novo deletion of the tyrosine aminotransferase gene locus at 16q22.1 → q22.3 in a patient with tyrosinemia type II

Summary Tyrosinemia II is an autosomal-recessively inherited condition caused by deficiency in the liver-specific enzyme tyrosine aminotransferase (TAT; EC 2.6.1.5). We have restudied a patient with typical symptoms of tyrosinemia II who in addition suffers from multiple congenital anomalies including severe mental retardation. Southern blot analysis using a human TAT cDNA probe revealed a complete deletion of both TAT alleles in the patient. Molecular and cytogenetic analysis of the patient and his family showed one deletion to be maternally inherited, extending over at least 27 kb and including the complete TAT structural gene, whereas loss of the second TAT allele results from a small de novo interstitial deletion, del 16 (pterq22.1::q22.3qter), in the paternally inherited chromosome 16. Three additional loci previously assigned to 16q22 were studied in our patient: haptoglobin (HP), lecithin: cholesterol acyltransferase (LCAT), and the metallothionein gene cluster MT1, MT2. Of these three markers, only the HP locus was found to be codeleted with the TAT locus on the del(16) chromosome.     

Structural organization and analysis of the human fumarylacetoacetate hydrolase gene in tyrosinemia type I

Fumarylacetoacetate hydrolase (FAH) is a metabolic enzyme functioning at the last steo of tyrosine catabolism. Deficiency in this enzyme activity is associated with tyrosinemia type I, characterized by hypertyrosinemia, liver dysfunction, renal tubular dysfunction, liver cirrhosis, and hepatic tumors. We isolated from a human gene library a chromosomal gene related to FAH. The human FAH gene is 30 kilobases long and is split into 14 exons. All of the splice donor and acceptor sites conform to the GT/AG rule. We also analyzed findings in a patient with tyrosinemia type I with respect to the mutation responsible for detects in the enzyme. A nucleotide change from T to G was found in the exon 2 of the gene and this change was accompanied by an amino acid substitution (Phe62Cys). Transfection and expression analysis of the cDNA is cultured BMT-10 cells with the nucleotide substitution demonstrated that the substitution was indeed responsible for the decreased activity of the enzyme in the patient. These results confirmed that the T to G mutation was one of the causes of tyrosinemia type I. Structure of the FAH gene and tests for expression of the mutant FAH will facilitate further understanding of various aspects of FAH.     

Mapping of 53 loci in American mink (Mustela vison)

Fifty-three genes were mapped in the American mink genome using polymerase chain reaction (PCR)-based analysis of a Chinese hamster-American mink somatic cell hybrid panel. Heterologous primers designed for cat gene mapping were used in this study. Forty-nine of these loci were localized into expected chromosome regions according to Zoo-FISH data, whereas four loci--ALPL, CDC20, ERF-2, and Fc(Mv)23617--were mapped out of expected conserved regions. PCR products amplified with primers corresponding to these four markers were partly sequenced and verified using BLAST. The results showed the homology to be more than 90% between mink and human or cat counterparts. At present, the gene map of American mink has expanded to 127 loci.     

Chromosomal localization of the gene coding for the beta-subunit of Na+,K+-ATPase in the American mink (Mustela vison)

The BATP gene coding for the beta-subunit of Na+,K+-ATPase has been localized on chromosome 13 of the American mink (Mustela vison) using mink-Chinese hamster somatic cell hybrids and pig cDNA clones as probes. The AATP gene for the alpha-subunit of Na+,K+-ATPase is on mink chromosome 2 [(1987) FEBS Lett. 217, 42-44]. Consequently, the AATP and BATP genes for the Na+,K+-ATPase occupy separate mink chromosomes.     

Albinism in the American mink (Neovison vison) is associated with a tyrosinase nonsense mutation

Albino phenotypes are documented in various species including the American mink. In other species the albino phenotypes are associated with tyrosinase (TYR) gene mutations; therefore TYR was considered the candidate gene for albinism in mink. Four microsatellite markers were chosen in the predicted region of the TYR gene. Genotypes at the markers Mvi6025 and Mvi6034 were found to be associated with the albino phenotype within an extended half-sib family. A BAC clone containing Mvi6034 was mapped to chromosome 7q1.1-q1.3 by fluorescent in situ hybridization. Subsequent analysis of genomic TYR sequences from wild-type and albino mink samples identified a nonsense mutation in exon 1, which converts a TGT codon encoding cysteine to a TGA stop codon (c.138T>A, p.C46X; EU627590). The mutation truncates more than 90% of the normal gene product including the putative catalytic domains. The results indicate that the nonsense mutation is responsible for the albino phenotype in the American mink.     

Role of alveolar type II cells and of surfactant-associated protein C mRNA levels in the pathogenesis of respiratory distress in mink kits infected with Aleutian mink disease parvovirus.

Neonatal mink kits infected with Aleutian mink disease parvovirus (ADV) develop an acute interstitial pneumonia with clinical symptoms and pathological lesions that resemble those seen in preterm human infants with respiratory distress syndrome and in human adults with adult respiratory distress syndrome. We have previously suggested that ADV replicates in the alveolar type II epithelial cells of the lung. By using double in situ hybridization, with the simultaneous use of a probe to detect ADV replication and a probe to demonstrate alveolar type II cells, we now confirm this hypothesis. Furthermore, Northern (RNA) blot hybridization showed that the infection caused a significant decrease of surfactant-associated protein C mRNA produced by the alveolar type II cells. We therefore suggest that the severe clinical symptoms and pathological changes characterized by hyaline membrane formation observed in ADV-infected mink kits are caused by a dysfunction of alveolar surfactant similar to that observed in respiratory distress syndrome in preterm infants. However, in the infected mink kits the dysfunction is due to the replication of ADV in the lungs, whereas the dysfunction of surfactant in preterm infants is due to lung immaturity.     

Chromosomal localization of the gene coding for alpha-subunit of Na+,K+-ATPase in the American mink (Mustela vison)

The gene coding for the alpha-subunit of Na+,K+-ATPase has been localized on chromosome 2 of the American mink (Mustela vison) using the somatic cell hybrids mink-Chinese hamster and pig cDNA clones as hybridization probes.     

Cloning and sequence analysis of mink growth hormone cDNA

A cDNA clone for mink growth hormone (GH) was isolated from a mink pituitary cDNA library, employing a part of rat growth hormone cDNA sequence as a probe. According to the nucleotide sequence, mature mink GH consists of 190 amino acids with a calculated molecular weight of 21,720. The amino acid sequence homology between the mature region of mink GH and those of pig GH, rat GH, bovine GH and human GH was 98.4%, 93.7%, 89.0% and 66.7%, respectively.     

Molecular characterization of the Himalayan mink

A rare color variant of the American mink (Neovison vison), discovered on a ranch in Nova Scotia and referred to as the “marbled” variety, carries a distinctive pigment distribution pattern resembling that found in some other species, e.g., the Siamese cat and the Himalayan mouse. We tested the hypothesis that the color pattern in question—light-colored body with dark-colored points (ears, face, tail, and feet)—is due to a mutation in the melanin-producing enzyme tyrosinase (TYR) that results in temperature-sensitive pigment production. Our study shows that marbled mink carry a mutation in exon 4 of the TYR gene (c.1835C > G) which results in an amino acid substitution (p.H420Q). The location of this substitution corresponds to the amino acid position that is also mutated in the TYR protein of the Himalayan mouse. Thus, the marbled variant is more aptly referred to as the Himalayan mink.     

Isolation, characterization and chromosomal mapping of the mouse tyrosine aminotransferase gene

The tyrosine aminotransferase (TAT) gene is expressed in a tissue and developmental-specific manner. In addition, this gene is regulated by glucocorticoid and polypeptide hormones and its expression is affected when a regulatory region near the albino locus of the mouse is deleted. In order to allow studies of the molecular effects of these deletion mutations we have isolated and characterized the mouse TAT gene. The gene is 9.2 x 10(3) bases in length and consists of 12 exons which give rise to a 2.3 x 10(3) base long messenger RNA. The DNA sequence at the 5' end of the gene was determined and compared with the corresponding sequence of the rat tyrosine aminotransferase gene. The sequence comparison showed extensive homology over the entire region sequenced. In addition, DNA: DNA heteroduplex studies between the mouse and rat tyrosine aminotransferase genes revealed that this homology extends over the entire gene and its flanking sequences. The mouse tyrosine aminotransferase gene has been mapped distal to the serum esterase-1 locus on mouse chromosome 8, using a restriction fragment length polymorphism between two mouse species. Since the albino deletions are located on mouse chromosome 7, the assignment of the TAT gene to chromosome 8 suggests that a regulatory factor(s) affecting TAT gene expression acts in trans.     

Chromosomal and regional localization of the genes for UMPH2, APRT, PEPD, PEPS, PSP, and PGP in mink: comparison with man and mouse

Segregation of mink biochemical markers uridine 5'-monophosphate phosphohydrolase-2 (UMPH2), adenine phosphoribosyltransferase (APRT), phosphoserine phosphatase (PSP), phosphoglycolate phosphatase (PGP), peptidases D (PEPD) and S (PEPS), as well as mink chromosomes, was investigated in a set of mink x mouse hybrid clones. The results obtained allowed us to make the following mink gene assignments: UMPH2, chromosome 8; PEPD and APRT, chromosome 7; PEPS, chromosome 6; and PSP and PGP, chromosome 14. The latter two genes are the first known markers for mink chromosome 14. For regional mapping, UMPH2 was analyzed in mouse cell clones transformed by means of mink metaphase chromosomes (Gradov et al., 1985) and also in mink x mouse hybrid clones carrying fragments of mink chromosome 8 of different sizes. Based on the data obtained, the gene for UMPH2 was assigned to the region 8pter----p26 of mink chromosome 8. The present data is compared with that previously established for man and mouse with reference to the conservation of syntenic gene groups and G-band homoeologies of chromosomes in mammals.     

Aleutian mink disease parvovirus infection of mink peritoneal macrophages and human macrophage cell lines.

Aleutian mink disease parvovirus (ADV) mRNAs are found in macrophages in lymph nodes and peritoneal exudate cells from ADV-infected mink. Therefore, we developed an in vitro infection system for ADV by using primary cultures of mink macrophages or macrophage cell lines. In peritoneal macrophage cultures from adult mink, virulent ADV-Utah I strain showed nuclear expression of viral antigens with fluorescein isothiocyanate-labeled ADV-infected mink serum, but delineation of specific viral proteins could not be confirmed by immunoblot analysis. Amplification of ADV DNA and production of replicative-form DNA were observed in mink macrophages by Southern blot analysis; however, virus could not be serially propagated. The human macrophage cell line U937 exhibited clear nuclear expression of viral antigens after infection with ADV-Utah I but not with tissue culture-adapted ADV-G. In U937 cells, ADV-Utah I produced mRNA, replicative-form DNA, virion DNA, and structural and nonstructural proteins; however, virus could not be serially passaged nor could [3H]thymidine-labeled virions be observed by density gradient analysis. These findings indicated that ADV-Utah I infection in U937 cells was not fully permissive and that there is another restricted step between gene amplification and/or viral protein expression and production of infectious virions. Treatment with the macrophage activator phorbol 12-myristate 13-acetate after adsorption of virus reduced the frequency of ADV-positive U937 cells but clearly increased that of human macrophage line THP-1 cells. These results suggested that ADV replication may depend on conditions influenced by the differentiation state of macrophages. U937 cells may be useful as an in vitro model system for the analysis of the immune disorder caused by ADV infection of macrophages.     

Dog chromosome-specific paints reveal evolutionary inter- and intrachromosomal rearrangements in the American mink and human

Forty chromosome-specific paint probes of the domestic dog (Canis familiaris, 2n = 78) were used to delineate conserved segments on metaphase chromosomes of the American mink (Mustela vison, 2n = 30) by fluorescence in situ hybridisation. Half of the 38 canine autosomal probes each painted one pair of homologous segments in a diploid mink metaphase, whereas the other 19 dog probes each painted from two to five pairs of discrete segments. In total, 38 canine autosomal paints highlighted 71 pairs of conserved segments in the mink. These painting results allow us to establish a complete comparative chromosome map between the American mink and domestic dog. This map demonstrates that extensive chromosome rearrangements differentiate the karyotypes of the dog and American mink. The 38 dog autosomes could be reconstructed from the 14 autosomes of the American mink through at least 47 fissions, 25 chromosome fusions, and six inversions. Furthermore, comparison of the current dog/mink map with the published human/dog map discloses 23 cryptic intrachromosomal rearrangements in 10 regions of conserved synteny in the human and American mink genomes and thus further refined the human/mink comparative genome map.     

Chromosome localization of the loci GOT1, PP,NP, SOD1, PEPA and PEPC in the American mink (Mustela vison)

Summary Twenty eight American mink × Chinese hamster somatic cell hybrids were analysed for the expression of mink enzymes and chromosome segregation. This analysis made it possible to assign the genes for glutamate-oxaloacetate transaminase-1 (soluble) (EC 2.6.1.1), inorganic pyrophosphatase (EC 3.6.1.1), purine nucleoside phosphorylase (EC 2.4.2.1) to mink chromosome 2, superoxide dismutase-1 (soluble) (EC 1.11.1.1) to chromosome 5, peptidase A (EC 3.4.11 or 3.4.13) to chromosome 4, and peptidase C (EC 3.4.11 or 3.4.13) to chromosome 13. It is suggested that the synthenic gene group GOT1-PP-NP is located on the short arm of mink chromosome 2.     

High prevalence of Aleutian mink disease virus in free-ranging mink on a remote Danish island

Aleutian mink disease virus (AMDV) causes severe disease in farmed mink (Neovison vison) worldwide. In Denmark, AMDV in farmed mink has been confined to the northern part of the mainland since 2002. From 1998 to 2009, samples from 396 free-ranging mink were collected from mainland Denmark, and a low AMDV antibody prevalence (3% of 296) was found using countercurrent immune electrophoresis. However, on the island of Bornholm in the Baltic Sea, a high prevalence (45% of 142 mink) was detected in the free-ranging mink. Aleutian mink disease virus was detected by polymerase chain reaction in 32 of 49 antibody-positive free-ranging mink on Bornholm, but not in mink collected from other parts of Denmark. Sequence analysis of 370 base pairs of the nonstructural gene of the AMDV of 17 samples revealed two clusters with closest similarity to Swedish AMDV strains.     

The human fumarylacetoacetase gene: characterisation of restriction fragment length polymorphisms and identification of haplotypes in tyrosinemia type 1 and pseudodeficiency

Summary Deficiency of human fumarylacetoacetase (FAH) activity results in hereditary tyrosinemia type I. Using the restriction enzymes BglII, KpnI and StuI and a 1.3-kb cDNA probe for the FAH gene, we have found 6 restriction fragment length polymorphisms (RFLPs). These RFLPs were utilised in 3 tyrosinemia families in which one or both parents are carriers of both a tyrosinemia and a pseudodeficiency gene for FAH. Full information was obtained in two of these families. The polymorphisms identified 6 haplotypes. The haplotype distribution was significantly different in 32 unrelated tyrosinemia patients compared with a reference population of 100 individuals. The combined polymorphism information content was 0.77.