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.     

Structure of the murine anion exchange protein

A full-length clone encoding the mouse erythrocyte anion exchange protein, band 3, has been isolated from a cDNA library using an antibody against the mature erythrocyte protein. The complete nucleotide sequence has been determined. Substantial homology is evident between the deduced murine amino acid sequence and published sequences of fragments of human band 3 protein. The amino-terminal 420 and the carboxy-terminal 32 residues constitute polar, soluble domains, while the intervening 475 amino acids are likely to be intimately associated with the lipid bilayer. Hydrophobic analysis of this sequence, together with structural studies on the human protein, suggests the possibility of at least 12 membrane spans, predicting that both the amino- and carboxy-termini are intracellular.     

Isolation of Tyrosinase From Bovine Eyes

Pigmented tissues from bovine eye were used as a source for isolation of tyrosinase from normal melanocytes. Tyrosinase is highly hydrophobic and the isolation procedure is mainly based on the use of hydrophobic interaction chromatography. The bovine enzyme is, in contrast to the human melanoma tyrosinase, mainly soluble. The predominant part of the ocular enzyme from cow has a molecular weight and isoelectric behavior similar to that of the soluble tyrosinase in the human melanoma cells. The N-terminal amino acid sequence of isolated bovine tyrosinase was determined by automated Edman degradation. The N-terminal amino acid sequence from normal bovine tyrosinase was identical to the sequence of an N-terminal region of mouse melanoma tyrosinase predicted from a c-DNA clone by Kwon et al. (1988). The amino acid sequence of bovine tyrosinase shows homology to that of human tyrosinase (Wittbjer et al., 1989), but three amino acids of the 16 residues determined by us differed. Histidine was the N-terminal amino acid.     

Primary structure of tyrosinase from Neurospora crassa. II. Complete amino acid sequence and chemical structure of a tripeptide containing an unusual thioether

To align the four cyanogen bromide peptides of Neurospora tyrosinase whose amino acid sequences were reported in the preceding paper, suitable methionine-containing overlap peptides were isolated. The required peptides were obtained by tryptic, peptic, and thermolytic digestion of the unmodified protein and of the maleylated derivative. From the partial sequence information of these peptides and a cyanogen bromide overlap peptide, the four cyanogen bromide fragments were aligned in the order CB3-CB1-CB4-CB2. These data establish Neurospora tyrosinase as a single-chain protein of 407 amino acids with a molecular weight of 46,000. The single cysteinyl residue 94 was found to be covalently linked via a thioether bridge to histidyl residue 96. The chemical nature of this unusual structure was elucidated by physicochemical analysis of peptides obtained from in vivo 35S, [2,5-3H]histidine, and [5-3H]histidine-labeled Neurospora tyrosinase.     

Molecular cloning and sequence analysis of human dipeptidyl peptidase IV, a serine proteinase on the cell surface.

The cDNA coding for the human dipeptidyl peptidase IV (DPPIV) has been isolated and sequenced. The nucleotide sequence (3465 bp) of the cDNA contains an open reading frame encoding a polypeptide comprising 766 amino acids, one residue less than those of rat DPPIV. The predicted amino acid sequence exhibits 84.9% identity to that of the rat enzyme, and contains nine potential N-linked glycosylation sites, one site more than those in the rat enzyme. A putative catalytic triad for serine proteinases, serine, aspartic acid and histidine, are found in a completely conserved COOH-terminal region (positions 625-752).     

Pyridoxal 5'-phosphate-dependent histidine decarboxylase. Nucleotide sequence of the hdc gene and the corresponding amino acid sequence

The nucleotide sequence of a 1.3-kilobase NaeI fragment from Morganella morganii AM-15 that contains the gene for histidine decarboxylase has been determined. The gene was initially identified among total chromosomal digests using a mixed sequence oligonucleotide probe corresponding to amino acids 11-16 of histidine decarboxylase and then cloned on a 5.5-kilobase PstI fragment. The structural gene contains 1131 nucleotides and encodes 377 amino acids with the sequence: (sequence: in text). The independently determined NH2-terminal sequence of this enzyme (Tanase, S., Guirard, B. M., and Snell, E. E. (1985) J. Biol. Chem. 260, 6738-6746) and the amino acid sequences of two tryptic peptides reported in the accompanying paper (Hayashi, H., Tanase, S., and Snell, E. E. (1986) J. Biol. Chem. 261, 11003-11009) are localized in the sequence presented here; the lysine that binds pyridoxal phosphate is situated at residue 232, whereas the serine that binds the adduct formed between pyridoxal phosphate and the inhibitor alpha-fluoromethylhistidine is positioned at residue 322.     

The Molecular Basis of Brown, an Old Mouse Mutation, and of an Induced Revertant to Wild Type

The murine b locus encodes the tyrosinase related protein, TRP-1, a putative membrane-bound, copper-containing enzyme having about 40% amino acid identity with tyrosinase. The protein is essential for production of black rather than brown hair pigment. We show that skin of mutant brown mice contains the same amount of TRP-1 mRNA as wild type. On sequencing the coding region of the mutant mRNA we find four nucleotide differences from the wild-type (Black) sequence. Two of these differences result in different amino acid residues encoded by the brown allele. By sequencing the TRP-1 gene from a mouse in which a reversion from brown to Black has been induced by ethylnitrosourea we are able to show that only one of these amino acid changes, which substitutes a tyrosine for a conserved cysteine, is the cause of the brown phenotype. This mutation is adjacent to another cysteine at which, in the analogous position in tyrosinase a mutation results in the albino phenotype. The sequence of the revertant is the first report of DNA sequence of an ethylnitrosourea-induced genetic change in mouse.     

Human apolipoprotein E mRNA. cDNA cloning and nucleotide sequencing of a new variant

The complete nucleotide sequences of three cloned cDNAs corresponding to human liver apolipoprotein E (apo-E) mRNA were determined. Analysis of the longest cDNA showed that it contained 1157 nucleotides of mRNA sequence with a 5'-terminal nontranslated region of 61 nucleotides, a signal peptide region corresponding to 18 amino acids, a mature protein region corresponding to 299 amino acids, and a 3'-terminal nontranslated region of 142 nucleotides. The inferred amino acid sequences from two cDNAs were identical and corresponded to the amino acid sequence for plasma apo-E3 that has been reported previously ( Rall , S. C., Jr., Weisgraber , K. H., and Mahley , R. W. (1982) J. Biol. Chem. 257, 4171-4178). The third cDNA differed from the other two cDNAs in five nucleotide positions. Three of these differences occurred in the third nucleotide position of amino acid codons, resulting in no change in the corresponding amino acids at residues Val-85, Ser-223, and Gln-248. The other two altered nucleotides occurred in the first nucleotide position of codons, leading to changes in the amino acids encoded. In the variant sequence, a threonine replaced the normal alanine at residue 99 and a proline replaced the normal alanine at residue 152. We have concluded that the human liver donor was heterozygous for the epsilon 3 genotype. The variant cDNA corresponds to a new, previously undescribed variant form of apo-E in which the amino acid substitutions of the protein are electrophoretically silent; it would probably be undetectable by standard apo-E phenotyping methods. The amino acid substitution at position 152 occurs in a region of apo-E that appears to be important for receptor binding, and it may have clinical significance.     

The nucleotide sequence and derived amino acid sequence of cDNA coding for mouse carbonic anhydrase II

The nucleotide sequence of a clone containing mouse carbonic anhydrase (CA) cDNA in pBR322 has been determined. The cloned cDNA contains all of the coding region except for nucleotides specifying the first eight amino acids, and all of the 3' noncoding region, which consists of 700 nucleotides. A cDNA clone was identified which contains an additional 54 bp at the 5' end, so that the complete amino acid sequence of mouse CA could be deduced. This sequence showed a 73-81% homology with other mammalian CA form II isozymes, 56-63% with form I isozymes, and 52-56% with form III isozymes. By examination of the amino acids which are unique and invariant for each isozyme, the mouse amino acid sequence was found to contain 16 of the 23 residues that are unique and invariant to mammalian CA form II isozymes, but only one or no residue for forms I and III, respectively.     

Effects of amino acid substitutions at glycine 420 on SR-BI cholesterol transport function

Scavenger receptor class B type I (SR-BI) facilitates the uptake of HDL cholesteryl esters (CEs) in a two-step process involving binding of HDL to its extracellular domain and transfer of HDL core CEs to a metabolically active membrane pool, where they are subsequently hydrolyzed by a neutral CE hydrolase. Recently, we characterized a mutant, G420H, which replaced glycine 420 in the extracellular domain of SR-BI with a histidine residue and had a profound effect on SR-BI function. The G420H mutant receptor exhibited a reduced ability to mediate selective HDL CE uptake and was unable to deliver HDL CE for hydrolysis, despite the fact that it retained the ability to bind HDL. This did not hold true if glycine 420 was replaced with an alanine residue; G420A maintained wild-type HDL binding and cholesterol transport activity. To further understand the role that glycine 420 plays in SR-BI function and why there was a disparity between replacing glycine 420 with a histidine versus an alanine, we generated a battery of point mutants by substituting glycine 420 with amino acids possessing side chains that were charged, hydrophobic, polar, or bulky and tested the resulting mutants for their ability to support HDL binding, HDL cholesterol transport, and delivery for hydrolysis. The results indicated that substitution with a negatively charged residue or a proline impaired cell surface expression of SR-BI or its interaction with HDL, respectively. Furthermore, substitution of glycine 420 with a positively charged residue reduced HDL CE uptake as well as its subsequent hydrolysis.     

Cloning and expression of cDNA encoding mouse tyrosinase.

We have isolated a pigment cell-specific cDNA clone from a B16 mouse melanoma cDNA library by differential hybridization. The mRNA of isolated cDNA is highly expressed in B16 melanoma cells and in black mouse (C57BL/6) skin, but is not detectable in mouse neuroblastoma cells nor in K1735 mouse amelanotic melanoma cells. The protein sequence deduced from the nucleotide sequence of the cloned cDNA shows significant similarity to the entire region of Neurospora tyrosinase. To know the identity of cDNA, we transfected K1735 amelanotic melanoma and COS-7 cells with the cDNA carried in a simian virus 40 vector (pKCRH2). We confirmed that the isolated cDNA encodes mouse tyrosinase by immunofluorescence staining of transfected cells using two different anti-T4-tyrosinase monoclonal antibodies. Tyrosinase is composed of 513 amino acids with a molecular weight of 57,872 excluding a hydrophobic signal peptide of 24 amino acids.     

Phylogeny of Regulatory Regions of Vertebrate Tyrosinase Genes

Highly homologous DNA elements were found to be shared by the upstream regions of the mouse tyrosinase and tyrosinase related protein (TRP-1) genes. Several nuclear proteins were shown to bind to both of these upstream regions. Shared homologous DNA elements were also found in the 5’ flanking sequences of Japanese quail and snapping turtle tyrosinase genes. Shared homologous nucleotide sequences were found to be scattered like an archipelago in the 5’ upstream regions of mouse and human tyrosinase genes. Comparisons between Japanese quail and snapping turtle tyrosinase genes gave similar results. On the contrary, mammalian (mouse and human) and nonmammalian (quail and snapping turtle) tyrosinase genes did not show significant homology in their 5’ upstream regions. In contrast, coding sequences in the first exons of vertebrate tyrosinase genes and their deduced amino acid sequences were found to be highly conserved except for their putative leader sequence-coding regions.     

Mitochondrial DNA of two independent oligomycin-resistant Chinese hamster ovary cell lines contains a single nucleotide change in the ATPase 6 gene

We have determined the nucleotide sequence of the URF A6L and ATPase 6 genes of the mitochondrial DNA of wild-type Chinese hamster ovary (CHO) cells and of two independently isolated, cytoplasmically inherited CHO mutant cell lines that are resistant to oligomycin, an inhibitor of the mitochondrial ATP synthase (ATPase) complex. Comparison of the nucleotide sequences of the mutants with that of their parental cell line revealed a single nucleotide difference, a G-to-A transition at nucleotide 433 of the ATPase 6 gene. This single base pair change predicts a nonconservative amino acid change, with a glutamic acid residue being replaced by a lysine residue at amino acid 145 of the ATPase 6 gene product in the mutants. This glutamic acid residue and several others in the surrounding amino acid sequence are conserved among all species examined to date. Analyses of several of the biochemical properties of the oligomycin-resistant CHO mutants indicate that the glutamic acid residue at position 145 of subunit 6 of the mitochondrial ATP synthase complex is important for the binding of oligomycin to the enzyme complex, but is not essential for proton translocation.     

Nucleotide sequence of the gene ompA coding the outer membrane protein II of Escherichia coli K-12.

A nucleotide sequence of 2271 basepairs has been determined from cloned E. coli DNA which contains ompA. Withing that sequence, starting at nucleotide 1037, an open translational reading frame encodes a protein of 367 amino acids which starting with amino acid 22 agrees with the primary structure of protein II. The preceeding 21 amino acids constitute a typical signal sequence. There is a non-translated region of 360 nucleotides in front of the translational start. The insertion point of an IS1 element 110 nucleotides upstream from the start codon and an amber codon at the position of amino acid residue 28 have been localized in the DNA from two ompA mutants.     

Isolation and characterization of variant cDNAs encoding mouse tyrosinase

Two different cDNA clones encoding mouse tyrosinase (monophenol oxygenase, E.C. 1.14.18.1) were isolated from B16 melanoma cells, and their primary structure was determined. One of the cDNAs consists of 3309 nucleotides with an open reading frame coding for a peptide of 533 amino acids. The other cDNA is approximately 1600 nucleotides long, with a shorter 3'-untranslated region and a deduced in-frame deletion of 77 amino acid residues with respect to the former clone. Neither of these clones is structurally identical to other described mouse tyrosinase cDNAs (1-3). RNA blotting analysis demonstrates that multiple tyrosinase mRNA species are not only present in B16 melanoma, but also in normal skin melanocytes.     

N-terminal amino acid sequence of human urinary prokallikrein

The N-terminal amino acid sequences of human urinary prokallikrein and kallikrein have been determined. Their amino acid sequences are as follows. (Formula; see text) The results showed that prokallikrein comprises an additional seven amino acids at the amino terminus of the kallikrein, of which the sequence is (H2N)Ala-Pro-Pro-Ile-Gln-Ser-Arg(COOH). Comparison of the structure of this peptide with those of other proteins revealed extensive sequence identity with the propeptide portions of rat and mouse tissue kallikreins, that were predicted from the preproenzyme-encoded nucleotide sequences. The amino acid sequence of the peptide was also highly homologous to that of the propeptide portion of EGF-binding protein, that was predicted from the nucleotide sequence, and that of the alpha-subunit of NGF. The N-terminal amino acid sequence of kallikrein was completely identical to the reported one (Lottspeich, F., et al. (1979) Hoppe-Seyler's Z. Physiol. Chem. 360, 1947-1950) and shows considerable amino acid sequence homology with the porcine and rat pancreatic kallikreins. As far as the present results are concerned, it is strongly indicated that the inactive kallikrein in human urine is a tissue type prokallikrein which is activated on the release of the N-terminal peptide consisting of seven amino acids.     

Hydrogen bonding of iron-coordinated histidine in heme proteins.

The hydrogen-bonding motifs of the proton on the N delta atom of iron-coordinated histidine residues in heme proteins have been classified into three categories: (1) Those in which the hydrogen-bond acceptor is either an amino acid residue (serine) directly adjacent to the histidine or a carbonyl group of the polypeptide chain less than five residues away from the histidine; (2) those in which the hydrogen-bonding acceptor is a carbonyl group of the polypeptide backbone associated with an amino acid residue 8 to 17 residues away from the histidine; and (3) those in which the hydrogen-bonding acceptor is an exogenous water molecule or an amino acid residue located far from the histidine in the amino acid sequence. Some biological functions are defined by this classification, whereas others span all classes.