Human indolethylamine N-methyltransferase: cDNA cloning and expression, gene cloning, and chromosomal localization.

Indolethylamine N-methyltransferase (INMT) catalyzes the N-methylation of tryptamine and structurally related compounds. We recently cloned and characterized the rabbit INMT cDNA and gene as a step toward cloning the cDNA and gene for this enzyme in humans. We have now used a PCR-based approach to clone a human INMT cDNA that had a 792-bp open reading frame that encoded a 263-amino-acid protein 88% identical in sequence to rabbit INMT. Northern blot analysis of 35 tissues showed that a 2.7-kb INMT mRNA species was expressed in most tissues. When the cDNA was expressed in COS-1 cells, the recombinant enzyme catalyzed the methylation of tryptamine with an apparent K(m) value of 2.9 mM. The human cDNA was then used to clone the human INMT gene from a human genomic BAC library. The gene was 5471 bp in length, consisted of three exons, and was structurally similar to the rabbit INMT gene as well as genes for nicotinamide N-methyltransferase and phenylethanolamine N-methyltransferase in several species. All INMT exon-intron splice junctions conformed to the "GT-AG" rule, and no canonical TATA or CAAT sequences were present within the 5'-flanking region of the gene. Human INMT mapped to chromosome 7p15.2-p15.3 on the basis of both PCR analysis and fluorescence in situ hybridization. Finally, two possible single nucleotide polymorphisms were identified within exon 3, both of which altered the encoded amino acid. The cloning and expression of a human INMT cDNA, as well as the cloning, structural characterization, and mapping of its gene represent steps toward future studies of the function and regulation of this methyltransferase enzyme in humans.     

Human sphingosine-1-phosphate lyase: cDNA cloning, functional expression studies and mapping to chromosome 10q22(1)

Sphingosine-1-phosphate lyase catalyzes the last step in sphingolipid breakdown, the cleavage of phosphorylated sphingoid bases such as sphingenine-1-phosphate. The latter lipid is not only a catabolite, but can influence as an inter- and/or intracellular second messenger many cellular processes. To allow for the diagnosis of human disorders that might be linked to a deficient lyase, the human sphingosine-1-phosphate lyase cDNA was cloned. The obtained cDNA encoded a protein of 568 amino acids with a calculated molecular mass of 63492 Da. Hydropathy plots revealed the presence of one membrane span near the amino-terminal which is however not required for enzyme activity since recombinant poly-His-tagged lyase, lacking this membrane span, was functionally active. Site-directed mutagenesis disclosed the importance of the cysteine residues 218 and 317 for the cleavage reaction. Northern analysis showed the presence of rare large-sized mRNAs of 6.7, 5.8 and 4 kb and the highest expression in liver. By fluorescent in situ hybridization, the gene was mapped to chromosome 10q22.     

cDNA cloning, characterization and chromosome mapping of the gene encoding human cartilage associated protein (CRTAP)

We have recently isolated and characterized cDNA clones coding for a novel developmentally regulated avian and mouse embryo protein, CASP for Cartilage Associated Protein. Here we describe the isolation and characterization of the gene coding for the human CASP. The comparison of the putative human and mouse protein sequences with the chick sequence revealed an overall high identity (89% and 51%, respectively). Homology search with known DNA and protein sequences showed that CASPs are related to two mammalian nuclear proteins. Here we demonstrate definitively that CASPs are distinct from these nuclear proteins. However, sequence comparison analyses suggest that all of these proteins belong to a new family. In all human tissues examined two CASP mRNA species were detected, whereas a single mRNA and three mRNAs were found in chick and mouse, respectively. The human CASP gene (CRTAP) was assigned to chromosome 3p22 by fluorescence in situ hybridization.     

cDNA cloning, characterization and chromosome mapping of Crtap encoding the mouse cartilage associated protein.

Recently we have isolated and characterized a cDNA coding for a novel developmentally regulated chick embryo protein, cartilage associated protein (CASP). Here we describe the isolation and characterization of the cDNAs coding for the mouse CASP. Comparison of the mammalian putative protein sequence with the chick sequence shows a very high identity overall (51%); in particular the chick protein is homologous to the half amino terminus of the mouse protein. Furthermore, the comparison of the CASP cDNA sequence with sequences of the genebank database confirms our hypothesis that the CASP genes belong to a novel family that also includes genes encoding for some nuclear antigens. In all mouse tissues examined three CASP mRNAs species are detected, whereas in chick tissues a single mRNA is present. Immunohistochemistry studies show that the protein is expressed in all mouse embryonic cartilages. The mouse cartilage associated protein gene (Crtap) was assigned to chromosome 9F3-F4 by fluorescence in situ hybridization.     

Human geranylgeranyl diphosphate synthase. cDNA cloning and expression

Geranylgeranyl diphosphate (GGPP) synthase (GGPPSase) catalyzes the synthesis of GGPP, which is an important molecule responsible for the C20-prenylated protein biosynthesis and for the regulation of a nuclear hormone receptor (LXR.RXR). The human GGPPSase cDNA encodes a protein of 300 amino acids which shows 16% sequence identity with the known human farnesyl diphosphate (FPP) synthase (FPPSase). The GGPPSase expressed in Escherichia coli catalyzes the GGPP formation (240 nmol/min/mg) from FPP and isopentenyl diphosphate. The human GGPPSase behaves as an oligomeric molecule with 280 kDa on a gel filtration column and cross-reacts with an antibody directed against bovine brain GGPPSase, which differs immunochemically from bovine brain FPPSase. Northern blot analysis indicates the presence of two forms of the mRNA.     

Human prostatic acid phosphatase: cDNA cloning, gene mapping and protein sequence homology with lysosomal acid phosphatase

The cDNAs encoding human prostatic acid phosphatase were cloned and characterized. The mRNAs contain 3' noncoding regions of heterogeneous sizes 646, 1887 or 1913 nucleotides. A dimer and a monomer of the conserved Alu-repeats are present in the longer 3' noncoding sequences. The complete sequence of 354 amino acids for the mature enzyme was determined by sequencing both cDNA and protein. Human prostatic and lysosomal acid phosphatases exhibit 50% sequence homology, including five Cys residues and two putative N-linked glycosylation sites. The Acp-3 gene coding for human prostatic acid phosphatase was mapped onto chromosome 3 in this investigation. The Acp-2 gene coding for lysosomal acid phosphatase has previously been located on chromosome 11, while the Acp-1 gene coding for red blood cell acid phosphatase is on chromosome 2.     

Human mitochondrial thioredoxin reductase cDNA cloning, expression and genomic organization.

We have isolated a 1918-bp cDNA from a human adrenal cDNA library which encodes a novel thioredoxin reductase (TrxR2) of 521 amino acid residues with a calculated molecular mass of 56.2 kDa. It is highly homologous to the previously described cytosolic enzyme (TrxR1), including the conserved active site CVNVGC and the FAD-binding and NADPH-binding domains. However, human TrxR2 differs from human TrxR1 by the presence of a 33-amino acid extension at the N-terminus which has properties characteristic of a mitochondrial translocation signal. Northern-blot analysis identified one mRNA species of 2.2 kb with highest expression in prostate, testis and liver. We expressed human TrxR2 as a fusion protein with green fluorescent protein and showed that in vivo it is localized in mitochondria. Removal of the mitochondrial targeting sequence abolishes the mitochondrial translocation. Finally, we determined the genomic organization of the human TrxR2 gene, which consists of 18 exons spanning about 67 kb, and its chromosomal localization at position 22q11.2.     

Barley embryo globulin 1 gene,Beg1: Characterization of cDNA,chromosome mapping and regulation of expression

We report identification of a 2189 by cDNA clone from barley corresponding to a single-copy gene, Beg1 (Barley embryo globulin), on chromosome 4, which encodes a storage globulin. In barley, the major protein reserve in the aleurone layer belongs to the 7S globulin class of proteins found in many seeds. Electrophoretically and antigenically similar proteins are present in the barley embryo. Accumulation of Beg1 mRNA was noted beginning 15–20 days post-anthesis in both the aleurone layer and embryo of the developing barley grain but not in the starchy endosperm. A high level of Beg1 mRNA is also present in the mature imbibed aleurones, which can be repressed by treatment with gibberellic acid. This repressive effect of gibberellin on the levels of Beg1 mRNA is confirmed in the gibberellin response-constitutive mutant, slender, whose aleurone layers do not accumulate Beg1 mRNA even in the absence of applied gibberellic acid. The deduced primary translation product of the Beg1 mRNA is a 637 amino acid (72 kDa) protein with homology to maize embryo globulin 1 (GLB1) and a partial sequence of a wheat 7S globulin. The internal amino acid sequence of BEG1 closely matches the N-terminal sequence of isolated barley aleurone globulin. Seven imperfect tandem repeats of 16 amino acids each are present near the N-terminus of BEG1, which conform to the consensus HGEGEREEEXGRGRGR, and contribute to the observed unusual amino acid composition of this protein. A second, distinct barley globulin gene, Beg2, which is homologous to maize Glb2, was detected by Northern and Southern analysis. Beg-2 and Beg1 are regulated differently which may indicate variation in storage or utilization properties among the barley globulins.     

Human repeat element-mediated PCR: cloning and mapping of chromosome 10 DNA markers.

Repeat element-mediated PCR can facilitate rapid cloning and mapping of human chromosomal region-specific DNA markers from somatic cell hybrid DNA. PCR primers directed to human repeat elements result in human-specific DNA synthesis; template DNA derived from a somatic cell hybrid containing the human chromosomal region of interest provides region specificity. We have generated a series of repeat element-mediated PCR clones from a reduced complexity somatic cell hybrid containing a portion of human chromosome 10. The cloning source retains the centromere and tightly linked flanking markers, plus additional chromosome 10 sequences. Twelve new inter-Alu, two inter-L1, and four inter-Alu/L1 repeat element-mediated PCR clones were mapped by hybridization to Southern blots of repeat element-mediated PCR products amplified from somatic cell hybrid DNA templates. Two inter-Alu clones mapped to the pericentromeric region. We propose that a scarcity of Alu elements in the pericentromeric region of chromosome 10 contributed to the low number of clones obtained from this region. One inter-Alu clone, pC11/A1S-6-c23, defines the D10S94 locus, which is tightly linked to MEN2A and D10Z1.