Gene Structure, Chromosomal Location, and Expression Pattern of Maleylacetoacetate Isomerase

The gene for maleylacetoacetate isomerase (MAAI) (EC 5.2.1.2) was the last gene in the mammalian phenylalanine/tyrosine catabolic pathway to be cloned. We have isolated the human and murine genes and determined their genomic structure. The human gene spans a genomic region of approximately 10 kb, has 9 exons ranging from 50 to 528 bp in size, and was mapped to 14q24.3-14q31.1 using fluorescence in situ hybridization. The complete catabolic pathway of phenylalanine/tyrosine is normally restricted to liver and kidney, but the maleylacetoacetate isomerase gene is expressed ubiquitously. This suggests a possible second role for the MAAI protein different from phenylalanine/tyrosine catabolism. We have searched for mutations in the maleylacetoacetate isomerase gene in four cases of unexplained severe liver failure in infancy with clinical similarities to hereditary tyrosinemia type I (pseudotyrosinemia). Several amino acid changes were identified, but all were found to retain MAAI activity and thus represent protein polymorphisms. We conclude that MAAI deficiency is not a common cause of the pseudotyrosinemic phenotype.     

Cloning, Tissue Expression Pattern, and Chromosome Location of a Novel Human Gene BRI3BP

A novel cDNA fragment was identified from a human fetal brain cDNA library by using the coding sequence of human BRI3 gene (Accession No. NM015379) as bait in a yeast two-hybrid screening. Then by 5'-RACE (rapid amplification of cDNA end) and electronic hybridization, we obtained a 1.9 kb contig which consists of a novel gene. It was designated as BRI3BP by the HUGO Nomenclature Committee. It contains an open reading frame encoding 251 amino acids. The calculated molecular weight of the deduced protein is 27.8 kU. The predicted isoelectric point is 9.48. Northern hybridization showed its mRNA was highly expressed in brain, kidney, and liver. By RH mapping, the BRI3BP gene was mapped to human chromosome 12q24.2-qter     

Structure, Expression, Chromosomal Location and Product of the Gene Encoding Adh2 in Petunia

In most higher plants the genes encoding alcohol dehydrogenase comprise a small gene family, usually with two members. The Adh1 gene of Petunia has been cloned and analyzed, but a second identifiable gene was not recovered from any of three genomic libraries. We have therefore employed the polymerase chain reaction to obtain the major portion of a second Adh gene. From sequence, mapping and northern data we conclude this gene encodes ADH2, the major anaerobically inducible Adh gene of Petunia. The availability of both Adh1 and Adh2 from Petunia has permitted us to compare their structures and patterns of expression to those of the well-studied Adh genes of maize, of which one is highly expressed developmentally, while both are induced in response to hypoxia. Despite their evolutionary distance, evidenced by deduced amino acid sequence as well as taxonomic classification, the pairs of genes are regulated in strikingly similar ways in maize and Petunia. Our findings suggest a significant biological basis for the regulatory strategy employed by these distant species for differential expression of multiple Adh genes.     

Genomic Structure and Chromosomal Localization of Mouse Cyclin G1 Gene

Mouse genomic DNA harboring the full coding sequence of cyclin G1 was cloned and analyzed. The locations of five coding exons and the intron–exon boundary sequences were found to be conserved between the mouse and the human genes. Two putative binding sites for thep53tumor suppressor gene product were found around the first exon: one was located in the 5′ regulatory region, and the other was in the first intron. The mouse cyclin G1 gene was mapped to bands A5 to B1 of chromosomes 11 (11A5–B1) by FISH using genomic DNA clone as a biotinylated probe. The location of mouse cyclin G1 is syntenic to that of its human homologue, which we previously mapped to 5q32–q34 of chromosome 5. An additional faint signal was detected on chromosome 4 (4B1–C2), probably indicating the presence of a cyclin G1-related gene or pseudogene in the mouse genome.     

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.     

The Human Hepatocyte Nuclear Factor 3/Fork Head Gene FKHL13: Genomic Structure and Pattern of Expression

We describe the isolation and characterization of the cDNA for FKHL13, the human homologue of the mouse hepatocyte nuclear factor 3/fork headhomologue 4 (HFH-4) gene, a member of the HNF-3/fork head(also called winged helix) gene family. Members of this gene family contain a conserved DNA binding region of approx. 110 amino acids and are thought to play an important role in cell-specific differentiation. Previous analysis of the mouse and rat HFH-4 cDNAs revealed a distinct pattern of expression for this gene, suggesting that the gene plays an important role in the differentiation of lung and oviduct/ampulla epithelial cells and testicular spermatids. Analysis of the human FKHL13 gene confirmed this pattern of expression. We also found expression in adult human brain cortex, which we were able to confirm for the mouse. The expression pattern of FKHL13/HFH-4, confined to cilia/flagella-producing cells, leads us to believe that the gene plays an important role in the regulation of axonemal structural proteins. We show that the human gene for FKHL13 lies on chromosome 17 (comparison with the chromosomal location of the mouse gene strongly suggests 17q22–q25) and that the gene, which is approx. 6 kb, contains a single intron disrupting thefork headDNA binding domain. Such a disruption of a functional unit provides strong evidence for the theory of intron insertion during gene evolution. The expression of the gene is probably controlled by the CpG island, which is located in the promoter region of the gene. We also demonstrate that the FKHL13 gene is highly conserved among a wide variety of species, including birds.     

小鼠Smad3基因的克隆及其在小鼠组织中的表达

采用PCR获得的Smad3cDNA片段作为探针筛选小鼠脑cDNA文库 .克隆了小鼠全长的Smad3基因 .对小鼠Smad3基因的全编码区进行了序列测定 .结果表明 ,小鼠SMAD3与人SMAD3氨基酸同源性高达 99% .与小鼠Smad2基因相比 ,碱基同源性高达 91 8% .Northern杂交显示 ,Smad3基因在小鼠胚胎发育和各成体器官中普遍表达 .原位杂交显示 ,Smad3基因表达在小鼠胚胎期E16 5d的软骨、骨髓和皮肤角质细胞中     

Cloning, Expression, and Chromosomal Assignment of the Human Mitochondrial Intermediate Peptidase Gene (MIPEP)

The mitochondrial intermediate peptidase ofSaccharomyces cerevisiae(YMIP) is a component of the yeast mitochondrial protein import machinery critically involved in the biogenesis of the oxidative phosphorylation (OXPHOS) system. This leader peptidase removes specific octapeptides from the amino terminus of nuclear-encoded OXPHOS subunits and components of the mitochondrial genetic apparatus. To address the biologic role of the human peptidase [MIPEP gene, HMIP polypeptide], we have initiated its molecular and functional characterization. A full-length cDNA was isolated by screening a human liver library using a rat MIP (RMIP) cDNA as a probe. The encoded protein contained a typical mitochondrial leader peptide and showed 92 and 54% homology to RMIP and YMIP, respectively. A survey of human mitochondrial protein precursors revealed that, similar to YMIP, HMIP is primarily involved in the maturation of OXPHOS-related proteins. Northern analysis showed that the MIPEP gene is differentially expressed in human tissues, with the highest levels of expression in the heart, skeletal muscle, and pancreas, three organ systems that are frequently affected in OXPHOS disorders. Using fluorescencein situhybridization, the MIPEP locus was assigned to 13q12. This information offers the possibility of testing the potential involvement of HMIP in the pathophysiology of nuclear-driven OXPHOS disorders.     

玉米扩展蛋白Expansin基因家族定位及基因表达模式分析

扩展蛋白（Expansin）是一类能够使植物细胞壁松弛的活性蛋白,在植物生长发育过程中起着重要作用。利用PLAZA、NCBI、MaizeGDB、Uniprot、PLEXdb等基因组数据库,获得玉米Expansin家族的基因序列、染色体基因座位、蛋白质序列以及长度,构建玉米Expansin基因家族系统进化树,进行基因组织表达谱的分析。结果表明,玉米基因组中含有93个Expansin基因,分布于玉米的9条染色体上;多数Expansin具有250~300个氨基酸;玉米Expansin基因家族有40个Expansin A（EXPA）、47个Expansin B（EXPB）、6个Expansin-like A（EXLA）,未发现Expansin-like B（EXLB）;44个玉米Expansin基因在不同玉米组织中特异表达。该研究结果不仅为玉米扩展蛋白的深入研究奠定了基础,而且为其他研究人员对基因信息的获取提供了参考。     

Molecular Cloning, Expression Pattern, and Chromosomal Localization of the Human Na–Cl Thiazide-Sensitive Cotransporter (SLC12A3)

Electrolyte homeostasis is maintained by several ion transport systems. Na–(K)–Cl cotransporters promote the electrically silent movement of chloride across the membrane in absorptive and secretory epithelia. Two kidney-specific Na–(K)–Cl cotransporter isoforms are known, so far, according to their sensitivity to specific inhibitors. We have cloned the human cDNA coding for the renal Na–Cl cotransporter selectively inhibited by the thiazide class of diuretic agents. The predicted protein sequence of 1021 amino acids (112 kDa) shows a structure common to the other members of the Na–(K)–Cl cotransporter family: a central region harboring 12 transmembrane domains and the 2 intracellular hydrophilic amino and carboxyl termini. The ex- pression pattern of the human Na–Cl thiazide-sensitive cotransporter (hTSC, HGMW-approved symbol SLC12A3) confirms the kidney specificity. hTSC has been mapped to human chromosome 16q13 by fluorescencein situhybridization. The cloning and characterization of hTSC now render it possible to study the involvement of this cotransport system in the pathogenesis of tubulopathies such as Gitelman syndrome.