The murine Fhit locus: isolation, characterization, and expression in normal and tumor cells

The murine Fhit locus maps near the centromere nu proximal Ptprg locus on mouse chromosome 14. The cDNA sequence and structure are similar to those of the human gene, with exons 5-9 encoding the protein. The predominant mRNA in the tissues and cell lines tested was an alternatively spliced form missing exon 3. Most murine cell lines tested, including lines established from normal mouse embryos and tumors, expressed very low or undetectable levels of Fhit mRNA. Most normal mouse tissues expressed wild-type Fhit mRNA, whereas approximately 40% of murine lung carcinomas expressed wild-type and aberrant Fhit RT-PCR products that lacked various exons. Several tumorigenic mouse cell lines exhibited homozygous deletions of Fhit exons. We conclude that the murine Fhit gene, like its human counterpart, is a target of alterations involved in murine carcinogenesis.     

Characterization of the mouse Myoc/Tigr gene

Mutations in the myocilin (MYOC), also known as Trabecular meshwork-Inducible Glucocorticoid Response (TIGR) gene can lead to juvenile open-angle glaucoma in human and may be responsible for at least 3% of primary open-angle glaucoma. To develop a mouse model of primary open angle glaucoma, and to get deeper insight into the mechanisms of the MYOC/TIGR gene regulation and function, we have isolated and characterized full size mouse Myoc/Tigr cDNA and genomic clones. The mouse and human MYOC/TIGR genes have the same exon-intron structure and contain 3 exons, although the mouse gene is 6 kb shorter than the human gene (10 kb versus 16 kb) due to differences in the length of introns. The MYOC/TIGR gene encodes a moderately conserved protein, which is 82% identical between human and mouse. The encoded protein is 14 amino acids shorter at the N-terminus in the mouse than in the human (490 versus 504 amino acids). Mouse and human MYOC/TIGR genes show a similar pattern of expression in adult ocular and nonocular tissues. The mouse Myoc/Tigr gene was mapped to Chromosome 1 at position 82.8 cM from the centromere. All residues, which were identified in the human MYOC/TIGR protein as critical for glaucoma development, are conserved in the mouse Myoc/Tigr.     

Optimizing potentials for the inverse protein folding problem

Autosomal dominant polycystic kidney disease (ADPKD) is one of the most frequent genetically transmitted disorders among Europeans with an attributed frequency of 0.1%. The two most common genetic determinants for ADPKD are the PKD1 and PKD2 genes. In this study we report the genomic structure and pattern of expression of the Pkd2 gene, the murine homolog of the human PKD2 gene. Pkd2 is localized on mouse Chromosome (Chr) 5 proximal to anchor marker D5Mit175, spans at least 35 kb of the mouse genome, and consists of 15 exons. Its translation product consists of 966 amino acids, and the peptide shows a 95% homology to human polycystin2. Functional domains are particularly well conserved in the mouse homolog. The expression of mouse polycystin2 in the developing embryo at day 12.5 post conception is localized in mesenchymally derived structures. In the adult mouse, the protein is mostly expressed in kidney, which suggests its functional relevance for this organ.     

Sequence, genomic organization, and chromosomal location of the mouse Müllerian-inhibiting substance type II receptor gene

We have determined the sequence and structure of the mouse Müllerian-inhibiting substance (MIS) type II receptor gene. Sequence comparisons demonstrate that the mouse, rat, rabbit, and human MIS type II receptors are highly conserved. The mouse MIS type II receptor gene is encoded by 11 exons and spans approximately 9-kb. Only half of the intron/exon boundaries of its kinase domain are conserved in comparison to the kinase domain of the related activin type II receptor. Whereas the activin type II receptor gene contains large introns (> 40-kb), the largest intron of the MIS type II receptor gene is only 4.3-kb. The MIS type II receptor gene (Amhr) is closely linked to Hoxc on mouse chromosome 15. Knowledge of the sequence and genomic structure of Amhr provides important information for the genetic manipulation of the Amhr locus.     

The human HNRPD locus maps to 4q21 and encodes a highly conserved protein

The hnRNP D protein interacts with nucleic acids both in vivo and in vitro. Like many other proteins that interact with RNA, it contains RBD (or "RRM") domains and arg-gly-gly (RGG) motifs. We have examined the organization and localization of the human and murine genes that encode the hnRNP D protein. Comparison of the predicted sequences of the hnRNP D proteins in human and mouse shows that they are 96.9% identical (98.9% similar). This very high level of conservation suggests a critical function for hnRNP D. Sequence analysis of the human HNRPD gene shows that the protein is encoded by eight exons and that two additional exons specify sequences in the 3' UTR. Use of two of the coding exons is determined by alternative splicing of the HNRPD mRNA. The human HNRPD gene maps to 4q21. The mouse Hnrpd gene maps to the F region of chromosome 3, which is syntenic with the human 4q21 region.     

Genetic structure and chromosomal mapping of MyD88

The myeloid differentiation (MyD) marker MyD88 was initially characterized as a primary response gene, upregulated in mouse M1 myeloleukemic cells in response to differentiation induced by interleukin-6. Subsequent analysis revealed that MyD88 possesses a unique modular structure, which consists of an N-terminal "death domain," similar to the intracellular segments of TNF receptor 1 and Fas, and a C-terminal region related to the cytoplasmic domains of the Drosophila morphogen Toll and vertebrate interleukin-1 receptors. In this report we describe the cloning and gene structure of mouse MyD88. The complete coding sequence of mouse MyD88 spans five exons, with the first exon encoding the complete death domain. Zooblot analysis revealed that MyD88 is an evolutionarily conserved gene. MyD88 was localized to the distal region of mouse chromosome 9 by interspecific backcross mapping. The human homolog (hMyD88) was mapped to chromosome 3p22-p21.3 by PCR analysis of a human chromosome 3 somatic cell hybrid mapping panel. Northern blot analysis revealed widespread expression of MyD88 in many adult mouse tissues, and RT-PCR studies detected MyD88 mRNA in T and B cell lines and differentiating embryonic stem cells. The broad expression pattern demonstrates that mouse MyD88 expression is not restricted to cells of myeloid lineage as was originally believed.     

Endogenous thrombopoietin levels and effect of recombinant human thrombopoietin on megakaryocyte precursors in term and preterm babies

We have isolated genomic DNA containing the human tissue inhibitor of metalloproteinases-4 gene (TIMP4) and determined the structure of the exons comprising the gene. Like other members of the TIMP family, the TIMP-4 protein is encoded by five exons. These span 6 kb of genomic DNA, so that TIMP4 is similar in size to Timp1 but considerably smaller than TIMP2 and TIMP3. The exon-intron boundaries of TIMP4 are at locations very similar to those of the other TIMP genes, demonstrating the high degree of conservation of gene structure in this family. The human and mouse TIMP-4 genes map to comparable locations in the respective genomes, localizing to human chromosome 3p25 and mouse chromosome 6.     

Sequence, structure, and chromosomal mapping of the mouse Lgals6 gene, encoding galectin-6

In the accompanying paper (Gitt, M. A., Colnot, C., Poirier, F., and Barondes, S. H., and Leffler, H. (1998) J. Biol. Chem. 273, 2954-2960), we reported that mouse gastrointestinal tract specifically expresses two closely related galectins, galectins-4 and -6, each with two carbohydrate recognition domains in the same peptide. Here, we report the isolation, characterization, and chromosomal mapping of the complete mouse Lgals6 gene, which encodes galectin-6, and of a fragment of a distinct gene, Lgals4, which encodes galectin-4. The coding sequence of galectin-6 is specified by eight exons. The upstream region contains two putative promoters. Both Lgals6 and the closely related Lgals4 are clustered together about 3.2 centimorgans proximal to the apoE gene on mouse chromosome 7. The syntenic human region is 19q13.1-13.3.     

Structural organization of the mouse and human GALR1 galanin receptor genes (Galnr and GALNR) and chromosomal localization of the mouse gene

The neuropeptide galanin elicits a range of biological effects by interaction with specific G-protein-coupled receptors. Human and rat GALR1 galanin receptor cDNA clones have previously been isolated using expression cloning. We have used the human GALR1 cDNA in hybridization screening to isolate the gene encoding GALR1 in both human (GALNR) and mouse (Galnr). The gene spans approximately 15-20 kb in both species; its structural organization is conserved and is unique among G-protein-coupled receptors. The coding sequence is contained on three exons, with exon 1 encoding the N-terminal end of the receptor and the first five transmembrane domains. Exon 2 encodes the third intracellular loop, while exon 3 encodes the remainder of the receptor, from transmembrane domain 6 to the C-terminus of the receptor protein. The mouse and human GALR1 receptor proteins are 348 and 349 amino acids long, respectively, and display 93% identity at the amino acid level. The mouse Galnr gene has been localized to Chromosome 18E4, homoeologous with the previously reported localization of the human GALNR gene to 18q23 in the same syntenic group as the genes encoding nuclear factor of activated T-cells, cytoplasmic 1, and myelin basic protein.     

Genomic organization of IFI16, an interferon-inducible gene whose expression is associated with human myeloid cell differentiation: correlation of predicted protein domains with exon organization

The human IFI16 gene is a member of an interferon-inducible family of mouse and human genes closely linked on syntenic regions of chromosome 1. Expression of these genes is largely restricted to hemopoietic cells, and is associated with the differentiation of cells of the myeloid lineages. As a prelude to defining the mechanisms governing IFI16 expression, we have deduced its genomic organization using a combination of genomic cloning and polymerase chain reaction amplification of genomic DNA. IFI16 consists of ten exons and nine intervening introns spanning at least 28 kilobases (kb) of DNA. The reiterated domain structure of IFI16 protein is closely reflected in its intron/exon boundaries, and may represent the evolutionary fusion of several independent functional domains. Thus, exon 1 consists of 5' untranslated (UT) sequences and contains sequence motifs that may confer interferon-inducibility, and exon 2 encodes the lysine-rich amino-terminal ("K") region, which possesses DNA-binding activity. Exon 3 codes for a domain which is poorly conserved between family members, except for a strongly retained basic motif likely to provide localization. The first of two 200 amino acid repeat domains that are the hallmark of this family (domain A) is represented jointly on exons 4 and 5, which are reiterated as exons 8 and 9, respectively, to encode the second 200 amino acid domain (B). Two intervening serine-threonine-rich domains (C and C'), unique to IFI16, are each encoded by single exons of identical length (exons 5 and 6). These domains are predicted to encode semi-rigid "spacer" domains between the 200 amino acid repeats. The reiterated nature of exons 4 to 6 and the insertion of introns into a single reading frame strongly suggest that IFI16 and related genes arose by a series of exon duplications, some of which antedated speciation into mouse and humans. Several alternative mRNA cap sites downstream of a TATA consensus sequence were defined, using primer extension analysis of mRNA. Sequencing of approximately 1.7 kb of DNA upstream of this region revealed no recognizable consensus elements for induction by interferon-alpha (interferon-alpha/beta-stimulated response elements), but two motifs resembling interferon-gamma activation sites were located. IFNs alpha and gamma both induce IFI16 mRNA expression in myeloid cells. Interferon-alpha inducibility of IFI16 may be regulated by an interferon-alpha/beta-stimulated response consensus element in the 5' UT exon, as a similar motif is conserved in the corresponding position in the related myeloid cell nuclear differentiation antigen gene.(ABSTRACT TRUNCATED AT 400 WORDS)     

Structure, genomic localization and recombinant expression of the mouse 6-pyruvoyl-tetrahydropterin synthase gene

The 6-pyruvoyl-tetrahydropterin synthase (PTPS) is the second enzyme in the biosynthetic pathway from GTP to tetrahydrobiopterin (BH4). BH4 is an essential cofactor of NO synthases and aromatic amino acid hydroxylases, the latter being responsible for hepatic phenylalanine degradation and monoamine neurotransmitter biosynthesis. BH4 deficiency due to autosomal recessive mutations in the human gene for PTPS leads to a broad range of phenotypes ranging from mild hyperphenylalaninemia to high phenylalanine levels concomitant with neurotransmitter depletion. An animal model to study PTPS deficiency is thus desired to investigate the molecular basis of the disease and its variability. Here, we report on the isolation and recombinant expression of the mouse PTPS gene, Pts. It is located on chromosome 9C-D and contains six exons with an open reading frame of 144 codons. The derived protein monomer has a molecular mass of 16187 Da and shows 82% and 93% identity to its human and rat counterparts, respectively. The mouse PTPS was expressed in bacterial cells and purified to homogeneity. The kinetic properties of the recombinant protein, apparent Km of approximately 10 microM and k(cat) of 0.27 s(-1), were similar to the native mouse enzyme in liver and brain extracts, and to the corresponding human and rat PTPS.