Isolation of mouse and human cDNA clones encoding a protein expressed specifically in osteoblasts and brain tissues.

Using the differential hybridization screening method between osteoblastic and fibroblastic cells, a cDNA clone coding for an osteoblast specific protein, named OSF-1, consisting of 168 amino acid residues including a possible 32 amino acid long leader sequence, was isolated from murine osteoblastic cell line MC3T3-E1. The OSF-1 gene was shown by Northern blotting analysis to be expressed in mouse calvarial osteoblast-enriched cells and in mouse brain tissues, but not in thymus, spleen, kidney, liver, lung, testis or heart. The human counterpart was also found in cDNA libraries from human osteosarcoma cell line MG63 and normal brain tissues. DNA sequence analysis revealed four amino acid sequence differences between the mouse and human, of which only one is located in the mature protein. This extremely high sequence conservation suggests that OSF-1 plays a fundamental role in bone and brain functions.     

Expression profile of mouse BWF1, a protein with a BEACH domain, WD40 domain and FYVE domain

We isolated a mouse cDNA encoding a protein that contains a BEACH domain, 5 WD40 repeats and a FYVE domain, which we designated as BWF1. The mRNA is approximately 10 kb in size and encodes a protein consisting of 3508 amino acids with a predicted molecular weight of 385 kDa. BWF1 has 45% homology with the Drosophila protein, blue cheese (BCHS). The BWF1 gene consists of 67 exons, which span 270 kb of genomic sequence, and has been mapped to mouse chromosome 5. Northern blot analysis revealed that it was strongly expressed in the liver, moderately in the kidney and testis, and weakly in the brain of adult mice. During the development of the mouse brain, BWF1 mRNA was abundant on embryonic day (E) 14-16; after birth, the level of BWF1 mRNA expression decreased markedly to reach the adult level at postnatal day 3. In situ hybridization analysis revealed that the expressed BWF1 mRNA was restricted to the marginal region both in E14 and E16 embryonic brain, but became diffuse after birth. Confocal microscopy studies of the epitope-tagged BWF1 protein showed that the protein was a cytoplasmic one.     

BSMAP, a novel protein expressed specifically in the brain whose gene is localized on chromosome 19p12.

Using the sequence of cosmids derived from chromosome 19p12, we have identified a gene encoding a novel protein, BSMAP (brain-specific membrane-anchored protein) and cloned cDNA encoding the full-length open reading frame. Northern blot analysis revealed that BSMAP mRNA is preferentially expressed at a high level in the brain. BSMAP has a putative transmembrane domain and is predicted to be a type-I membrane glycoprotein. Genomic sequence analysis revealed that the gene encoding BSMAP consists of eight exons spanning approximately 8 kb and lies 6 kb away from the gene encoding CLF-1 in a reverse orientation. Although no candidate genetic disorders were found to map either to this precise region of chromosome 19 or to the syntenic region of the mouse genome, the highly specific expression of BSMAP mRNA suggests a role for the protein in CNS function.     

Rat copper/zinc superoxide dismutase gene: isolation, characterization, and species comparison.

A 13 kb rat Cu/ZnSOD genomic clone has been purified from a rat liver genomic library and completely characterized by restriction mapping, detailed sequencing and Southern blot analysis. This gene spans approximately 6 kb and contains five exons and four introns. Comparison of rat, mouse, and human Cu/ZnSOD genes reveals a high conservation in genomic organization and exon-intron junctions, including an unusual 5'GC donor sequence at the first intron. The gene contains a TATA box as well as an inverted CCAAT box, a feature common to both the mouse and human genes. Furthermore, several repeats were identified in the 5' promoter region of this gene, and these regulatory elements are also strikingly conserved in these three species.     

Sequence conservation and structural organization of the glycerol-3-phosphate dehydrogenase promoter in mice and humans.

Cloned segments of the mouse glycerol-3-phosphate dehydrogenase (GPDH) gene, Gdc-1, were used to screen a human library. Human clones obtained spanned 25 kilobases of genomic DNA containing the human GPDH gene, GPD1. The 4 kb of sequence obtained from the 5'-flanking region and first exon of GPD1 was compared with the corresponding mouse sequence. Both sequences share a HindIII site located in what has proven to be the highly conserved 3' untranslated region of an upstream gene of unknown function, D15Kzl. The 3.6-kilobase segment of mouse DNA located between D15Kzl and Gdc-1 was provisionally termed the GPDH promoter. Alignment of the mouse promoter with the corresponding human sequence revealed two conserved domains. An upstream distal promoter region is approximately 900 base pairs in length. A downstream or proximal promoter region consists of approximately 300 base pairs immediately upstream of a TATA-like box and contains the fat-specific elements 1 and 2. Analysis of the chromatin structure of the Gdc-1 promoter revealed four DNase I-hypersensitive sites. They were present in DNA of liver and brown fat, in which GPDH expression is high, but were absent in DNA of spleen, in which GPDH expression is low. Methylation studies of the promoter showed it to be heavily methylated in sperm. However, the DNA from each adult somatic tissue had a unique distribution of nonmethylated sites and could easily be identified by its methylation pattern. These data suggest a structural model of the promoter that explains how Gdc-1 expression is differentially regulated in many types of cells.