Identification of chicken and C. elegans fibulin-1 homologs and characterization of the C. elegans fibulin-1 gene

Fibulin-1, a member of the emerging family of fibulin proteins, is a component of elastic extracellular matrix fibers, basement membranes and blood. Homologs of fibulin-1 have been described in man, mouse and zebrafish. In this study, we describe the isolation and sequencing of chicken fibulin-1C and D cDNA variants. We also describe identification of a C. elegans cDNA encoding fibulin-1D and cosmids containing the C. elegans fibulin-1 gene. Using the cDNA, RT-PCR and computer-based analysis of genomic sequences, the exon/intron organization of the C. elegans fibulin-1 gene was determined. The C. elegans fibulin-1 gene is located on chromosome IV, is approximately 6 kb in length, contains 16 exons and encodes fibulin-1C and D variants. Comparative analysis of the deduced amino acid sequences of nematode and chicken fibulin-1 variants with other known vertebrate fibulin-1 polypeptides showed that the number and organization of structural modules are identical. The results of this study indicate that the structure of the fibulin-1 protein has remained highly conserved over a large period of evolution, suggestive of functional conservation.     

Identification of the Tslc1 gene,a mouse orthologue of the human tumor suppressor TSLC1 gene

We have recently identified the TSLC1 gene as a novel tumor suppressor in human non-small lung cancer on chromosome 11q23.2. TSLC1 encodes a membrane glycoprotein showing significant homology with immunoglobulin superfamily molecules. Here, we report the isolation of a mouse orthologous gene, Tslc1. The Tslc1 cDNA contains a single open reading frame of 1335 bp encoding a putative protein of 445 amino acids, and its expression was detected in all tissues examined. The Tslc1 gene is mapped on mouse chromosome 9, a synteny of human chromosome 11q, and is composed of ten exons, the exon-intron junctions being highly conserved between human and mouse. The predicted amino acids of mouse Tslc1 display 98% identity with that of human TSLC1. Furthermore, data base analysis indicates that the amino acid sequences corresponding to the cytoplasmic domain of Tslc1 are identical in five mammals and highly conserved in vertebrates, suggesting an important role of Tslc1 in normal cell-cell interaction.     

Genomic organization of the mouse OSF-1 gene.

The mouse OSF-1 protein (also known as pleiotrophin, HB-GAM, HBGF-8, or HBNF) gene was isolated from a mouse genomic library and sequenced. OSF-1 is a 15-kD secreted protein specifically expressed in bone and brain, and is believed to play a role in brain development and osteogenesis. The mouse OSF-1 gene consists of at least 5 exons and 4 introns and spans > 32 kb. Computer analysis of approximately 4 kb of 5'-flanking sequence of the OSF-1 gene revealed two candidate promoter regions. One candidate promoter contains a thyroid hormone/retinoic acid-responsive element and the other contains two glucocorticoid-responsive elements. DNA sequence analysis of novel OSF-1 cDNA clones indicates that two promoters can be utilized in MC3T3-E1 osteoblastic cells. The overall organization of the mouse OSF-1 gene is similar and the locations of the three exon-intron junctions within the coding region are identical to the mouse gene encoding the differentiation-related factor midkine (MK). Based on this similarity and on the high degree of nucleotide sequence homology (approximately 55%) of mouse OSF-1 and mouse MK, we conclude that OSF-1 and MK are generated from a common ancestral gene and are members of a family of structurally and probably functionally related proteins.     

Cloning, genomic structure, and expression profiles of TULIP1 (GARNL1), a brain-expressed candidate gene for 14q13-linked neurological phenotypes, and its murine homologue

Previously, we have described the clinical and molecular characterization of a de novo 14q13.1-q21.1 microdeletion, less than 3.5 Mb in size, in a patient with severe microcephaly, psychomotor retardation, and other clinical anomalies. Here we report the characterization of the genomic structure of the human tuberin-like protein gene 1 (TULIP1; approved gene symbol GARNL1), a CpGisland-associated, brain-expressed candidate gene for the neurological findings in our patient, and its murine homologue. The human TULIP1 gene was mapped to chromosome band 14q13.2 by fluorescence in situ hybridization of BAC clone RP11-355C3 (GenBank Accession No. AL160231), containing the 3' region of the gene. TULIP1 spans about 271 kb of human genomic DNA and is divided into 41 exons. An untranscribed, processed pseudogene of TULIP1 was found on human chromosome band 9q31.1. The active locus TULIP1, encoding a predicted protein of 2036 amino acids, is expressed ubiquitously in pre- and postnatal human tissues. The murine homologue Tulip1 spans about 220 kb of mouse genomic DNA and is also divided into 41 exons, encoding a predicted protein of 2035 amino acids. No pseudogene could be found in the available mouse sequence data. Several splicing variants were found. Considering the location, expression profile, and predicted function, TULIP1 is a strong candidate for several neurological features seen in 14q deletion patients. Additionally we searched for mutations in the coding region of TULIP1 in subjects from a family with idiopathic basal ganglia calcification (IBGC; Fahr disease), previously linked to chromosome 14q. We identified two novel SNPs in the intron-exon boundaries; however, they did not segregate only with affected subjects in the predicted model of an autosomal dominant disease such as IBGC.     

Genomic structure, alternative splicing, and physical mapping of the killer cell lectin-like receptor G1 gene (KLRG1), the mouse homologue of MAFA

The mouse killer cell lectin-like receptor G1 (KLRG1), the mouse homologue of the mast cell function-associated antigen (MAFA), is an inhibitory C-type lectin expressed on natural killer (NK) cells and activated CD8 T cells. Here we report the complete nucleotide sequence, alternatively spliced variants, and the physical mapping of the KLRG1 gene in the mouse. The gene spans about 13 kb and consists of five exons. Short interspersed repeats of the B1 and B2 family, a LINE-1-like element, and a (CTT)170 triplet repeat were found in intron sequences. In contrast to human KLRG1 and to the murine KLR family members, mouse KLRG1 locates outside the NK complex on Chromosome 6 between the genes encoding CD9 and CD4.     

Characterization and expression of the gene encoding membralin, an evolutionary conserved protein expressed in the central nervous system

We have identified a novel gene that encodes an evolutionary conserved protein that we name membralin since it contains multiple transmembrane regions. The human gene C19orf6 localizes to chromosome 19p13.3. Splice variant membralin-1 is encoded by 11 exons, translating into 620 amino acids. In addition, we found evidence for two additional splice variants in the human. The mouse gene ORF61 localizes to chromosome 10. We cloned two splice variants in mouse: membralin-1, which is encoded by 12 exons, translating into 574 amino acids, and membralin-2, which translates into 598 amino acids. The existence of rat membralin-1 (574 amino acids long) is, so far, only supported by in situ hybridization result, whereas the existence of rat membralin-2 (598 amino acids long) is strongly supported by overlapping ESTs. Gene homologues were also identified in fruit-fly (CG8405, chromosome 2R 52; two splice variants), nematode (chromosome III), and Arabidopsis thaliana (chromosome 1). Sequence analysis revealed no closely related genes, suggesting that membralin represents the sole member of a unique protein family.     

Cloning and characterization of the rabbit POU5F1 gene.

The product of the POUSF1 gene, Oct4, plays an important role both in embryonic development and in the self-renewal and differentiation of totipotent cells. To understand the function of Oct4 in rabbit ES cells, we cloned and sequenced the rabbit POU5F1 gene, as well as the cDNA encoded by the gene. The Oct4 cDNA contains a 1083 bp ORF encoding a 360 aa protein and a 241 bp 3' UTR sequence. Oct4 mRNA was expressed at a high level in rabbit ES cells and was barely detectable in the adult spleen, kidney, brain and muscle tissues. The POU5F1 gene is approximately 6 kb in length and includes five exons and four introns. Gene organization is similar to that of the mouse, human and bovine orthologs. Sequencing of the gene revealed an 82% (mouse), 90% (human) and 89% (bovine) overall identity at the protein level. The rabbit POUSF1 gene was mapped to chromosome 12q1.1 by PCR amplification of DNA from two putative POU5F1-containing BAC clones, which were previously mapped to chromosome 12q1.1. The cloning of the rabbit POU5F1 gene will facilitate studies on its roles in rabbit embryogenesis and ES cells.     

Structure and mapping of the gene encoding mouse high affinity Fc gamma RI and chromosomal location of the human Fc gamma RI gene.

We describe the isolation and characterization of the gene encoding the mouse high affinity Fc receptor Fc gamma RI. Using a mouse cDNA Fc gamma RI probe four unique overlapping genomic clones were isolated and were found to encode the entire 9 kb of the mouse Fc gamma RI gene. Sequence analysis of the gene showed that six exons account for the entire Fc gamma RI cDNA sequences including the 5'- and 3'-untranslated sequences. The first and second exons encode the signal peptide; exons 3, 4, and 5 encode the extracellular Ig binding domains; and exon 6 encodes the transmembrane domain, the cytoplasmic region, and the entire 3'-untranslated sequence. This exon pattern is similar to Fc gamma RIII and Fc epsilon RI but differs from the related Fc gamma RII gene which contains 10 exons and encodes the b1 and b2 Fc gamma RII. Southern blot analysis had shown that the mouse Fc gamma RI gene is a single copy gene with no RFLP in inbred strains of mice, but analysis of an intersubspecies backcross of mice showed that unlike other mouse FcR genes which are on mouse chromosome 1 the locus encoding Fc gamma RI, termed Fcg1, is located on chromosome 3. Interestingly, the Fcg1 locus is located near the end of a region with known linkage homology to human chromosome 1. Analysis of human x rodent somatic cell hybrid cell lines indicates that the human FCG1 locus encoding the human Fc gamma RI maps to chromosome I and therefore possibly linked to other FcR genes on this chromosome. These results suggest that the linkage relationships among these genes in the human genome are not preserved in the mouse.     

Structure, expression, and conserved physical linkage of mouse testicular cell adhesion molecule-1 (TCAM-1) gene.

Isolation and characterization were performed for cDNA encoding mouse testicular cell adhesion molecule-1 (TCAM-1) using 2908 bases coding for a protein having 548 amino acids (60 kDa). Mouse TCAM-1 protein was found to consist of seven domains for signal sequence, five immunoglobulin (Ig) domains, and the transmembrane plus cytoplasmic domain. TCAM-1 gene and the region linking it to growth hormone (GH) gene located downstream from the TCAM-1 gene were then analyzed. The mouse TCAM-1 gene was 11.6 kb in length with 8 exons; the same as for the 12.0 kb rat gene. The distance from the TCAM-1 to GH gene was 12.5 kb in the mouse genome, and 7.6 kb in the rat. By Northern hybridization, 3.1-kb TCAM-1 mRNA was detected in 17-day testis and would appear present in pachytene spermatocytes and round spermatids.     

Mouse Hus1, a homolog of the Schizosaccharomyces pombe hus1+ cell cycle checkpoint gene.

Cell cycle checkpoints are regulatory mechanisms that arrest the cell cycle or initiate programmed cell death when critical events such as DNA replication fail to be completed or when DNA or spindle damage occurs. In fission yeast, cell cycle checkpoint responses to DNA replication blocks and DNA damage require the hus1+ gene. Mammalian homologs of hus1+ were recently identified, and here we report a detailed analysis of mouse Hus1. An approximately 4.2-kb full-length cDNA encoding the 32-kDa mouse Hus1 protein was isolated. The genomic structure and exon-intron boundary sequences of the gene were determined, and mouse Hus1 was found to consist of nine exons. Mouse Hus1 was mapped to the proximal end of chromosome 11 and is therefore a candidate gene for the mouse mutation germ cell deficient, which maps to the same genomic region. Finally, mouse Hus1 was found to be expressed in a variety of adult tissues and at several stages of embryonic development.