Identification and characterization of C6orf37, a novel candidate human retinal disease gene on chromosome 6q14

We have identified a novel human gene, chromosome 6 open reading frame 37 (C6orf37), that is expressed in the retina and maps to human chromosome 6q14, a genomic region that harbors multiple retinal disease loci. The cDNA sequence contains an open reading frame of 1314 bp that encodes a 437-amino acid protein with a predicted molecular mass of 49.2 kDa. Northern blot analysis indicates that this gene is widely expressed, with preferential expression observed in the retina compared to other ocular tissues. The C6orf37 protein shares homology with putative proteins in R. norvegicus, M. musculus, D. melanogaster, and C. elegans, suggesting evolutionary conservation of function. Additional sequence analysis predicts that the C6orf37 gene product is a soluble, globular cytoplasmic protein containing several conserved phosphorylation sites. Furthermore, we have defined the genomic structure of this gene, which will enable its analysis as a candidate gene for chromosome 6q-associated inherited retinal disorders.     

Molecular biology of Diazepam Binding Inhibitor peptide

Complementary DNA (cDNA) clones containing the entire coding sequence for Diazepam Binding Inhibitor (DBI) peptide, a 10-kDa precursor of putative natural ligands of benzodiazepine recognition sites, were isolated from rat, human and cow libraries. The sequence of all these clones is highly conserved; however, the N-terminal sequence predicted by the human DBI clone differed from that of the other two clones. DBI cDNA, utilized as hybridization probe in Southern blot analysis, revealed that DBI of both human and rat might be encoded by a multiple family of 4–6 genes. Furthermore, we have used in situ chromosomes hybridization to map human DBI genes. The results indicate that a human DBI gene is localized on chromosome 2 and that three of the four hybridization signals detected by the human DBI probe are located on three other chromosomes. These findings raise a question as whether multiple DBI genes encode for different molecular forms of DBI. In the attempt to test this hypothesis, cow cDNA and human genomic libraries were screened with DBI cDNA. In this paper I report the isolation of clones from these libraries which, although hybridizing well to DBI cDNA, possess a low percentage of homology (46.7%), randomly distributed within the coding region of DBI cDNA. Whether or not these clones encode for peptides sharing the same physiological role as DBI is under investigation.Special issue dedicated to Dr. Erminio Costa     

A class III myosin expressed in the retina is a potential candidate for Bardet-Biedl syndrome

Class III myosins are actin-based motors with amino-terminal kinase domains. Expression of these motors is highly enhanced in retinal photoreceptors. As mutations in the gene encoding NINAC, a Drosophila melanogaster class III myosin, cause retinal degeneration, human homologs of this gene are potential candidates for human retinal disease. We have recently reported the cloning of MYO3A, a human myosin III expressed predominantly in the retina and retinal pigmented epithelium [1]. The map locus of MYO3A is close to, but does not overlap, that of human Usher's 1F [2]. Here we introduce a shorter class III myosin isoform, MYO3B, which is expressed in the retina, kidney, and testis. We describe the cDNA sequence, genomic organization, and splice variants of MYO3B expressed in the human retina. A product of 36 exons, MYO3B has several splice variants containing either one or two calmodulin binding (IQ) motifs in the neck domain and one of three predominant tail variations: a short tail ending just past the second IQ motif, or two alternatively spliced longer tails. MYO3B maps to 2q31.1-q31.2, a region that overlaps the locus for a Bardet-Biedl syndrome (BBS5) linked to markers at 2q31 [3].     

Expressed sequence tags and chromosomal localization of cDNA clones from a subtracted retinal pigment epithelium library.

Expressed sequence tags (ESTs) provide useful molecular landmarks for physical mapping and identify the position of an expressed region in the genome. The use of subtracted cDNA libraries enriched for tissue-specific genes as a source of ESTs should reduce the repetitive isolation of constitutively expressed sequences. We report here the sequence tags from the 3'-end region of 58 new directionally cloned cDNAs from a subtracted human retinal pigment epithelium (RPE) cell line library. Eight of the cDNAs have been assigned to human chromosomes using PCR-based EST assays. Chromosomal mapping of subtracted RPE cDNA clones may also help in identifying candidate genes for inherited eye diseases.     

The mouse X-linked juvenile retinoschisis cDNA: expression in photoreceptors

Retinal photoreceptor cells are particularly vulnerable to degenerations that can eventually lead to blindness. Our purpose is to identify and characterize genes expressed specifically in photoreceptors in order to increase our understanding of the biochemistry and function of these cells, and then to use these genes as candidates for the sites of mutations responsible for degenerative retinal diseases. We have characterized a cDNA, a fragment of which (SR3.1) was originally isolated by subtractive hybridization of adult, photoreceptorless rd mouse retinal cDNAs from the cDNAs of normal mouse retina. The full-length sequence of this cDNA was determined from clones obtained by screening mouse retinal and eye cDNA libraries and by using the 5'- and 3'-RACE methods. Both Northern blot analysis and in situ hybridization showed that the corresponding mRNA is expressed in rod and cone photoreceptors. The gene encoding this cDNA was mapped to the X chromosome using an interspecific cross. Based on the nucleotide and amino acid sequences, as well as chromosome mapping, we determined that this gene is the mouse ortholog (Xlrs1) of the human X-linked juvenile retinoschisis gene (XLRS1). Analysis of the predicted amino acid sequence indicates that the Xlrs1 mRNA may encode a secretable, adhesion protein. Therefore, our data suggest that X-linked juvenile retinoschisis originates from abnormalities in a photoreceptor-derived adhesion protein.     

Assignment of 118 novel cDNAs of cynomolgus monkey brain to human chromosomes

In order to isolate genes that may not be represented in current human brain cDNA libraries, we have sequenced about 20,000 sequence tags of cDNA clones derived from cerebellum and parietal lobe of cynomolgus monkeys (Macaca fascicularis). We determined the entire cDNA sequence of approximately 700 clones whose 5'-terminal sequences showed no homology to annotated putative genes or expressed sequence tags in current databases of genetic information. From this, 118 clones with sequences encoding novel open reading frames of more than 100 amino acid residues were selected for further analysis. To localize the genes corresponding to these 118 newly identified cDNA clones on human chromosomes, we performed a homology search using the human genome sequence and fluorescent in situ hybridization. In total, 108 of 118 clones were successfully assigned to specific regions of human chromosomes. This result demonstrates that genes expressed in cynomolgus monkey are highly conserved throughout primate evolution, and that virtually all had human homologs. Furthermore, we will be able to discover novel human genes in the human genome using monkey homologs as probes.     

Molecular cloning and functional expression of cDNA encoding a mammalian inorganic pyrophosphatase.

Extracts of soluble proteins from bovine retina contain multiple species of inorganic pyrophosphatase (PPase) that can be resolved by hydroxylapatite or ion exchange chromatography. We have purified one of these isoforms by a combination of chromatography and electrophoresis under denaturing conditions and have partially sequenced four peptides generated from it by CNBr digestion. This sequence information was used to clone PPase cDNA from a retinal cDNA library. Of five cDNA inserts, three were 1.3 kilobase pairs in length and two of these contained a complete open reading frame that was 867 base pairs long and encoded a 289-amino acid protein of 33 kDa. The deduced amino acid sequence is 49.5% identical to that of PPase from Saccharomyces cerevisiae, and contains identical amino acid residues at all of the positions previously identified as essential for catalytic activity in that enzyme. When the bovine PPase cDNA was expressed in Escherichia coli, catalytically active PPase was produced that comigrated with bovine retinal PPase in a nondenaturing gel and was clearly distinguishable from the host PPase. Northern analysis of poly(A)+ RNA from human, canine, and bovine retinas revealed that each contained a single major band of 1.4 kilobases that hybridized strongly with a pyrophosphatase cDNA probe. Southern analysis of bovine genomic DNA was consistent with the existence of one PPase gene. Thus, the multiple forms separated by chromatography may be derived from a common precursor or from mRNAs of very similar size.     

A novel gene (retinovin) expressed selectively in the early stage of chick retinal development

To understand molecular mechanisms of retinal development, genes expressed selectively only in the early stage of retinal development were isolated by subtractive hybridization based on suppression polymerase chain reaction. The retina has no layered structure in 7-day chick embryos, in contrast with the fully developed multilayered structure of neurons in 15-day embryos. The subtraction between cDNA derived from retinal tissues at these different stages, followed by repeat rounds of 5'-RACE (rapid amplification of cDNA ends) and 3'-RACE, led to isolation of a novel gene with an open reading frame encoding a putative protein with 753 amino acids. Its specific expression in the 7-day embryonic retina was confirmed by Northern blot analysis. The gene, named "retinovin," would be used as a marker for identifying retinal stem cells present at the early stage of retinal development.     

Characterization of a Human Fovea cDNA Library and Regional Differential Gene Expression in the Human Retina

The primate fovea is the region of the retina responsible for acute vision. This region constitutes less than 5% of the total area of the retina and has not been intensely studied at the molecular level. As a first step in the molecular characterization of the fovea, we have constructed a primary human fovea cDNA library. Experiments confirm that our cDNA library reflects a nonbiased distribution of foveal expressed sequences. Single-pass sequencing was performed on 209 randomly isolated clones from this library. Analysis of the sequences generated reveals that the distributions of fovea clones with either human mitochondrial gene sequences or repetitive elements are different than those observed in cDNA libraries made from other tissues. A significant number of the fovea expressed sequence tags (ESTs) (88, 42.1%) represent novel human ESTs. This suggests that the library will be useful in identifying new human genes. Northern analysis of specific fovea ESTs defined in this study suggests that there are significant quantitative differences in gene expression that distinguish the fovea from the rest of the retina.     

Localization of the humanRGR opsin gene to chromosome 10q23

The humanRGR gene encodes an opsin protein (retinal G protein-coupled receptor), which is expressed in Müller cells and the retinal pigment epithelium and is thought to play a role in the visual process. To investigate a possible linkage of theRGR gene to retinal dystrophies, the locus of the gene was mapped on human metaphase chromosomes. Genomic and cDNA fragments of the humanRGR gene were used as probes for fluorescence in situ hybridization. Analysis of the fluorescence signals on high-resolution banded chromosomes showed that theRGR gene is localized to human chromosome lOq23. This result now provides for the rapid analysis of this gene with respect to inherited diseases of the retina.     

Nucleotide sequence of the gene for human factor IX (antihemophilic factor B)

Two different human genomic DNA libraries were screened for the gene for blood coagulation factor IX by employing a cDNA for the human protein as a hybridization probe. Five overlapping lambda phages were identified that contained the gene for factor IX. The complete DNA sequence of about 38 kilobases for the gene and the adjacent 5' and 3' flanking regions was established by the dideoxy chain termination and chemical degradation methods. The gene contained about 33.5 kilobases of DNA, including seven introns and eight exons within the coding and 3' noncoding regions of the gene. The eight exons code for a prepro leader sequence and 415 amino acids that make up the mature protein circulating in plasma. The intervening sequences range in size from 188 to 9473 nucleotides and contain four Alu repetitive sequences, including one in intron A and three in intron F. A fifth Alu repetitive sequence was found immediately flanking the 3' end of the gene. A 50 base pair insert in intron A was found in a clone from one of the genomic libraries but was absent in clones from the other library. Intron A as well as the 3' noncoding region of the gene also contained alternating purine-pyrimidine sequences that provide potential left-handed helical DNA or Z-DNA structures for the gene. KpnI repetitive sequences were identified in intron D and the region flanking the 5' end of the gene. The 5' flanking region also contained a 1.9-kb HindIII subfamily repeat. The seven introns in the gene for factor IX were located in essentially the same position as the seven introns in the gene for human protein C, while the first three were found in positions identical with those in the gene for human prothrombin.