Structures and chromosomal localizations of two human genes encoding synaptobrevins 1 and 2

Synaptobrevins 1 and 2 are small integral membrane proteins specific for synaptic vesicles in neurons. Two cosmid clones containing the human genes encoding synaptobrevins 1 and 2 (gene symbols SYB1 and SYB2, respectively) were isolated and characterized. The coding regions of the synaptobrevin genes are highly homologous to each other and are interrupted at identical positions by introns of different size and sequence. Each gene is organized into five exons whose boundaries correspond to those of the protein domains. Exon I contains part of the initiator methionine codon whereas exon II encodes the variable and immunogenic amino-terminal domain of the synaptobrevins. The third exon comprises the highly conserved central domain of the synaptobrevins, exon IV encodes most of the transmembrane region, and exon V contains the last residues of the transmembrane region and the small intravesicular carboxyl terminus. Comparisons of the synaptobrevin sequences in five species from Drosophila with man indicate a selective conservation of sequences adjacent to the synaptic vesicle surface, suggesting a function at the membrane-cystosol interface. The chromosomal localizations of the human and mouse SYB1 and SYB2 genes were determined using hybrid cell lines. SYB1 was localized to the short arm of human chromosome 12 and to mouse chromosome 6 whereas SYB2 was found on the distal portion of the short arm of human chromosome 17 and on mouse chromosome 11. A PstI restriction fragment length polymorphism was identified at the SYB2 locus.     

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.     

Organization and conservation of the GART/SON/DONSON locus in mouse and human genomes

The SON gene, which maps to human chromosome 21q22.1-q22.2, encodes a novel regulatory protein. Here we describe the organization of the Son locus in the mouse genome. The mouse Son gene spans a region of approximately 35 kb. The coding region is more than 8 kb in length and has been completely sequenced. The gene is organized into 11 coding exons and 1 noncoding 3'UTR exon, with over 70% of the coding region residing in one 5.7-kb exon. The gene contains at least one alternative exon, N/C exon 1, which can be used, by splicing, to generate a truncated form of the SON protein. Further investigation of the mouse Son locus has identified the genes directly flanking Son. The glycinamide ribonucleotide formyltransferase gene, Gart, is encoded 5' of Son in a head-to-head arrangement, with the start of both genes lying within 899 bp. Sequence comparison with the expressed sequence tagged database identified a novel gene within 65 bp of the 3' end of Son, which we have named Donson. In this unusually compact gene cluster, we have found overlap in the pattern of expression between Gart, Son, and Donson. However, at least two of these genes have very different functions. While GART is involved in purine biosynthesis, we find that SON shows the characteristics of "SR- type" proteins, which are involved in mRNA processing and gene expression.     

Assignment of the βB1 Crystallin Gene (CRYBB1) to Human Chromosome 22 and Mouse Chromosome 5

By using primers complementary to the rat βB1 crystallin gene sequence, we amplified exons 5 and 6 of the orthologous human gene (CRYBB1). The amplified human segments displayed greater than 88% sequence homology to the corresponding rat and bovine sequences.CRYBB1was assigned to the group 5 region in 22q11.2–q12.1 by hybridizing the exon 6 PCR product to somatic cell hybrids containing defined portions of human chromosome 22. The exon 5 and exon 6 PCR products ofCRYBB1were used to localize, by interspecific backcross mapping, the mouse gene (Crybb1) to the central portion of chromosome 5. Three other β crystallin genes (βB2(−1), βB3, and βA4) have previously been mapped to the same regions in human and mouse. We demonstrate that the βB1 and βA4 crystallin genes are very closely linked in the two species. These assignments complete the mapping and identification of the human and mouse homologues of the major β crystallins genes that are expressed in the bovine lens.     

cDNA and genomic cloning of HRC, a human sarcoplasmic reticulum protein, and localization of the gene to human chromosome 19 and mouse chromosome 7

Histidine-rich calcium binding protein (HRC) is a luminal sarcoplasmic reticulum (SR) protein of 165 kDa identified by virtue of its ability to bind 125I-labeled low-density lipoprotein with high affinity after sodium dodecyl sulfate-polyacrylamide gel electrophoresis (Hofmann et al., J. Biol. Chem. 264: 8260-8270, 1989). Its role in SR function is unknown. In this report, the gene encoding human HRC was localized to human chromosome 19 and mouse chromosome 7 by hybridization of a human HRC cDNA fragment to a panel of somatic cell hybrids. Known synteny between a portion of human chromosome 19 and a portion of mouse chromosome 7 and in situ hybridization of a biotin-labeled HRC probe to human chromosomes suggest a localization to a region corresponding to 19q13.3. The locus for myotonic dystrophy resides in the region 19q13.2-13.3. Therefore, we considered HRC, a muscle-specific gene, to possibly represent a "candidate gene" for myotonic muscular dystrophy. As a first step toward localizing HRC in relation to the myotonic dystrophy locus, we report the cloning of the human HRC gene, its intron-exon organization, and characterization of several informative polymorphisms to be used in future linkage studies in families with myotonic dystrophy. Of particular interest is an Alu-associated poly-d(GA) sequence located in an intron in the middle of the gene, and two stretches of acidic amino acids in the coding region of exon 1 that vary in length among different individuals.     

Genomic organization and characterization of human PEX2 encoding a 35-kDa peroxisomal membrane protein

Peroxins are proteins involved in peroxisome biogenesis and are encoded by PEX genes. The human PEX2 gene encodes a 35-kDa peroxisomal integral membrane protein which is a member of the zinc finger protein family. Mutations in the PEX2 gene are the primary defect in a subset of patients with Zellweger syndrome and related peroxisome biogenesis disorders. The role of zinc finger proteins in peroxisome assembly and function is poorly understood. Here we report the cloning and characterisation of the human PEX2 structural gene. PEX2 was assigned to human chromosome 8q13-q21 and its murine homologue to mouse chromosome 3. The gene is approximately 17.5 kb in length, and contains four exons. The entire coding sequence is included in one exon, exon 4. The 5'-flanking region has features of housekeeping genes (GC enrichment, two Sp1 sites) and tissue-specific, inducible genes (two CCAAT boxes). In more than 1.5 kb of 5'-flanking sequences we did not identify consensus peroxisomal proliferator responsive elements (PPRE).     

Genomic organization and chromosomal localization of the mouse IKBKAP gene.

The autosomal recessive disorder familial dysautonomia (FD) has recently been demonstrated to be caused by mutations in the IKBKAP gene, so named because an initial report suggested that it encoded an IkappaB kinase complex associated protein (IKAP). Two mutations in IKBKAP have been reported to cause FD. The major mutation is a T-->C transition in the donor splice site of intron 20 and the minor mutation is a missense mutation in exon 19 that disrupts a consensus serine/threonine kinase phosphorylation site. We have characterized the cDNA sequences of the mouse, rat and rabbit IKBKAP-encoded mRNAs and determined the genomic organization and chromosomal location of mouse IKBKAP. There is significant homology in the amino acid sequence of IKAP across species and the serine/threonine kinase phosphorylation site altered in the minor FD mutation of IKAP is conserved. The mouse and human IKBKAP genes exhibit significant conservation of their genomic organization and the intron 20 donor splice site sequence, altered in the major FD mutation, is conserved in the human and mouse genes. Mouse IKBKAP is located on the central portion of chromosome 4 and maps to a region in which there is conserved linkage homology between the human and mouse genomes. The homologies observed in the human and mouse sequences should allow, through the process of homologous recombination, for the generation of mice that bear the IKBKAP mutations present in individuals with FD. The characterization of such mice should provide significant information regarding the pathophysiology of FD.     

Gene organization of human NOTCH4 and (CTG)n polymorphism in this human counterpart gene of mouse proto-oncogene Int3

The cDNA and genomic clones for the human counterpart of the mouse mammary tumor gene Int3 were isolated and sequenced. We designated this human major histocompatibility complex (MHC) class III gene as NOTCH4, since very recently, by sequencing cDNA clones, the complete form of the mouse proto-oncogene Int3 has been clarified and named Notch4. The present human NOTCH4 sequence is the first example of the genomic sequence for the extracellular portion of the mammalian Notch4, and by comparing it with the mouse Notch4 cDNA sequence, the exon/intron organization was clarified. The comparison of the predicted amino acid sequence of human NOTCH4 with those of other Notch homologues of a wide range of species revealed four subfamilies for mammalian Notch. In the protein coding region of human NOTCH4, we found (CTG)_n repeats showing a variable number tandem repeat (VNTR) polymorphism for different human leukocyte antigen (HLA) haplotypes. Ten genes mapped on 6p21.3, including NOTCH4, were found to have counterparts structurally and functionally similar to those mostly mapped on 9q33-q34, indicating segmental chromosome duplication during the course of evolution. Similarity of genes on chromosomes 1, 6, 9 and 19 was also discussed.     

A novel snoRNA (U73) is encoded within the introns of the human and mouse ribosomal protein S3a genes

The mouse ribosomal protein S3a-encoding gene (mRPS3a) was cloned and sequenced in this study. mRPS3a shares identical exon/intron structure with its human counterpart. Both genes are split to six exons and exhibit remarkable conservation of the promoter region (68.8% identity in the 250 bp upstream of cap site) and coding region (the proteins differ in two amino acids). mRPS3a displays many features common to other r-protein genes, including the CpG-island at 5′-end of the gene, cap site within an oligopyrimidine tract and no consensus TATA or CAAT boxes. However, mRPS3a represents a rare subclass of r-protein genes that possess a long coding sequence in the first exon. Comparison of human and mouse S3a genes revealed sequence fragments with striking similarity within introns 3 and 4. Here we demonstrate that these sequences encode for a novel small nucleolar RNA (snoRNA) designated U73. U73 contains C, D and D′ boxes and a 12-nucleotide antisense complementarity to the 28S ribosomal RNA. These features place U73 into the family of intron-encoded antisense snoRNAs that guide site-specific 2′-O-ribose methylation of pre-rRNA. We propose that U73 is involved in methylation of the G1739 residue of the human 28S rRNA. In addition, we present the mapping of human ribosomal protein S3a gene (hRPS3a) and internally nested U73 gene to the human chromosome 4q31.2–3.     

Assignment of the Y4Receptor Gene (PPYR1) to Human Chromosome 10q11.2 and Mouse Chromosome 14

The human and mouse genes for the neuropeptide Y₄receptor have been isolated, sequenced, and shown to contain no introns within the coding region of the gene. Nonisotopicin situhybridization and interspecific mouse backcross mapping have localized the genes to human chromosome 10q11.2 and mouse chromosome 14. Five nucleotide variants, which do not alter the protein sequence, have been identified within the coding region of the human receptor gene. The human Y₄subtype is most closely related to the Y₁-receptor subtype (42%), suggesting that it evolved from an ancestral Y₁-like receptor via an RNA-mediated transpositional event.     

Structure of the rat p53 tumor suppressor gene.

Aberration within the p53 tumor suppressor gene is the most frequently identified genetic damage in human cancer. Regulatory functions proposed for the p53 protein include modulation of the cell cycle, cellular differentiation, signal transduction, and gene expression. Additionally, the p53 gene product may guard the genome against incorporation of damaged DNA. To facilitate study of its role in carcinogenesis using a common animal model, we determined the structure of the rat p53 gene. We identified 18 splice sites and defined 25 bases of the intervening sequences adjacent to these sites. We also discovered an allelic polymorphism that occurs within intron 5 of the gene. The rat gene approximates the mouse ortholog. It is 12 kb in length with the non-coding exon 1 separated from exon 2 by 6.2 kb of intervening sequence. The location and size of all rat gene introns approximate those of the mouse. Whereas the mouse and human genes each contain 11 exons, the rat p53 gene is composed of only 10. No intervening sequence occurs between the region of the rat gene corresponding to exons 6 and 7 of the mouse and human p53 genes. This implies intron 6 may be functionally insignificant for species in which it is retained. To extrapolate to p53 involvement in human tumorigenesis, we suggest that mutational events within intron 6 may not be of pathological significance unless splicing is hindered.