Characterization and chromosomal mapping of a mouse ortholog of the late-infantile ceroid-lipofuscinosis gene CLN2

Late-infantile ceroid-lipofuscinosis (CLN2) is an autosomal recessively inherited, neurodegenerative disease in humans. The CLN2 locus has been mapped to Chromosome (Chr) 11p15, and its sequence and genomic organization have recently been reported. In the present study, the cDNA sequence, exon/intron organization, and chromosomal localization of a mouse ortholog of the CLN2 gene are described. The mouse cDNA contains an open reading frame that predicts a protein product of 562 amino acids. The mouse and human coding regions are 86% and 88% identical at the nucleic acid and amino acid levels, respectively. One less codon appears in the mouse cDNA when compared with the human ortholog. The mouse gene (Cln2) spans more than 6 kb and consists of 13 exons separated by introns ranging in size from 111 to 1259 bp. Length polymorphism in an (AC)_n microsatellite in intron 3 of the mouse Cln2 gene was used to perform segregation analysis with The Jackson Laboratory DNA Panel Mapping Resource. On the basis of this analysis, the Cln2 gene was localized to a region of mouse Chr 7 that corresponds to human Chr 11p15. Characterization of the mouse Cln2 gene will facilitate generation of a mouse model for late-infantile ceroid-lipofuscinosis by gene targeting and identification of functionally important regions of the Cln2 protein. Received: 25 May 1999 / Accepted: 22 July 1999     

Characterization of the mouse neutrophil elastase gene and localization to Chromosome 10

Neutrophil elastase (NE), a serine proteinase, is considered to play a role in normal tissue turnover and host defense. NE may also cause tissue damage in acute and chronic inflammatory diseases. We have isolated and characterized the gene for mouse NE and determined its chromosomal location. The mouse NE gene has been localized by interspecific backcross analysis to Chromosome (Chr) 10. The gene for mouse NE is composed of 5 exons and 4 introns, similar to the human NE. Mouse NE shares the highly conserved exon size and intron-exon borders with human NE. The coding exons of the mouse NE gene predict a translation product in a pre-pro form, similar to human NE. Knowledge of the genomic organization and chromosomal location of mouse NE may allow us to further define mechanisms responsible for cell and tissue-specific expression of mouse NE. Received: 16 July 1996 / Accepted: 1 September 1996     

A mouse Y Chromosome pseudogene is related to human ubiquitin activating enzyme E1

A 2041 bp DNA fragment isolated from the Sxr (sex reversed) region of the mouse Y Chromosome (Chr) was sequenced and characterized. The sequence, pY8/b, contains four exons that are highly similar to 525 contiguous bases from the cDNA of human ubiquitin activating enzyme El. Two of the exons contain stop codons, indicating that pY8/b is not part of a functional gene. Sequences related to pY8/b were amplified from the Y Chr of the inbred mouse strain, C57BL/6J. These sequences may be portions of the recently discovered functional equivalent of pY8/b. Despite a high degree of similarity with the human El gene, the functional equivalent of pY8/b is not the mouse El gene, because unlike El, the functional equivalent of pY8/b is expressed in a tissue-specific manner. These data are discussed with respect to theory on the evolution of the mammalian Y Chr, and in particular, to the prediction that functional genes on the Y Chr have a male-specific function.     

Genomic organization of the human CD5 gene

CD5 is a member of the family of receptors which contain extracellular domains homologous to the type I macrophage scavenger receptor cysteine-rich (SRCR) domain. Here, we compare the exon/intron organization of the human CD5 gene with its mouse homologue, as well as with the human CD6 gene, the closest related member of the SRCR superfamily. The human CD5 gene spans about 24.5 kb and consists of at least 11 exons. These exons are conserved in size, number, and structure in the mouse CD5 homologue. No evidence for the biallelic polymorphism reported in the mouse could be found among a population of 100 individuals of different ethnic origins. The human CD5 gene maps to the Chromosome (Chr) 11q12.2 region, 82 kb downstream from the human CD6 gene, in a head-to-tail orientation, a situation which recalls that reported at mouse Chr 19. The exon/intron organization of the human CD5 and CD6 genes was very similar, differing in the size of intron 1 and the number of exons coding for their cytoplasmic regions. While several isoforms, resulting from alternative splicing of the cytoplasmic exons, have been reported for CD6, we only found evidence of a cytoplasmic tailless CD5 isoform. The conserved structure of the CD5 and CD6 loci, both in mouse and human genomes, supports the notion that the two genes may have evolved from duplication of a primordial gene. The existence of a gene complex for the SRCR superfamily on human Chr 11q (and mouse Chr 19) still remains to be disclosed.     

Organization of the mouse microfibril-associated glycoprotein-2 (MAGP-2) gene

A 1.4-kb EST clone encoding mouse microfibril-associated glycoprotein-2 (MAGP-2), identified by its similarity with the reported human cDNA, was used to screen a mouse 129 genomic bacterial artificial chromosome (BAC) library. The mouse gene contains 10 exons spanning 16 kb, located on the distal region of Chromosome (Chr) 6. The exons range in size from 24 to 963 bp, with the ATG located in exon 2. The tenth and largest exon contains 817 bp of 3′ untranslated sequence, including a B2 repetitive element. Northern analysis demonstrates abundant expression of MAGP-2 mRNA in skeletal muscle, lung, and heart. Sequence analysis of additional cDNA clones suggests that the two mRNA forms of MAGP-2 in the mouse arise from alternative polyadenylation site usage. The promoter does not contain an obvious TATA box, and the sequence surrounding the start site does not conform to the consensus for an initiator promoter element. Additionally, the mouse promoter contains 22 copies of a CT dinucleotide repeat sequence located ∼155 bp 5′ to exon 1. Received: 27 August 1999 / Accepted: 2 November 1999     

Human and mouse mitochondrial orthologs of bacterial ClpX

We have determined the cDNA sequence and exon/intron structure of the human CLPX gene encoding a human ortholog of the E. coli ClpX chaperone and protease subunit. The CLPX gene comprises 14 exons and encodes a 633-amino acid-long precursor polypeptide. The polypeptide contains an N-terminal putative mitochondrial transit peptide, and expression of a full-length ClpX cDNA tagged at its C-terminus (Myc-His) shows that the polypeptide is transported into mitochondria. FISH analysis localized the CLPX gene to human Chromosome (Chr) 15q22.1-22.32. This localization was refined by radiation hybrid mapping placing the CLPX gene 4.6 cR distal to D15S159. Murine ClpX cDNA was sequenced, and the mouse Clpx locus was mapped to a position between 31 and 42 cM offset from the centromere on mouse Chr 9. Experimental observations indicate the presence of a pseudogene in the mouse genome and sequence variability between mouse ClpX cDNAs from different strains. Alignment of the human and mouse ClpX amino acid sequences with ClpX sequences from other organisms shows that they display the typical modular organization of domains with one AAA⁺ domain common to a large group of ATPases and several other domains conserved in ClpX orthologs linked by non-conserved sequences. Notably, a C-4 zinc finger type motif is recognized in human and mouse ClpX. This motif of so far unknown function is present only in a subset of the known ClpX sequences. Received: 5 April 2000 / Accepted: 14 June 2000     

Gene structure of human and mouse methylenetetrahydrofolate reductase (MTHFR)

Methylenetetrahydrofolate reductase (MTHFR) catalyzes the conversion of 5,10-methylenetetrahydrofolate to 5-methyltetrahydrofolate, a co-substrate for homocysteine remethylation to methionine. A human cDNA for MTHFR, 2.2 kb in length, has been expressed and shown to result in a catalytically active enzyme of approximately 70 kDa. Fifteen mutations have been identified in the MTHFR gene: 14 rare mutations associated with severe enzymatic deficiency and 1 common variant associated with a milder deficiency. The common polymorphism has been implicated in three multifactorial diseases: occlusive vascular disease, neural tube defects, and colon cancer. The human gene has been mapped to chromosomal region 1p36.3 while the mouse gene has been localized to distal Chromosome (Chr) 4. Here we report the isolation and characterization of the human and mouse genes for MTHFR. A human genomic clone (17 kb) was found to contain the entire cDNA sequence of 2.2 kb; there were 11 exons ranging in size from 102 bp to 432 bp. Intron sizes ranged from 250 bp to 1.5 kb with one exception of 4.2 kb. The mouse genomic clones (19 kb) start 7 kb 5′ exon 1 and extend to the end of the coding sequence. The mouse amino acid sequence is approximately 90% identical to the corresponding human sequence. The exon sizes, locations of intronic boundaries, and intron sizes are also quite similar between the two species. The availability of human genomic clones has been useful in designing primers for exon amplification and mutation detection. The mouse genomic clones will be helpful in designing constructs for gene targeting and generation of mouse models for MTHFR deficiency. Received: 28 January 1998 / Accepted: 9 April 1998     

Cloning and chromosomal mapping of the human p53-related KET gene to Chromosome 3q27 and its murine homolog Ket to mouse Chromosome 16

KET is a member of the newly discovered family of proteins that is related to the tumor suppressor p53. Here we describe the molecular cloning of a human cDNA of 4846 bp encoding a protein of 680 amino acids. The human KET protein shares 98% identity with the previously characterized rat homolog. The remarkably high degree of conservation lends support to the notion that KET proteins have important basic functions in development and differentiation. Using the GeneBridge 4 radiation hybrid panel, we have mapped KET to human Chromosome (Chr) 3q27. KET is located between the somatostatin gene SST (proximal) and the apolipoprotein D gene APOD (distal) in a region of conserved synteny to mouse Chr 16. This chromosomal region is deleted in early stages of tumorigenesis of mouse islet cell carcinomas and contains the hitherto unidentified Loh2 gene, a putative suppressor of angiogenesis. The murine homolog Ket was mapped in an interspecific backcross panel and falls into this region of loss of heterozygosity. From our mapping data we infer that KET might act as a tumor suppressor and is considered as a candidate for Loh2. Received: 30 April 1998 / Accepted: 17 July 1998     

Sequence and expression pattern of the Drosophila melanogaster mitochondrial porin gene: evidence of a conserved protein domain between fly and mouse

We have recently cloned a cDNA encoding mitochondrial porin in Drosophila melanogaster and shown its chromosomal localization (Messina et al., FEBS Lett. (1996) 384, 9–13). Such cDNA was used as a probe for screening a genomic library. We thus cloned and sequenced a 4494-bp genomic region which contained the whole gene for the mitochondrial porin or VDAC. It was found that this D. melanogaster porin gene contains five exons, numbered IA (115 bp), IB (123 bp), II (320 bp), III (228 bp) and IV (752 bp). The exons II, III and IV contain the protein coding sequence and the 3′ untranslated sequence (3′-UTR). The first base in exon II precisely corresponds to the first base of the starting ATG codon. Exon IA corresponds to the 5′-UTR sequence reported in the published cDNA sequence. Exon IB corresponds to an alternative 5′-UTR sequence, demonstrated to be transcribed by 5′-RACE experiments. The exon-intron splicing borders and the length of the exon III perfectly match a homologous internal exon detected in the mouse genes. Such exon encodes a protein domain predicted by sequence transmembrane arrangement models to contain major hydrophilic loops and it is thus suspected to have a conserved distinct function. In situ hybridization experiments confirmed the localization of the genomic clone on the chromosome 2L at region 32B3-4. Together with genomic Southern blotting at various stringencies, the same experiment did not confirm the presence of a second genetic locus on D. melanogaster chromosomes. Northern blots demonstrated that the porin gene is a housekeeping one: three messages of approx. 1.2–1.6 kbp are transcribed in every fly developmental stage that was studied. They were shown to derive by an alternative usage of different promoters and polyadenylation sites.     

The WFDC1 gene encoding ps20 localizes to 16q24, a region of LOH in multiple cancers

We previously identified ps20 protein as a secreted growth inhibitor and purified the protein from fetal rat prostate urogenital sinus mesenchymal cell conditioned medium. The rat cDNA was subsequently cloned, and ps20 was found to contain a WAP-type four-disulfide core motif, indicating it may function as a protease inhibitor. We now report cloning and characterization of the mouse ps20 gene (designated Wfdc1), the human homolog cDNA, and the human gene (designated WFDC1). Both the mouse and human WFDC1 genes consist of seven exons and encode respective ps20 proteins sharing 79.1% identity and nearly identical WAP motifs in exon 2. The WFDC1 gene was mapped by FISH analysis to human Chromosome (Chr) 16q24, an area of frequent loss of heterozygosity (LOH) previously identified in multiple cancers including prostate, breast, hepatocellular, and Wilms' tumor. Identification and characterization of the WFDC1 gene may aid in better understanding the potential role of this gene and ps20 in prostate biology and carcinogenesis.     

Molecular cloning and chromosomal assignment of the porcine 54 and 56 kDa vacuolar H(+)-ATPase subunit gene (V-ATPase)

Vacuolar proton-translocating ATPases (V-ATPase) are multisubunit enzyme complexes located in the membranes of eukaryotic cells regulating cytoplasmic pH. So far, nothing is known about the genomic organization and chromosomal location of the various subunit genes in higher eukaryotes. Here we describe the isolation and analysis of a cDNA coding for the 54- and 56-kDa porcine V-ATPase subunit alpha and beta isoforms. We have determined the genomic structure of the V-ATPase subunit gene spanning at least 62 kb on Chromosome (Chr) 4q14-q16. It consists of 14 exons with sizes ranging from 54 bp to 346 bp, with a non-coding first exon and an alternatively spliced seventh exon leading to two isoforms. The 5′ end of the V-ATPase cDNA was isolated by RACE-PCR. The V-ATPase alpha isoform mRNA, lacking the seventh exon, has an open reading frame of 1395 nucleotides encoding a hydrophilic protein of 465 amino acids with a calculated molecular mass of 54.2 kDa and a pI of 7.8, whereas the beta isoform has a length of 1449 nucleotides encoding a protein of 483 amino acids with a calculated molecular mass of 55.8 kDa. Amino acid and DNA sequence comparison revealed that the porcine V-ATPase subunit exhibits a significant homology to the VMA13 subunit of Saccharomyces cerevisiae V-ATPase complex and V-ATPase subunit of Caenorhabditis elegans. Received: 14 May 1998 / Accepted: 20 October 1998     

A Novel Zinc Finger Gene ZNF468 with Two Co-Expressional Splice Variants, ZNF468.1 and ZNF468.2

A novel human zinc finger protein encoding gene ZNF468 was obtained from a fetal brain cDNA library. By BLAST-N analysis we found two different splice variants. We termed the two splice variants ZNF468.1 and ZNF468.2. By BLAST search against the human genome database, ZNF468 was mapped to 19q13.4. The ZNF468.1 cDNA has four exons, and the ZNF468.2 cDNA has one more, between the third and fourth exon. This extra exon creates a difference between the deduced protein N-termini of the two splice variants. The ZNF468.1 cDNA is 3906 bp in length, encoding a 522a a protein, and ZNF468.2 is 4024 bp, encoding a 469-aa-protein. Both proteins contain 11 C2H2-type zinc finger motifs at their C-termini. The N-terminus of the deduced protein of ZNF468.1 has a well-conserved Krüppel-associated box (KRAB) domain that consists of KRAB boxes A and B, whereas the protein of ZNF468.2 does not have the {KRAB} domain. Tissue distribution of the ZNF468 gene indicates that the two splice variants are widely expressed in normal human tissues, except in heart and brain, and they are also co-expressional.