Genomic organisation of the spinocerebellar ataxia type 7 (SCA7) gene responsible for autosomal dominant cerebellar ataxia with retinal degeneration

Autosomal dominant cerebellar ataxia with retinal degeneration (ADCA type II) is a progressive neurodegenerative disorder caused by a CAG expansion in the spinocerebellar ataxia 7 (SCA7) gene. Here, we describe the genomic organisation of the human SCA7 gene. The exon-intron boundaries were identified by sequencing plasmid subclones of a P1 artificial chromosome (PAC) clone containing the entire SCA7 gene. We found 13 exons, ranging in size from 69 to 979 bp, with all exon-intron boundaries following the GT-AG rule. The ATG initiation codon at position 554 of the cDNA occurs in exon 3 at position 12 and the coding region extends to the first five codons of exon 13, with the CAG repeat being located in exon 3 starting at codon 30. The intron sizes were determined by long-distance polymerase chain reaction with primers from neighbouring exons and by restriction mapping of the SCA7 PAC clone. The introns varied in size from 233 bp to about 40 kb, resulting in an overall size estimate for the SCA7 gene of 140 kb. Sequence analysis of intron 7 (491 bp) revealed a polymorphic GT/AC repeat, a useful intragenic marker for SCA7 in segregation studies.     

Structural organization and mutational analysis of the human uncoupling protein-2 (hUCP2) gene

Uncoupling proteins (UCPs) are mitochondrial membrane transporters which are involved in dissipating the proton electrochemical gradient thereby releasing stored energy as heat. This implies a major role of UCPs in energy metabolism and thermogenesis which when deregulated are key risk factors for the development of obesity and other eating disorders. From the three different human UCPs identified so far by gene cloning both UCP2 and UCP3 were mapped in close proximity (75-150 kb) to regions of human chromosome 11 (11q13) that have been linked to obesity and hyperinsulinaemia. At the amino acid level hUCP2 has about 55% identity to hUCP1 while hUCP3 is 71% identical to hUCP2. In this study we have deduced the genomic structure of the human UCP2 gene by PCR and direct sequence analysis. The hUCP2 gene spans over 8.7 kb distributed on 8 exons. The localization of the exon/intron boundaries within the coding region matches precisely that of the hUCP1 gene and is almost conserved in the recently discovered hUCP3 gene as well. The high degree of homology at the nucleotide level and the conservation of the exon /intron boundaries among the three UCP genes suggests that they may have evolved from a common ancestor or are the result from gene duplication events. Mutational analysis of the hUCP2 gene in a cohort of 172 children (aged 7 - 13) of Caucasian origin revealed a polymorphism in exon 4 (C to T transition at position 164 of the cDNA resulting in the substitution of an alanine by a valine at codon 55) and an insertion polymorphism in exon 8. The insertion polymorphism consists of a 45 bp repeat located 150 bp downstream of the stop codon in the 3'-UTR. The allele frequencies were 0.63 and 0.37 for the alanine and valine encoded alleles, respectively, and 0.71 versus 0.29 for the insertion polymorphism. The allele frequencies of both polymorphisms were not significantly elevated in a subgroup of 25 children characterized by low Resting Metabolic Rates (RMR). So far a direct correlation of the observed genotype with (RMR) and Body Mass Index (BMI) was not evident. Expression studies of the wild type and mutant forms of UCP2 should clarify the functional consequences these polymorphisms may have on energy metabolism and body weight regulation.     

Structural organization of the gene for the alpha 1 chain of human type IV collagen

The complete exon size and distribution pattern in the gene for the alpha 1 chain of human type IV collagen was determined. Clones covering 145 kilobases (kb) of genomic DNA including 100 kb of the gene itself as well as 25 kb upstream and 20 kb downstream of the gene sequences, respectively, were isolated from lambda phage and cosmid libraries. The overall gene structure was determined by endonuclease restriction mapping and R-loop analyses and all exon sizes by nucleotide sequencing. The characterized clones contained all the coding sequences except for exon 2 whose sequence was determined after its amplification by the polymerase chain reaction. There were four gaps in the intron sequences; the exact size of the gene is unknown. The entire gene is at least 100 kb in size and contains 52 exons whose size distribution is completely different from that of the genes for fibrillar collagens. In the -Gly-X-Y- coding region there are three exons of 99, 90, and 45 base pairs (bp) each and two exons of 27, 36, 42, 51, 54, 63, and 84 bp each. The rest of the exons have sizes between 71 and 192 bp in the collagenous region. About one-half of the -Gly-X-Y- repeat coding exons start with the second base for the codon of glycine, whereas the other half starts (with two exceptions) with a complete glycine codon. The distribution of split versus unsplit codons is uneven in that the first 19 exons of the gene start with a complete codon. The gene contains repetitive sequences in several regions. A 185-nucleotide segment containing 40 copies of CCT flanked by poly(C) and poly(T) sequences was shown to be located adjacent to an exon. The gene has previously been shown to be located head-to-head to the alpha 2(IV) collagen gene at the distal end of the long arm of chromosome 13, such that the first exons of the two genes are separated by as little as 42 bp (P?schl, E., Pollner, R., and Kühn, K. (1988) EMBOJ. 7,2687-2695; Soininen, R., Huotari, M., Hostikka, S. L., Prockop, D. J., and Tryggvason, K. (1988) J. Biol. Chem. 263, 17217-17220). The results demonstrate that the human alpha 1(IV) collagen gene has a structure distinctly different from the genes for fibrillar collagens and also that it is considerably larger than any collagen gene characterized to date.     

Chromosomal Localization in Mouse and Human of the Vasoactive Intestinal Peptide Receptor Type 2 Gene: A Possible Contributor to the Holoprosencephaly 3 Phenotype

The neuropeptides vasoactive intestinal peptide (VIP) and pituitary adenylate cyclase activating polypeptide (PACAP) have been shown to act on a wide range of tissue and cell types, both in the central nervous system and in the periphery. Two distinct receptors for VIP, the VIP receptor type 1 (VIPR1) and the VIP receptor type 2 (VIPR2), have recently been cloned, each of which binds PACAP and VIP with equal affinity. We report here the chromosomal mapping of the human and mouse VIPR2 genes by fluorescencein situhybridization. The VIPR2 gene maps to the human chromosomal region 7q36.3 and to the F2 region of mouse chromosome 12. Our localization of the human gene places it in the region where the locus for the craniofacial defect holoprosencephaly type 3 (HPE3) maps. Further mapping experiments, carried out on cell lines derived from patients with HPE or HPE microforms and associated 7q deletions, have led us to redefine the distal extent of the HPE3 minimal critical region, originally characterized by Gurrieriet al.(1993,Nature Genet.3: 247–251.) The VIPR2 gene lies within this new HPE3 minimal critical region. Our results suggest that deletion of the VIPR2 gene is not the sole factor responsible for the HPE3 phenotype. However, it is possible that monosomy at the VIPR2 locus may contribute to the phenotype observed in many cases of HPE3.     

The human preproapolipoprotein C-II gene. Complete nucleic acid sequence and genomic organization

The complete nucleic acid sequence of human preproapolipoprotein (apo) C-II has been determined from 2 apoC-II clones isolated from 2 different human genomic DNA libraries. The cloned fragments were approx. 14 and 18 kb long, and sequence analysis established that the apoC-II gene consists of 3338 nucleotides containing 3 intervening sequences of 2391, 167, and 298 bases. The first intron is located within the 5'-untranslated region of apoC-II and contains 4 Alu type sequences. The second intron interrupts the codon specifying amino acid - 11 of the apoC-II signal peptide. The last intron, which contains a 38 bp sequence which is repeated 6 times, interrupts the codon specifying for amino acid +44 of the mature apolipoprotein.     

The divergent 5' ends of DPM2 mRNAs originate from the alternative splicing of two adjacent introns: characterization of the hamster DPM2 gene

Mammalian dolichol-phosphate-mannose (DPM) synthase has three subunits, DPM1, DPM2, and DPM3. In this report, an analysis of the gene and cDNAs of hamster DPM2 is presented. The CHO DPM2 gene has two special features. First, the initiation codon ATG is separated from the remainder of the coding region by intron sequences. Second, within these intron sequences the DPM2 gene contains an adjacent 3' splice site (acceptor) and a 5' splice site (donor), suggestive of a deleted exon between the first and second codons. In fact, these sites overlap by four nucleotides (nt) of AGGT. Splicing intermediates using both of these alternative splice sites were observed. This latter feature appears unique and is particularly unusual considering the relatively small size of the gene (2.7 kb) and of introns a (123 bp) and b (152 bp).