Genomic characterization of the human and mouse protein tyrosine phosphatase-1B genes

PTP-1B is a ubiquitously expressed intracellular protein tyrosine phosphatase (PTP) that has been implicated in the negative regulation of insulin signaling. Mice deficient in PTP-1B were found to have an enhanced insulin sensitivity and a resistance to diet-induced obesity. Interestingly, the human PTP-1B gene maps to chromosome 20 q13.1 in a region that has been associated with diabetes and obesity. Although there has been a partial characterization of the 3′ end of the human PTP-1B gene, the complete gene organization has not been described. In order to further characterize the PTP-1B gene, we have cloned and determined the genomic organization for both the human and mouse PTP-1B genes including the promoter. The human gene spans >74 kb and features a large first intron of >54 kb; the mouse gene likewise contains a large first intron, although the exact size has not been determined. The organization of the human and mouse PTP-1B genes is identical except for an additional exon at the 3′ end of the human that is absent in the mouse. The mouse PTP-1B gene maps to the distal arm of mouse chromosome 2 in the region H2-H3. This region is associated with a mouse obesity quantitiative trait locus (QTL) and is syntenic with human chromosome 20. The promoter region of both the human and mouse genes contain no TATA box but multiple GC-rich sequences that contain a number of consensus SP-1 binding sites. The basal activity of the human PTP-1B promoter was characterized in Hep G2 cells using up to 8 kb of 5′ flanking sequence. A 432 bp promoter construct immediately upstream of the ATG was able to confer maximal promoter activity. Within this sequence, there are at least three GC-rich sequences and one CCAAT box, and deletion of any of these elements results in decreased promoter activity. In addition, the promoter in a number of mouse strains contains, 3.5 kb upstream of the start codon, an insertion of an intracisternal a particle (IAP) element that possibly could alter the expression of PTP-1B mRNA in these strains.     

The rat peptidylarginine deiminase-encoding gene: structural analysis and the 5'-flanking sequence.

Genomic clones of the rat peptidylarginine deiminase (PAD)-encoding gene (PAD) were isolated, and the gene organization was analyzed by restriction mapping and nucleotide sequencing. The PAD spans more than 50 kb and contains 16 exons and 15 introns. The lengths of the introns from 0.5 kb to more than 16.5 kb. A 1.7-kb sequence in the 5'-flanking region was determined. S1 nuclease mapping revealed two putative cap sites 79 and 81 bp upstream from the N-terminal ATG codon of PAD, which had been determined by amino acid sequence analysis. This ATG was confirmed to be the translation start site, since no other ATG codon was found in the open reading frame downstream from the cap sites. The 5'-flanking sequence contains four potential SP1-binding sites, a putative Pit-1/GHF-1-binding site, four short sequences either identical or homologous to the sequences in the promoter regions of rat or human growth hormone encoding genes, as well as a sequence similar to an estrogen-responsive element. However, neither a typical TATAA box, nor CCAAT box is present. These results provide important clues for elucidating the mechanism of female-specific and/or sex cycle-dependent gene expression.     

Human thymidylate synthase gene: isolation of phage clones which cover a functionally active gene and structural analysis of the region upstream from the translation initiation codon

Two genomic DNA fragments partially encoding human thymidylate synthase (TS) [EC 2.1.1.45] were previously cloned in lambda phage from the mouse cell transformant, but had no transforming activity on mouse TS-negative mutant cells. In this study, an additional genomic DNA for human TS was cloned and demonstrated to have the transforming activity in combination with one of the two previously cloned DNAs and to produce human TS mRNA. The two transforming genomic DNAs overlapped and covered a region of 23 kb in total. Using fragments from one of these DNAs, the structure of the 1.2-kb region around the ATG initiator codon of the TS gene was analyzed in relation to regulatory sequences of the gene. Sequence determination demonstrated the presence of an unusual inverted repeat consisting of a triple tandem repeat of a 28-bp sequence and an inverted sequence of the same length. These sequences can form three possible, stable, stem-loop structures, which may be interconvertible. Based on S1 nuclease mapping data and a line of circumstantial evidence, we deduced two major mRNA cap sites within the inverted sequence. Comparison of the human and mouse sequences upstream from the ATG initiator codon revealed many significant blocks of sequence homology, especially in the regions around the deduced cap sites.