Gene structure and promoter analysis of the human GJB6 gene encoding connexin 30

Connexins (Cx) are the protein subunits of gap junctions, which play an important role in cell-to-cell communication. We characterized the genomic structure of the human GJB6 gene, encoding connexin 30 (C x 30), and showed that it differs from most connexin-encoding genes. GJB6 presents six different exons, some of which can be alternatively spliced. We also mapped a basal promoter sequence active in a human keratinocyte cell line which responds to the activation of the EGF receptor. One of the non-encoding exons of GJB6, which has been described in brain C x 30 cDNA, was not found in cDNA obtained from human keratinocytes, suggesting tissue-specific splicing.     

Role of connexin37 and connexin40 in vascular development

Mice lacking both connexin37 (Cx37) and connexin40 (Cx40), gap junction proteins expressed in vascular endothelium, die perinatally with pronounced vascular abnormalities. Early vasculogenesis proceeds normally, but by E18.5 Cx37(-/-)Cx40(-/-) animals display vessel dilatation and congestion as well as localized hemorrhages in skin, testis, intestines, and lungs. Abnormal vascular channels are present in the testis, often forming cavernous hemangioma-like defects. Unusually large, distended vessels are also present in the submucosa and lamina propria of the intestine. Ablation of Cx40 has a greater effect on endothelial dye-transfer than ablation of Cx37, and the effect of Cx40 ablation is age-dependent. Only in embryonic aortas lacking both Cx37 and Cx40 is there a complete loss of endothelial coupling. Surprisingly, elimination of Cx40 results in a large drop in aortic endothelial Cx37 on western blots, and deletion of Cx37 also reduces endothelial Cx40 levels. In contrast, in the medial layer, both Cx37 and Cx43 increase when Cx40 is ablated. These studies indicate that Cx37 and Cx40 are collectively critical for endothelial communication and provide evidence of an important role for gap junctions in vascular development. In addition, Cx37 and Cx40 appear to be mutually dependent on each other for normal expression in vascular endothelium.     

Sequence and structure of the mouse connexin45 gene

The connexin45 (Cx45) gene was cloned from a mouse genomic Bacterial Artificial Chromosome library. Approximately 8.4 kb of the genomic DNA was sequenced, and the structure of the Cx45 gene was determined. The mouse Cx45 gene is composed of 3 exons, with the entire coding sequence contained within exon III (EMBL Accession Number AJ300716). This structure is unique for the Cx45 gene, since all other members of the connexin family have only two exons. In addition, computer analysis reveals a potential TATA box and two putative AP-1 binding sites in the 5 region of the gene. Sequence alignment with connexin43 indicates substantial homology in the intronic sequences upstream of the 3 exons of the two genes, suggesting that the Cx45 gene is inherently similar to the rest of the connexin family, and that it probably evolved from an ancestor common to the other connexins.     

Genomic structure and promoter analysis of the mouse neutral ceramidase gene

We report here the molecular cloning of the mouse neutral ceramidase gene and its promoter analysis. The gene, composed of 27 exons ranging in size from 40 to 292 bp, spans more than 70 kb. Analysis of the 5(')-flanking region of the ceramidase genes revealed that the first exon of the gene of mouse liver was exactly the same as that of mouse kidney and Swiss 3T3 fibroblasts but completely different from that of mouse brain. The putative promoter regions of liver and brain ceramidase genes contained several well-characterized promoter elements such as GATA-2, C/EBP, and HNF3beta but lacked TATA and CAAT boxes, a typical feature of a housekeeping gene, although the expression is regulated in a tissue-specific manner. Interestingly, a GC box was exclusively found in the putative promoter of mouse liver whereas potential AP1 and AP4 binding sites were present in that of mouse brain. By a luciferase reporter gene assay, it was shown that the GC-rich region, which exists just upstream of the first exon, conferred the promoter activity in Swiss 3T3 cells.     

Mouse connexin 45: genomic cloning and exon usage

Connexin 45 is a gap junction protein that is prominent in early embryos and is widely expressed in many mature cell types. To elucidate its gene structure, expression, and regulation, we isolated mouse Cx45 genomic clones. Alignment of the genomic DNA and cDNA sequences revealed the presence of three exons and two introns. The first two exons contained only 5' untranslated sequences, while exon 3 contained the remaining 5' UTR, the entire coding region, and the 3' UTR. An RT-PCR with exon-specific primers was utilized to examine exon usage in F9 mouse embryonal carcinoma cells and adult mouse tissues. In all samples, PCR products amplified using exon 2/exon 3 or exon 3/exon 3 primer pairs were much more abundant than products produced using exon 1/exon 2 or exon 1/exon 3 primer pairs, suggesting that Cx45 mRNAs containing exon 1 were relatively rare compared with mRNAs containing the other exons. Rapid amplification of cDNA ends (5'-RACE) was performed using antisense primers from within exon 3 and template RNA prepared from F9 cells or from adult mouse kidney. We obtained multiple RACE products from both templates, including products that contained all three exons and were spliced identically to the cDNA. However, clones were also isolated (from kidney) that began within the region previously identified as intron 1 and continued upstream with a sequence identical to the cDNA, including splicing to exon 3. These results show that mouse Cx45 has a gene structure that differs from that of previously studied connexins and allows the production of heterogeneous Cx45 mRNAs with differing 5' UTRs. These differences might contribute to regulation of Cx45 protein levels by modulating mRNA stability or translational efficiency.