The alternative exons 1 of the mouse aromatase cytochrome P-450 gene

Aromatase cDNA clones were isolated from cDNA libraries of mouse hypothalamus, amygdala and ovary. Analysis of the nucleotide sequences of the 5′ regions of the obtained cDNAs suggested that the mouse aromatase gene is tissue-specifically regulated by alternative exons 1. There were obvious differences between the 5′ regions of the brain and ovary aromatase cDNAs, but no difference was found between the sequences of the hypothalamus and amygdala ones. We further isolated a mouse genomic DNA clone containing brain- and ovary-specific exons 1. The brain specific exons 1 and their promoters were highly homologous in the human and mouse aromatase genes. In contrast there were several differences in the sequences among the promoter regions of the ovary-specific exons 1 of the mouse, human and rat aromatase genes, significant homology between their sequences was also observed. The present results demonstrate that expression of the mouse aromatase gene is also tissue-specifically regulated through the use of alternative exons 1 and promoters, as reported for man.     

Nonconservative utilization of aldolase A alternative promoters

Recently, analysis of the sequence and expression of the human aldolase A gene revealed the unique arrangement of three tandem promoters and exons preceding a common coding sequence. A muscle-specific promoter (M) and two flanking widely used promoters (N and H) produce mRNA species which, in their mature forms, differ only in the sequence of their 5'-untranslated regions. We have isolated and investigated the expression of a mouse aldolase A gene. This mouse gene represents a functional gene by sequence analysis, recombinational screening, and by transfection into C2C12 cells. Although there is a high degree of sequence similarity between the mouse and the human gene in the region of the alternative first exons, we have been unable to detect a functional utilization of the 5'-most promoter (N) in the mouse. Steady state mRNAs isolated from a variety of adult tissues and cultured cells were analyzed by RNase protection and primer extension to identify first exon utilization. Consistent with previous reports, exon M is found only in skeletal muscle and exon H, the "housekeeping" exon, is utilized in every tissue where aldolase A is expressed. Under identical conditions we fail to see any evidence of the N exon. Therefore, although sequence homology exists between rodents and primates in the N region, the absence of selective pressure to preserve its primate pattern of expression may have resulted in functional promoter extinction.     

Alternative intronic promoters in development and disease

Approximately 20,000 mammalian genes are estimated to encode between 250 thousand and 1 million different proteins. This enormous diversity of the mammalian proteome is caused by the ability of a single-gene locus to encode multiple protein isoforms. Protein isoforms encoded by one gene locus can be functionally distinct, and they can even have antagonistic functions. One of the mechanisms involved in creating this proteome complexity is alternative promoter usage. Alternative intronic promoters are located downstream from their canonical counterparts and drive the expression of alternative RNA isoforms that lack upstream exons. These upstream exons can encode some important functional domains, and proteins encoded by alternative mRNA isoforms can be thus functionally distinct from the full-length protein encoded by canonical mRNA isoforms. Since any misbalance of functionally distinct protein isoforms is likely to have detrimental consequences for the cell and the whole organism, their expression must be precisely regulated. Misregulation of alternative intronic promoters is frequently associated with various developmental defects and diseases including cancer, and it is becoming increasingly clear that this phenomenon deserves more attention.