Human erythroid 5-aminolevulinate synthase. Gene structure and species-specific differences in alternative RNA splicing.

Erythroid 5-aminolevulinate synthase (ALAS) is expressed exclusively in differentiating erythroid cells as the principal isoform of the enzyme to catalyze the first step of the heme biosynthetic pathway. The human gene encoding this isozyme was isolated from a cosmid library, and its structure was characterized with restriction mapping followed by sequencing of fragments. The gene is 22 kilobases long and has 11 exons. Exon 2 encodes the N-terminal signal sequence required for mitochondrial import, exons 3 and 4 encode a variable portion of the N-terminal end, and exons 5-11 the highly conserved C-terminal portion of the mature protein, respectively. Enzymatic amplification of human reticulocyte RNA using PCR techniques revealed two erythroid ALAS mRNA transcripts predicted to encode both the prototypical 64-kDa isoform as well as a novel smaller isoform with a deletion of 37 amino acids near the N terminus. The two mRNA isoforms are generated by alternative splicing of exon 4 and are expressed in fetal erythroid cells as well as at all stages of erythroid development tested, so that there is no evidence of differentiation-specific regulation of exon 4 splicing. However, striking species-specific differences were observed in that alternative splicing of exon 4 was found in man but not dog or mouse; also, the previously described alternative splicing within exon 3 in mouse was not observed in man. This transcript heterogeneity suggests the existence of erythroid ALAS protein isoforms with potentially distinct functional or regulatory roles. The occurrence of species-specific splicing in the least conserved region of the enzyme may reflect another mechanism of gene evolution in eukaryotes.