Constraints on intron evolution in the gene encoding the myosin alkali light chain in Drosophila.

Abstract

Abstract Interspecific comparisons of intron sequences reveal conserved blocks of invariant nucleotides and several other departures from the strictly neutral model of molecular evolution. To distinguish the past action of evolutionary forces in introns known to have regulatory information, we examined nucleotide sequence variation at 991 sites in a random sample of 16 Drosophila melanogaster alleles of the gene encoding the myosin alkali light chain (Mlc1). The Mlc1 gene of D. melanogaster encodes two MLC1 isoforms via developmentally regulated alternative pre-mRNA splicing. Analyses of these data reveal that introns 4 and 5, which flank the alternatively spliced exon 5, have reduced levels of both intraspecific polymorphism and interspecific divergence relative to intron 3. No polymorphism was observed in any of the exons examined in D. melanogaster. A genealogical analysis clearly demonstrates the occurrence of intragenic recombination in the ancestral history of Mlc1. Recombination events are estimated to be 13 times more likely than mutation events over the span of the sequenced region. Although there is little evidence for pairwise linkage disequilibrium in the Mlc1 region, higher order disequilibrium does seem to be present in the 5' half of the portion of the gene that was examined. Predictions of the folding free energy of the pre-mRNA reveal that sampled alleles have a significantly higher (less stable) free energy than do randomly permuted sequences. These results are consistent with the hypothesis that introns surrounding an alternatively spliced exon are subjected to additional constraints, perhaps due to specific aspects of secondary structure required for appropriate splicing of the pre-mRNA molecule.