Bernhard F. Benkel

Enzyme-coding genes as molecular clocks: The molecular evolution of animal alpha-amylases

SummaryWe constructed a cDNA library for the beetle,Tribolium castaneum. This library was screened using a cloned amylase gene fromDrosophila melanogaster as a molecular probe. Beetle amylase cDNA clones were isolated from this bank, and the nucleotide sequence was obtained for a cDNA clone with a coding capacity for 228 amino acids. Both the nucleotide sequence and predicted amino acid sequence were compared to our recent results forD. melanogaster alpha-amylases, along with published sequences for other alpha-amylases. The results show that animal alpha-amylases are highly conserved over their entire length. A borader comparison, which includes plant and microbial alpha-amylase sequences, indicates that parts of the gene are conserved between prokaryotes, plants, and animals. We discuss the potential importance of this and other enzyme-coding genes for the construction of molecular phylogenies and for the study of the general question of molecular clocks in evolution.

Introns as relict retrotransposons: Implications for the evolutionary origin of eukaryotic mRNA splicing mechanisms*

A model is presented for the evolutionary origin of intron sequences within eukaryotic protein-coding genes. We propose that introns are the vestiges of transposable elements and, specifically, that they represent a novel class of retrovirus-like transposons. The attraction of the retrotransposon model is that it gives the RNA splicing mechanism a central role in the evolution of introns. There is a growing body of evidence to suggest that several aspects of splicing are intron-encoded. Consequently, it is reasonable to look for evolutionary explanations of the splicing mechanism in the context of the evolution of the intron sequences themselves. According to this model the ancestral intron genomes were replicated into RNA copies simply because of their insertion within transcriptionally active regions of the host genome. Splicing was necessary not only to minimize their negative effects on host gene expression, but also, and perhaps more importantly, to generate new copies of the intron genome free of flanking exon sequences. These spliced intron copies were then available for reverse transcription and reinsertion elsewhere in the genome. Thus, splicing can be seen as an essential step in the intron replication cycle. Most modern introns have probably lost the majority of their original genetic content and may be considered as degenerate evolutionary relicts. An exception to this degeneracy is the set of splicing signals which must be retained because of its continued importance to host cell survival.(ABSTRACT TRUNCATED AT 250 WORDS)

DNA rearrangement causes multiple changes in gene expression at the amylase locus inDrosophila melanogaster

A spontaneous null mutation at the α-amylase locus inDrosophila melanogaster was recovered from a laboratory population. The mutant strain was found to lack amylase enzyme production and to produce low, but detectable, levels of amylase mRNA. Moreover, the null strain is also lacking the glucose repression of amylase mRNA production which is seen in wild-type strains. The mutant phenotype correlates with a rearrangement in genomic DNA which, in turn, corresponds to a simple inversion in the arrangement observed most frequently in North American populations ofD. melanogaster, including the common laboratory strain, Oregon-R. These results have implications for our understanding of both the evolution of the duplicated amylase gene structure and the regulation of amylase gene expression.

Sequence and phylogenetic analysis of the SNF4/AMPK gamma subunit gene from Drosophila melanogaster

To optimize gene expression under different environmental conditions, many organisms have evolved systems which can quickly up- and down-regulate the activity of other genes. Recently, the SNF1 kinase complex from yeast and the AMP-activated protein kinase complex from mammals have been shown to represent homologous metabolic sensors that are key to regulating energy levels under times of metabolic stress. Using heterologous probing, we have cloned the Drosophila melanogaster homologue of SNF4, the noncatalytic effector subunit from this kinase complex. A sequence corresponding to the partial genomic sequence as well as the full-length cDNA was obtained, and shows that the D. melanogaster SNF4 is encoded in a 1944-bp cDNA representing a protein of 648 amino acids (aa). Southern analysis of Drosophila genomic DNA in concert with a survey of mammalian SNF4 ESTs indicates that in metazoans, SNF4 is a duplicated gene, and possibly even a larger gene family. We propose that one gene copy codes for a short (330 aa) protein, whereas the second locus codes for a longer version (<410 aa) that is extended at the carboxy terminus, as typified by the Drosophila homologue presented here. Phylogenetic analysis of yeast, invertebrate, and multiple mammalian isoforms of SNF4 shows that the gene duplication likely occurred early in the metazoan lineage, as the protein products of the different loci are relatively divergent. When the phylogeny was extended beyond the SNF4 gene family, SNF4 shares sequence similarity with other cystathionine-beta-synthase domain-containing proteins, including IMP dehydrogenase and a variety of uncharacterized Methanococcus proteins.