Abstract
The methionine salvage pathway is responsible for regenerating methionine from its derivative, methylthioadenosine. The complete set of enzymes of the methionine pathway has been previously described in bacteria. Despite its importance, the pathway has only been fully described in one eukaryotic organism, yeast. Here we use a computational approach to identify the enzymes of the methionine salvage pathway in another eukaryote, Tetrahymena thermophila. In this organism, the pathway has two fused genes, MTNAK and MTNBD. Each of these fusions involves two different genes whose products catalyze two different single steps of the pathway in other organisms. One of the fusion proteins, mtnBD, is formed by enzymes that catalyze non-consecutive steps in the pathway, mtnB and mtnD. Interestingly the gene that codes for the intervening enzyme in the pathway, mtnC, is missing from the genome of Tetrahymena. We used complementation tests in yeast to show that the fusion of mtnB and mtnD from Tetrahymena is able to do in one step what yeast does in three, since it can rescue yeast knockouts of mtnB, mtnC, or mtnD. Fusion genes have proved to be very useful in aiding phylogenetic reconstructions and in the functional characterization of genes. Our results highlight another characteristic of fusion proteins, namely that these proteins can serve as biochemical shortcuts, allowing organisms to completely bypass steps in biochemical pathways.
Highlights
The amino acid methionine and its derivative S-adenosylmethionine (SAM) are essential substrates in a variety of cellular reactions, including protein and nucleic acid methylation and polypeptide, polyamine and ethylene syntheses [1,2,3,4,5]
While the complete methionine salvage pathway has been known for some years in bacteria [4,5], only recently were all of the enzymes of the pathway characterized in an eukaryotic organism, the yeast Saccharomyces cerevisiae [9]
The methionine salvage pathway in Tetrahymena We used the sequences of the methionine salvage pathway enzymes from yeast and Bacillus subtillis as queries in blastp searches to find homologs in Tetrahymena
Summary
The amino acid methionine and its derivative S-adenosylmethionine (SAM) are essential substrates in a variety of cellular reactions, including protein and nucleic acid methylation and polypeptide, polyamine and ethylene syntheses [1,2,3,4,5]. The hormone that regulates plant growth and development, is synthesized when the aminobutyrate group of SAM is released as 1-aminocyclopropane-1carboxylic acid and oxidized to form ethylene. SAM contributes to the synthesis of polyamines by providing the source of the groups spermidine and spermine [6]. The synthesis of polyamines and ethylene from the precursor SAM results in the production of the byproduct 59-methylthioadenosine (MTA), which can be converted back to methionine via the methionine salvage pathway. While the complete methionine salvage pathway has been known for some years in bacteria [4,5], only recently were all of the enzymes of the pathway characterized in an eukaryotic organism, the yeast Saccharomyces cerevisiae [9]
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