Abstract
Homospermidine synthase (HSS), the first pathway-specific enzyme of pyrrolizidine alkaloid biosynthesis, is known to have its origin in the duplication of a gene encoding deoxyhypusine synthase. To study the processes that followed this gene duplication event and gave rise to HSS, we identified sequences encoding HSS and deoxyhypusine synthase from various species of the Convolvulaceae. We show that HSS evolved only once in this lineage. This duplication event was followed by several losses of a functional gene copy attributable to gene loss or pseudogenization. Statistical analyses of sequence data suggest that, in those lineages in which the gene copy was successfully recruited as HSS, the gene duplication event was followed by phases of various selection pressures, including purifying selection, relaxed functional constraints, and possibly positive Darwinian selection. Site-specific mutagenesis experiments have confirmed that the substitution of sites predicted to be under positive Darwinian selection is sufficient to convert a deoxyhypusine synthase into a HSS. In addition, analyses of transcript levels have shown that HSS and deoxyhypusine synthase have also diverged with respect to their regulation. The impact of protein-protein interaction on the evolution of HSS is discussed with respect to current models of enzyme evolution.
Highlights
Plants produce an amazing diversity of secondary metabolites of which several classes of compounds occur only in individual plant lineages
Using cDNA preparations of Ipomoea neei and M. quinquefolia of various tissues, we were able to identify two fragments of each species showing a high degree of identity to the previously identified cDNA encoding the deoxyhypusine synthase (DHS) of Ipomoea hederifolia (Reimann et al, 2004)
We were able to amplify the full-length cDNA sequences coding for DHS of I. meyeri and I. neei and Homospermidine synthase (HSS) of I. meyeri and I. hederifolia with primers that had been designed for the amplification of the open reading frame (ORF) of the DHS of I. hederifolia and the HSS of I. neei
Summary
Plants produce an amazing diversity of secondary metabolites of which several classes of compounds occur only in individual plant lineages. Secondary metabolism and the enzymes involved therein are suitable for the study of molecular evolutionary mechanisms of adaptation and enzyme evolution in particular (Pichersky and Gang, 2000; Grotewold, 2005). In this regard, pyrrolizidine alkaloid (PA) biosynthesis has proved to be a powerful model system (Ober, 2005, 2010; Ober and Kaltenegger, 2009).
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