Evolution of l‐DOPA 4,5‐dioxygenase activity allows for recurrent specialisation to betalain pigmentation in Caryophyllales
Citations Over TimeTop 10% of 2019 papers
Abstract
Summary The evolution of l ‐ DOPA 4,5‐dioxygenase activity, encoded by the gene DODA , was a key step in the origin of betalain biosynthesis in Caryophyllales. We previously proposed that l ‐ DOPA 4,5‐dioxygenase activity evolved via a single Caryophyllales‐specific neofunctionalisation event within the DODA gene lineage. However, this neofunctionalisation event has not been confirmed and the DODA gene lineage exhibits numerous gene duplication events, whose evolutionary significance is unclear. To address this, we functionally characterised 23 distinct DODA proteins for l ‐ DOPA 4,5‐dioxygenase activity, from four betalain‐pigmented and five anthocyanin‐pigmented species, representing key evolutionary transitions across Caryophyllales. By mapping these functional data to an updated DODA phylogeny, we then explored the evolution of l ‐ DOPA 4,5‐dioxygenase activity. We find that low l ‐ DOPA 4,5‐dioxygenase activity is distributed across the DODA gene lineage. In this context, repeated gene duplication events within the DODA gene lineage give rise to polyphyletic occurrences of elevated l ‐ DOPA 4,5‐dioxygenase activity, accompanied by convergent shifts in key functional residues and distinct genomic patterns of micro‐synteny. In the context of an updated organismal phylogeny and newly inferred pigment reconstructions, we argue that repeated convergent acquisition of elevated l ‐ DOPA 4,5‐dioxygenase activity is consistent with recurrent specialisation to betalain synthesis in Caryophyllales.
Related Papers
- → Relationship between color and betalain content in different thermally treated beetroot products(2020)91 cited
- → Interaction of soy protein isolate fibrils with betalain from red beetroots: Morphology, spectroscopic characteristics and thermal stability(2020)80 cited
- → Effects of Gamma Irradiation on Physicochemical Properties of Red Beet and Stability of Betalain in the Red Beet (Beta vulgaris L.)(2007)14 cited
- → Biosynthesis and Regulation of Betalains in Red Beet(2012)4 cited
- → Hectorella: A member of the betalain-suborderChenopodiineae of the orderCentrospermae(1978)19 cited