Abstract
Dehydrins, plant proteins that are upregulated during dehydration stress conditions, have modular sequences that can contain three conserved motifs (the Y-, S-, and K-segments). The presence and order of these motifs are used to classify dehydrins into one of five architectures: Kn, SKn, KnS, YnKn, and YnSKn, where the subscript n describes the number of copies of that motif. In this study, an architectural and phylogenetic analysis was performed on 426 dehydrin sequences that were identified in 53 angiosperm and 3 gymnosperm genomes. It was found that angiosperms contained all five architectures, while gymnosperms only contained Kn and SKn dehydrins. This suggests that the ancestral dehydrin in spermatophytes was either Kn or SKn, and the Y-segment containing dehydrins first arose in angiosperms. A high-level split between the YnSKn dehydrins from either the Kn or SKn dehydrins could not be confidently identified, however, two lower level architectural divisions appear to have occurred after different duplication events. The first likely occurred after a whole genome duplication, resulting in the duplication of a Y3SK2 dehydrin; the duplicate subsequently lost an S- and K- segment to become a Y3K1 dehydrin. The second split occurred after a tandem duplication of a Y1SK2 dehydrin, where the duplicate lost both the Y- and S- segment and gained four K-segments, resulting in a K6 dehydrin. We suggest that the newly arisen Y3K1 dehydrin is possibly on its way to pseudogenization, while the newly arisen K6 dehydrin developed a novel function in cold protection.
Highlights
Due to their sessile nature, plants have evolved various methods for responding to biotic and abiotic stresses
After performing the filtering and iterative searching as described in the Material and Methods, a total of 426 dehydrin sequences were collected from 56 spermatophyte genomes
There are five main mechanisms that result in gene duplication: whole genome duplication (WGD), tandem duplication, transposon-mediated duplication, segmental duplication, and retroduplication [68,69]
Summary
Due to their sessile nature, plants have evolved various methods for responding to biotic and abiotic stresses. Contact with abiotic (environmental) stresses can cause severe damage to plants, which can result in crop loss, growth impairment, and even death [1,2]. Dehydration, itself a significant abiotic stress in plants, can take many forms, such as drought, cold, and high salinity. Under such conditions, plants face numerous problems, including mechanical impairment, alterations in turgor pressure, and loss of cell integrity [1]. A group of proteins, known as dehydration proteins (dehydrins), have their expression correlated with dehydration stress and protection [3]. Dehydrins are a member of a protein family known as the late
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