Abstract
As with other environmental stresses, cold stress limits plant growth, geographical distribution, and agricultural productivity. CBF/DREB (CRT-binding factors/DRE-binding proteins) regulate tolerance to cold/freezing stress across plant species. ICE (inducer of CBF expression) is regarded as the upstream inducer of CBF expression and plays a crucial role as a main regulator of cold acclimation. Snow lotus (Saussurea involucrata) is a well-known traditional Chinese herb. This herb is known to have greater tolerance to cold/freezing stress compared to other plants. According to transcriptome datasets, two putative ICE homologous genes, SiICE1 and SiICE2, were identified in snow lotus. The predicted SiICE1 cDNA contains an ORF of 1506 bp, encoding a protein of 501 amino acids, whereas SiICE2 cDNA has an ORF of 1482 bp, coding for a protein of 493 amino acids. Sequence alignment and structure analysis show SiICE1 and SiICE2 possess a S-rich motif at the N-terminal region, while the conserved ZIP-bHLH domain and ACT domain are at the C-terminus. Both SiICE1 and SiICE2 transcripts were cold-inducible. Subcellular localization and yeast one-hybrid assays revealed that SiICE1 and SiICE2 are transcriptional regulators. Overexpression of SiICE1 (35S::SiICE1) and SiICE2 (35S::SiICE2) in transgenic Arabidopsis increased the cold tolerance. In addition, the expression patterns of downstream stress-related genes, CBF1, CBF2, CBF3, COR15A, COR47, and KIN1, were up-regulated when compared to the wild type. These results thus provide evidence that SiICE1 and SiICE2 function in cold acclimation and this cold/freezing tolerance may be regulated through a CBF-controlling pathway.
Highlights
In contrast to animals, plants are not able to move to a suitable environment in order to survive
Our studies revealed that SiICE1 and SiICE2 of snow lotus play an important role as positive regulators in cold acclimation
The full-length cDNA of SiICE1 contains 1506 bps, encoding a protein of 501 amino acids with the molecular weight (MW) of 54.3 kDa and a pI of 5.81, whereas cDNA of SiICE2 is composed of 1482 bps, coding for a protein of 493 amino acids, MW of 53.2 kDa, and a pI of 5.28
Summary
Plants are not able to move to a suitable environment in order to survive. COR15A, COR15B, and COR47 were identified to be cold-related genes These genes were further proved to have the capacity to increase plant tolerance to cold/freezing stress [18,19,20]. Overexpression of AtICE2 (superHALF2-ICE2) transgenic Arabidopsis exhibits increased tolerance to cold/freezing treatment (4 ◦C acclimation, following −20 ◦C stress) when compared to the wild type. Based on re-assembled snow lotus transcriptome datasets, we identified two putative ICE homologous genes, SiICE1 and SiICE2, which were revealed to be phylogenetically similar to other plant ICE genes We isolated these two genes and functionally characterized their roles in cold tolerance by overexpressing them in 35S::SiICE1 (L7 and L14) and 35S::SiICE2 (L10 and L17) transgenic Arabidopsis. Our studies revealed that SiICE1 and SiICE2 of snow lotus play an important role as positive regulators in cold acclimation
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