Molecular cloning and characterization of a novel ice gene from Capsella bursa-pastoris

Traditional Uses, Bioactive Compounds, and New Findings on Pharmacological, Nutritional, Cosmetic and Biotechnology Utility of Capsella bursa-pastoris

Capsella bursa-pastoris (L.) Medik. (shepherd's purse) is a medicinal plant recently introduced to European Pharmacopoeia. The main active compounds responsible for the activity profile of the raw material are flavonoids, phenolic acids, amino acids, phytosterols, vitamins and bioelements. This species is known for its properties supporting the functioning of the digestive system and antihemorrhagic properties in the ethnomedicine of Far Eastern countries. Modern research confirms these directions of activity. Additionally, the latest studies prove the anti-inflammatory, antioxidant, antibacterial, antifungal, acetylcholinesterase and anticancer properties and supportive action in the treatment of gynecological diseases. Shepherd's purse herb also has a strong position as an edible plant due to the growing interest in this plant as "healthy food". The protective, softening, antibacterial and antioxidant properties of sprout and herb extracts are useful in the production of modern cosmetics. Moreover, C. bursa-pastoris is valuable thanks to phytoremediation properties and the numerous practical uses in biotechnology for the creation of new resistant varieties of crop plants from the Brassicaceae family.

Zoysia japonica MYC type transcription factor ZjICE1 regulates cold tolerance in transgenic Arabidopsis

ICE1 (Inducer of CBF Expression 1) is a regulator of cold-induced transcriptome, which plays an important role in plant cold response pathway. To enhance the cold tolerance of Zoysia japonica, one of the warm-season turfgrasses, it is helpful to understand the cold response mechanism in Zoysia japonica. We identified stress-responsive ZjICE1 from Zoysia japonica and characterized its function in cold stress. Our results showed that ZjICE1 shared the typical feature of ICE homolog proteins belonging to a nucleic protein. Transactivation activity assay revealed that ZjICE1 bound to the MYC cis-element in the ZjDREB1's promotor. The ZjICE1 overexpressed transgenic Arabidopsis showed enhanced tolerance to cold stress with an increases in SOD, POD, and free proline content and reduction in MDA content. They also induced the transcripts abundance of cold-responsive genes (CBF1, CBF2, CBF3, COR47A, KIN1, and RD29A) after cold treatment. These results suggest that ZjICE1 is a positive regulator in Zoysia japonica plant during cold stress and can be a useful gene for the molecular breeding program to develop the cold tolerant zoysiagrass. Furthermore, the ZjICE1 also conferred resistance to salt and drought stresses, providing the better understanding of the basic helix-loop-helix (bHLH) gene family in abiotic stress responses.

Chinese wild-growing Vitis amurensis ICE1 and ICE2 encode MYC-type bHLH transcription activators that regulate cold tolerance in Arabidopsis

Winter hardiness is an important trait for grapevine breeders and producers, so identification of the regulatory mechanisms involved in cold acclimation is of great potential value. The work presented here involves the identification of two grapevine ICE gene homologs, VaICE1 and VaICE2, from an extremely cold-tolerant accession of Chinese wild-growing Vitis amurnensis, which are phylogenetically related to other plant ICE1 genes. These two structurally different ICE proteins contain previously reported ICE-specific amino acid motifs, the bHLH-ZIP domain and the S-rich motif. Expression analysis revealed that VaICE1 is constitutively expressed but affected by cold stress, unlike VaICE2 that shows not such changed expression as a consequence of cold treatment. Both genes serve as transcription factors, potentiating the transactivation activities in yeasts and the corresponding proteins localized to the nucleus following transient expression in onion epidermal cells. Overexpression of either VaICE1 or VaICE2 in Arabidopsis increase freezing tolerance in nonacclimated plants. Moreover, we show that they result in multiple biochemical changes that were associated with cold acclimation: VaICE1/2-overexpressing plants had evaluated levels of proline, reduced contents of malondialdehyde (MDA) and decreased levels of electrolyte leakage. The expression of downstream cold responsive genes of CBF1, COR15A, and COR47 were significantly induced in Arabidopsis transgenically overexpressing VaICE1 or VaICE2 upon cold stress. VaICE2, but not VaICE1 overexpression induced KIN1 expression under cold-acclimation conditions. Our results suggest that VaICE1 and VaICE2 act as key regulators at an early step in the transcriptional cascade controlling freezing tolerance, and modulate the expression levels of various low-temperature associated genes involved in the C-repeat binding factor (CBF) pathway.

The constitutive expression of Chrysanthemum dichrum ICE1 in Chrysanthemum grandiflorum improves the level of low temperature, salinity and drought tolerance

The quality and productivity of chrysanthemum are severely compromised by various abiotic stresses. Here, we describe the isolation of CdICE1 from Chrysanthemum dichrum using RACE PCR, which shared identical nucleotide of ICE1 ORF from Chrysanthemum grandiflorum variety 'Jinba'. CdICE1 contains a conserved bHLH domain, a nuclear localization domain, a S-rich motif and a ACT domain. The constitutive expression of CdICE1 in C. grandiflorum improved the tolerance of C. grandiflorum to low temperature/freezing, drought and salinity. When the transgene was inserted in the antisense direction, the expression of the endogenous ICE1 gene was down-regulated, and the level of the plant's sensitivity to abiotic stress increased. The level of expression of CgDREBa and CgDREBb, activities of superoxide dismutase and peroxidase and the proline content were enhanced in the sense transgenic lines, and lowered in the antisense ones under stresses. In conclusion, CdICE1 represents a promising candidate for a biotechnological approach to improve the level of crop abiotic stress tolerance.

KEY MESSAGE

Overexpression of CdICE1 in C. grandiflorum confers the stress tolerance via its regulation of CgDREB involved in the oxidative and osmotic homeostasis pathways.