Molecular Cloning and Functional Identification of a Pericarp- and Testa-Abundant Gene's ( AhN8DT-2 ) Promoter from Arachis hypogaea .
Yasir SharifYuhui ZhuangWenpin XieChong ZhangKun ChenYe DengYuting ChenHuiwen FuLihui WangXiangyu ChenWeijian ZhuangHua ChenPublished in: International journal of molecular sciences (2024)
Cultivated peanut ( Arachis hypogaea L.) is a key oil- and protein-providing legume crop of the world. It is full of nutrients, and its nutrient profile is comparable to that of other nuts. Peanut is a unique plant as it showcases a pegging phenomenon, producing flowers above ground, and after fertilization, the developing peg enters the soil and produces seeds underground. This geocarpic nature of peanut exposes its seeds to soil pathogens. Peanut seeds are protected by an inedible pericarp and testa. The pericarp- and testa-specific promoters can be effectively used to improve the seed defense. We identified a pericarp- and testa-abundant expression gene ( AhN8DT-2 ) from available transcriptome expression data, whose tissue-specific expression was further confirmed by the qRT-PCR. The 1827bp promoter sequence was used to construct the expression vector using the pMDC164 vector for further analysis. Quantitative expression of the GUS gene in transgenic Arabidopsis plants showed its high expression in the pericarp. GUS staining showed a deep blue color in the pericarp and testa. Cryostat sectioning of stained Arabidopsis seeds showed that expression is only limited to seed coat (testa), and staining was not present in cotyledons and embryos. GUS staining was not detected in any other tissues, including seedlings, leaves, stems, and roots, except for some staining in flowers. Under different phytohormones, this promoter did not show an increase in expression level. These results indicated that the AhN8DT-2 promoter drives GUS gene expression in a pericarp- and testa-specific manner. The identified promoter can be utilized to drive disease resistance genes, specifically in the pericarp and testa, enhancing peanut seed defense against soil-borne pathogens. This approach has broader implications for improving the resilience of peanut crops and other legumes, contributing to sustainable agricultural practices and food security.
Keyphrases
- poor prognosis
- gene expression
- dna methylation
- transcription factor
- binding protein
- genome wide
- healthcare
- climate change
- risk assessment
- machine learning
- public health
- heavy metals
- copy number
- depressive symptoms
- single cell
- artificial intelligence
- single molecule
- mass spectrometry
- human health
- electronic health record
- global health
- protein protein
- gram negative