Your search keyword '"Hu, Songshen"' showing total 3 results

1. SlWRKY81 regulates Spd synthesis and Na+/K+ homeostasis through interaction with SlJAZ1 mediated JA pathway to improve tomato saline‐alkali resistance.

Author

Shang, Chunyu, Liu, Xiaoyan, Chen, Guo, Li, Guobin, Hu, Songshen, Zheng, Hao, Ge, Lei, Long, Yanghao, Wang, Qiaomei, and Hu, Xiaohui

Subjects

JASMONIC acid, TOMATOES, HOMEOSTASIS, PROMOTERS (Genetics), OXIDANT status, GENE families, ABIOTIC stress

Abstract

SUMMARY: Saline‐alkali stress is an important abiotic stress factor affecting tomato (Solanum lycopersicum L.) plant growth. Although the involvement of the tomato SlWRKY gene family in responses to saline‐alkali stress has been well established, the mechanism underlying resistance to saline‐alkali stress remains unclear. In this study, we investigated the role of SlWRKY81 in conferring saline‐alkali stress resistance by using overexpression and knockout tomato seedlings obtained via genetic modification. We demonstrated that SlWRKY81 improves the ability of tomato to withstand saline‐alkali stress by enhancing antioxidant capacity, root activity, and proline content while reducing malondialdehyde levels. Saline‐alkali stress induces an increase in jasmonic acid (JA) content in tomato seedlings, and the SlWRKY81 promoter responds to JA signaling, leading to an increase in SlWRKY81 expression. Furthermore, the interaction between SlJAZ1 and SlWRKY81 represses the expression of SlWRKY81. SlWRKY81 binds to W‐box motifs in the promoter regions of SlSPDS2 and SlNHX4, thereby positively regulating their expression. This regulation results in increased spermidine (Spd) content and enhanced potassium (K+) absorption and sodium (Na+) efflux, which contribute to the resistance of tomato to saline‐alkali stress. However, JA and SlJAZ1 exhibit antagonistic effects. Elevated JA content reduces the inhibitory effect of SlJAZ1 on SlWRKY81, leading to the release of additional SlWRKY81 protein and further augmenting the resistance of tomato to saline‐alkali stress. In summary, the modulation of Spd synthesis and Na+/K+ homeostasis mediated by the interaction between SlWRKY81 and SlJAZ1 represents a novel pathway underlying tomato response to saline‐alkali stress. [ABSTRACT FROM AUTHOR]

Published

2024

2. The brassinosteroid signaling component SlBZR1 promotes tomato fruit ripening and carotenoid accumulation.

Author

Meng, Fanliang, Liu, Haoran, Hu, Songshen, Jia, Chengguo, Zhang, Min, Li, Songwen, Li, Yuanyuan, Lin, Jiayao, Jian, Yue, Wang, Mengyu, Shao, Zhiyong, Mao, Yuanyu, Liu, Lihong, and Wang, Qiaomei

Subjects

FRUIT ripening, TOMATO ripening, TOMATOES, PLANT hormones, BRASSINOSTEROIDS, BIOFORTIFICATION

Abstract

The plant hormone ethylene is essential for climacteric fruit ripening, although it is unclear how other phytohormones and their interactions with ethylene might affect fruit ripening. Here, we explored how brassinosteroids (BRs) regulate fruit ripening in tomato (Solanum lycopersicum) and how they interact with ethylene. Exogenous BR treatment and increased endogenous BR contents in tomato plants overexpressing the BR biosynthetic gene SlCYP90B3 promoted ethylene production and fruit ripening. Genetic analysis indicated that the BR signaling regulators Brassinazole‐resistant1 (SlBZR1) and BRI1‐EMS‐suppressor1 (SlBES1) act redundantly in fruit softening. Knocking out SlBZR1 inhibited ripening through transcriptome reprogramming at the onset of ripening. Combined transcriptome deep sequencing and chromatin immunoprecipitation followed by sequencing identified 73 SlBZR1‐repressed targets and 203 SlBZR1‐induced targets involving major ripening‐related genes, suggesting that SlBZR1 positively regulates tomato fruit ripening. SlBZR1 directly targeted several ethylene and carotenoid biosynthetic genes to contribute to the ethylene burst and carotenoid accumulation to ensure normal ripening and quality formation. Furthermore, knock‐out of Brassinosteroid‐insensitive2 (SlBIN2), a negative regulator of BR signaling upstream of SlBZR1, promoted fruit ripening and carotenoid accumulation. Taken together, our results highlight the role of SlBZR1 as a master regulator of tomato fruit ripening with potential for tomato quality improvement and carotenoid biofortification. [ABSTRACT FROM AUTHOR]

Published

2023

3. Overexpression of FBR41 enhances resistance to sphinganine analog mycotoxin‐induced cell death and Alternaria stem canker in tomato.

Author

Shao, Zhiyong, Zhao, Yanting, Liu, Lihong, Chen, Shanshan, Li, Chuanyou, Meng, Fanliang, Liu, Haoran, Hu, Songshen, Wang, Jiansheng, and Wang, Qiaomei

Subjects

TOMATOES, TOMATO varieties, CELL death, ALTERNARIA, JASMONATE, APOPTOSIS, PLANT health, ALTERNARIA alternata

Abstract

Summary: Fumonisin B1 (FB1) and Alternaria alternate f. sp. lycopersici (AAL)‐toxin are classified as sphinganine analog mycotoxins (SAMTs), which induce programmed cell death (PCD) in plants and pose health threat to humans who consume the contaminated crop products. Herein, Fumonisin B1 Resistant41 (FBR41), a dominant mutant allele, was identified by map‐based cloning of Arabidopsis FB1‐resistant mutant fbr41, then ectopically expressed in AAL‐toxin sensitive tomato (Solanum lycopersicum) cultivar. FBR41‐overexpressing tomato plants exhibited less severe cell death phenotype upon AAL‐toxin treatment. Analysis of free sphingoid bases showed that both fbr41 and FBR41‐overexpressing tomato plants accumulated less sphinganine and phytosphingosine upon FB1 and AAL‐toxin treatment, respectively. Alternaria stem canker is a disease caused by AAL and responsible for severe economic losses in tomato production, and FBR41‐overexpressing tomato plants exhibited enhanced resistance to AAL with decreased fungal biomass and less cell death, which was accompanied by attenuated accumulation of free sphingoid bases and jasmonate (JA). Taken together, our results indicate that FBR41 is potential in inhibiting SAMT‐induced PCD and controlling Alternaria stem canker in tomato. [ABSTRACT FROM AUTHOR]

Published

2020