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8 results on '"Wenxian Gai"'

1. Heat-inducible SlWRKY3 confers thermotolerance by activating the SlGRXS1 gene cluster in tomato

Author

Ying Wang, Wenxian Gai, Liangdan Yuan, Lele Shang, Fangman Li, Zhao Gong, Pingfei Ge, Yaru Wang, Jinbao Tao, Xingyu Zhang, Haiqiang Dong, and Yuyang Zhang

Subjects
Tomato, WRKY transcription factor, SlWRKY3, Thermotolerance, SlGRXS1, Gene cluster, Plant culture, SB1-1110
Abstract

High temperature stress is one of the major environmental factors that affect the growth and development of plants. Although WRKY transcription factors play a critical role in stress responses, there are few studies on the regulation of heat stress by WRKY transcription factors, especially in tomato. Here, we identified a group I WRKY transcription factor, SlWRKY3, involved in thermotolerance in tomato. First, SlWRKY3 was induced and upregulated under heat stress. Accordingly, overexpression of SlWRKY3 led to an increase, whereas knock-out of SlWRKY3 resulted in decreased tolerance to heat stress. Overexpression of SlWRKY3 accumulated less reactive oxygen species (ROS), whereas knock-out of SlWRKY3 accumulated more ROS under heat stress. This indicated that SlWRKY3 positively regulates heat stress in tomato. In addition, SlWRKY3 activated the expression of a range of abiotic stress-responsive genes involved in ROS scavenging, such as a SlGRXS1 gene cluster. Further analysis showed that SlWRKY3 can bind to the promoters of the SlGRXS1 gene cluster and activate their expression. Collectively, these results imply that SlWRKY3 is a positive regulator of thermotolerance through direct binding to the promoters of the SlGRXS1 gene cluster and activating their expression and ROS scavenging.

Published
2024
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2. Altered brassinolide sensitivity1 Regulates Fruit Size in Association with Phytohormones Modulation in Tomato

Author

Muhammad Ali Mumtaz, Fangman Li, Xingyu Zhang, Jinbao Tao, Pingfei Ge, Ying Wang, Yaru Wang, Wenxian Gai, Haiqiang Dong, and Yuyang Zhang

Subjects
BR-insensitivity, fruit development, phytohormones, tomato, Plant culture, SB1-1110
Abstract

BRs (Brassinosteroids) regulate many essential pathways related to growth, cell elongation, cell expansion, plant architecture, and fruit development. The potential exogenous application of BR-derivatives has been proven to stimulate plant growth and development, including quality attributes of fruits, whereas its biosynthesis inhibition has shown the opposite effect. In this study, BR-insensitive tomato mutants were used to reveal the potential function of BR signaling in the regulation of fruit development to elaborate the regulatory mechanism of BR signaling in tomato fruits. The BR-signaling mutant exhibited a typical dwarf phenotype and reduced vegetative growth, fruit size, and weight. Microscopic and transcriptional evaluation of the abs1 mutant fruits implies that reduced cell size and number are responsible for the phenotypic variations. Additionally, we also found that the altered content of phytohormones, such as auxin, gibberellin, cytokinin, and ethylene levels, contributed to altered fruit development. Moreover, fruit growth and cell development-specific gene expression levels were downregulated in BR-insensitive plants; culminating in reduced cell size, cell number, and cell layers. These findings provide insight into physio-chemical changes during fruit development in response to BR-insensitivity.

Published
2022
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3. Methylation profiling of biosynthetic genes reveals the role of D-galacturonic acid reductase in ascorbic acid accumulation in tomato fruit

Author

Yaru Wang, Ying Wang, Fangman Li, Lele Shang, Jinbao Tao, Xingyu Zhang, Haiqiang Dong, Wenxian Gai, Yuyang Zhang, and Zongjun Ren

Subjects
Physiology, food and beverages, Plant Science, Agronomy and Crop Science
Abstract

Ascorbic acid (AsA) is an important nutrient component contributing to major flavor value of tomato fruit and human health. Although transcription regulation of AsA biosynthetic genes have been well demonstrated, epigenetic modification underlying AsA accumulation remains unclear. In this study, we exposed immature tomato fruits to a methyltransferase inhibitor (5-azacytidine) and detected the impacts on AsA accumulation. Inhibition of DNA methylation enhanced AsA accumulation in tomato leaves and fruits. We further isolated a AsA biosynthetic gene, SlGalUR5, which encodes a D-galacturonic acid reductase. SlGalUR5 showed reduced DNA methylation levels and higher transcription levels in Slmet1 mutant while have converse pattern in Sldml2 mutant. 5-azacytidine treatment significantly decreased DNA methylation levels of SlGalUR5 in fruits. Conversely, transcription profiles of SlGalUR5 and enzyme activity of GalUR were enhanced in 5-azacytidine–treated fruits. Our finding revealed a new insight into epigenome modification of SlGalUR5 involved in ascorbic acid accumulation and provide a potential means of increasing AsA levels for tomato breeding.

Published
2022

6. Multiple-model GWAS identifies optimal allelic combinations of quantitative trait loci for malic acid in tomato

Author

Wenxian Gai, Fan Yang, Liangdan Yuan, Saeed ul Haq, Yaru Wang, Ying Wang, Lele Shang, Fangman Li, Pingfei Ge, Haiqiang Dong, Jinbao Tao, Fei Wang, Xingyu Zhang, and Yuyang Zhang

Subjects
Genetics, Plant Science, Horticulture, Biochemistry, Biotechnology
Abstract

Malic acid (MA) is an important flavor acid in fruits and acts as a mediator in a series of metabolic pathways. It is important to understand the factors affecting MA metabolism for fruit flavor improvement and to understand MA-mediated biological processes. However, the metabolic accumulation of MA is controlled by complex heredity and environmental factors, making it difficult to predict and regulate the metabolism of MA. In this study, we carried out a genome-wide association study (GWAS) on MA using eight milestone models with two-environment repeats. A series of associated SNP variations were identified from the GWAS, and 15 high-confidence annotated genes were further predicted based on linkage disequilibrium and lead SNPs. The transcriptome data of candidate genes were explored within different tomato organs as well as various fruit tissues, and suggested specific expression patterns in fruit pericarp. Based on the genetic parameters of population differentiation and SNP distribution, tomato MA content has been more influenced by domestication sweeps and less affected by improvement sweeps in the long-term history of tomato breeding. In addition, genotype × environment interaction might contribute to the difference in domestication phenotypic data under different environments. This study provides new genetic insights into how tomato changed its MA content during breeding and makes available function-based markers for breeding by marker-assisted selection.

Published
2023

7. A 21-bp InDel in the promoter ofSTP1selected during tomato improvement accounts for soluble solid content in fruits

Author

Ying Wang, Chunmei Shi, Pingfei Ge, Fangman Li, Lihui Zhu, Yaru Wang, Jinbao Tao, Xingyu Zhang, Haiqiang Dong, Wenxian Gai, Fei Wang, Zhibiao Ye, Donald Grierson, Wei Xu, and Yuyang Zhang

Subjects
Genetics, Plant Science, Horticulture, Biochemistry, Biotechnology
Abstract

Domestication and improvement are important processes that generate the variation in genome and phonotypes underlying crop improvement. Unfortunately, during selection for certain attributes, other valuable traits may be inadvertently discarded. One example is the decline in fruit soluble solids content (SSC) during tomato breeding. Several genetic loci for SSC have been identified, but few reports on the underlying mechanisms are available. In this study we performed a genome-wide association study (GWAS) for SSC of the red-ripe fruits in a population consisting of 481 tomato accessions with large natural variations and found a new quantitative trait locus, STP1, encoding a sugar transporter protein. The causal variation of STP1, a 21-bp InDel located in the promoter region 1124 bp upstream of the start codon, alters its expression. STP1Insertion accessions with an 21-bp insertion have higher SSC than STP1Deletion accessions with the 21-bp deletion. Knockout of STP1 in TS-23 with high SSC using CRISPR/Cas9 greatly decreased SSC in fruits. In vivo and in vitro assays demonstrated that ZAT10-LIKE, a zinc finger protein transcription factor (ZFP TF), can specifically bind to the promoter of STP1Insertion to enhance STP1 expression, but not to the promoter of STP1Deletion, leading to lower fruit SSC in modern tomatoes. Diversity analysis revealed that STP1 was selected during tomato improvement. Taking these results together, we identified a naturally occurring causal variation underlying SSC in tomato, and a new role for ZFP TFs in regulating sugar transporters. The findings enrich our understanding of tomato evolution and domestication, and provide a genetic basis for genome design for improving fruit taste.

Published
2023

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