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413 results on '"Pan, Guangtang"'

20. Integrated analysis of transcriptomics and defense-related phytohormones to discover hub genes conferring maize Gibberella ear rot caused by Fusarium graminearum

Author

Yuan, Guangsheng, primary, Shi, Jiahao, additional, Zeng, Cheng, additional, Shi, Haoya, additional, Yang, Yong, additional, Zhang, Chuntian, additional, Ma, Tieli, additional, Wu, Mengyang, additional, Jia, Zheyi, additional, Du, Juan, additional, Zou, Chaoying, additional, Ma, Langlang, additional, Pan, Guangtang, additional, and Shen, Yaou, additional

Published
2024
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25. The maize PLASTID TERMINAL OXIDASE (PTOX) locus controls the carotenoid content of kernels

Author

Nie, Yongxin, primary, Wang, Hui, additional, Zhang, Guan, additional, Ding, Haiping, additional, Han, Beibei, additional, Liu, Lei, additional, Shi, Jian, additional, Du, Jiyuan, additional, Li, Xiaohu, additional, Li, Xinzheng, additional, Zhao, Yajie, additional, Zhang, Xiaocong, additional, Liu, Changlin, additional, Weng, Jianfeng, additional, Li, Xinhai, additional, Zhang, Xiansheng, additional, Zhao, Xiangyu, additional, Pan, Guangtang, additional, Jackson, David, additional, Li, Qin‐Bao, additional, Stinard, Philip S., additional, Arp, Jennifer, additional, Sachs, Martin M., additional, Moose, Steven, additional, Hunter, Charles T., additional, Wu, Qingyu, additional, and Zhang, Zhiming, additional

Published
2024
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29. Kernel Bioassay Evaluation of Maize Ear Rot and Genome-Wide Association Analysis for Identifying Genetic Loci Associated with Resistance to Fusarium graminearum Infection

Author

Zhang, Jihai, primary, Shi, Haoya, additional, Yang, Yong, additional, Zeng, Cheng, additional, Jia, Zheyi, additional, Ma, Tieli, additional, Wu, Mengyang, additional, Du, Juan, additional, Huang, Ning, additional, Pan, Guangtang, additional, Li, Zhilong, additional, and Yuan, Guangsheng, additional

Published
2023
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38. Kernel Bioassay Evaluation of Maize Ear Rot and Genome-Wide Association Analysis for Identifying Genetic Loci Associated with Resistance to Fusarium graminearum Infection.

Author

Zhang, Jihai, Shi, Haoya, Yang, Yong, Zeng, Cheng, Jia, Zheyi, Ma, Tieli, Wu, Mengyang, Du, Juan, Huang, Ning, Pan, Guangtang, Li, Zhilong, and Yuan, Guangsheng

Subjects
FUSARIOSIS, GENOME-wide association studies, BIOLOGICAL assay, LOCUS (Genetics), PLANT-pathogen relationships, CORN diseases, CORN seeds, CORN
Abstract

Gibberella ear rot (GER) caused by Fusarium graminearum (teleomorph Gibberella zeae) is one of the most destructive diseases in maize, which severely reduces yield and contaminates several potential mycotoxins in the grain. However, few efforts had been devoted to dissecting the genetic basis of maize GER resistance. In the present study, a genome-wide association study (GWAS) was conducted in a maize association panel consisting of 303 diverse inbred lines. The phenotypes of GER severity were evaluated using kernel bioassay across multiple time points in the laboratory. Then, three models, including the fixed and random model circulating probability unification model (FarmCPU), general linear model (GLM), and mixed linear model (MLM), were conducted simultaneously in GWAS to identify single-nucleotide polymorphisms (SNPs) significantly associated with GER resistance. A total of four individual significant association SNPs with the phenotypic variation explained (PVE) ranging from 3.51 to 6.42% were obtained. Interestingly, the peak SNP (PUT-163a-71443302-3341) with the greatest PVE value, was co-localized in all models. Subsequently, 12 putative genes were captured from the peak SNP, and several of these genes were directly or indirectly involved in disease resistance. Overall, these findings contribute to understanding the complex plant–pathogen interactions in maize GER resistance. The regions and genes identified herein provide a list of candidate targets for further investigation, in addition to the kernel bioassay that can be used for evaluating and selecting elite germplasm resources with GER resistance in maize. [ABSTRACT FROM AUTHOR]

Published
2023
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40. The maizePLASTID TERMINAL OXIDASE(PTOX) gene controls the carotenoid content of kernels

Author

Nie, Yongxin, primary, Wang, Hui, additional, Zhang, Guan, additional, Ding, Haiping, additional, Han, Beibei, additional, Liu, Lei, additional, Shi, Jian, additional, Du, Jiyuan, additional, Li, Xiaohu, additional, Li, Xinzheng, additional, Zhao, Yajie, additional, Zhang, Xiaocong, additional, Liu, Changlin, additional, Weng, Jianfeng, additional, Li, Xinhai, additional, Zhang, Xiansheng, additional, Zhao, Xiangyu, additional, Pan, Guangtang, additional, Jackson, David, additional, Wu, Qingyu, additional, and Zhang, Zhiming, additional

Published
2023
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45. An Integration of Linkage Mapping and GWAS Reveals the Key Genes for Ear Shank Length in Maize

Author

Liang, Zhenjuan, primary, Xi, Na, additional, Liu, Hao, additional, Liu, Peng, additional, Xiang, Chenchaoyang, additional, Zhang, Chen, additional, Zou, Chaoying, additional, Cheng, Xuyujuan, additional, Yu, Hong, additional, Zhang, Minyan, additional, Chen, Zhong, additional, Pan, Guangtang, additional, Yuan, Guangsheng, additional, Gao, Shibin, additional, Ma, Langlang, additional, and Shen, Yaou, additional

Published
2022
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47. Green tissue-targeted expression of the Cry1Ab/c gene in transgenic maize using the Cre/loxP system as an alternative strategy against lepidopteran pests.

Author

Yuan, Guangsheng, Shi, Jiaxin, Shi, Jiahao, He, Dandan, Li, Youliang, Du, Juan, Zou, Chaoying, Ma, Langlang, Pan, Guangtang, and Shen, Yaou

Subjects
TRANSGENE expression, GENE expression, FALL armyworm, GENETIC techniques, GENETIC engineering, CORN
Abstract

Genetically modified (GM) proteins in edible tissues of transgenic maize are of intense public concern. We provided a Cre/ lox P-based strategy for manipulating the expression of transgenes in green tissues while locking them in nongreen tissues. First, the Cre gene was driven by the green tissue-specific promoter Zm1rbcS to generate transgenic maize KEY. Meanwhile, a gene cassette containing a Nos terminator (NosT) in front of the Cry1Ab/c gene was driven by the strong promoter ZmUbi to generate another transgenic maize LOCK. By crossing KEY and LOCK plants, the expressed Cre recombinase under the control of the Zm1rbcS promoter from KEY maize accurately removed the NosT of LOCK maize. Consequently, the expression of blocked Cry1Ab/c was enabled in specific green tissues in their hybrids. The expression level and concentration of Cry1Ab/c were observed using a strategy with high specific accumulation in green tissues (leaf and stem). Still, only a small or absent amount was observed in root and kernel tissues. Furthermore, we assessed the bioactivity of transgenic maize against 2 common lepidopteran pests, Ostrinia furnacalis and Spodoptera frugiperda, in the laboratory and field. The transgenic plants showed high plant resistance levels against the 2 pests, with mortality rates above 97.2% and damage scales below 2.2 compared with the control group. These findings are significant for exploring novel genetic engineering techniques in GM maize and providing a feasible strategy for transgenes avoiding expression in edible parts. In addition, implementing the Cre/ lox P - mediated system could relieve public sentiment toward the biosafety of GM plants. [ABSTRACT FROM AUTHOR]

Published
2023
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