Your search keyword '"Liu, Liezhao"' showing total 149 results

1. Natural variation in BnaA9.NF-YA7 contributes to drought tolerance in Brassica napus L

Author

Wang, Jia, Mao, Lin, Li, Yangyang, Lu, Kun, Qu, Cunmin, Tang, Zhanglin, Li, Jiana, and Liu, Liezhao

Published

2024

2. Decryption of superior allele and candidate genes for total lignin contents of rapeseed

Author

Yu, Wenkai, Yang, Yuting, Liu, Liezhao, Li, Zhi, Zhu, Cheng, Hu, Qiong, and Liu, Jia

Published

2024

3. A Golden2-like transcription factor, BnGLK1a, improves chloroplast development, photosynthesis, and seed weight in rapeseed

Author

Zhang, Qianwei, Mao, Yuanyi, Zhao, Zikun, Hu, Xin, Hu, Ran, Yin, Nengwen, Sun, Xue, Sun, Fujun, Chen, Si, Jiang, Yuxiang, Liu, Liezhao, Lu, Kun, Li, Jiana, and Pan, Yu

Published

2024

4. Screening of microRNAs and target genes involved in Sclerotinia sclerotiorum (Lib.) infection in Brassica napus L.

Author

Xie, Ling, Jian, Hongju, Dai, Haoxi, Yang, Youhong, Liu, Yiling, Wei, Lijuan, Tan, Min, Li, Jiana, and Liu, Liezhao

Published

2023

5. Comparative genomic analyses reveal the genetic basis of the yellow-seed trait in Brassica napus

Author

Qu, Cunmin, Zhu, Meichen, Hu, Ran, Niu, Yongchao, Chen, Si, Zhao, Huiyan, Li, Chengxiang, Wang, Zhen, Yin, Nengwen, Sun, Fujun, Chen, Zhiyou, Shen, Shulin, Shang, Guoxia, Zhou, Yan, Yan, Xingying, Wei, Lijuan, Liu, Liezhao, Yi, Bin, Lian, Jinmin, Li, Jiang, Tang, Zhanglin, Liang, Ying, Xu, Xinfu, Wang, Rui, Yin, Jiaming, Wan, Huafang, Du, Hai, Qian, Wei, Chai, Yourong, Zhou, Qingyuan, He, Yajun, Zhong, Silin, Qiu, Xiao, Yu, Hao, Lam, Hon-Ming, Lu, Kun, Fu, Fuyou, and Li, Jiana

Published

2023

6. Comparative transcriptome and co-expression network analysis revealed the genes associated with senescence and polygalacturonase activity involved in pod shattering of rapeseed

Author

Mahmood, Umer, Li, Xiaodong, Qian, Mingchao, Fan, Yonghai, Yu, Mengna, Li, Shengting, Shahzad, Ali, Qu, Cunmin, Li, Jiana, Liu, Liezhao, and Lu, Kun

Published

2023

7. Meta-analysis of seed weight QTLome using a consensus and highly dense genetic map in Brassica napus L.

Author

Bilgrami, Sayedehsaba, Darzi Ramandi, Hadi, Farokhzadeh, Sara, Rousseau-Gueutin, Mathieu, Sobhani Najafabadi, Ahmad, Ghaderian, Mostafa, Huang, Pu, and Liu, Liezhao

Published

2023

8. Identification and characterization of a curly-leaf locus CL1 encoding an IAA2 protein in Brassica napus

Author

Tan, Yingchao, Ren, Lanyang, Wang, Jia, Ran, Shuyao, Wu, Liusha, Cheng, Ziyi, Qu, Cunmin, Li, Jiana, and Liu, Liezhao

Published

2023

9. BnbHLH92a negatively regulates anthocyanin and proanthocyanidin biosynthesis in Brassica napus

Author

Hu, Ran, Zhu, Meichen, Chen, Si, Li, Chengxiang, Zhang, Qianwei, Gao, Lei, Liu, Xueqin, Shen, Shulin, Fu, Fuyou, Xu, Xinfu, Liang, Ying, Liu, Liezhao, Lu, Kun, Yu, Hao, Li, Jiana, and Qu, Cunmin

Published

2023

10. Integrated genetic mapping and transcriptome analysis reveal the BnaA03.IAA7 protein regulates plant architecture and gibberellin signaling in Brassica napus L.

Author

Ping, Xiaoke, Ye, Qianjun, Yan, Mei, Zeng, Jianyan, Yan, Xingying, Li, Haitao, Li, Jiana, and Liu, Liezhao

Published

2022

11. Meta-analysis of QTLs controlling seed quality traits based on QTL alignment in Brassica napus

Author

Bilgrami, Sayedehsaba, Liu, Liezhao, Farokhzadeh, Sara, Najafabadi, Ahmad Sobhani, Ramandi, Hadi Darzi, Nasiri, Najmeh, and Darwish, Ibrahim

Published

2022

12. Genetic mapping and physiological analysis of chlorophyll-deficient mutant in Brassica napus L

Author

Lin, Na, Gao, Yumin, Zhou, Qingyuan, Ping, Xiaoke, Li, Jiana, Liu, Liezhao, and Yin, Jiaming

Published

2022

13. Overexpression of DEFECTIVE IN ANTHER DEHISCENCE 1 increases rapeseed silique length through crosstalk between JA and auxin signaling

Author

Liu, Miao, Chang, Wei, Yu, Mengna, Fan, Yonghai, Shang, Guoxia, Xu, Yuanfang, Niu, Yue, Liu, Xumei, Zhu, Hong, Dai, Lishi, Tang, Zhanglin, Zhang, Kai, Liu, Liezhao, Qu, Cunmin, Li, Jiana, and Lu, Kun

Published

2021

14. Comprehensive analysis of polygalacturonase genes offers new insights into their origin and functional evolution in land plants

Author

Mahmood, Umer, Fan, Yonghai, Wei, Siyu, Niu, Yue, Li, Yanhua, Huang, Hualei, Chen, Yuling, Tang, Zhanglin, Liu, Liezhao, Qu, Cunmin, Zhang, Kai, Li, Jiana, and Lu, Kun

Published

2021

15. Overexpression of BnaA10.WRKY75 Decreases Cadmium and Salt Tolerance via Increasing ROS Accumulation in Arabidopsis and Brassica napus L.

Author

Ping, Xiaoke, Ye, Qianjun, Yan, Mei, Wang, Jia, Zhang, Taiyuan, Chen, Sheng, Siddique, Kadambot H. M., Cowling, Wallace A., Li, Jiana, and Liu, Liezhao

Subjects

CADMIUM, RAPESEED, TRANSCRIPTION factors, ARABIDOPSIS, RUTABAGA, GENE expression, SALT, REACTIVE oxygen species

Abstract

Soil is indispensable for agricultural production but has been seriously polluted by cadmium and salt in recent years. Many crops are suffering from this, including rapeseed, the third largest global oilseed crop. However, genes simultaneously related to both cadmium and salt stress have not been extensively reported yet. In this study, BnaA10.WRKY75 was screened from previous RNA-seq data related to cadmium and salt stress and further analyses including sequence comparison, GUS staining, transformation and qRT-PCR were conducted to confirm its function. GUS staining and qRT-PCR results indicated BnaA10.WRKY75 was induced by CdCl2 and NaCl treatment. Sequence analysis suggested BnaA10.WRKY75 belongs to Group IIc of the WRKY gene family and transient expression assay showed it was a nuclear localized transcription factor. BnaA10.WRKY75-overexpressing Arabidopsis and rapeseed plants accumulated more H2O2 and O2− and were more sensitive to CdCl2 and NaCl treatment compared with untransformed plants, which may be caused by the downregulation of BnaC03.CAT2. Our study reported that BnaA10.WRKY75 increases sensitivity to cadmium and salt stress by disrupting the balance of reactive oxygen species both in Arabidopsis and rapeseed. The results support the further understanding of the mechanisms underlying cadmium and salt tolerance and provide BnaA10.WRKY75 as a valuable gene for rapeseed abiotic stress breeding. [ABSTRACT FROM AUTHOR]

Published

2024

16. Regulation by sugar and hormone signaling of the growth of Brassica napus L. axillary buds at the transcriptome level

Author

Li, Zhihui, Ding, Yiran, Xie, Ling, Jian, Hongju, Gao, Yumin, Yin, Jiaming, Li, Jiana, and Liu, Liezhao

Published

2020

17. Genome-wide association study and transcriptome analysis dissect the genetic control of silique length in Brassica napus L.

Author

Wang, Jia, Fan, Yueling, Mao, Lin, Qu, Cunmin, Lu, Kun, Li, Jiana, and Liu, Liezhao

Published

2021

18. Comparative transcriptomic analysis of seed coats with high and low lignin contents reveals lignin and flavonoid biosynthesis in Brassica napus

Author

Ding, Yiran, Yu, Shizhou, Wang, Jia, Li, Maoteng, Qu, Cunmin, Li, Jiana, and Liu, Liezhao

Published

2021

19. Genetic mapping high protein content QTL from soybean ‘Nanxiadou 25’ and candidate gene analysis

Author

Wang, Jia, Mao, Lin, Zeng, Zhaoqiong, Yu, Xiaobo, Lian, Jianqiu, Feng, Jun, Yang, Wenying, An, Jiangang, Wu, Haiying, Zhang, Mingrong, and Liu, Liezhao

Published

2021

20. Integrating GWAS, linkage mapping and gene expression analyses reveals the genetic control of growth period traits in rapeseed (Brassica napus L.)

Author

Wang, Tengyue, Wei, Lijuan, Wang, Jia, Xie, Ling, Li, Yang Yang, Ran, Shuyao, Ren, Lanyang, Lu, Kun, Li, Jiana, Timko, Michael P., and Liu, Liezhao

Published

2020

21. Combined QTL mapping, physiological and transcriptomic analyses to identify candidate genes involved in Brassica napus seed aging

Author

Wang, Tengyue, Hou, Lintao, Jian, Hongju, Di, Feifei, Li, Jiana, and Liu, Liezhao

Published

2018

22. Screening of candidate gene responses to cadmium stress by RNA sequencing in oilseed rape (Brassica napus L.)

Author

Ding, Yiran, Jian, Hongju, Wang, Tengyue, Di, Feifei, Wang, Jia, Li, Jiana, and Liu, Liezhao

Published

2018

23. Whole-genome resequencing reveals Brassica napus origin and genetic loci involved in its improvement

Author

Lu, Kun, Wei, Lijuan, Li, Xiaolong, Wang, Yuntong, Wu, Jian, Liu, Miao, Zhang, Chao, Chen, Zhiyou, Xiao, Zhongchun, Jian, Hongju, Cheng, Feng, Zhang, Kai, Du, Hai, Cheng, Xinchao, Qu, Cunming, Qian, Wei, Liu, Liezhao, Wang, Rui, Zou, Qingyuan, Ying, Jiamin, Xu, Xingfu, Mei, Jiaqing, Liang, Ying, Chai, You-Rong, Tang, Zhanglin, Wan, Huafang, Ni, Yu, He, Yajun, Lin, Na, Fan, Yonghai, Sun, Wei, Li, Nan-Nan, Zhou, Gang, Zheng, Hongkun, Wang, Xiaowu, Paterson, Andrew H., and Li, Jiana

Published

2019

24. Joint QTL mapping and transcriptome sequencing analysis reveal candidate flowering time genes in Brassica napus L

Author

Jian, Hongju, Zhang, Aoxiang, Ma, Jinqi, Wang, Tengyue, Yang, Bo, Shuang, Lan Shuan, Liu, Min, Li, Jiana, Xu, Xinfu, Paterson, Andrew H., and Liu, Liezhao

Published

2019

25. Genetic and transcriptomic analyses of lignin- and lodging-related traits in Brassica napus

Author

Wei, Lijuan, Jian, Hongju, Lu, Kun, Yin, Nengwen, Wang, Jia, Duan, Xiujian, Li, Wei, Liu, Liezhao, Xu, Xinfu, Wang, Rui, Paterson, Andrew H., and Li, Jiana

Published

2017

26. Genome-wide association analysis of seed germination percentage and germination index in Brassica napus L. under salt and drought stresses

Author

Tan, Min, Liao, Fang, Hou, Lintao, Wang, Jia, Wei, Lijuan, Jian, Hongju, Xu, Xinfu, Li, Jiana, and Liu, Liezhao

Published

2017

27. Integrated mRNA, sRNA, and degradome sequencing reveal oilseed rape complex responses to Sclerotinia sclerotiorum (Lib.) infection

Author

Jian, Hongju, Ma, Jinqi, Wei, Lijuan, Liu, Pu, Zhang, Aoxiang, Yang, Bo, Li, Jiana, Xu, Xinfu, and Liu, Liezhao

Published

2018

28. Dynamic and comparative QTL analysis for plant height in different developmental stages of Brassica napus L.

Author

Wang, Xiaodong, Wang, Hao, Long, Yan, Liu, Liezhao, Zhao, Yajun, Tian, Jianhua, Zhao, Weiguo, Li, Baojun, Chen, Li, Chao, Hongbo, and Li, Maoteng

Published

2015

29. Genome-wide analysis and expression profiling of the SUC and SWEET gene families of sucrose transporters in oilseed rape (Brassica napus L.)

Author

JIAN Hongju, LU Kun, YANG Bo, WANG Tengyue, ZHANG Li, ZHANG Aoxiang, WANG Jia, LIU Liezhao, QU Cunmin, and LI Jianna

Subjects

Brassica napus, sucrose transporters, sweet, SUC, Expression analysis， Stresses response, Plant culture, SB1-1110

Abstract

Sucrose is the principal transported product of photosynthesis from source leaves to sink organs. SUTs/SUCs (sucrose transporters or sucrose carriers) and SWEETs (Sugars Will Eventually be Exported Transporters) play significant central roles in phloem loading and unloading. SUTs/SUCs and SWEETs are key players in sucrose translocation and are associated with crop yields. The SUT/SUC and SWEET genes have been characterized in several plant species, but a comprehensive analysis of these two gene families in oilseed rape has not yet been reported. In our study, 22 and 68 members of the SUT/SUCs and SWEET gene families, respectively, were identified in the oilseed rape (Brassica napus) genome through homology searches. An analysis of the chromosomal distribution, phylogenetic relationships, gene structures, motifs and the cis-acting regulatory elements in the promoters of BnSUC and BnSWEET genes were analysed. Furthermore, we examined the expression of the 18 BnSUC and 16 BnSWEET genes in different tissues of ‘ZS11’ and the expression of 9 BnSUC and 7 BnSWEET genes in ‘ZS11’ under various conditions, including biotic stress (Sclerotinia sclerotiorum), abiotic stresses (drought, salt and heat), and hormone treatments (abscisic acid, auxin, cytokinin, brassinolide, gibberellin and salicylic acid). In conclusion, our study provides the first comprehensive analysis of the oilseed rape SUC and SWEET gene families. Information regarding the phylogenetic relationships, gene structure and expression profiles of the SUC and SWEET genes in the different tissues of oilseed rape helps to identify candidates with potential roles in specific developmental processes. Our study advances our understanding of the important roles of sucrose transport in oilseed rape.

Published

2016

30. Identification of genomic regions involved in resistance against Sclerotinia sclerotiorum from wild Brassica oleracea

Author

Mei, Jiaqin, Ding, Yijuan, Lu, Kun, Wei, Dayong, Liu, Yao, Disi, Joseph Onwusemu, Li, Jiana, Liu, Liezhao, Liu, Shengyi, McKay, John, and Qian, Wei

Published

2013

31. A knockout mutation in the lignin biosynthesis gene CCR1 explains a major QTL for acid detergent lignin content in Brassica napus seeds

Author

Liu, Liezhao, Stein, Anna, Wittkop, Benjamin, Sarvari, Pouya, Li, Jiana, Yan, Xingying, Dreyer, Felix, Frauen, Martin, Friedt, Wolfgang, and Snowdon, Rod J.

Published

2012

32. Knockout of the lignin pathway gene BnF5H decreases the S/G lignin compositional ratio and improves Sclerotinia sclerotiorum resistance in Brassica napus.

Author

Cao, Yanru, Yan, Xingying, Ran, Shuyao, Ralph, John, Smith, Rebecca A., Chen, Xueping, Qu, Cunmin, Li, Jiana, and Liu, Liezhao

Subjects

RAPESEED, LIGNINS, SCLEROTINIA sclerotiorum, DISEASE resistance of plants, LIGNIN structure, RAPESEED oil

Abstract

Ferulate‐5‐hydroxylase is a key enzyme involved in the conversion of the guaiacyl monolignol to the syringyl monolignol in angiosperms. The monolignol ratio has been proposed to affect biomass recalcitrance and the resistance to plant disease. Stem rot caused by the fungus Sclerotinia sclerotiorum in Brassica napus causes severe losses in its production. To date, there is no information about the effect of the lignin monomer ratio on the resistance to S. sclerotiorum in B. napus. Four dominantly expressed ferulate‐5‐hydroxylase genes were concertedly knocked out by CRISPR/Cas9 in B. napus, and three mutant lines were generated. The S/G lignin compositional ratio was decreased compared to that of the wild type based on the results of Mӓule staining and 2D‐NMR profiling in KO‐7. The resistance to S. sclerotiorum in stems and leaves increased for the three f5h mutant lines compared with WT. Furthermore, we found that the stem strength of f5h mutant lines was significantly increased. Overall, we demonstrate for the first time that decreasing the S/G ratio by knocking out of the F5H gene improves S. sclerotiorum resistance in B. napus and increases stem strength. The oilseed rape production is unremittingly affected by Sclerotinia sclerotiorum, which causes stem and leaf rot and reduces the production of rapeseed oil. Lignin is an established physical barrier against pathogens, and the different lignin monomer G and S content can have different lignin structures. In this study, four dominantly expressed BnF5H genes were knocked out by CRISPR/Cas9 simultaneously in B. napus, and the f5h mutants were generated. The S‐/G‐lignin composition ratio was decreased compared to that of the wild type (WT) based on the results of Mӓule staining and 2D‐NMR profiling in the KO‐7 line. The resistance to S. sclerotiorum in stems and leaves increased in knock‐out lines. Furthermore, we found that the stem strength of mutants was significantly increased compared to that of the WT. Collectively, for the first time, we demonstrate that knockout of the lignin pathway gene F5H decreases the S/G ratio, improves S. sclerotiorum resistance in B. napus, and increases stem strength. [ABSTRACT FROM AUTHOR]

Published

2022

33. Transcriptome and proteome analyses of the molecular mechanisms underlying changes in oil storage under drought stress in Brassica napus L.

Author

Li, Yangyang, Zhang, Linxue, Hu, Sheng, Zhang, Jinfeng, Wang, Lin, Ping, Xiaoke, Wang, Jia, Li, Jiana, Lu, Kun, Tang, Zhanglin, and Liu, Liezhao

Subjects

PROTEOMICS, RAPESEED, RAPESEED oil, OIL changes, OILSEEDS, VEGETABLE oils, DROUGHTS, ABSCISIC acid

Abstract

Rapeseed (Brassica napus L.) is the second most important oilseed crop in edible vegetable oil and bioenergy; however, drought stress generally causes a decrease in rapeseed yield and oil content, especially during the reproductive stage. In our study, we measured the oil and protein contents and gibberellic acid (GA) and abscisic acid (ABA) levels in seeds that were acquired on the 30th, 40th, and 50th days after flowering under control and drought treatments. RNA and protein libraries were constructed from the stressed seeds to perform transcriptome and proteome analyses, respectively. Our results demonstrated that the oil content decreased due to four primary mechanisms: downregulation of fatty acid biosynthesis‐associated genes and proteins; upregulation of fatty acid degradation‐associated genes and proteins; enhancement of protein storage due to changes in the abundances of relevant genes and proteins; and upregulation of Gly‐Asp‐Ser‐Leu (GDSL) gene expression, potentially as the result of upregulating the GA biosynthesis gene GA20ox3 and downregulating the GA inactivating gene GA2ox3 and thus an increase in GA content. During seed maturation, oil storage change may also relate to increasing ABA content as the upregulation of two members of NCED6 (9‐cis‐epoxycarotenoid dioxygenase) gene family involved in ABA biosynthesis, and the upregulation of genes involved in ABA signal transduction. These results will help to establish a foundation for breeding excellent varieties of rapeseed with high oil content for areas with frequent droughts to promote the supply of edible vegetable oil and biofuel. [ABSTRACT FROM AUTHOR]

Published

2021

34. Genetic Mapping Combined with a Transcriptome Analysis to Screen for Candidate Genes Responsive to Abscisic Acid Treatment in Brassica napus Embryos During Seed Germination.

Author

Di, Feifei, Wang, Tengyue, Ding, Yiran, Chen, Xueping, Wang, Hao, Li, Jiana, and Liu, Liezhao

Subjects

RUTABAGA, GERMINATION, ABSCISIC acid, GENE mapping, EMBRYOS, BRASSICA, COTYLEDONS, SOMATIC embryogenesis

Abstract

Brassica napus embryos contain precursor tissues for the leaves, stem, and root, as well as the cotyledons, and these precursor tissues play key roles in seed germination, seedling survival, and subsequent seedling growth. Abscisic acid (ABA) plays a prominent role in the inhibition of seed germination. The underlying molecular mechanisms of the embryo responses to ABA stress followed by inhibited seed germination have not been reported in B. napus to date. In this study, we conducted quantitative trait locus (QTL) analysis of B. napus seed in response to ABA stress using 170 recombinant inbred lines. Furthermore, we performed transcriptome sequencing (RNA-seq) analyses by using B. napus ZS11 embryos under sterile deionized water (control) and 10 mg/L (10A), 20 mg/L (20A), and 30 mg/L (30A) ABA treatment conditions. In total, 10 QTLs were screened for explaining 2.70–6.73% of the phenotypic variation under ABA stress. In addition, 1495, 3332, and 3868 differentially expressed genes (DEGs) were identified in the "control vs 10A," "control vs 20A," and "control vs 30A" comparisons, respectively. Gene Ontology (GO) enrichment analysis indicated that DEG functions are mainly related to response to stimuli, response to oxygen-containing compounds, response to lipids, and the transport and seed dormancy processes. These DEGs mainly participated in the response to plant hormone signal transduction, starch and sucrose metabolism, cutin, suberine, and wax biosynthesis, and phenylpropanoid biosynthesis processes pathways. Our results provide a foundation for further explorations of the molecular regulatory mechanisms of B. napus embryos in response to abiotic stress during the seed germination stage. [ABSTRACT FROM AUTHOR]

Published

2020

35. Genome-Wide Analysis of the PYL Gene Family and Identification of PYL Genes That Respond to Abiotic Stress in Brassica napus.

Author

Di, Feifei, Jian, Hongju, Wang, Tengyue, Chen, Xueping, Ding, Yiran, Du, Hai, Lu, Kun, Li, Jiana, and Liu, Liezhao

Subjects

GENOMES, ABIOTIC stress, RUTABAGA, ABSCISIC acid, PLANT hormones

Abstract

Abscisic acid (ABA) is an endogenous phytohormone that plays important roles in the regulation of plant growth, development, and stress responses. The pyrabactin resistance 1-like (PYR/PYL) protein is a core regulatory component of ABA signaling networks in plants. However, no details regarding this family in Brassica napus are available. Here, 46 PYLs were identified in the B. napus genome. Based on phylogenetic analysis, BnPYR1 and BnPYL1-3 belong to subfamily I, BnPYL7-10 belong to subfamily II, and BnPYL4-6 and BnPYL11-13 belong to subfamily III. Analysis of BnPYL conserved motifs showed that every subfamily contained four common motifs. By predicting cis-elements in the promoters, we found that all BnPYL members contained hormoneand stress-related elements and that expression levels of most BnPYLs were relatively higher in seeds at the germination stage than those in other organs or at other developmental stages. Gene Ontology (GO) enrichment showed that BnPYL genes mainly participate in responses to stimuli. To identify crucial PYLs mediating the response to abiotic stress in B. napus, expression changes in 14 BnPYL genes were determined by quantitative real-time RT-PCR after drought, heat, and salinity treatments, and identified BnPYR1-3, BnPYL1-2, and BnPYL7-2 in respond to abiotic stresses. The findings of this study lay a foundation for further investigations of PYL genes in B. napus. [ABSTRACT FROM AUTHOR]

Published

2018

36. Screening of Candidate Leaf Morphology Genes by Integration of QTL Mapping and RNA Sequencing Technologies in Oilseed Rape (Brassica napus L.).

Author

Jian, Hongju, Yang, Bo, Zhang, Aoxiang, Zhang, Li, Xu, Xinfu, Li, Jiana, and Liu, Liezhao

Subjects

LEAVES, PLANT morphology, OILSEEDS, RNA sequencing, PLANT physiology

Abstract

Leaf size and shape play important roles in agronomic traits, such as yield, quality and stress responses. Wide variations in leaf morphological traits exist in cultivated varieties of many plant species. By now, the genetics of leaf shape and size have not been characterized in Brassica napus. In this study, a population of 172 recombinant inbred lines (RILs) was used for quantitative trait locus (QTL) analysis of leaf morphology traits. Furthermore, fresh young leaves of extreme lines with more leaf lobes (referred to as ‘A’) and extreme lines with fewer lobes (referred to as ‘B’) selected from the RIL population and leaves of dissected lines (referred to as ‘P’) were used for transcriptional analysis. A total of 31 QTLs for the leaf morphological traits tested in this study were identified on 12 chromosomes, explaining 5.32–39.34% of the phenotypic variation. There were 8, 6, 2, 5, 8, and 2 QTLs for PL (petiole length), PN (lobe number), LW (lamina width), LL (Lamina length), LL/LTL (the lamina size ratio) and LTL (leaf total length), respectively. In addition, 74, 1,166 and 1,272 differentially expressed genes (DEGs) were identified in ‘A vs B’, ‘A vs P’ and ‘B vs P’ comparisons, respectively. The Gene ontology (GO) and Kyoto Encyclopedia of Genes and Genomes (KEGG) databases were used to predict the functions of these DEGs. Gene regulators of leaf shape and size, such as ASYMMETRIC LEAVES 2, gibberellin 20-oxidase 3, genes encoding gibberellin-regulated family protein, genes encoding growth-regulating factor and KNOTTED1-like homeobox were also detected in DEGs. After integrating the QTL mapping and RNA sequencing data, 33 genes, including a gene encoding auxin-responsive GH3 family protein and a gene encoding sphere organelles protein-related gene, were selected as candidates that may control leaf shape. Our findings should be valuable for studies of the genetic control of leaf morphological trait regulation in B. napus. [ABSTRACT FROM AUTHOR]

Published

2017

37. Genome-wide association analysis and differential expression analysis of resistance to Sclerotinia stem rot in Brassica napus.

Author

Wei, Lijuan, Jian, Hongju, Lu, Kun, Filardo, Fiona, Yin, Nengwen, Liu, Liezhao, Qu, Cunmin, Li, Wei, Du, Hai, and Li, Jiana

Subjects

PLANT genomes, GENE expression in plants, BRASSICA, OILSEED plants, BIOLOGICAL control of sclerotinia diseases

Abstract

Brassica napus is one of the most important oil crops in the world, and stem rot caused by the fungus Sclerotinia sclerotiorum results in major losses in yield and quality. To elucidate resistance genes and pathogenesis-related genes, genome-wide association analysis of 347 accessions was performed using the Illumina 60K Brassica SNP (single nucleotide polymorphism) array. In addition, the detached stem inoculation assay was used to select five highly resistant (R) and susceptible (S) B. napus lines, 48 h postinoculation with S. sclerotiorum for transcriptome sequencing. We identified 17 significant associations for stem resistance on chromosomes A8 and C6, five of which were on A8 and 12 on C6. The SNPs identified on A8 were located in a 409-kb haplotype block, and those on C6 were consistent with previous QTL mapping efforts. Transcriptome analysis suggested that S. sclerotiorum infection activates the immune system, sulphur metabolism, especially glutathione ( GSH) and glucosinolates in both R and S genotypes. Genes found to be specific to the R genotype related to the jasmonic acid pathway, lignin biosynthesis, defence response, signal transduction and encoding transcription factors. Twenty-four genes were identified in both the SNP-trait association and transcriptome sequencing analyses, including a tau class glutathione S-transferase ( GSTU) gene cluster. This study provides useful insight into the molecular mechanisms underlying the plant's response to S. sclerotiorum. [ABSTRACT FROM AUTHOR]

Published

2016

38. Genome-Wide Analysis of Seed Acid Detergent Lignin (ADL) and Hull Content in Rapeseed (Brassica napus L.).

Author

Wang, Jia, Jian, Hongju, Wei, Lijuan, Qu, Cunmin, Xu, Xinfu, Lu, Kun, Qian, Wei, Li, Jiana, Li, Maoteng, and Liu, Liezhao

Subjects

RAPESEED, LIGNINS, PLANT genomes, CULTIVARS, SINGLE nucleotide polymorphisms, PLANT gene mapping

Abstract

A stable yellow-seeded variety is the breeding goal for obtaining the ideal rapeseed (Brassica napus L.) plant, and the amount of acid detergent lignin (ADL) in the seeds and the hull content (HC) are often used as yellow-seeded rapeseed screening indices. In this study, a genome-wide association analysis of 520 accessions was performed using the Q + K model with a total of 31,839 single-nucleotide polymorphism (SNP) sites. As a result, three significant associations on the B. napus chromosomes A05, A09, and C05 were detected for seed ADL content. The peak SNPs were within 9.27, 14.22, and 20.86 kb of the key genes BnaA.PAL4, BnaA.CAD2/BnaA.CAD3, and BnaC.CCR1, respectively. Further analyses were performed on the major locus of A05, which was also detected in the seed HC examination. A comparison of our genome-wide association study (GWAS) results and previous linkage mappings revealed a common chromosomal region on A09, which indicates that GWAS can be used as a powerful complementary strategy for dissecting complex traits in B. napus. Genomic selection (GS) utilizing the significant SNP markers based on the GWAS results exhibited increased predictive ability, indicating that the predictive ability of a given model can be substantially improved by using GWAS and GS. [ABSTRACT FROM AUTHOR]

Published

2015

39. A High-Density SNP Map for Accurate Mapping of Seed Fibre QTL in Brassica napus L.

Author

Liu, Liezhao, Qu, Cunmin, Wittkop, Benjamin, Yi, Bin, Xiao, Yang, He, Yajun, Snowdon, Rod J., and Li, Jiana

Subjects

*SINGLE nucleotide polymorphisms, *RUTABAGA, *HEMICELLULOSE, *GENOMES, *GENE mapping, *NUCLEOTIDE sequence

Abstract

A high density genetic linkage map for the complex allotetraploid crop species Brassica napus (oilseed rape) was constructed in a late-generation recombinant inbred line (RIL) population, using genome-wide single nucleotide polymorphism (SNP) markers assayed by the Brassica 60 K Infinium BeadChip Array. The linkage map contains 9164 SNP markers covering 1832.9 cM. 1232 bins account for 7648 of the markers. A subset of 2795 SNP markers, with an average distance of 0.66 cM between adjacent markers, was applied for QTL mapping of seed colour and the cell wall fiber components acid detergent lignin (ADL), cellulose and hemicellulose. After phenotypic analyses across four different environments a total of 11 QTL were detected for seed colour and fiber traits. The high-density map considerably improved QTL resolution compared to the previous low-density maps. A previously identified major QTL with very high effects on seed colour and ADL was pinpointed to a narrow genome interval on chromosome A09, while a minor QTL explaining 8.1% to 14.1% of variation for ADL was detected on chromosome C05. Five and three QTL accounting for 4.7% to 21.9% and 7.3% to 16.9% of the phenotypic variation for cellulose and hemicellulose, respectively, were also detected. To our knowledge this is the first description of QTL for seed cellulose and hemicellulose in B. napus, representing interesting new targets for improving oil content. The high density SNP genetic map enables navigation from interesting B. napus QTL to Brassica genome sequences, giving useful new information for understanding the genetics of key seed quality traits in rapeseed. [ABSTRACT FROM AUTHOR]

Published

2013

40. Identification of QTLs Associated with Oil Content in a High-Oil Brassica napus Cultivar and Construction of a High-Density Consensus Map for QTLs Comparison in B. napus.

Author

Wang, Xiaodong, Wang, Hao, Long, Yan, Li, Dianrong, Yin, Yongtai, Tian, Jianhua, Chen, Li, Liu, Liezhao, Zhao, Weiguo, Zhao, Yajun, Yu, Longjiang, and Li, Maoteng

Subjects

QUANTITATIVE genetics, BRASSICA varieties, RAPESEED, PLANT breeding, PLANT genetics, HAPLOIDY, PHENOTYPES

Abstract

Increasing seed oil content is one of the most important goals in breeding of rapeseed (B. napus L.). To dissect the genetic basis of oil content in B. napus, a large and new double haploid (DH) population containing 348 lines was obtained from a cross between ‘KenC-8’ and ‘N53-2’, two varieties with >10% difference in seed oil content, and this population was named the KN DH population. A genetic linkage map consisting of 403 markers was constructed, which covered a total length of 1783.9 cM with an average marker interval of 4.4 cM. The KN DH population was phenotyped in eight natural environments and subjected to quantitative trait loci (QTL) analysis for oil content. A total of 63 identified QTLs explaining 2.64–17.88% of the phenotypic variation were identified, and these QTLs were further integrated into 24 consensus QTLs located on 11 chromosomes using meta-analysis. A high-density consensus map with 1335 marker loci was constructed by combining the KN DH map with seven other published maps based on the common markers. Of the 24 consensus QTLs in the KN DH population, 14 were new QTLs including five new QTLs in A genome and nine in C genome. The analysis revealed that a larger population with significant differences in oil content gave a higher power detecting new QTLs for oil content, and the construction of the consensus map provided a new clue for comparing the QTLs detected in different populations. These findings enriched our knowledge of QTLs for oil content and should be a potential in marker-assisted breeding of B. napus. [ABSTRACT FROM AUTHOR]

Published

2013

41. Dissection of a major QTL for seed colour and fibre content in Brassica napus reveals colocalization with candidate genes for phenylpropanoid biosynthesis and flavonoid deposition.

Author

Stein, Anna, Wittkop, Benjamin, Liu, Liezhao, Obermeier, Christian, Friedt, Wolfgang, Snowdon, Rod J., and Chevre, A.‐M.

Subjects

SEED colors, FLAVONOIDS, BIOSYNTHESIS, PHENYLPROPANOIDS, GENE expression, RUTABAGA, LOCUS (Genetics)

Abstract

A major quantitative trait locus ( QTL) influencing seed fibre and colour in Brassica napus was dissected by marker saturation in a doubled haploid ( DH) population from the black-seeded oilseed rape line 'Express 617' crossed with a yellow-seeded B. napus line, '1012-98'. The marker at the peak of a sub- QTL with a strong effect on both seed colour and acid detergent lignin content lay only 4 kb away from a Brassica (H+)- ATPase gene orthologous to the transparent testa gene AHA10. Near the peak of a second sub- QTL, we mapped a copy of the key phenylpropanoid biosynthesis gene cinnamyl alcohol dehydrogenase, while another key phenylpropanoid biosynthesis gene, cinnamoyl co-a reductase 1, was found nearby. In a cross between 'Express 617' and another dark-seeded parent, 'V8', Bna. CCR1 was localized in silico near the peak of a corresponding seed fibre QTL, whereas in this case Bna. CAD2/ CAD3 lay nearby. Re-sequencing of the two phenylpropanoid genes via next-generation amplicon sequencing revealed intragenic rearrangements and functionally relevant allelic variation in the three parents. [ABSTRACT FROM AUTHOR]

Published

2013

42. Metabolite Profiling and Transcriptome Analysis Provide Insight into Seed Coat Color in Brassica juncea.

Author

Shen, Shulin, Tang, Yunshan, Zhang, Chao, Yin, Nengwen, Mao, Yuanyi, Sun, Fujun, Chen, Si, Hu, Ran, Liu, Xueqin, Shang, Guoxia, Liu, Liezhao, Lu, Kun, Li, Jiana, and Qu, Cunmin

Subjects

BRASSICA juncea, ANIMAL coloration, HYDROXYCINNAMIC acids, CATECHIN, SEEDS, SEED development, EPICATECHIN, PHENOLIC acids

Abstract

The allotetraploid species Brassica juncea (mustard) is grown worldwide as oilseed and vegetable crops; the yellow seed-color trait is particularly important for oilseed crops. Here, to examine the factors affecting seed coat color, we performed a metabolic and transcriptomic analysis of yellow- and dark-seeded B. juncea seeds. In this study, we identified 236 compounds, including 31 phenolic acids, 47 flavonoids, 17 glucosinolates, 38 lipids, 69 other hydroxycinnamic acid compounds, and 34 novel unknown compounds. Of these, 36 compounds (especially epicatechin and its derivatives) accumulated significantly different levels during the development of yellow- and dark-seeded B. juncea. In addition, the transcript levels of BjuDFR, BjuANS,BjuBAN, BjuTT8, and BjuTT19 were closely associated with changes to epicatechin and its derivatives during seed development, implicating this pathway in the seed coat color determinant in B. juncea. Furthermore, we found numerous variations of sequences in the TT8A genes that may be associated with the stability of seed coat color in B. rapa, B. napus, and B. juncea, which might have undergone functional differentiation during polyploidization in the Brassica species. The results provide valuable information for understanding the accumulation of metabolites in the seed coat color of B. juncea and lay a foundation for exploring the underlying mechanism. [ABSTRACT FROM AUTHOR]

Published

2021

43. Genome-wide exploration and characterization of miR172/euAP2 genes in Brassica napus L. for likely role in flower organ development.

Author

Wang, Tengyue, Ping, Xiaoke, Cao, Yanru, Jian, Hongju, Gao, Yumin, Wang, Jia, Tan, Yingchao, Xu, Xinfu, Lu, Kun, Li, Jiana, and Liu, Liezhao

Subjects

FLOWER development, MORPHOGENESIS, GENE families, BRASSICA, GENE expression, ENDOSPERM, GENES

Abstract

Background: APETALA2-like genes encode plant-specific transcription factors, some of which possess one microRNA172 (miR172) binding site. The miR172 and its target euAP2 genes are involved in the process of phase transformation and flower organ development in many plants. However, the roles of miR172 and its target AP2 genes remain largely unknown in Brassica napus (B. napus). Results: In this study, 19 euAP2 and four miR172 genes were identified in the B. napus genome. A sequence analysis suggested that 17 euAP2 genes were targeted by Bna-miR172 in the 3′ coding region. EuAP2s were classified into five major groups in B.napus. This classification was consistent with the exon-intron structure and motif organization. An analysis of the nonsynonymous and synonymous substitution rates revealed that the euAP2 genes had gone through purifying selection. Whole genome duplication (WGD) or segmental duplication events played a major role in the expansion of the euAP2 gene family. A cis-regulatory element (CRE) analysis suggested that the euAP2s were involved in the response to light, hormones, stress, and developmental processes including circadian control, endosperm and meristem expression. Expression analysis of the miR172-targeted euAP2s in nine different tissues showed diverse spatiotemporal expression patterns. Most euAP2 genes were highly expressed in the floral organs, suggesting their specific functions in flower development. BnaAP2–1, BnaAP2–5 and BnaTOE1–2 had higher expression levels in late-flowering material than early-flowering material based on RNA-seq and qRT-PCR, indicating that they may act as floral suppressors. Conclusions: Overall, analyses of the evolution, structure, tissue specificity and expression of the euAP2 genes were peformed in B.napus. Based on the RNA-seq and experimental data, euAP2 may be involved in flower development. Three euAP2 genes (BnaAP2–1, BnaAP2–5 and BnaTOE1–2) might be regarded as floral suppressors. The results of this study provide insights for further functional characterization of the miR172 /euAP2 module in B.napus. [ABSTRACT FROM AUTHOR]

Published

2019

44. Genome-Wide Identification of the LAC Gene Family and Its Expression Analysis Under Stress in Brassica napus.

Author

Ping, Xiaoke, Wang, Tengyue, Lin, Na, Di, Feifei, Li, Yangyang, Jian, Hongju, Wang, Hao, Lu, Kun, Li, Jiana, Xu, Xinfu, and Liu, Liezhao

Abstract

Lignin is an important biological polymer in plants that is necessary for plant secondary cell wall ontogenesis. The laccase (LAC) gene family catalyzes lignification and has been suggested to play a vital role in the plant kingdom. In this study, we identified 45 LAC genes from the Brassica napus genome (BnLACs), 25 LAC genes from the Brassica rapa genome (BrLACs) and 8 LAC genes from the Brassica oleracea genome (BoLACs). These LAC genes could be divided into five groups in a cladogram and members in same group had similar structures and conserved motifs. All BnLACs contained hormone- and stress- related elements determined by cis-element analysis. The expression of BnLACs was relatively higher in the root, seed coat and stem than in other tissues. Furthermore, BnLAC4 and its predicted downstream genes showed earlier expression in the silique pericarps of short silique lines than long silique lines. Three miRNAs (miR397a, miR397b and miR6034) target 11 BnLACs were also predicted. The expression changes of BnLACs under series of stresses were further investigated by RNA sequencing (RNA-seq) and quantitative real-time polymerase chain reaction (qRT-PCR). The study will give a deeper understanding of the LAC gene family evolution and functions in B. napus. [ABSTRACT FROM AUTHOR]

Published

2019

45. Genome-Wide Identification and Characterization of NODULE-INCEPTION-Like Protein (NLP) Family Genes in Brassica napus.

Author

Liu, Miao, Chang, Wei, Fan, Yonghai, Sun, Wei, Qu, Cunmin, Zhang, Kai, Liu, Liezhao, Xu, Xingfu, Tang, Zhanglin, Li, Jiana, and Lu, Kun

Subjects

NITROGEN deficiency, RUTABAGA, AMINO acids, PHYLOGENETIC models, TRANSCRIPTION factors, MONOCOTYLEDONS, COLEOPTILES

Abstract

NODULE-INCEPTION-like proteins (NLPs) are conserved, plant-specific transcription factors that play crucial roles in responses to nitrogen deficiency. However, the evolutionary relationships and characteristics of NLP family genes in Brassica napus are unclear. In this study, we identified 31 NLP genes in B. napus, including 16 genes located in the A subgenome and 15 in the C subgenome. Subcellular localization predictions indicated that most BnaNLP proteins are localized to the nucleus. Phylogenetic analysis suggested that the NLP gene family could be divided into three groups and that at least three ancient copies of NLP genes existed in the ancestor of both monocots and dicots prior to their divergence. The ancestor of group III NLP genes may have experienced duplication more than once in the Brassicaceae species. Three-dimensional structural analysis suggested that 14 amino acids in BnaNLP7-1 protein are involved in DNA binding, whereas no binding sites were identified in the two RWP-RK and PB1 domains conserved in BnaNLP proteins. Expression profile analysis indicated that BnaNLP genes are expressed in most organs but tend to be highly expressed in a single organ. For example, BnaNLP6 subfamily members are primarily expressed in roots, while the four BnaNLP7 subfamily members are highly expressed in leaves. BnaNLP genes also showed different expression patterns in response to nitrogen-deficient conditions. Under nitrogen deficiency, all members of the BnaNLP1/4/5/9 subfamilies were upregulated, all BnaNLP2/6 subfamily members were downregulated, and BnaNLP7/8 subfamily members showed various expression patterns in different organs. These results provide a comprehensive evolutionary history of NLP genes in B. napus, and insight into the biological functions of BnaNLP genes in response to nitrogen deficiency. [ABSTRACT FROM AUTHOR]

Published

2018

46. Genome-Wide Identification of MicroRNAs in Response to Cadmium Stress in Oilseed Rape (Brassica napus L.) Using High-Throughput Sequencing.

Author

Jian, Hongju, Yang, Bo, Zhang, Aoxiang, Ma, Jinqi, Ding, Yiran, Chen, Zhiyou, Li, Jiana, Xu, Xinfu, and Liu, Liezhao

Subjects

MICRORNA, CADMIUM, OILSEED plants, RAPE (Plant), GENOMES

Abstract

MicroRNAs (miRNAs) have important roles in regulating stress-response genes in plants. However, identification of miRNAs and the corresponding target genes that are induced in response to cadmium (Cd) stress in Brassica napus remains limited. In the current study, we sequenced three small-RNA libraries from B. napus after 0 days, 1 days, and 3 days of Cd treatment. In total, 44 known miRNAs (belonging to 27 families) and 103 novel miRNAs were identified. A comprehensive analysis of miRNA expression profiles found 39 differentially expressed miRNAs between control and Cd-treated plants; 13 differentially expressed miRNAs were confirmed by qRT-PCR. Characterization of the corresponding target genes indicated functions in processes including transcription factor regulation, biotic stress response, ion homeostasis, and secondary metabolism. Furthermore, we propose a hypothetical model of the Cd-response mechanism in B. napus. Combined with qRT-PCR confirmation, our data suggested that miRNAs were involved in the regulations of TFs, biotic stress defense, ion homeostasis and secondary metabolism synthesis to respond Cd stress in B. napus. [ABSTRACT FROM AUTHOR]

Published

2018

47. Identification of QTL for seed coat colour and oil content in Brassica napus by association mapping using SSR markers

Author

Qu, Cunmin, Hasan, Maen, Lu, Kun, Liu, Liezhao, Zhang, Kai, Fu, Fuyou, Wang, Min, Liu, Shuiyan, Bu, Haidong, Wang, Rui, Xu, Xinfu, Chen, Li, and Li, Jiana

Published

2015

48. Identification of QTLs Associated with Oil Content in a High-Oil Brassica napus Cultivar and Construction of a High-Density Consensus Map for QTLs Comparison in B. napus.

Author

Wang, Xiaodong, Wang, Hao, Long, Yan, Li, Dianrong, Yin, Yongtai, Tian, Jianhua, Chen, Li, Liu, Liezhao, Zhao, Weiguo, Zhao, Yajun, Yu, Longjiang, and Li, Maoteng

Subjects

*QUANTITATIVE genetics, *BRASSICA varieties, *RAPESEED, *PLANT breeding, *PLANT genetics, *HAPLOIDY, *PHENOTYPES

Abstract

Increasing seed oil content is one of the most important goals in breeding of rapeseed (B. napus L.). To dissect the genetic basis of oil content in B. napus, a large and new double haploid (DH) population containing 348 lines was obtained from a cross between ‘KenC-8’ and ‘N53-2’, two varieties with >10% difference in seed oil content, and this population was named the KN DH population. A genetic linkage map consisting of 403 markers was constructed, which covered a total length of 1783.9 cM with an average marker interval of 4.4 cM. The KN DH population was phenotyped in eight natural environments and subjected to quantitative trait loci (QTL) analysis for oil content. A total of 63 identified QTLs explaining 2.64–17.88% of the phenotypic variation were identified, and these QTLs were further integrated into 24 consensus QTLs located on 11 chromosomes using meta-analysis. A high-density consensus map with 1335 marker loci was constructed by combining the KN DH map with seven other published maps based on the common markers. Of the 24 consensus QTLs in the KN DH population, 14 were new QTLs including five new QTLs in A genome and nine in C genome. The analysis revealed that a larger population with significant differences in oil content gave a higher power detecting new QTLs for oil content, and the construction of the consensus map provided a new clue for comparing the QTLs detected in different populations. These findings enriched our knowledge of QTLs for oil content and should be a potential in marker-assisted breeding of B. napus. [ABSTRACT FROM AUTHOR]

Published

2013

49. Editorial: Genetics, breeding and engineering to enhance oil quality and yield.

Author

Chao H, Kilaru A, and Liu L

Abstract

Competing Interests: The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.

Published

2023

50. Characterization of cold stress responses in different rapeseed ecotypes based on metabolomics and transcriptomics analyses.

Author

Jian H, Xie L, Wang Y, Cao Y, Wan M, Lv D, Li J, Lu K, Xu X, and Liu L

Abstract

The winter oilseed ecotype is more tolerant to low temperature than the spring ecotype. Transcriptome and metabolome analyses of leaf samples of five spring Brassica napus L. ( B. napus ) ecotype lines and five winter B. napus ecotype lines treated at 4 °C and 28 °C were performed. A total of 25,460 differentially expressed genes (DEGs) of the spring oilseed ecotype and 28,512 DEGs of the winter oilseed ecotype were identified after cold stress; there were 41 differentially expressed metabolites (DEMs) in the spring and 47 in the winter oilseed ecotypes. Moreover, more than 46.2% DEGs were commonly detected in both ecotypes, and the extent of the changes were much more pronounced in the winter than spring ecotype. By contrast, only six DEMs were detected in both the spring and winter oilseed ecotypes. Eighty-one DEMs mainly belonged to primary metabolites, including amino acids, organic acids and sugars. The large number of specific genes and metabolites emphasizes the complex regulatory mechanisms involved in the cold stress response in oilseed rape. Furthermore, these data suggest that lipid, ABA, secondary metabolism, signal transduction and transcription factors may play distinct roles in the spring and winter ecotypes in response to cold stress. Differences in gene expression and metabolite levels after cold stress treatment may have contributed to the cold tolerance of the different oilseed ecotypes., Competing Interests: Kun Lu is an Academic Editor for PeerJ., (© 2020 Jian et al.)

Published

2020