广东省农业科学院机构知识库

Comparative transcriptome analysis of sweet corn seedlings under low-temperature stress

收藏
分享
全文链接

文献类型：外文期刊

作者： Mao, Jihua ¹ ; Yu, Yongtao ¹ ; Yang, Jing ¹ ; Li, Gaoke ¹ ; Li, Chunyan ¹ ; Qi, Xitao ¹ ; Wen, Tianxiang ¹ ; Hu, Jianguan ¹ ;

作者机构： 1.Guangdong Acad Agr Sci, Crop Res Inst, Guangdong Prov Key Lab Crops Genet & Improvement, Guangzhou 510640, Guangdong, Peoples R China

2.Guangdong Acad Agr Sci, Crop Res Inst, Guangdong Prov Key Lab Crops Genet & Imp

关键词： Maize (Zea mays L.);Low temperature stress;RNA-seq;Cold-responsive gene

期刊名称：CROP JOURNAL （影响因子：4.407；五年影响因子：5.687 ）

ISSN： 2095-5421

年卷期： 2017 年 5 卷 5 期

页码：

收录情况： SCI

摘要： Stress induced by low temperature, which represents a widespread environmental factor, strongly affects maize growth and yield. However, the physiological characteristics and molecular regulatory mechanisms of maize seedlings in response to cold remain poorly understood. In this study, using RNA-seq, we investigated the transcriptome profiles of two sweet corn inbred lines, ?Richao? (RC) and C5, under cold stress. A total of 357 and 455 differentially expressed genes (DEGs) were identified in the RC and C5 lines, respectively, 94 DEGs were detected as common DEGs related to cold response in both genotypes, and a total of 589 DEGs were detected as cold tolerance-associated genes. By combining protein function clustering analysis and significantly enriched Gene Ontology (GO) terms analysis, we suggest that transcription factors may play a dominating role in the cold stress response and tolerance of sweet corn. Furthermore, 74 differentially expressed transcription factors were identified, of those many genes involved in the metabolism and regulation of hormones. These results expand our understanding of the complex mechanisms involved in chilling tolerance in maize, and provide a set of candidate genes for further genetic analyses.(C) 2017 Crop Science of China and Institute of Crop Science, CAAS. Production and hosting by Elsevier B.V.

相关文献

[1]Arbuscular mycorrhizal fungi (AMF) increase growth and secondary metabolism in cucumber subjected to low temperature stress. Jin, Wenjuan,Liu, Airong,Zhang, Shaojie,Wang, Fenghua,Lin, Xiaomin,He, Chaoxing,Liu, Dilin. 2013

[2]Arbuscular Mycorrhizal Fungus Alleviates Chilling Stress by Boosting Redox Poise and Antioxidant Potential of Tomato Seedlings. Liu, Airong,Chen, Shuangchen,Wang, Mengmeng,Chang, Rui,Lin, Xiaomin,Ahammed, Golam Jalal,Chen, Shuangchen,Wang, Zhonghong,Liu, Dilin,Bai, Bing.

[3]基于RNA-seq筛选影响猪肉品质的关键候选基因. 肖明飞,申露露,何逸懿,易宏波,唐青松,李莉,洪兴,李大江,徐娥. 2022

[4]辣椒杂交种与亲本苗期叶片基因差异表达分析. 徐小万,李颖,王恒明,李涛,何水林,官德义. 2016

[5]玫烟色棒束孢诱导的小菜蛾免疫响应表达谱分析. 雷妍圆,何余容,谢梅琼,吕利华,顾家睿. 2016

[6]RNA-Seq Analyses for Two Silkworm Strains Reveals Insight into Their Susceptibility and Resistance to Beauveria bassiana Infection. Xing, Dongxu,Jiang, Liang,Xia, Qingyou,Xing, Dongxu,Yang, Qiong,Li, Qingrong,Xiao, Yang,Ye, Mingqiang. 2017

[7]De novo Transcriptome Assembly of Chinese Kale and Global Expression Analysis of Genes Involved in Glucosinolate Metabolism in Multiple Tissue. Wu, Shuanghua,Lei, Jianjun,Chen, Guoju,Cao, Bihao,Chen, Changming,Chen, Hancai. 2017

[8]Transcriptome profiling of resistant and susceptible Cavendish banana roots following inoculation with Fusarium oxysporum f. sp cubense tropical race 4. Li, Chun-yu,Jin, Yan,Kuang, Rui-bin,Yang, Qiao-song,Sheng, Ou,Wei, Yue-rong,Hu, Chun-hua,Dong, Tao,Yi, Gan-jun,Li, Chun-yu,Jin, Yan,Kuang, Rui-bin,Yang, Qiao-song,Sheng, Ou,Wei, Yue-rong,Hu, Chun-hua,Dong, Tao,Yi, Gan-jun,Deng, Gui-ming,Yang, Jing,Zuo, Cun-wu,Lv, Zhi-cheng,Viljoen, Altus. 2012

[9]GADD45 beta, an anti-tumor gene, inhibits avian leukosis virus subgroup J replication in chickens. Zhang, Xinheng,Yan, Zhuanqiang,Li, Xinjian,Lin, Wencheng,Dai, Zhenkai,Yan, Yiming,Lu, Piaopiao,Chen, Weiguo,Chen, Feng,Ma, Jingyun,Xie, Qingmei,Zhang, Xinheng,Yan, Zhuanqiang,Li, Xinjian,Lin, Wencheng,Dai, Zhenkai,Yan, Yiming,Lu, Piaopiao,Chen, Weiguo,Chen, Feng,Ma, Jingyun,Xie, Qingmei,Zhang, Xinheng,Yan, Zhuanqiang,Li, Xinjian,Lin, Wencheng,Dai, Zhenkai,Yan, Yiming,Lu, Piaopiao,Chen, Weiguo,Chen, Feng,Ma, Jingyun,Xie, Qingmei,Zhang, Xinheng,Li, Xinjian,Lin, Wencheng,Dai, Zhenkai,Yan, Yiming,Lu, Piaopiao,Chen, Weiguo,Chen, Feng,Ma, Jingyun,Xie, Qingmei,Lin, Wencheng,Chen, Weiguo,Chen, Feng,Xie, Qingmei,Zhang, Huanmin. 2016

[10]Comparative Transcriptome Analysis Reveals Differential Transcription in Heat-susceptible and Heat-tolerant Pepper (Capsicum annum L.) Cultivars under Heat Stress. Li, Tao,Xu, Xiaowan,Li, Ying,Wang, Hengming,Li, Zhiliang,Li, Zhenxing,Li, Tao,Xu, Xiaowan.

[11]Transcriptome comparison in the pituitary-adrenal axis between Beagle and Chinese Field dogs after chronic stress exposure. Luo, Wei,Xu, Haiping,Nie, Qinghua,Luo, Wei,Xu, Haiping,Nie, Qinghua,Luo, Wei,Xu, Haiping,Nie, Qinghua,Fang, Meixia,Xing, Huijie.

[12]Transcriptome sequencing reveals genetic mechanisms underlying the transition between the laying and brooding phases and gene expression changes associated with divergent reproductive phenotypes in chickens. Shen, Xu,Shen, Xu,Shen, Xu,Xu, Haipin,Nie, Qinghua,Zhang, Xiquan,Shen, Xu,Xu, Haipin,Nie, Qinghua,Zhang, Xiquan,Shen, Xu,Bai, Xue,Xu, Jin,Lu, Xuemei,Zhou, Min.

[13]Transcriptional profiling of the responses to infection by the false smut fungus Ustilaginoidea virens in resistant and susceptible rice varieties. Yang, Chao,Li, Luoye,Li, Jianxiong,Feng, Aiqing,Zhu, Xiaoyuan.

[14]Transcriptome-wide sequencing provides insights into geocarpy in peanut (Arachis hypogaea L.). Li, Haifen,Hong, Yanbin,Zhu, Fanghe,Zhu, Wei,Liu, Haiyan,Zhang, Erhua,Zhong, Ni,Wen, Shijie,Li, Xingyu,Zhou, Guiyuan,Li, Shaoxiong,Varshney, Rajeev,Liang, Xuanqiang,Yang, Qingli,Pan, Lijuan,Chen, Na,Chi, Xiaoyuan,Chen, Mingna,Yang, Zhen,Wang, Tong,Wang, Mian,Yu, Shanlin,Yang, Qingli,Li, Heying,Liu, Hong,Wu, Hong,Varshney, Rajeev.

作者其他论文更多>>

Citrus huanglongbing detection: A hyperspectral data-driven model integrating feature band selection with machine learning algorithms

作者：Yan, Kangting;Yang, Jing;Xiao, Junqi;Xu, Xidan;Guo, Jun;Lan, Yubin;Zhang, Yali;Yan, Kangting;Lan, Yubin;Yang, Jing;Xiao, Junqi;Xu, Xidan;Guo, Jun;Zhu, Hongyun;Zhang, Yali;Song, Xiaobing

关键词：Hyperspectral technology; Citrus Huanglongbing; Machine learning; Feature band extraction; Rapid detection
Maize leaf yellowing gene ZmCAAX modulates growth and drought resistance by regulating abscisic acid contents through interaction with the ABA biosynthetic enzyme ZmNCED3

作者：Li, Xiaohu;Du, Jiyuan;Zhuge, Shilin;Li, Xinzheng;Nie, Yongxin;Zhang, Zhiming;Ding, Haiping;Zhang, Bin;Wang, Yujiao;Chen, Shuai;Yang, Aiguo;Li, Qigui;Li, Gaoke;Xu, Fang

关键词：Zea mays; drought stress; abscisic acid; carotenoids; map-based cloning; ZmCAAX
Genome-Wide Analysis of the Maize LBD Gene Family Reveals a Role for ZmLBD12 in the Development of Lateral Roots

作者：Wang, Shifeng;Wang, Yang;Zhong, Jianbing;Huang, Jun;Xu, Wenlin;Zhai, Lihong;Gong, Qingyou;Li, Gaoke

关键词：maize; LBD gene family; ZmLBD12; function analysis; lateral root
Transcriptome Analysis of Potential Regulatory Genes under Chemical Doubling in Maize Haploids

作者：Li, Youqiang;Pu, Rumin;Xiang, Wenqi;Meng, Xin;Yang, Shiqi;Hu, Gaojiao;Zhao, Shuang;Han, Jialong;Xia, Chao;Lan, Hai;Wang, Qingjun;Li, Jingwei;Lu, Yanli;Lin, Haijian;Zhan, Penglin;Liao, Changjian;Yu, Yongtao;Li, Gaoke

关键词：maize; haploid; transcriptome; mitosis; kinesin
Modulation of carotenoid biosynthesis in maize (Zea mays L.) seedlings by exogenous abscisic acid and salicylic acid under low temperature

作者：Xiang, Nan;Zhang, Bing;Guo, Xinbo;Xiang, Nan;Hu, Jianguang;Li, Kun

关键词：Abscisic acid; Salicylic acid; Maize seedlings; Carotenoid; Temperature stress
Exploring a maize-derived dietary fiber-phenolic acid complex with prebiotic effects

作者：Sun, Yujing;Zhang, Tao;Miao, Ming;Li, Gaoke;Li, Wu;Li, Chunyan;Li, Gaoke;Li, Wu;Li, Chunyan

关键词：Cell wall; Dietary fiber; Structural properties; Functional properties; Phenolic compounds
Impact of low temperature on the chemical profile of sweet corn kernels during post-harvest storage

作者：Xiao, Yingni;Xie, Lihua;Li, Yuliang;Li, Chunyan;Yu, Yongtao;Hu, Jianguang;Li, Gaoke

关键词：Sweet corn; Low temperature; Metabolomics; Metabolite profile; Sucrose

Comparative transcriptome analysis of sweet corn seedlings under low-temperature stress

作者其他论文更多>>

Citrus huanglongbing detection: A hyperspectral data-driven model integrating feature band selection with machine learning algorithms

Maize leaf yellowing gene ZmCAAX modulates growth and drought resistance by regulating abscisic acid contents through interaction with the ABA biosynthetic enzyme ZmNCED3

Genome-Wide Analysis of the Maize LBD Gene Family Reveals a Role for ZmLBD12 in the Development of Lateral Roots

Transcriptome Analysis of Potential Regulatory Genes under Chemical Doubling in Maize Haploids

Modulation of carotenoid biosynthesis in maize (Zea mays L.) seedlings by exogenous abscisic acid and salicylic acid under low temperature

Exploring a maize-derived dietary fiber-phenolic acid complex with prebiotic effects

Impact of low temperature on the chemical profile of sweet corn kernels during post-harvest storage

意见箱

Comparative transcriptome analysis of sweet corn seedlings under low-temperature stress

作者其他论文 更多>>

Citrus huanglongbing detection: A hyperspectral data-driven model integrating feature band selection with machine learning algorithms

Maize leaf yellowing gene ZmCAAX modulates growth and drought resistance by regulating abscisic acid contents through interaction with the ABA biosynthetic enzyme ZmNCED3

Genome-Wide Analysis of the Maize LBD Gene Family Reveals a Role for ZmLBD12 in the Development of Lateral Roots

Transcriptome Analysis of Potential Regulatory Genes under Chemical Doubling in Maize Haploids

Modulation of carotenoid biosynthesis in maize (Zea mays L.) seedlings by exogenous abscisic acid and salicylic acid under low temperature

Exploring a maize-derived dietary fiber-phenolic acid complex with prebiotic effects

Impact of low temperature on the chemical profile of sweet corn kernels during post-harvest storage

意 见 箱

作者其他论文更多>>

意见箱