苗期甘蓝型油菜长期受渍下的转录组分析

doi:10.12190/j.issn.2096-1197.2025.06.03

摘要/Abstract

摘要： 【目的】解析苗期甘蓝型油菜响应长期渍害的分子机理,筛选相关的重要代谢通路和核心基因。【方法】以敏渍甘蓝型油菜自交系YZ59为研究对象,取正常生长和渍水7 d的苗期叶片进行转录组测序,筛选差异表达基因并进行GO富集分析和KEGG富集分析。【结果】从正常生长叶片和渍水7 d叶片中筛选到差异表达基因3 085个,其中,上调基因2 313个、下调基因772个;从3 085个差异表达基因中共筛选到312个转录因子,其中,206个上调、106个下调。上调数目最多的是bHLH家族转录因子,为30个;下调数目最多的是MYB家族转录因子,为20个。GO富集分析表明,差异表达基因主要富集在分子功能、细胞组分和生物过程三大一级条目中;在四级条目中,DNA结合和RNA结合条目富集到的差异表达基因数目最多。KEGG富集分析表明,差异表达基因主要富集在植物激素信号转导通路、MAPK信号通路和植物-病原体互作通路中;MAPK信号通路和植物-病原体互作通路中绝大多数基因均表达上调;植物激素信号转导通路中上调基因和下调基因均存在,但前者个数多于后者。对淀粉蔗糖代谢通路以及糖酵解糖异生通路进行单独分析发现,其中有许多关键基因发生差异表达,上调居多。长期渍害促进了苗期甘蓝型油菜体内D-葡萄糖向D-葡萄糖-6-磷酸的转化和D-果糖向D-果糖-6-磷酸的转化以及海藻糖的合成,以维持细胞正常生命活动;长期渍害还加速了糖酵解释放能量的过程,并促进了机体内乙酸、乙醛和乙醇之间的相互转化。【结论】苗期甘蓝型油菜对长期渍害的响应以基因上调为主,bHLH和MYB家族转录因子是关键调控因子;糖酵解过程在苗期甘蓝型油菜应对长期渍害时起关键作用。

关键词: 甘蓝型油菜, 渍害, 转录组测序, bHLH转录因子, MYB转录因子, 富集分析

Abstract: 【Objective】 To elucidate the molecular mechanism by which Brassica napus responds to long-term waterlogging stress at the seedling stage,and to screen for relevant important metabolic pathways and core genes. 【Methods】 The waterlogging-sensitive B. napus inbred line YZ59 was used as the research object. Seedling leaves under normal growth and under 7 d of waterlogging stress were subjected to transcriptome sequencing. Differentially expressed genes were screened,followed by GO （gene ontology） and KEGG （Kyoto encyclopedia of genes and genomes） enrichment analyses. 【Results】 A total of 3 085 differentially expressed genes were identified between the normal growth leaves and the 7 d waterlogged leaves,including 2 313 upregulated genes and 772 downregulated genes;among the 3 085 differentially expressed genes,312 transcription factors were identified,with 206 upregulated and 106 downregulated. The bHLH family transcription factors showed the largest number of upregulated genes （30）,while the MYB family transcription factors showed the largest number of downregulated genes （20）. GO enrichment analysis indicated that the differentially expressed genes were mainly enriched in the three primary categories：molecular function,cellular component,and biological process;the highest number of differentially expressed genes enriched in the fourth-level terms were DNA binding and RNA binding. KEGG enrichment analysis showed that differentially expressed genes were primarily enriched in the plant hormone signal transduction pathway,the MAPK signaling pathway,and the plant-pathogen interaction pathway;the vast majority of genes in the MAPK signaling pathway and the plant-pathogen interaction pathway were upregulated;in the plant hormone signal transduction pathway,both upregulated and downregulated genes were present,but the former outnumbered the latter. Separate analysis of the starch and sucrose metabolism pathway,as well as the glycolysis and gluconeogenesis pathways,revealed that many key genes were differentially expressed,with upregulation predominating. Long-term waterlogging promoted the conversion of D-glucose to D-glucose-6-phosphate and the conversion of D-fructose to D-fructose-6-phosphate,as well as the synthesis of trehalose,to maintain normal cellular life activities in the seedling B. napus;long-term waterlogging also accelerated the process of energy release through glycolysis and promoted the interconversion among acetate,acetaldehyde,and ethanol in the organism. 【Conclusion】 The response of seedling B. napus to long-term waterlogging stress is dominated by gene upregulation,with bHLH and MYB transcription factor families being the key regulatory factors;the glycolysis process plays a crucial role in the response of seedling B. napus to long-term waterlogging stress.

Key words: Brassica napus, Waterlogging stress, Transcriptome sequencing, bHLH transcription factor, MYB transcription factor, Enrichment analysis

中图分类号:

S634.3

龙金佳, 徐劲松. 苗期甘蓝型油菜长期受渍下的转录组分析[J]. 北方农业学报, 2025, 53(6): 26-42.

LONG Jinjia, XU Jinsong. Transcriptome analysis of Brassica napus at the seedling stage under long-term waterlogging stress[J]. Journal of Northern Agriculture, 2025, 53(6): 26-42.

参考文献

[1] 郭奕邑.甘蓝型油菜发芽期耐渍基因型差异及候选基因鉴定[D].杭州:浙江大学,2021.
[2] 周果曦,周香玉,李超,等.植物生长调节剂调控甘蓝型油菜苗期耐渍性的生理机制[J].中国油料作物学报,2025,47(3):714-723.
[3] 杨奕涵.渍水对油菜生长的影响及其调控研究[D].长沙:湖南农业大学,2022.
[4] 李兴华.油菜氮素利用规律及苗期渍水对其出苗和幼苗生长影响研究[D].武汉:华中农业大学,2015.
[5] 何泽威.播种期阴雨渍害对油菜产量、品质的影响[D].荆州:长江大学,2023.
[6] 龙光桥.油菜渍害的危害及其防治[J].湖南农业,2010(12):15.
[7] 余霆杰,郑倩倩,龚容,等.油菜BnMPK5激酶基因的克隆及其在渍害胁迫下的功能分析[J].四川农业大学学报,2025,43(3):597-606.
[8] 胡珂,何鹏,高文波.西南地区甘蓝型冬油菜苗期渍害危险性分布特征研究[J].农学学报,2023,13(10):62-69.
[9] 李东.MYB89转录因子和褪黑素调控拟南芥和甘蓝型油菜种子脂肪酸积累的分子机制研究[D].杨凌:西北农林科技大学,2022.
[10] ZHANG Y S,XU Y,XING W T,et al.Identification of the passion fruit(Passiflora edulis Sims)MYB family in fruit development and abiotic stress,and functional analysis of PeMYB87 in abiotic stresses[J].Frontiers in Plant Science,2023,14:1124351.
[11] HE J,LIU Y,YUAN D,et al.An R2R3 MYB transcription factor confers brown planthopper resistance by regulating the phenylalanine ammonia-lyase pathway in rice[J].Proceedings of the National Academy of Sciences,2020,117(1):271-277.
[12] ZHANG H F,GUO J B,CHEN X Q,et al.Pepper bHLH transcription factor CabHLH035 contributes to salt tolerance by modulating ion homeostasis and proline biosynthesis[J].Horticulture Research,2022,9:uhac203.
[13] AN J P,WANG X F,ZHANG X W,et al.An apple MYB transcription factor regulates cold tolerance and anthocyanin accumulation and undergoes MIEL1-mediated degradation[J].Plant Biotechnology Journal,2020,18(2):337-353.
[14] LIANG Y F,MA F,LI B Y,et al.A bHLH transcription factor,SlbHLH96,promotes drought tolerance in tomato[J].Horticulture Research,2022,9:uhac198.
[15] CHU X Q,LI M Z,ZHANG S J,et al.HBI1-TCP20 interaction positively regulates the CEPs-mediated systemic nitrate acquisition[J].Journal of Integrative Plant Biology,2021,63(5):902-912.
[16] HIROTA A,KATO T,FUKAKI H,et al.The auxin-regulated AP2/EREBP gene PUCHI is required for morphogenesis in the early lateral root primordium of Arabidopsis[J].The Plant Cell,2007,19(7):2156-2168.
[17] JUNG H,CHUNG P J,PARK S H,et al.Overexpression of OsERF48 causes regulation of OsCML16,a calmodulin-like protein gene that enhances root growth and drought tolerance[J].Plant Biotechnology Journal,2017,15(10):1295-1308.
[18] LYU S K,GUO H,ZHANG M,et al.Large-scale cloning and comparative analysis of TaNAC genes in response to stripe rust and powdery mildew in wheat(Triticum aestivum L.)[J].Genes,2020,11(9):1073.
[19] FANG L C,SU L Y,SUN X M,et al.Expression of Vitis amurensis NAC26 in Arabidopsis enhances drought tolerance by modulating jasmonic acid synthesis[J].Journal of Experimental Botany,2016,67(9):2829-2845.
[20] SHAHNEJAT-BUSHEHRI S,TARKOWSKA D,SAKURA BA Y,et al.Arabidopsis NAC transcription factor JUB1 regulates GA/BR metabolism and signalling[J].Nature Plants,2016,2:16013.
[21] 杨华庚,黎彬,李娜,等.胡椒扦插苗对涝渍胁迫的生理响应[J].生物技术进展,2023,13(4):565-574.
[22] 王亚玲,闫鹏涛,张丽娟,等.环核苷酸门控离子通道蛋白在植物生长发育及胁迫响应中的研究进展[J].河南农业大学学报,2025,59(1):21-28.
[23] YANG D,CHEN T,WU Y S,et al.Genome-wide analysis of the peanut CaM/CML gene family reveals that the AhCML69 gene is associated with resistance to Ralstonia solanacearum[J].BMC Genomics,2024,25(1):200.
[24] YUAN X P,ZHAO Y.SnRK2 kinases sense molecular crowding and form condensates to disrupt ABI1 inhibition[J].Science Advances,2025,11(5):eadr8250.
[25] LI C,ZHANG S,LI J J,et al.PHB3 interacts with BRI1 and BAK1 to mediate brassinosteroid signal transduction in Arabidopsis and tomato[J].New Phytologist,2024,241(4):1510-1524.
[26] ELSISI M,ELSHIEKH M,SABRY N,et al.The genetic orchestra of salicylic acid in plant resilience to climate change induced abiotic stress:critical review[J].Stress Biology,2024,4(1):31.
[27] 张璐.过表达油菜BrMAPK3和BrMAPK5拟南芥的抗性研究[D].兰州:西北师范大学,2022.
[28] 刘亚菲,张帆,梁卫红.水稻MAPK级联的功能和作用机制[J].中国生物化学与分子生物学报,2021,37(12):1569-1576.
[29] 张曼.甘蓝型油菜zs-d半矮秆性状形成机制的研究[D].武汉:华中农业大学,2024.
[30] 耿存娟.淹水胁迫下玉米幼苗的转录组分析及耐渍候选基因克隆[D].武汉:华中农业大学,2014.