花生荚果响应干旱和渍涝胁迫的转录组学分析

doi:10.7668/hbnxb.20195949

华北农学报 ›› 2025, Vol. 40 ›› Issue (6): 31-39. doi: 10.7668/hbnxb.20195949

所属专题： 油料作物；抗旱节水；生物技术；

• 作物遗传育种·种质资源·生物技术 • 上一篇下一篇

花生荚果响应干旱和渍涝胁迫的转录组学分析

于天一¹, 樊兆博², 张佳蕾³, 路亚¹, 吴菊香¹, 杨吉顺¹, 李尚霞¹, 吴正锋¹, 万书波⁴

¹ 山东省花生研究所,山东青岛 266100
² 山东省烟台市农业科学研究院,山东烟台 265500
³ 山东省农业科学院农作物种质资源研究所,山东济南 250100
⁴ 山东省农业科学院,山东济南 250100

收稿日期:2025-03-24 出版日期:2025-12-31
通讯作者:
吴正锋(1976—),男,山东茌平人,研究员,博士,主要从事花生栽培生理相关研究。
万书波(1962—),男,山东栖霞人,研究员,主要从事花生栽培与生理生态研究。
作者简介:
于天一(1984—),男,山东青岛人,副研究员,博士,主要从事花生栽培生理研究。
基金资助:
青岛市自然科学基金原创探索项目(24-4-4-zrjj-146-jch); 国家重点研发计划课题(2021YFB3901303); 山东省农业科学院农业科技创新工程项目(CXGC2025G13); 山东省农业科学院农业科技创新工程项目(CXGC2025A08); 山东省重点研发计划项目(2021LZGC026); 青岛市科技惠民计划项目(25-1-5-xdny-21-nsh)

Transcriptomic Analysis of Peanut Pods in Response to Drought and Waterlogging Stresses

YU Tianyi¹, FAN Zhaobo², ZHANG Jialei³, LU Ya¹, WU Juxiang¹, YANG Jishun¹, LI Shangxia¹, WU Zhengfeng¹, WAN Shubo⁴

¹ Shandong Peanut Research Institute,Qingdao 266100,China
² Yantai Academy of Agricultural Sciences, Yantai 265500,China
³ Institute of Crop Germplasm Resources,Shandong Academy of Agricultural Sciences, Jinan 250100,China
⁴ Shandong Academy of Agricultural Sciences,Jinan 250100,China

Received:2025-03-24 Published:2025-12-31

摘要/Abstract

摘要： 为解析花生荚果响应水分胁迫的分子机制,利用盆栽试验并结合转录组学分析,以正常供水处理为对照,系统探究了花针期阶段性干旱和渍涝胁迫对花生产量、品质及基因表达的影响。结果表明,干旱和渍涝胁迫均显著降低花生荚果产量(降幅分别为26.43%和77.69%)及籽仁粗脂肪含量(降幅分别为9.46, 6.71百分点)。转录组分析进一步表明,干旱胁迫组与对照组、渍涝胁迫组与对照组分别鉴定出1 525,1 382个差异表达基因,且两类差异表达基因均以表达下调为主,其中,干旱胁迫抑制了花生荚果中与脂质和脂肪酸代谢相关的6个关键代谢过程,其中88.38%的基因表达呈下调趋势,揭示了脂质代谢紊乱可能是干旱导致花生产量和品质下降的主要原因。渍涝胁迫则主要通过下调催化活性、跨膜运输、氧化还原及次生代谢物的生物合成等相关基因的表达,干扰荚果的代谢与防御功能。此外,KEGG富集分析结果显示,代谢途径和次生代谢物生物合成通路在2种水分胁迫下均受到显著影响。关键基因qRT-PCR验证结果与RNA-seq数据一致,证实了转录组结果的可靠性。综上,从转录组层面阐明了花生荚果响应水分胁迫的分子基础,明确脂质代谢紊乱是干旱胁迫导致花生产量下降、品质变劣的主要原因,而花生主要通过调控荚果中氧化还原及代谢相关通路基因的表达,以应对渍涝胁迫带来的不利影响。

关键词: 花生荚果, 干旱胁迫, 渍涝胁迫, 转录组, 籽仁品质, 产量

Abstract:

To elucidate the molecular mechanisms underlying peanut pod responses to water stress,this study employed pot experiments combined with transcriptomic analysis.Using well-watered conditions as the control, we systematically investigated the effects of periodic drought and waterlogging stress during the flowering-pegging stage on yield,quality,and gene expression in peanut pods. Results demonstrated that both drought and waterlogging stresses significantly reduced peanut pod yield(by 26.43% and 77.69%,respectively)and crude fat content in kernels (by 9.46, 6.71 percentage points,respectively).Transcriptomic analysis further revealed 1 525 and 1 382 differentially expressed genes(DEGs)in the drought-stress and waterlogging-stress groups compared to the control, respectively, with down-regulated expression being predominant in both sets of DEGs. Specifically, drought stress suppressed six key metabolic processes related to lipid and fatty acid metabolism in peanut pods,with 88.38% of associated genes showing downregulated expression,indicating that lipid metabolic disruption may be the primary cause of yield and quality reduction under drought. Waterlogging stress predominantly interfered with pod metabolism and defense functions by downregulating genes associated with catalytic activity,transmembrane transport,redox reactions,and biosynthesis of secondary metabolites.Moreover, KEGG enrichment analysis indicated that metabolic pathways and biosynthesis of secondary metabolites were significantly affected under both water stress conditions. Key gene validation via qRT-PCR corroborated the RNA-seq data, confirming the reliability of the transcriptomic findings. In summary, this research elucidates the molecular basis of peanut pod response to water stress at the transcriptome level, demonstrating that lipid metabolic disruption is the primary factor underlying yield reduction and quality deterioration under drought stress, whereas peanut pods mitigate the adverse effects of waterlogging mainly by modulating the expression of genes associated with redox homeostasis and metabolic pathways.

Key words: Peanut pod, Drought stress, Waterlogging stress, Transcriptome, Kernel quality, Yield

中图分类号:

S565.2

于天一, 樊兆博, 张佳蕾, 路亚, 吴菊香, 杨吉顺, 李尚霞, 吴正锋, 万书波. 花生荚果响应干旱和渍涝胁迫的转录组学分析[J]. 华北农学报, 2025, 40(6): 31-39. doi: 10.7668/hbnxb.20195949.

YU Tianyi, FAN Zhaobo, ZHANG Jialei, LU Ya, WU Juxiang, YANG Jishun, LI Shangxia, WU Zhengfeng, WAN Shubo. Transcriptomic Analysis of Peanut Pods in Response to Drought and Waterlogging Stresses[J]. Acta Agriculturae Boreali-Sinica, 2025, 40(6): 31-39. doi: 10.7668/hbnxb.20195949.

http://www.hbnxb.net/CN/Y2025/V40/I6/31

图/表 8

表1 引物序列信息

Tab.1 Primers sequence information

基因名称 Gene name	基因注释 Gene annotation	上下调情况 Up-down situation	引物序列(5'—3') Primer sequence (5'—3')
LOC112697400	硬脂酰-[酰基-载体蛋白]9-去饱和酶6%2C叶绿体	D vs CK:不显著 W vs CK:上调	F:GGATCAGGAGGCTGCAAGAG R:TCTTGTGATGCAAGCAAAGCC
LOC112710465	亚油酸 9S-脂氧合酶	D vs CK:上调 W vs CK:下调	F:AGCACAGATGCCGTACACTC R:CAATACTGAAGAACCATAACTCCCT
LOC112727170	乙醇脱氢酶三类	D vs CK:不显著 W vs CK:下调	F:AACAGCTTTCGGAGGCTTCA R:AGAACACAACGGAGACACCC
LOC112738386	蔗糖合成酶	D vs CK:不显著 W vs CK:不显著	F:TGAACCTTGTCGTGGTAGCC R:GTGTCGCAGATCACACGGTA
LOC112764235	葡萄糖-1-磷酸腺苷基转移酶小亚基2%2C叶绿体	D vs CK:不显著 W vs CK:不显著	F:CACTCACACAACTCTCGCAAT R:CGGAAAGTTGTGAGGAGGAGA
LOC112766166	1% 2c4 -葡聚糖分支酶1%2C叶绿体/淀粉体	D vs CK:上调 W vs CK:不显著	F:CAGCGGGTGGTGTGTGTA R:AGTTCTCCCTCAAGCTACTGG
LOC112776097	亚油酸 9S-脂氧合酶	D vs CK:上调 W vs CK:下调	F:ATGCAAACTCGTGCGGAG R:CGGCATGAATTGCCTGCTAA
LOC112802430	β-淀粉酶1%2C叶绿体	D vs CK:不显著 W vs CK:不显著	F:CAGCAGCCTATCTCTCTGGC R:CGGCATTACGCTACATGAATGG
LOC112802492	乙醛脱氢酶家族2成员B7%2C线粒体异构体X3\|\|乙醛脱氢酶家族2成员B7%2C线粒体%2C转录变体	D vs CK:不显著 W vs CK:上调	F:GGAAGTGGTACAGAGGGCAA R:TCCCTTGTCCACTCATCTTGT

表2 干旱和渍涝胁迫对花生产量、产量构成因素及干物质量的影响

Tab.2 Effects of drought and waterlogging stress on peanut yield,yield components and dry matter weight

处理 Treatments	产量/(g/株) Yield	生物产量/(g/株) Biomass	收获指数/% Harvest index	单株果数 Pod number per plant	千克果数 Pod number per kg
CK	29.32±2.74a	54.80±3.89a	53.53±3.98a	25.42±3.26a	875.39±161.60b
D	21.57±0.78b	43.64±4.49b	49.66±3.58a	21.42±3.39a	991.15±130.26b
W	6.54±1.73c	37.41±2.47b	17.33±3.64b	8.17±1.18b	1 286.36±235.88a

图1 干旱和渍涝胁迫对花生籽仁品质的影响柱上不同小写字母表示处理间差异达0.05显著水平。

Fig.1 Effects of drought and waterlogging stress on kernel quality of peanut Different lowercase letters on the column indicate significant difference of 0.05 among different treatments.

表3 转录组数据质控

Tab.3 Summary of the RNA-Seq results

样本名称 Sample name	过滤后读数 Clean reads	Q20/%	Q30/%	GC/%
CK1	46 203 906	98.31	94.64	46.47
CK2	51 365 320	98.29	94.57	46.28
CK3	45 946 732	98.22	94.43	45.57
D1	46 391 496	98.16	94.28	46.58
D2	50 736 972	98.30	94.67	47.55
D3	45 234 596	97.96	93.81	45.43
W1	54 049 742	98.25	94.50	46.50
W2	52 552 574	98.02	93.96	45.41
W3	49 924 880	97.89	93.60	45.52

图2 干旱及渍涝胁迫下花生荚果差异表达基因分析 A.差异表达基因数量;B.差异表达基因韦恩图。

Fig.2 Analysis of differential expression gene in peanut pods under drought and waterlogging stress A.The number of differentially expressed genes;B.Venn diagram of differentially expressed genes.

图3 差异表达基因 GO 富集分析 A.干旱与对照组;B.渍涝与对照组;C.干旱与渍涝组。GO:0003824.催化活性;GO:0003854.3-β-羟基-δ-类固醇脱氢酶活性;GO:0004312.脂肪酸合成酶活性;GO:0004315.3-氧酰基-[酰基载体蛋白]合成酶活性;GO:0004553.水解酶活性,水解O-糖基化合物;GO:0004601.过氧化物酶活性;GO:0004866.内肽酶抑制剂活性;GO:0005506.铁离子结合;GO:0005975.碳水化合物代谢过程;GO:0006629.脂质代谢过程;GO:0006631.脂肪酸代谢过程;GO:0006633.脂肪酸生物合成过程;GO:0008171.O-甲基转移酶活性;GO:0008610.脂质生物合成过程;GO:0016053.有机酸生物合成过程;GO:0016229.类固醇脱氢酶活性;GO:0016491.氧化还原酶活性;GO:0016684.氧化还原酶活性,作为受体作用于过氧化物;GO:0016705.氧化还原酶活性,作用于配对供体,结合或减少分子氧;GO:0016746.转移酶活性,转移酰基;GO:0016747.转移酶活性,转移除氨基酰基以外的酰基;GO:0016758.转移酶活性,转移己糖基;GO:0016798.水解酶活性,作用于糖基键;GO:0020037.血红素结合;GO:0030001.金属离子输运;GO:0030414.肽酶抑制剂活性:GO:0032787.一元羧酸代谢过程;GO:0033764.类固醇脱氢酶活性,作用于CH-OH基团的供体,NAD或NADP作为受体;GO:0044255.细胞脂质代谢过程;GO:0044281.小分子代谢过程;GO:0044283.小分子生物合成过程;GO:0046394.羧酸生物合成过程;GO:0046906.四吡咯绑定;GO:0055085.跨膜运输;GO:0055114.氧化还原过程;GO:0060962.RNA聚合酶Ⅱ对核糖体蛋白基因转录的调控;GO:0061135.内多肽酶调节剂活性;GO:0072330.一元羧酸生物合成过程。

Fig.3 GO enrichment of differentially expressed genes A. Drought and control group;B. Waterlogging and control group;C. Drought and waterlogging group.GO:0003824. Catalytic activity;GO:0003854. 3-beta-hydroxy-delta5-steroid dehydrogenase activity;GO:0004312. Fatty acid synthase activity;GO:0004315. 3-oxoacyl-[acyl-carrier-protein]synthase activity;GO:0004553. Hydrolase activity,hydrolyzing O-glycosyl compounds;GO:0004601. Peroxidase activity;GO:0004866. Endopeptidase inhibitor activity;GO:0005506. Iron ion binding;GO:0005975. Carbohydrate metabolic process;GO:0006629. Lipid metabolic process;GO:0006631. Fatty acid metabolic process;GO:0006633. Fatty acid biosynthetic process;GO:0008171. O-methyltransferase activity;GO:0008610. Lipid biosynthetic process;GO:0016053. Organic acid biosynthetic process;GO:0016229. Steroid dehydrogenase activity;GO:0016491. Oxidoreductase activity;GO:0016684. Oxidoreductase activity,acting on peroxide as acceptor;GO:0016705. Oxidoreductase activity,acting on paired donors,with incorporation or reduction of molecular oxygen;GO:0016746. Transferase activity,transferring acyl groups;GO:0016747. Transferase activity,transferring acyl groups other than amino-acyl groups;GO:0016758. Transferase activity,transferring hexosyl groups;GO:0016798. Hydrolase activity,acting on glycosyl bonds;GO:0020037. Heme binding;GO:0030001. Metal ion transport;GO:0030414. Peptidase inhibitor activity;GO:0032787. Monocarboxylic acid metabolic process;GO:0033764. Steroid dehydrogenase activity,acting on the CH-OH group of donors,NAD or NADP as acceptor;GO:0044255. Cellular lipid metabolic process;GO:0044281. Small molecule metabolic process;GO:0044283. Small molecule biosynthetic process;GO:0046394. Carboxylic acid biosynthetic process;GO:0046906. Tetrapyrrole binding;GO:0055085. Transmembrane transport;GO:0055114. Oxidation-reduction process;GO:0060962. Regulation of ribosomal protein gene transcription by RNA polymerase Ⅱ;GO:0061135. Endopeptidase regulator activity;GO:0072330. Monocarboxylic acid biosynthetic process.

图4 差异表达基因 Top 20 KEGG 富集图 A.干旱与对照组;B.渍涝与对照组;C.干旱与渍涝组。adu00010.糖酵解/糖异生;adu00040.戊糖和葡萄糖醛酸之间的相互转化;adu00052.半乳糖代谢;adu00061.脂肪酸生物合成;adu00071.脂肪酸降解;adu00232.咖啡因代谢;adu00330.精氨酸和脯氨酸代谢;adu00350.酪氨酸代谢;adu00430.牛磺酸和次牛磺酸代谢;adu00460.氰胺酸代谢;adu00500.淀粉和蔗糖代谢;adu00520.氨基糖和核苷酸糖的代谢;adu00561.甘油酯代谢;adu00591.亚油酸代谢;adu00592.α亚麻酸代谢;adu00710.光合生物中的碳固定;adu00905.油菜素内酯生物合成;adu00909.倍半萜类和三萜类生物合成;adu00910.氮代谢;adu00940.苯丙烷类物质生物合成;adu00941.类黄酮生物合成;adu00943.异黄酮生物合成;adu00944.黄酮和黄酮醇的生物合成;adu00945.二苯乙烯,二芳基庚烷和姜辣素的生物合成;adu00950.异喹啉生物碱的生物合成;adu00965.甜菜红碱生物合成;adu01100.代谢途径;adu01110.次生代谢物的生物合成;adu04016.MAPK信号通路-植物;adu04075.植物激素信号转导;adu04130.囊泡运输中的SNARE相互作用;adu04712.昼夜节律-植物。

Fig.4 Enrichment map of Top 20 KEGG of differentially expressed genes A.Drought and control group;B.Waterlogging and control group;C.Drought and waterlogging group.adu00010:Glycolysis/Gluconeogenesis;adu00040.Pentose and glucuronate interconversions;adu00052.Galactose metabolism;adu00061.Fatty acid biosynthesis;adu00071.Fatty acid degradation;adu00232.Caffeine metabolism;adu00330.Arginine and proline metabolism;adu00350.Tyrosine metabolism;adu00430.Taurine and hypotaurine metabolism;adu00460.Cyanoamino acid metabolism;adu00500.Starch and sucrose metabolism;adu00520.Amino sugar and nucleotide sugar metabolism;adu00561.Glycerolipid metabolism;adu00591.Linoleic acid metabolism;adu00592.alpha-Linolenic acid metabolism;adu00710.Carbon fixation in photosynthetic organisms;adu00905.Brassinosteroid biosynthesis;adu00909.Sesquiterpenoid and triterpenoid biosynthesis;adu00910.Nitrogen metabolism;adu00940.Phenylpropanoid biosynthesis;adu00941.Flavonoid biosynthesis;adu00943.Isoflavonoid biosynthesis;adu00944.Flavone and flavonol biosynthesis;adu00945.Stilbenoid,diarylheptanoid and gingerol biosynthesis;adu00950.Isoquinoline alkaloid biosynthesis;adu00965.Betalain biosynthesis;adu01100.Metabolic pathways;adu01110.Biosynthesis of secondary metabolites;adu04016.MAPK signaling pathway-plant;adu04075.Plant hormone signal transduction;adu04130.SNARE interactions in vesicular transport;adu04712.Circadian rhythm-plant.

图5 关键基因的qRT-PCR验证

Fig.5 The qRT-PCR detection of key differentially expressed genes

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