In Vitro Culture Screening of High Oil Peanut New Germplasm and WRI1 Gene Validation

doi:10.7668/hbnxb.20195403

Abstract

Abstract:

In order to explore new approaches for high-oil peanut breeding and establish a new method for directly developing high-oil peanut germplasm,this study employed in vitro mutagenesis breeding technology to create new high-oil peanut germplasm.Jihua 9 embryo leaflet was used as mutagenic test materials,Jihua 9 and Jihua 54 were used as control test materials,and bleomycin was used as mutagenic agent.The ovules were sterilized and placed in gradient mutagenesis medium and screened for semi-lethal concentrations of bleomycin.After somatic embryos germinated into seedlings,sterile peanut seedlings were used as rootstocks,and transplanted to the field.Bioinformatics analysis of two known regulated peanut fat synthesis genes WRI1 and experimental feasibility validation by the correlation of WRI1 gene expression in grain and crude fat content of mutagenic plants were conducted.The results were best when the bleomycin was 3 mg/L.The crude fat content of IM13-3 was higher than that of Jihua 9(CK₁,test variety control)and Jihua 54(CK₂,high oil variety control).Two WRI1 genes,WRI1X2 and WRI1X1,encoding 366 and 357 amino acids,respectively,were both unstable hydrophilic proteins. WRI1 gene expression and crude fat content were significantly positively associated in grain.Bleomycin was first used as a peanut vitro mutagenesis agent,and IM13-3 was obtained with a crude fat content of 56.64%.It further proves the authenticity of Jihua 9 high oil mutant and the feasibility of peanut in vitro mutagenesis method. The gene expression level of the high-oil mutant WRI1 was determined and was significantly different from the control varieties. Demonstrate the feasibility of breeding methods for in vitro mutagenesis of peanut.

Key words: High-oil peanut, Mutagenesis in vitro, Bleomycin, WRI1, Expression analysis

WANG Wei, ZHANG Yutong, NIU Hailong, LIU Hongxin, ZHANG Wannian, XIAO Xia, ZHANG Lianxi, LI Yufa. In Vitro Culture Screening of High Oil Peanut New Germplasm and WRI1 Gene Validation[J]. Acta Agriculturae Boreali-Sinica, 2025, 40(1): 36-44. doi: 10.7668/hbnxb.20195403.

/ / Recommend / Download Citations

URL: http://www.hbnxb.net/EN/10.7668/hbnxb.20195403

http://www.hbnxb.net/EN/Y2025/V40/I1/36

Figures/Tables 17

References 25

[1]	宋兆锋, 张志民, 李美君, 丁红, 赵跃, 孙日丹, 陈小姝, 李春雨, 赫思聪, 高华援. 赤霉素和脱落酸对花生生长与后熟进程的影响[J]. 花生学报, 2024, 53(2):10-19,30.doi:10.14001/j.issn.1002-4093.2024.02.002.
	Song Z F, Zhang Z M, Li M J, Ding H, Zhao Y, Sun R D, Chen X S, Li C Y, He S C, Gao H Y. Effects of abscisic acid and gibberellin on growth and post-ripening process of peanut[J]. Journal of Peanut Science, 2024, 53(2):10-19,30.
[2]	张国伟, 束红梅, 陈志德, 杨长琴, 王晓婧, 黄波, 徐婕, 刘瑞显. 江苏省花生生产现状及可持续发展的关键技术[J]. 耕作与栽培, 2023, 43(5):109-113.doi:10.13605/j.cnki.52-1065/s.2023.05.026.
	Zhang G W, Shu H M, Chen Z D, Yang C Q, Wang X J, Huang B, Xu J, Liu R X. Situation and key technologies for sustainable development of peanut production in Jiangsu Province[J]. Tillage and Cultivation, 2023, 43(5):109-113.
[3]	王伟, 李玉发, 何中国, 刘红欣, 李伟堂, 杨翔宇, 张连喜, 牛海龙. 种植技术和种植密度对吉花2号主要农艺性状和产量的影响[J]. 安徽农业科学, 2024, 52(8):36-40.doi:10.3969/j.issn.0517-6611.2024.08.009.
	Wang W, Li Y F, He Z G, Liu H X, Li W T, Yang X Y, Zhang L X, Niu H L. Planting technology and planting density on major agronomic characters and yield of Jihua 2[J]. Journal of Anhui Agricultural Sciences, 2024, 52(8):36-40.
[4]	苑翠玲, 李春娟, 闫彩霞, 赵小波, 王娟, 张浩, 孙全喜, 单世华. 花生EMS诱变体系的探索及突变体鉴定[J]. 中国油料作物学报, 2021, 43(4):627-637.doi:10.19802/j.issn.1007-9084.2020079.
	Yuan C L, Li C J, Yan C X, Zhao X B, Wang J, Zhang H, Sun Q X, Shan S H. Exploration of EMS mutagenesis system and mutants screening of peanut[J]. Chinese Journal of Oil Crop Sciences, 2021, 43(4):627-637. doi: 10.19802/j.issn.1007-9084.2020079
[5]	王晶珊, 姜亚男, 尹秀波, 衣艳君, 赵健, 史普祥, 李松坚, 禹山林. 离体诱变定向培育高油花生新品种宇花9号[J]. 生物工程学报, 2019, 35(7):1277-1285.doi:10.13345/j.cjb.190010.
	Wang J S, Jiang Y N, Yin X B, Yi Y J, Zhao J, Shi P X, Li S J, Yu S L. Directional breeding of high oil content peanut variety Yuhua 9 by in vitro mutagenesis and screening[J]. Chinese Journal of Biotechnology, 2019, 35(7):1277-1285.
[6]	祁伟. 红掌离体化学诱变技术的研究[D]. 苏州: 苏州大学, 2016.doi:10.7666/d.D01005920.
	Qi W. Study on chemical mutation technology of Anthurium andraeanum in vitro[D]. Suzhou: Soochow University, 2016.
[7]	邓倩. EMS诱变3个纤维亚麻品种下胚轴段耐盐突变体的离体筛选[D]. 乌鲁木齐: 新疆大学, 2013.
	Deng Q. In vitro screening of salt-tolerant mutants in hypocotyl segment of three fiber flax varieties induced by EMS[D]. Urumqi: Xinjiang University, 2013.
[8]	岑慧慧. 高粱花粉生殖细胞MNU诱变技术的研发[D]. 太原: 山西大学, 2018.doi:10.7666/d.D01596346.
	Cen H H. Research and development of mutation technology of sorghum pollen germ cell MNU[D]. Taiyuan: Shanxi University, 2018.
[9]	李冠, 王霞, 尹秀波, 胡晓辉, 陈静, 乔利仙, 隋炯明, 王晶珊. 利用离体诱变培育花生新品种宇花4号[J]. 生物工程学报, 2017, 33(5):766-774.doi:10.13345/j.cjb.160444.
	Li G, Wang X, Yin X B, Hu X H, Chen J, Qiao L X, Sui J M, Wang J S. Breeding of peanut variety Yuhua 4 by in vitro mutagenesis[J]. Chinese Journal of Biotechnology, 2017, 33(5):766-774.
[10]	Bailly C, Kénani A, Waring M J. Altered cleavage of DNA sequences by bleomycin and its deglycosylated derivative in the presence of actinomycin[J]. Nucleic Acids Research, 1997, 25(8):1516-1522.doi:10.1093/nar/25.8.1516. pmid: 9106360
[11]	Ku-CenturiÓn M, Gonzílez-Marín B, CalderÓn-Ezquerro M C, Martínez-Valenzuela M C, Maldonado E, CalderÓn-Segura M E. DNA damage assessment in zebrafish embryos exposed to monceren250 SC fungicide using the alkaline comet assay[J]. Zebrafish, 2016, 13(5):442-448.doi:10.1089/zeb.2016.1265. pmid: 27557408
[12]	Manova V, Gecheff K, Stoilov L. Efficient repair of bleomycin-induced double-strand breaks in barley ribosomal genes[J]. Mutation Research, 2006, 601(1/2):179-190.doi:10.1016/j.mrfmmm.2006.07.004.
[13]	张希太, 肖磊, 董策, 路其祥. 博莱霉素对小麦的诱变效应研究[J]. 河南科技学院学报(自然科学版), 2022, 50(4):10-16.doi:10.3969/j.issn.2096-9473.2022.04.002.
	Zhang X T, Xiao L, Dong C, Lu Q X. Study on chemical mutagenesis of bleomycin on wheat[J]. Journal of Henan Institute of Science and Technology(Natural Science Edition), 2022, 50(4):10-16.
[14]	乔利仙, 隋炯明, 赵丽兰, 雷萍萍, 孙世孟, 郭宝太, 王晶珊. 平阳霉素离体诱变花生M₂农艺性状分析[J]. 核农学报, 2014, 28(6):955-960.doi:10.11869/j.issn.100-8551.2014.06.0955.
	Qiao L X, Sui J M, Zhao L L, Lei P P, Sun S M, Guo B T, Wang J S. Agronomic traits of M₂ generation by in vitro mutagenesis with pingyangmycin in peanut[J]. Journal of Nuclear Agricultural Sciences, 2014, 28(6):955-960.
[15]	刘文林, 张宏纪, 孙岩, 唐婧泉, 杨淑萍, 王翔宇, 张宝辉. 平阳霉素对小麦雌雄配子诱变效果的研究[J]. 黑龙江农业科学, 2021(1):1-5.doi:10.11942/j.issn1002-2767.2021.1.0001.
	Liu W L, Zhang H J, Sun Y, Tang J Q, Yang S P, Wang X Y, Zhang B H. Effects of pingyangmycin on mutagenesis of male and female gametes in Triticum aestivum L.[J]. Heilongjiang Agricultural Sciences, 2021(1):1-5.
[16]	孙金波, 石素华, 杨利, 李凤丽, 王兴军, 赵术珍. 花生WRI1基因家族的全基因组与表达谱分析[J]. 花生学报, 2020, 49(1):9-18.doi:10.14001/j.issn.1002-4093.2020.01.002.
	Sun J B, Shi S H, Yang L, Li F L, Wang X J, Zhao S Z. Genome-wide analysis of WRI1 gene family and their expression profiles in peanut[J]. Journal of Peanut Science, 2020, 49(1):9-18.
[17]	Yang Y Q, Li Y R, Cheng Z S, Su Q, Jin X X, Song Y H, Wang J. Genetic analysis and exploration of major effect QTLs underlying oil content in peanut[J]. Theoretical and Applied Genetics, 2023, 136(5):97.doi:10.1007/s00122-023-04328-8. pmid: 37027047
[18]	Lu Q, Huang L, Liu H, Garg V, Gangurde S S, Li H F, Chitikineni A, Guo D D, Pandey M K, Li S X, Liu H Y, Wang R F, Deng Q Q, Du P X, Varshney R K, Liang X Q, Hong Y B, Chen X P. A genomic variation map provides insights into peanut diversity in China and associations with 28 agronomic traits[J]. Nature Genetics, 2024, 56(3):530-540.doi:10.1038/s41588-024-01660-7.
[19]	禹山林, 王晶珊, 乔利仙, 隋炯明, 姜德锋. 花生离体诱变及精准高效高油新品种培育技术[Z]. 北京: 中国农学会, 2019-04-30.
	Yu S L, Wang J S, Qiao L X, Sui J M, Jiang D F. Peanut mutagenesis and new varieties of high oil[Z]. Beijing: Chinese Society of Agriculture, 2019-04-30.
[20]	Livak K J, Schmittgen T D. Analysis of relative gene expression data using real-time quantitative PCR and the 2^-ΔΔCT method[J]. Methods, 2001, 25(4):402-408.doi:10.1006/meth.2001.1262. pmid: 11846609
[21]	王亚, 乔利仙, 武秀玲, 胡晓辉, 王晶珊, 隋炯明. 平阳霉素诱变与NaCl定向筛选对花生后代产量和品质性状的影响[J]. 华北农学报, 2015, 30(1):202-206.doi:10.7668/hbnxb.2015.01.034.
	Wang Y, Qiao L X, Wu X L, Hu X H, Wang J S, Sui J M. Effect of in vitro mutagenesis with pingyangmycin and NaCl-directed screening on production and quality of offspring in peanut[J]. Acta Agriculturae Boreali-Sinica, 2015, 30(1):202-206.
[22]	崔雪艳, 孙继军. 平阳霉素诱导花生胚小叶再生体系的抑制探析[J]. 园艺与种苗, 2016, 36(11):62-64.doi:10.16530/j.cnki.cn21-1574/s.2016.11.021.
	Cui X Y, Sun J J. Discussion on inhibition of pingyangmycin(PYM)on induction regeneration system of peanut embryo leaflet[J]. Horticulture & Seed, 2016, 36(11):62-64.
[23]	王霞, 李艳, 朱虹, 迟晓元, 吴兰荣, 赵龙刚, 王晶珊, 禹山林. 花生高油突变体的定向筛选及籽仁含油率与叶片水势的相关性分析[J]. 青岛农业大学学报(自然科学版), 2019, 36(1):30-33.doi:10.3969/J.ISSN.1674-148X.2019.01.006.
	Wang X, Li Y, Zhu H, Chi X Y, Wu L R, Zhao L G, Wang J S, Yu S L. Directional screening on peanut mutant with high oil content and correlation between oil content and leaf water potential[J]. Journal of Qingdao Agricultural University(Natural Science), 2019, 36(1):30-33.
[24]	Focks N, Benning C. wrinkled1:a novel,low-seed-oil mutant of Arabidopsis with a deficiency in the seed-specific regulation of carbohydrate metabolism[J]. Plant Physiology, 1998, 118(1):91-101.doi:10.1104/pp.118.1.91. pmid: 9733529
[25]	Cernac A, Benning C. WRINKLED1 encodes an AP2/EREB domain protein involved in the control of storage compound biosynthesis in Arabidopsis[J]. The Plant Journal, 2004, 40(4):575-585.doi:10.1111/j.1365-313X.2004.02235.x.

名称 Name	类型 Style	主茎高/ cm Main stem height	第一侧枝长/cm The length of the first lateral branch	总分枝数 Total number of branches	荚果形状 The pod shape	种子形状 Shape of the seed	果腰深度 Waist depth	叶色 Leaf colour	果壳厚度 Shell thickness	出苗至成熟时间/d Time of emergence to maturity
吉花9号(CK)	珍珠豆	35.5	37.8	6.5	普通形	圆形	无	黄绿色	较厚	115
Jihua 9(CK)
IM44-1	多粒	40.2	41.4	5.8	曲棍形	圆柱形	轻微	黄绿色	薄	106
IM51-10	珍珠豆	35.8	40.6	6.0	普通形	圆柱形	中等	黄绿色	薄	115
IM56-5	珍珠豆	32.1	35.4	6.8	普通形	圆柱形	轻微	绿色	较薄	117
IM61-14	珍珠豆	35.2	36.3	6.1	普通形	圆形	轻微	黄绿色	中等	113
IM67-1	珍珠豆	34.9	39.8	8.3	普通形	圆柱形	中等	黄绿色	较薄	104
IM72-6	珍珠豆	37.1	39.5	6.7	普通形	圆形	无	黄绿色	中等	111
IM84-3	珍珠豆	34.0	36.2	7.7	普通形	圆形	轻微	黄绿色	中等	113
IM86-19	珍珠豆	31.4	40.3	7.2	茧形	圆形	轻微	深绿色	中等	110

名称 Name	类型 Style	主茎高/ cm Main stem height	第一侧枝长/cm The length of the first lateral branch	总分枝数 Total number of branches	荚果形状 The pod shape	种子形状 Shape of the seed	果腰深度 Waist depth	叶色 Leaf colour	果壳厚度 Shell thickness	出苗至成熟时间/d Time of emergence to maturity
吉花9号(CK)	珍珠豆	35.5	37.8	6.5	普通形	圆形	无	黄绿色	较厚	115
Jihua 9(CK)
IM44-1	多粒	40.2	41.4	5.8	曲棍形	圆柱形	轻微	黄绿色	薄	106
IM51-10	珍珠豆	35.8	40.6	6.0	普通形	圆柱形	中等	黄绿色	薄	115
IM56-5	珍珠豆	32.1	35.4	6.8	普通形	圆柱形	轻微	绿色	较薄	117
IM61-14	珍珠豆	35.2	36.3	6.1	普通形	圆形	轻微	黄绿色	中等	113
IM67-1	珍珠豆	34.9	39.8	8.3	普通形	圆柱形	中等	黄绿色	较薄	104
IM72-6	珍珠豆	37.1	39.5	6.7	普通形	圆形	无	黄绿色	中等	111
IM84-3	珍珠豆	34.0	36.2	7.7	普通形	圆形	轻微	黄绿色	中等	113
IM86-19	珍珠豆	31.4	40.3	7.2	茧形	圆形	轻微	深绿色	中等	110

名称 Name	粗蛋白含量 Crude protein content	还原糖含量 Reducing sugar content	粗脂肪含量 Crude fat content	可溶性糖含量 Soluble sugar content	亚油酸含量 Linoleic acid content	油酸含量 Oleinic acid content	蔗糖含量 Sucrose content	总糖含量 Total sugar content
吉花9号(CK)	25.84	0.75	51.36	3.06	46.79	30.23	1.74	15.19
Jihua 9(CK)
IM13-3	21.73	0.81	56.64	4.41	36.31	40.03	2.53	18.30
IM14-6	30.17	0.81	49.16	2.83	45.00	31.99	1.74	11.44
IM30-2	32.65	1.01	42.08	7.25	33.24	42.38	4.70	21.40
IM32-12	30.93	0.78	48.77	3.27	45.38	30.25	2.08	13.00
IM57-18	28.98	0.98	43.54	9.31	33.71	41.29	5.76	30.35
IM69-2	23.56	0.88	49.14	3.44	9.26	82.27	2.75	13.53
IM74-1	27.10	0.88	44.97	7.10	16.73	65.42	4.34	25.04
IM88-1	27.35	0.61	54.46	1.30	33.32	45.77	1.10	12.45
吉花54	24.48	0.72	55.35	3.36	42.96	35.47	2.69	19.99
Jihua 54

名称 Name	粗蛋白含量 Crude protein content	还原糖含量 Reducing sugar content	粗脂肪含量 Crude fat content	可溶性糖含量 Soluble sugar content	亚油酸含量 Linoleic acid content	油酸含量 Oleinic acid content	蔗糖含量 Sucrose content	总糖含量 Total sugar content
吉花9号(CK)	25.84	0.75	51.36	3.06	46.79	30.23	1.74	15.19
Jihua 9(CK)
IM13-3	21.73	0.81	56.64	4.41	36.31	40.03	2.53	18.30
IM14-6	30.17	0.81	49.16	2.83	45.00	31.99	1.74	11.44
IM30-2	32.65	1.01	42.08	7.25	33.24	42.38	4.70	21.40
IM32-12	30.93	0.78	48.77	3.27	45.38	30.25	2.08	13.00
IM57-18	28.98	0.98	43.54	9.31	33.71	41.29	5.76	30.35
IM69-2	23.56	0.88	49.14	3.44	9.26	82.27	2.75	13.53
IM74-1	27.10	0.88	44.97	7.10	16.73	65.42	4.34	25.04
IM88-1	27.35	0.61	54.46	1.30	33.32	45.77	1.10	12.45
吉花54	24.48	0.72	55.35	3.36	42.96	35.47	2.69	19.99
Jihua 54

基因ID Gene ID	所在染色体 Host chromosome	物理位置 Physical location	基因序列长度/bp Gene sequence length	CDS序列/bp CDS sequence length	基因注释 Gene annotation	亚细胞定位 Subcellular localization
112707793	8	45710245—45721409	2 131	1 101	花生乙烯应答转录因子WRI1,转录变体X2,mRNA	细胞核
112750138	15	32463399—32472631	1 222	1 074	花生乙烯应答转录因子WRI1,转录变体X1,mRNA	细胞核

Please choose a citation manager

Content to export