GmBI-1互作蛋白的筛选及GmNod44在大豆结瘤固氮过程中的功能

doi:10.3864/j.issn.0578-1752.2026.11.002

摘要/Abstract

摘要：

【目的】大豆是重要的植物蛋白作物和粮豆间作作物。挖掘大豆的生物固氮潜力，对推动生态农业的可持续发展具有深远意义。前期筛选到一个大豆细胞凋亡抑制因子GmBI-1，可与大豆结瘤因子受体蛋白GmNFR1α形成异源蛋白复合体，在早期根瘤菌侵染阶段发挥正调控作用。利用酵母双杂交文库筛选其互作蛋白，并探究互作蛋白在结瘤固氮过程中的功能，为进一步解析大豆共生固氮分子调控网络提供理论依据。【方法】采用酵母双杂交技术，筛选大豆根和根瘤AD-cDNA文库，从文库中分离鉴定GmBI-1潜在的互作蛋白，对互作蛋白进行注释及功能预测，并对其组织表达进行分析。以其中一个文库蛋白GmNod44为研究目标，对其进行生物信息学分析；进一步利用酵母双杂交（Y2H）和烟草体内萤火虫荧光素酶互补技术（LCI）验证二者的相互作用，并在拟南芥原生质体中观察GmBI-1蛋白与GmNod44蛋白的共定位情况。此外，利用发根农杆菌介导的大豆毛根转化技术过表达GmNod44，探究该基因在大豆结瘤固氮中的生物学功能。【结果】利用酵母双杂交文库筛选到18个GmBI-1潜在的互作蛋白，包括晚期结瘤素、豆血红蛋白、丝/苏氨酸蛋白激酶、半胱氨酸氧化酶、胞苷三磷酸合成酶、泛素结合酶等与免疫、蛋白质翻译后修饰相关的蛋白。基因组织表达分析表明，有6个基因在根中表达水平较高，有4个基因在根瘤中表达水平较高，其中，GmNod44在根瘤中特异性高表达。系统进化分析表明，大豆GmNod44与野生大豆GsNod22同源性最高。GmNod44与GmBI-1在酵母和烟草体内均能够发生互相作用，共定位于拟南芥原生质体的内质网。GmNod44过表达后，复合体大豆毛状根的结瘤数目显著增加，互作基因GmBI-1及3个结瘤标志基因Apyrase GS52、Calmodulin和Lb1的表达水平显著上调。根瘤中的固氮酶和ROS清除酶活性明显升高，而半胱氨酸蛋白酶活性显著降低。以上结果表明，过表达GmNod44能够促进大豆结瘤，提高根瘤的固氮能力并延缓根瘤衰老。【结论】晚期结瘤素GmNod44能够与细胞凋亡抑制因子GmBI-1互作，正调控大豆结瘤固氮过程。

关键词: 大豆, 共生固氮, GmBI-1, 酵母双杂交, GmNod44

Abstract:

【Objective】Soybean is an important source of plant protein and a key crop in cereal-legume intercropping systems. Unlocking its biological nitrogen fixation potential holds profound significance for promoting sustainable ecological agriculture. Our previous research identified a soybean apoptosis inhibitor, GmBI-1, which forms a heteroprotein complex with the soybean nodulation factor receptor GmNFR1α and plays a positive regulatory role during early rhizobial infection. This study aims to screen for proteins interacting with GmBI-1 using a yeast two-hybrid library and investigate their functions in the nodulation and nitrogen fixation process, thereby providing a theoretical basis for further elucidating the molecular regulatory network of symbiotic nitrogen fixation in soybean. 【Method】 The yeast two-hybrid system was employed to screen an AD-cDNA library from soybean roots and root nodules, aiming to isolate and identify potential interacting proteins of GmBI-1. The identified interacting proteins were annotated and functionally predicted, followed by analysis of their tissue-specific expression. Taking one of the library proteins, GmNod44, as the research target, bioinformatics analysis was conducted on it. Further validation of the interaction between GmBI-1 and GmNod44 was performed using yeast two-hybrid retesting (Y2H) and tobacco in vivo luciferase complementation imaging (LCI) assays. Additionally, co-localization of GmBI-1 and GmNod44 proteins was observed in Arabidopsis protoplasts. Moreover, GmNod44 was overexpressed using Agrobacterium rhizogenes-mediated hairy root transformation in soybean to investigate its biological function in nodulation and nitrogen fixation.【Result】Screening of the yeast two-hybrid library identified 18 potential interacting proteins of GmBI-1, including late nodulins, leghemoglobins, serine/ threonine protein kinases, cysteine oxidases, cytidine triphosphate synthases, ubiquitin-conjugating enzymes, and other proteins related to immunity and post-translational modifications. Tissue expression analysis revealed that six genes exhibited relatively high expression levels in roots, while four genes showed higher expression in root nodules. Among them, GmNod44 was specifically and highly expressed in root nodules. Phylogenetic analysis indicated that soybean GmNod44 shares the highest homology with wild soybean GsNod22. GmNod44 and GmBI-1 were confirmed to interact in both yeast and tobacco in vivo assays and were co-localized to the endoplasmic reticulum in Arabidopsis protoplasts. Following overexpression of GmNod44, the number of nodules on composite soybean hairy roots significantly increased, and the expression levels of the interacting gene GmBI-1 and three nodulation marker genes-Apyrase GS52, Calmodulin, and Lb1-were significantly upregulated. Nitrogenase and reactive oxygen species (ROS)-scavenging enzyme activities in the nodules markedly rose, while cysteine protease activity significantly decreased. The above results indicate that overexpression of GmNod44 can promote soybean nodulation, enhance the nitrogen fixation capacity of nodules, and delay nodule senescence. 【Conclusion】The late nodulin GmNod44 interacts with the apoptosis inhibitor GmBI-1 and positively regulates the process of nodulation and nitrogen fixation in soybean.

Key words: soybean, symbiotic nitrogen fixation, GmBI-1, yeast two-hybrid, GmNod44

柯丹霞, 侯仕博, 周兆源, 林佳诺, 宋晓莉, 张可馨. GmBI-1互作蛋白的筛选及GmNod44在大豆结瘤固氮过程中的功能[J]. 中国农业科学, 2026, 59(11): 2314-2324.

KE DanXia, HOU ShiBo, ZHOU ZhaoYuan, LIN JiaNuo, SONG XiaoLi, ZHANG KeXin. Screening of GmBI-1 Interacting Proteins and Functional Analysis of GmNod44 in Soybean Nodulation and Nitrogen Fixation[J]. Scientia Agricultura Sinica, 2026, 59(11): 2314-2324.

图/表 8

表1

图1

表2

候选蛋白的功能注释"

编号 Number	序列名 Sequence lD	注释 Annotation	预测功能 Predictive function
1	Glyma.16G130300	结瘤素-26b Nodulin-26b	介导水和小分子跨膜运输 Mediation of transmembrane transport of water and small molecules
2	Glyma.01G208200	RB7-5A型液泡膜内在蛋白 Aquaporin TIP-type RB7-5A	介导水分及小分子物质运输 Transports of water and small molecules
3	Glyma.18G062900	肽基脯氨酰顺反异构酶亲环蛋白24 Peptidyl-prolyl cis-transisomerase CYP24	作为分子伴侣催化蛋白质折叠 Chaperones catalyze protein folding
4	Glyma.03G177400	60S核糖体蛋白L18 60S ribosomal protein L18	参与核糖体组装和蛋白质合成 Participates in ribosome assembly and protein synthesis
5	Glyma.15G217500	胞苷三磷酸合成酶 CTP synthase	为核酸合成和磷脂代谢提供底物 Provide substrates for nucleic acid synthesis and phospholipid metabolism
6	Glyma.09G015400	丝氨酸/苏氨酸蛋白激酶 Serine/threonine-protein kinase D6PKL2	参与信号转导 Mediates signal transduction
7	Glyma.09G240100	半胱氨酸氧化酶2 Cysteine oxidase 2	氧气感知和低氧应激响应的核心组件 Central to oxygen sensing and hypoxia signaling
8	Glyma.09G038500	几丁质酶类似蛋白2 Chitinase-like protein 2	调控免疫应答 Regulates immune response
9	Glyma.10G199100	豆血红蛋白A Leghemoglobin A	调节根瘤内部的氧浓度 Regulates the oxygen concentration inside the root nodule
10	Glyma.18G092300	转运蛋白 SEC13 Transport protein SEC13	介导蛋白质从内质网向高尔基体的运输 Mediates ER-to-Golgi transport
11	Glyma.03G142300	40S核糖体蛋白S3a 40S ribosomal protein S3a	核糖体组装与蛋白质合成 Ribosome assembly and protein synthesis
12	Glyma.10G251900	E2泛素结合酶 Ubiquitin-conjugating enzyme E2	介导信号蛋白的泛素化降解 Mediates the ubiquitin-mediated degradation of signaling proteins
13	Glyma.09G205900	RNA结合蛋白34 RNA-binding protein 34	通过结合RNA分子参与转录后调控 Involves in post transcriptional regulation by binding RNA molecules
14	Glyma.04G127900	壁薄1相关蛋白 WAT1-related protein	调控木质部的次级细胞壁形成 Regulates the formation of secondary cell walls in xylem
15	Glyma.10G007600	结瘤素-44 Nodulin-44	参与共生过程Participates in the symbiotic process
16	Glyma.12G093100	转录复合体亚基CAF1 CCR4-associated factor 1	参与mRNA的降解 Participates in mRNA degradation
17	Glyma.13G117900	多聚泛素Polyubiquitin (SUBl-2)	参与蛋白质降解Participates in protein degradation
18	Glyma.12G036800	V型质子ATP酶蛋白脂质亚基 V-type proton ATPase proteolipid subunit	参与形成质子传导通道 Participates in the formation of proton conduction channels

表2

图2

图3

图4

图5

图6

参考文献 28

[1]	BISWAS B, GRESSHOFF P M, BISWAS B, GRESSHOFF P M. The role of symbiotic nitrogen fixation in sustainable production of biofuels. International Journal of Molecular Sciences, 2014, 15(5): 7380-7397. doi: 10.3390/ijms15057380 pmid: 24786096
[2]	LUO Z P, LIU H Y, XIE F. Cellular and molecular basis of symbiotic nodule development. Current Opinion in Plant Biology, 2023, 76: 102478. doi: 10.1016/j.pbi.2023.102478
[3]	INDRASUMUNAR A, KERESZT A, SEARLE I, MIYAGI M, LI D X, NGUYEN C D T, MEN A, CARROLL B J, GRESSHOFF P M. Inactivation of duplicated nod factor receptor 5 (NFR5) genes in recessive loss-of-function non-nodulation mutants of allotetraploid soybean (Glycine max LMerr.). Plant & Cell Physiology, 2010, 51(2): 201-214.
[4]	INDRASUMUNAR A, SEARLE I, LIN M H, KERESZT A, MEN A, CARROLL B J, GRESSHOFF P M. Nodulation factor receptor kinase 1α controls nodule organ number in soybean (Glycine max LMerr). The Plant Journal, 2011, 65(1): 39-50. doi: 10.1111/tpj.2010.65.issue-1
[5]	WATANABE N, LAM E. Bax Inhibitor-1, a conserved cell death suppressor, is a key molecular switch downstream from a variety of biotic and abiotic stress signals in plants. International Journal of Molecular Sciences, 2009, 10(7): 3149-3167. doi: 10.3390/ijms10073149 pmid: 19742129
[6]	ANWAR S, SIDDIQUE R, AHMAD S, HAIDER M Z, ALI H, SAMI A, LUCAS R S, SHAFIQ M, NISA B U, JAVED B, et al. Genome wide identification and characterization of Bax inhibitor-1 gene family in cucumber (Cucumis sativus) under biotic and abiotic stress. BMC Genomics, 2024, 25(1): 1032. doi: 10.1186/s12864-024-10704-5 pmid: 39497028
[7]	ISHIKAWA T, WATANABE N, NAGANO M, KAWAI-YAMADA M, LAM E. Bax inhibitor-1: A highly conserved endoplasmic reticulum-resident cell death suppressor. Cell Death & Differentiation, 2011, 18(8): 1271-1278.
[8]	XU G Y, WANG S S, HAN S J, XIE K, WANG Y, LI J L, LIU Y L. Plant Bax Inhibitor-1 interacts with ATG6 to regulate autophagy and programmed cell death. Autophagy, 2017, 13(7): 1161-1175. doi: 10.1080/15548627.2017.1320633 pmid: 28537463
[9]	LU P P, YU T F, ZHENG W J, CHEN M, ZHOU Y B, CHEN J, MA Y Z, XI Y J, XU Z S. The wheat Bax inhibitor-1 protein interacts with an aquaporin TaPIP1 and enhances disease resistance in Arabidopsis. Frontiers in Plant Science, 2018, 9: 20. doi: 10.3389/fpls.2018.00020
[10]	HOEFLE C, LOEHRER M, SCHAFFRATH U, FRANK M, SCHULTHEISS H, HÜCKELHOVEN R. Transgenic suppression of cell death limits penetration success of the soybean rust fungus Phakopsora pachyrhizi into epidermal cells of barley. Phytopathology, 2009, 99(3): 220-226. doi: 10.1094/PHYTO-99-3-0220
[11]	HERNÁNDEZ-LÓPEZ A, DÍAZ M, RODRÍGUEZ-LÓPEZ J, GUILLÉN G, SÁNCHEZ F, DÍAZ-CAMINO C. Uncovering Bax inhibitor-1 dual role in the legume-rhizobia symbiosis in common bean roots. Journal of Experimental Botany, 2019, 70(3): 1049-1061. doi: 10.1093/jxb/ery417
[12]	JIN F X, KE D X, LU L, HU Q Q, ZHANG C J, LI C, LIANG W W, YUAN S L, CHEN H F. Suppression of nodule formation by RNAi knock-down of bax inhibitor-1a in Lotus japonicus. Genes, 2025, 16(1): 58. doi: 10.3390/genes16010058
[13]	YUAN S L, KE D X, LIU B, ZHANG M K, LI X Y, CHEN H F, ZHANG C J, HUANG Y, SUN S, SHEN J F, et al. The Bax inhibitor GmBI-1α interacts with a Nod factor receptor and plays a dual role in the legume-rhizobia symbiosis. Journal of Experimental Botany, 2023, 74(18): 5820-5839. doi: 10.1093/jxb/erad276 pmid: 37470327
[14]	YOO S D, CHO Y H, SHEEN J. Arabidopsis mesophyll protoplasts: A versatile cell system for transient gene expression analysis. Nature Protocols, 2007, 2(7): 1565-1572.
[15]	KERESZT A, LI D X, INDRASUMUNAR A, NGUYEN C D, NONTACHAIYAPOOM S, KINKEMA M, GRESSHOFF P M. Agrobacterium rhizogenes -mediated transformation of soybean to study root biology. Nature Protocols, 2007, 2(4): 948-952. doi: 10.1038/nprot.2007.141 pmid: 17446894
[16]	XU Q Z, WANG X, WANG N, LI S N, YAO X L, KUANG H Q, QIU Z M, KE D X, YANG W Q, GUAN Y F. Nitrogen inhibition of nitrogenase activity involves the modulation of cytosolic invertase in soybean nodule. Journal of Genetics and Genomics, 2024, 51(12): 1404-1412. doi: 10.1016/j.jgg.2024.06.013 pmid: 38950857
[17]	ADHIKARI B, GAYRAL M, HERATH V, BEDSOLE C O, KUMAR S, BALL H, ATALLAH O, SHAW B, PAJEROWSKA-MUKHTAR K M, et al. bZIP60 and Bax inhibitor 1 contribute IRE1-dependent and independent roles to potexvirus infection. The New Phytologist, 2024, 243(3): 1172-1189. doi: 10.1111/nph.v243.3
[18]	LIU X, GUO N, LI S S, DUAN M M, WANG G X, ZONG M, HAN S, WU Z H, LIU F, ZHANG J J. Characterization of the bax inhibitor-1 family in cauliflower and functional analysis of BobBIL4. International Journal of Molecular Sciences, 2024, 25(17): 9562. doi: 10.3390/ijms25179562
[19]	WANG D P, JIN R, SHI X B, GUO H R, TAN X H, ZHAO A C, LIAN X H, DAI H L, LI S Z, XIN K X, et al. A kinase mediator of rhizobial symbiosis and immunity in Medicago. Nature, 2025, 643(8072): 768-775. doi: 10.1038/s41586-025-09057-0
[20]	元占鑫. 基于转录组测序解析GmNARK抑制大豆结瘤的分子调控网络[D]. 武汉: 华中农业大学, 2021.
	YUAN Z X. The molecular regulatory network of transcriptome sequencing-based analysis of GmNARK in suppressing soybean nodulation[D]. Wuhan: Huazhong Agricultural University, 2021. (in Chinese)
[21]	MERGAERT P, KERESZT A, KONDOROSI E. Gene expression in nitrogen-fixing symbiotic nodule cells in Medicago truncatula and other nodulating plants. The Plant Cell, 2020, 32(1): 42-68. doi: 10.1105/tpc.19.00494
[22]	JIANG S Y, JARDINAUD M F, GAO J P, PECRIX Y, WEN J Q, MYSORE K, XU P, SANCHEZ-CANIZARES C, RUAN Y T, LI Q J, et al. NIN-like protein transcription factors regulate leghemoglobin genes in legume nodules. Science, 2021, 374(6567): 625-628. doi: 10.1126/science.abg5945 pmid: 34709882
[23]	ZHANG L, ZHU Q, TAN Y H, DENG M M, ZHANG L, CAO Y R, GUO X L. Mitogen-activated protein kinases MPK3 and MPK6 phosphorylate receptor-like cytoplasmic kinase CDL1 to regulate soybean basal immunity. The Plant Cell, 2024, 36(4): 963-986. doi: 10.1093/plcell/koae008 pmid: 38301274
[24]	周莉娜. 植物半胱氨酸氧化酶和硫化氢在拟南芥低氧胁迫应答反应中的功能及其机制研究[D]. 兰州: 兰州大学, 2018.
	ZHOU L N. The functions and their mechanisms of plant cysteine oxidases and hydrogen sulfide in response to low oxygen stress in Arabidopsis[D]. Lanzhou: Lanzhou University, 2018. (in Chinese)
[25]	YOON J, CHO L H, KIM S R, TUN W, PENG X, PASRIGA R, MOON S, HONG W J, JI H, JUNG K H, et al. CTP synthase is essential for early endosperm development by regulating nuclei spacing. Plant Biotechnology Journal, 2021, 19(11): 2177-2191. doi: 10.1111/pbi.13644 pmid: 34058048
[26]	CHEN K, TANG W S, ZHOU Y B, XU Z S, CHEN J, MA Y Z, CHEN M, LI H Y. Overexpression of GmUBC9 gene enhances plant drought resistance and affects flowering time via histone H2B monoubiquitination. Frontiers in Plant Science, 2020, 11: 555794. doi: 10.3389/fpls.2020.555794
[27]	ZHANG W Q, LIU W Y, WANG K, CHENG H P, BAI X L, ZHANG J H, WEI G H, CHEN J. Persulfidation of host NADPH oxidase RbohB by rhizobial 3-mercaptopyruvate sulfurtransferase maintains redox homeostasis and promotes symbiotic nodulation in soybean. Molecular Plant, 2025, 18(11): 1843-1863. doi: 10.1016/j.molp.2025.09.013
[28]	柯丹霞, 彭昆鹏. 利用酵母双杂交系统筛选大豆结瘤因子受体NFR1α的互作蛋白. 作物学报, 2020, 46(1): 31-39.
	KE D X, PENG K P. Screening of NFR1α-interactive proteins in soybean using yeast two hybrid system. Acta Agronomica Sinica, 2020, 46(1): 31-39. (in Chinese) doi: 10.3724/SP.J.1006.2020.94036

引物名称Primer name	引物序列Sequence of primer (5′-3′)
F-GmBI-1	ATGGACACTTTCTTCAAGTCC
R-GmBI-1	TTAATCTCTCCTCCTCTTCTTC
F-GmBI-1-BD	CATG CCATGGATGGACACTTTCTTCAAG
R-GmBI-1-BD	GC GTCGACTTAATCTCTCCTCCTC
F-GmBI-1-cLUC	GG GGTACCATGGACACTTTCTTCAAG
R-GmBI-1-cLUC	GC GTCGACTTAATCTCTCCTCCTC
F-GmNod44-nLUC	GG GGTACCATGGAGAAAATGAGAG
R-GmNod44-nLUC	CG GGATCCTCATATTCTGAGGTGAG
F-GmBI-1-GFP	CGC GGATCCATGGACACTTTCTTC
R-GmBI-1-GFP	GAC GTCGACATCTCTCCTCCTCTT
F-GmNod44-GFP	CGG GGTACCATGGAGAAAATGAGAG
R-GmNod44-GFP	TGC TCTAGATCATATTCTGAGGTGAG
F-GmNod44-RFP	CTA GCTAGCATGGAGAAAATGAGAG
R-GmNod44-RFP	TCC CCCGGGTCATATTCTGAGGTGAG
F-GmNod44-OX	GG GGTACCATGGAGAAAATGAGAG
R-GmNod44-OX	CG GGATCCTCATATTCTGAGGTGAG
F-GmNod44-rt	GAATTTATCAAATGTGGGTAG
R-GmNod44-rt	CATGAATTGCACAACACATG
F-Apyrase GS52-rt	AAGATCTTCCCCAAACAGGAA
R-Apyrase GS52-rt	CAAGTTCTGGTCGAAATGGAA
F-Calmodulin-rt	TCTCCCAGTCCAAGATCACC
R-Calmodulin-rt	GCCGATATTTTCCCATCTCC
F-Lb1-rt	CTCCAAGCCCATGCTGAAAA
R-Lb1-rt	TGGCATCTGCAAGTGTCACTTC
F-TefS1-rt	CTCCAAGCCCATGCTGAAAA
R-TefS1-rt	TGGCATCTGCAAGTGTCACTTC