应用GST pull-down技术筛选番茄SIVQ6互作蛋白

doi:10.3864/j.issn.0578-1752.2020.15.014

摘要/Abstract

摘要：

【目的】含有VQ基序（VQ）的蛋白质是植物特异性蛋白质,具有保守的“FxxhVQxhTG”氨基酸序列,调节植物生长和发育。番茄SlMPK1在高温胁迫过程中发挥重要作用,酵母双杂交（Y2H）显示SlVQ6蛋白能够与SlMPK1相互作用,通过GST pull-down技术进一步验证SlMPK1与SlVQ6的互作以及SlVQ6的互作网络,为研究SlVQ6介导的高温应答信号通路奠定基础。【方法】通过pGEX-4T-1-PC-VQ6质粒构建,以含有目的基因SIVQ6的菌液为模板,设计特异性引物,扩增目的基因序列,将获得的目的基因VQ6克隆到载体pGEX-4T-1的BamHⅠ和NotⅠ的酶切位点之间,将获得的重组质粒pGEX-4T-1-PC-VQ6转入TOP10克隆菌株经IPTG（异丙基硫代半乳糖苷）诱导表达,通过GST柱亲和纯化获得目标蛋白PC-VQ6,进而获得预期GST-SlVQ6融合蛋白,通过体外磷酸化进一步确定SlVQ6是否是SlMPK1的下游底物;以GST-SlVQ6为诱饵蛋白固定于GST Sepharose Beads上,与番茄叶片总蛋白孵育后洗脱,收集洗脱液进行SDS-PAGE凝胶电泳验证,通过LC-MS/MS检测SlVQ6可能互作的候选蛋白,并对筛选的SIVQ6互作蛋白通过GO、KEGG和蛋白互作网络进行生物信息学分析。【结果】成功构建pGEX-4T-1-PC-SlVQ6基因重组表达质粒,并获得带有GST标签的GST-SlVQ6融合蛋白,其分子量大小约为54 kD;将GST-SlVQ6和His-SlMPK1进行体外磷酸化试验,SlMPK1能够磷酸化SlVQ6,而作为阴性对照的GST与SlMPK1无相互作用,且SlVQ6不存在自磷酸化的现象,表明GST-SlVQ6和His-SlMPK1具有相互作用,且SlVQ6是SlMPK1的下游底物;以GST-SlVQ6融合蛋白为诱饵蛋白（空GST为阴性对照）,利用pull-down试验筛选番茄叶片组织蛋白中与SlVQ6蛋白结合的蛋白,经SDS-PAGE分离、液相色谱-串联质谱（LC-MS/MS）鉴定以及Mascot与蛋白数据库检索,共鉴定出37个与SlVQ6结合的蛋白,包括蛋白激酶Receptor for Activated C Kinase 1B（RACK1B）,通过GO、KEGG和蛋白互作网络的生物信息学分析,表明这些蛋白参与多种信号通路,其中8个核糖体蛋白可能与高温胁迫密切相关。【结论】SlVQ6是SlMPK1的底物蛋白,且37个蛋白可能与SlVQ6互作,这些蛋白与胁迫反应有着密切的联系,可能会在提高番茄植株高温耐受性等方面发挥重要作用。

关键词: 番茄, SlVQ6, SlMPK1, pull-down, 互作蛋白

Abstract:

【Objective】The VQ motif-containing (VQ) proteins are plant-specific proteins with a conserved “FxxhVQxhTG” amino acid sequence, which regulate plant growth and development. SlMPK1 plays an important role in the process of high temperature stress, but its downstream target proteins are poorly understood. Although yeast double hybridization (Y2H) showed that SlVQ6 protein could interact with SlMPK1, there was no further experimental evidence. Therefore, it is especially important to verify the interaction between SlMPK1 and SlVQ6 and to study the interaction network of SIVQ6. 【Method】First, pGEX-4T-1-PC-VQ6 plasmid was constructed. Through design of specific primers based on the SlVQ6 gene sequence, and using the plasmid containing the target gene SIVQ6 as a template to amplify the target gene sequence, the obtained target gene VQ6 was cloned between the restriction sites of BamHⅠ and NotⅠ of the vector pGEX-4T-1, and the pGEX-4T-1-PC-VQ6 was transferred into a TOP10 clone strain. The target protein PC-VQ6 was obtained by IPTG (isopropyl thiogalactoside) inducing expression and the expected GST-SlVQ6 fusion protein was obtained by affinity purification by GST column. Phosphorylation was performed in vitro to further determine whether SlVQ6 is the substrate of SlMPK1. GST-SlVQ6 was used as the bait protein to fix on GST Sepharose Beads and incubated with tomato leaf total protein, and then the incubated fusion material was eluated. The eluate was collected and verified by SDS-PAGE gel electrophoresis. LC-MS/MS was used to detect the candidate proteins that could interact with SlVQ6, and the screened SIVQ6 interacting proteins were used for bioinformatics analysis by GO, KEGG, and protein interaction networks. 【Result】The results showed that we successfully constructed the recombinant gene expression plasmid pGEX4T-1-PC-SlVQ6 and obtained the GST-SlVQ6 fusion protein with a GST tag, of which the molecular weight is about 54 kD. GST-SlVQ6 and His-SlMPK1 were subjected to phosphorylation experiments in vitro. SlVQ6 could be phosphorylated by SlMPK1, however the GST could not be phosphorylated by SlMPK1 as a negative control and there was no autophosphorylation phenomenon in SlVQ6, indicating that SlVQ6 has an interaction with SlMPK1, and SlVQ6 is a downstream substrate of SlMPK1. GST-SlVQ6 fusion protein was used as bait protein (GST as negative control), and the protein bound to SlVQ6 protein in tomato leaf tissue protein was screened by pull-down test. Through SDS-PAGE, liquid chromatography-tandem mass spectrometry (LC-MS/MS) identification, and Mascot protein database search, 37 SlVQ6-bound proteins were identified, including protein kinase Receptor for Activated C Kinase 1B (RACK1B). Bioinformatics analysis of GO, KEGG, and protein interaction networks indicated that these proteins are involved in a variety of signaling pathways, and eight of the ribosomal proteins may be closely related to high temperature stress. 【Conclusion】This research shows that SlVQ6 is a substrate protein of SlMPK1 and 37 proteins may interact with SlVQ6. These proteins are closely related to the stress response and may play an important role in the high temperature tolerance of tomato plants.

Key words: tomato, SlVQ6, SlMPK1, pull-down, interaction protein

原贵波,莫双榕,钱莹,臧栋楠,杨帆,蒋红亮,武媛,丁海东. 应用GST pull-down技术筛选番茄SIVQ6互作蛋白[J]. 中国农业科学, 2020, 53(15): 3146-3157.

YUAN GuiBo,MO ShuangRong,QIAN Ying,ZANG DongNan,YANG Fan,JIANG HongLiang,WU Yuan,DING HaiDong. Screening of Interacting Protein of Tomato SIVQ6 by GST Pull-Down[J]. Scientia Agricultura Sinica, 2020, 53(15): 3146-3157.

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链接本文: https://www.chinaagrisci.com/CN/10.3864/j.issn.0578-1752.2020.15.014

https://www.chinaagrisci.com/CN/Y2020/V53/I15/3146

图/表 8

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表1

通过GST pull-down鉴定的37个SlVQ6特异性结合蛋白"

蛋白质ID UniProt ID	拟南芥ID At ID	基因ID^a Gene ID	描述^b Description
R4KMW8	ATCG00490		二磷酸核酮糖羧化酶大链Ribulose bisphosphate carboxylase large chain
K4DC90	AT2G24200	Solyc12g010020	胞质氨肽酶Cytosol aminopeptidase
K4BQD5	AT5G58420	Solyc04g016350	40S核糖体蛋白S4 (RPS4D) 40S ribosomal protein S4 (RPS4D)
K4CAN7	AT2G20450	Solyc06g083820	60S核糖体蛋白l14（RPL14A） 60S ribosomal protein L14 (RPL14A)
K4ASC2	AT1G65930	Solyc01g005560	异柠檬酸脱氢酶/ NADP⁺异柠檬酸脱氢酶,推定 Isocitrate dehydrogenase / NADP⁺ isocitrate dehydrogenase, putative
K4CPX9	AT1G32990	Solyc08g083350	PRPL11;核糖体的结构组成 PRPL11; Structural constituent of ribosome
K4BWB5	AT5G14320	Solyc05g005880	核糖体蛋白S13,叶绿体（CS13） 30S ribosomal protein S13, chloroplast (CS13)
H1ZXA8	AT3G12580		热休克蛋白70亚型2 Heat shock protein 70 isoform 2
K4BEV0	AT3G04770	Solyc03g019780	RPSAb;核糖体的结构组成 RPSAb; Structural constituent of ribosome
K4CLA3	AT4G33010	Solyc08g065220	AtGLDP1（拟南芥黄曲霉毒素P-蛋白1）AtGLDP1 (Arabidopsis thaliana glycine decarboxylase P-protein 1)
K4BMD5	AT1G74070	Solyc03g119860	肽基脯氨酸顺反异构酶亲环素型家族蛋白 Eptidyl-prolyl cis-trans isomerase cyclophilin-type family protein
K4B1M5	AT5G49840	Solyc01g102990	ATP结合/ATP酶/核苷三磷酸酶/核苷酸结合 ATP binding/ATPase/nucleoside-triphosphatase/ nucleotide binding
K4DEU5	AT1G48630	Solyc12g040510	RACK1B_AT;核苷酸结合 RACK1B_AT; Nucleotide binding
P07369	AT1G29930	Solyc03g005780	CAB1,AB140,CAB140,LHCB1.3
K4D831	AT2G37270	Solyc11g042610	ATRPS5B;核糖体的结构组成ATRPS5B; Structural constituent of ribosome
K4CP59	AT4G11650	Solyc08g080590	ATOSM34\|ATOSM34（渗调蛋白34）ATOSM34\|ATOSM34 (osmotin 34)
K4CAM4	AT4G28730	Solyc06g083690	谷氨酸家族蛋白 Glutaredoxin family protein
K4C3Z3	AT3G62410	Solyc06g009630	CP12-2,CP12\|CP12-2;蛋白结合 CP12-2, CP12\|CP12-2; protein binding
K4BQ07	AT2G43560	Solyc04g015040	免疫亲和蛋白Immunophilin
K4ASQ6	AT5G06480	Solyc01g006900	MD-2相关脂质识别含域蛋白MD-2-related lipid recognition domain-containing protein
Q9XGI9	AT2G27450	Solyc11g068540	NLP1,ATNLP1,CPA;N-氨基甲酰腐胺酰胺酶NLP1, ATNLP1, CPA; N-carbamoylputrescine amidase
K4C3Z6	AT4G02080	Solyc06g009660	ASAR1,ATSARA1C,ATSAR2\|ATSAR2;GTP结合 ASAR1, ATSARA1C, ATSAR2\|ATSAR2; GTP binding
Q8LPU1	AT4G11650	Solyc08g080620	ATOSM34\|ATOSM34（渗调蛋白34）ATOSM34\|ATOSM34 (osmotin 34)
K4CMN4	AT2G35040	Solyc08g075160	AICARFT/IMPCHase双酶家族蛋白AICARFT/IMPCHase bienzyme family protein
K4D621	AT1G12050	Solyc11g012160	延胡索酰乙酰乙酸酶,推定 Fumarylacetoacetase, putative
K4B1B8	AT2G47170	Solyc01g100870	ARF1A1C;GTP结合/磷脂酶激活剂/蛋白结合ARF1A1C; GTP binding / phospholipase activator/ protein binding
K4BB24	AT5G66530	Solyc02g085100	Aldose 1-变旋酶家族蛋白 Aldose 1-epimerase family protein
K4CNE8	AT4G17040	Solyc08g077890	ATP依赖的Clp蛋白酶水解亚基,推定 ATP-dependent Clp protease proteolytic subunit, putative
Q9XG54	AT1G76690	Solyc10g086220	OPR2,ATOPR2\|OPR2
K4BG20	AT3G49910	Solyc03g044000	60S核糖体蛋白L26（RPL26A）60S ribosomal protein L26 (RPL26A)
K4DA30	AT5G22300	Solyc11g068730	NIT4;3-氰基丙氨酸水合酶/氰基丙氨酸腈水解酶NIT4; 3-cyanoalanine hydratase/cyanoalanine nitrilase
K4C952	AT3G11710	Solyc06g073330	ATP结合/氨酰基-tRNA连接酶/赖氨酸-tRNA连接酶ATP binding/aminoacyl-tRNA ligase/lysine-tRNA ligase
K4D3M1	AT3G09630	Solyc10g084350	60S核糖体蛋白L4/L1（RPL4A）60S ribosomal protein L4/L1 (RPL4A)
K4CJ96	AT2G44050	Solyc08g015660	COS1;6,7-二甲基-8-核苷鲁嗪合酶COS1; 6,7-dimethyl-8-ribityl lumazine synthase
K4CSE1	AT3G25530	Solyc09g018790	GHBDH,ATGHBDH;3-羟丁酸脱氢酶GHBDH, ATGHBDH; 3-hydroxybutyrate dehydrogenase
K4C8R4	AT3G04120	Solyc06g071920	GAPC,GAPC-1,GAPC1\|GAPC1
K4D3F2	AT3G52960	Solyc10g083650	2类过氧化物酶,推定Peroxiredoxin type 2, putative

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