油茶根系与内生细菌枯草芽孢杆菌互作早期的转录组分析

doi:10.11707/j.1001-7488.20220306

摘要/Abstract

摘要：

目的: 研究油茶-内生细菌互作早期的油茶根系转录组变化规律，为阐明油茶与内生细菌互作的分子机制提供依据。方法: 构建内生细菌枯草芽孢杆菌1-L-29gfp^r与油茶根系互作体系，以不同时间(0、6、12、24 h)的互作体系为研究材料，利用RNA-Seq技术对油茶根部进行转录组测序及分析。结果: 1) 转录组测序共产生52 958 922条序列，约46.1 Gb，差异表达基因10 314条(FDR < 0.05且|log₂FC|>1)。随着互作时间的延长差异表达基因数量呈高-低-高的趋势，接种6 h后差异表达基因数量为6 306个，其中显著上调3 434个，显著下调2 572个；接种12 h后显著上调903个，显著下调526个；接种24 h后显著上调1 195个，显著下调1 384个。2)GO富集分析表明：接种6 h油茶的生物学过程、分子功能方面变化最为明显，生物学过程中磷酸代谢、含磷化合物代谢、响应激素途径、茉莉酸代谢、响应细菌途径等；分子功能中萜烯合酶活性、双加氧酶活性等；细胞组分中膜固有成分等得到富集。3)KEGG通路分析中差异表达基因主要被富集到碳水化合物代谢、氨基酸代谢、信号转导、环境适应性等通路。接种6 h后富集的代谢通路与12、24 h差异较大，其中差异明显的主要有植物激素合成信号通路、植物病原互作通路、苯丙素生物合成通路。4)基因表达量变化较大的有生长素诱导蛋白编码基因(SAUR)、木葡聚糖内糖基转移酶/水解蛋白酶编码基因(XTH)、茉莉酮酸酯ZIM结构域蛋白编码基因(TIFY)、钙调蛋白编码基因(CAM2)、转录因子MYB编码基因、抗病蛋白编码基因(RPM、RPS)、呼吸爆发氧化酶编码基因(RBOHC)、过氧化物酶编码基因(POD)。结论: 利用活体互作体系对不同时间段内生细菌-油茶互作转录组进行分析表明，内生细菌可刺激植物根系生长，提高抗性，诱导免疫反应，但随后免疫反应逐渐减弱。

关键词: 油茶, 内生细菌, 枯草芽孢杆菌, 转录组分析, 互作早期

Abstract:

Objective: This study aims to investigate the change pattern of transcriptomics of Camellia olefolia root in the early stage of its interaction with endophytic bacteria, so as to provide reference for clarifying the molecular mechanism of interaction between C. olefolia and endophytic bacteria. Method: An interaction system between endophytic Bacillus subtilis 1-L-29 and C. olefolia root was constructed. The transcriptomes of the interaction system were sequenced and analyzed by RNA-Seq at different time periods (0, 6, 12, 24 h). Result: 1) The transcriptome sequencing produced a total of 52 958 922 sequences, about 46.1 Gb, and 10 314 differentially expressed genes (FDR < 0.05 and |log₂FC|>1). With the extension of interaction time, the expression of differentially expressed genes showed a high-low-high trend. The number of differentially expressed genes at 6 h after vaccination was 6 306, of which 3 434 genes were significantly up-regulated and 2 572 were significantly down-regulated. At 24 h, a total of 903 genes were significantly up-regulated, and 526 genes were significantly down-regulated. At 24 h, a total of 1 195 genes were significantly up-regulated, and 1 384 genes were significantly down-regulated. 2) Go enrichment analysis showed that the biological process and molecular function of C. olefolia were changed most obviously after 6 hours of interaction. In the biological process, phosphate metabolism pathway, phosphorus-containing compound metabolism pathway, hormone response pathway, jasmonic acid metabolism pathway, bacterial response pathway, hormone-mediated signal pathway, cell response to hormone stimulation, phenylpropane biosynthesis pathway and so on were enriched. The activities of terpene synthase and dioxygenase in molecular functions were enriched. The membrane and intrinsic components of the membrane were enriched. 3) KEGG pathway analysis showed that the differentially expressed genes were mainly enriched into carbohydrate metabolism, amino acid metabolism, signal transduction, environmental adaptability and other pathways. The metabolic pathways enriched at 6 h after inoculation were significantly different from those at 12 h and 24 h, among which the significant differences were mainly plant hormone synthesis signaling pathway, plant pathogen interaction pathway and phenylpropanol biosynthesis pathway. 4) The genes with large changes in expression included auxin-inducible protein coding gene (SAUR), xyloglucan endoglycosyltransferase/hydrolytic protease coding gene (XTH), jasmonate ZIM domain protein coding gene (TIFY), calmodulin coding gene (CAM2), transcription factor MYB coding gene, disease resistance protein coding gene (RPM, RPS), respiratory burst oxidase coding gene (RBOHC), peroxidase coding gene (POD). Conclusion: In this study, for the first time, the living body interaction system has been used to analyze the endophytic bacteria-C. olefolia root interaction transcriptome at different time periods. The results indicate that endophytic bacteria can stimulate plant root growth, increase resistance, and induce immune response, but then the immune response gradually weakens. The results of this study laid a theoretical foundation for the analysis of the molecular mechanism of interaction between endophytic bacteria and C. oleifera.

Key words: Camellia oleifera, endophytic bacteria, Bacillus subtilis, transcriptome analysis, early interactions

中图分类号:

S763.1

李梓杨,陈晓琳,李丽丽,许诗萍,何苑皞. 油茶根系与内生细菌枯草芽孢杆菌互作早期的转录组分析[J]. 林业科学, 2022, 58(3): 48-58.

Zhiyang Li,Xiaolin Chen,Lili Li,Shiping Xu,Yuanhao He. Transcriptome Analysis of Camellia olefolia Root and the Endophytic Bacteria Bacillus Subtilis at the Early Stage of Their Interaction[J]. Scientia Silvae Sinicae, 2022, 58(3): 48-58.

图/表 10

表1

表2

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表3

植物激素信号转导通路差异基因"

家族 Family	基因ID Gene ID	表达量变化的log₂值 log₂ value of fold change			描述(符号) Description(Symbol)
家族 Family	基因ID Gene ID	h6	h12	h24	描述(符号) Description(Symbol)
生长素响应基因家族SAUR The auxin response gene family SAUR	Unigene0224095	5.271 017	-1.797 32	0.397 943	生长素诱导蛋白 Auxin-induced protein X15(SAUR15)
	Unigene0208543	-2.391 3	0.664 469	-0.731 89	生长素诱导蛋白 Auxin-induced protein 15A(SAUR32)
	Unigene0224842	-4.887 15	5.342 368	-3.498 13	生长素诱导蛋白 Auxin-induced protein 15A (SAUR50)
糖苷水解酶家族GH16 Glycoside hydrolase family GH16	Unigene0074914	4.234 786	-0.121 78	-0.231 35	木葡聚糖内糖基转移酶/水解蛋白酶 Xyloglucan endotransglucosylase/hydrolase protein 23(XTH25)
糖苷水解酶家族GH16 Glycoside hydrolase family GH16	Unigene0115871	3.840 573	-0.004 68	-0.151 34	木葡聚糖内糖基转移酶/水解蛋白酶 Xyloglucan endotransglucosylase/hydrolase protein 22(XTH22)
TIFY家族基因 TIFY family gene	Unigene0041523	4.115 512	-1.814 64	-0.207 01	茉莉酮酸酯ZIM结构域蛋白 Jasmonate ZIM domain-containing protein (TIFY9)
TIFY家族基因 TIFY family gene	Unigene0098739	3.869 918	-1.349 38	0.522 57	茉莉酮酸酯ZIM结构域蛋白 Jasmonate-zim-domain protein (TIFY10B)
生长素早期响应基因家族AUX/IAA Auxin early response gene family AUX/IAA	Unigene0082739	2.984 088	-2.344 58	-0.231 92	生长素 Auxin-responsive protein IAA(IAA17)
转录因子bZIP Transcription factor bZIP	Unigene0061614	-2.504 95	1.864 647	-0.385 94	脱落酸应答元件结合因子 ABA responsive element binding factor(ABI5)
转录因子bZIP Transcription factor bZIP	Unigene0118601	-4.000 41	1.824 728	-1.405 45	含碱性亮氨酸拉链结构域的蛋白 Basic-leucine zipper domain-containing protein(TGAL4)
GH3基因家族 GH3 gene family	Unigene0061751	-3.476 34	1.027 397	1.369 855	生长素响应GH3基因家族 Auxin responsive GH3 gene family (GH3)
DELLA基因家族 DELLA gene family	Unigene0089563	-7.258 48	5.469 323	-10.347 1	DELLA蛋白 DELLA protein (GAI)

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表5

图5

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基因名称 Gene name	引物 Primer(5′-3′)	扩增长度 Amplification length/bp	退火温度 Annealing temperature(Tm)/℃
POD	TCATACATTCGGACGGGCTG AGTTGTAAAGGCGTGGGGTC	104	56.9
RBOHC	ATCGCTCAACCATGCCAAGA ATCGCTCAACCATGCCAAGA	109	57.0
TCH4	AACTCAAGCTTGTGCCTGGA TCATGTGTTGGCCCTTGTGA	84	56.8
TIFY	TTCCCGGCTGATAAGGCAAA TTTTGGACCGGTGTTGAAGC	105	56.3
XTH	GGGGAATTTGAGTGGTGATCCT TGGAAATCAGCAGTCGGGTC	104	57.0
EF1α	CAAAGAAGGGTGCCAAGTGA ACCAAACAACCGACCTACGA	128	56.2

时间 Time/hpi	总序列数 Total reads	唯一比对读段 Number of uniquely mapped reads	比对率 Proportion of mapped reads (%)	GC含量 GC percentage(%)	Q30含量 Q30 percentage(%)
0	139 674 846	80 575 830	69.58	43.69	92.2
6	130 079 280	78 164 416	72.83	43.89	92.19
12	124 726 484	72 206 074	70.34	44.21	92.18
24	135 478 312	79 027 352	70.85	43.98	92.29
N50长度 N50 length/bp			1 175 866
平均长度 Average length/bp			1 175 866
比对率 Unique mapped ratio (%)			71.13
注释的基因数量 Annotated gene number			67 700

家族 Family	基因ID Gene ID	表达量变化的log₂值 log₂ value of fold change			描述(符号) Description(Symbol)
家族 Family	基因ID Gene ID	h6	h12	h24	描述(符号) Description(Symbol)
CAM	Unigene0154452	6.431 758	0.194 622	-1.359 71	钙调蛋白 Calmodulin (CAM2)
MYB	Unigene0006849	5.059 191	-3.267 78	2.442 811	MYB相关蛋白Myb4 Myb-related protein Myb4 (MYB102)
	Unigene0091260	3.342 609	-1.393 12	1.400 094	转录因子MYB36 Transcription factor MYB36 (MYB36)
	Unigene0079478	2.615 85	-2.153 92	1.069 583	转录因子MYB Transcription factor MYB (MYB4)
RPM	Unigene0140632	-3.087 74	1.679 16	1.575 752	抗病蛋白 Disease resistance protein (RPM1)
	Unigene0076986	-2.419 19	1.434 07	-0.188 74	抗病蛋白 Disease resistance protein At4g27220 (RPS5)
	Unigene0134868	-3.151 73	0.296 655	1.008 148	核苷酸结合位点-富含亮氨酸重复蛋白 Nucleotide-binding site leucine-rich repeat protein (At4g27190)
RBOH	Unigene0041782	2.166 077	0.104 336	-1.046 16	呼吸爆发氧化酶 Respiratory burst oxidase (RBOHC)
MAPK	Unigene0176521	1.873 724	-0.689 07	0.553 341	MAPK激酶3 Mitogen-activated protein kinase 3 (NTF4)
MAPK	Unigene0008839	-1.662 43	0.789 679	-0.486 96	MAPK同源物 Mitogen-activated protein kinase homolog MMK2(MMK2)
RPM1互作蛋白 RPM1 interacting protein	Unigene0126538	1.872 688	-0.307 55	-0.702 38	RPM1互作蛋白 RPM1-interacting protein (RIN4)
LysM受体类激酶 LysM receptor kinases	Unigene0043775	-3.029 47	-0.579 95	-0.056 76	LysM受体类激酶 LysM domain receptor-like kinase (CERK1)
气味结合蛋白 Odorant binding protein	Unigene0003058	-2.260 62	0.780 021	-1.123 88	气味结合蛋白 Protein ODORANT1 (ODO1)

家族 Family	基因ID Gene ID	表达量变化的log₂值 log₂ value of fold change			描述(符号) Description(Symbol)
家族 Family	基因ID Gene ID	h6	h12	h24	描述(符号) Description(Symbol)
过氧化物酶基因家族 Peroxidase gene family(POD)	Unigene0059080	3.777 526	-0.643 98	0.573 304	类木质素形成阴离子过氧化物酶 Lignin-forming anionic peroxidase-like (PER5)
	Unigene0163356	3.407 953	-1.814 69	0.370 634	木质素形成阴离子过氧化物酶 Lignin-forming anionic peroxidase (pod)
	Unigene0163359	1.999 275	-0.126 23	0.149 761	类过氧化物酶 Peroxidase A2-like(PER58)
糖苷水解酶家族 Glycoside hydrolase family(GH)	Unigene0164751	-1.465 3	1.472 489	-1.055 36	类β-葡萄糖苷酶12 Beta-glucosidase 12-like(BGLU12)
	Unigene0001162	-1.559 93	0.931 72	0.399 258	类β-葡萄糖苷酶11 Beta-glucosidase 11-like(AA7GT)
	Unigene0055474	-2.519 19	1.392 39	-0.277 75	β-葡萄糖苷酶 Beta glucosidase 11(BGLU11)
肉桂醇脱氢酶 Cinnamyl alcohol (CAD) dehydrogenase	Unigene0086215	-1.826 91	-0.280 1	0.181 386	肉桂醇脱氢酶1 Cinnamyl alcohol dehydrogenase 1 (CAD1)

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