伊氏线虫真菌碳氮条件下的表型和毒力基因表达差异

doi:10.11707/j.1001-7488.20210411

摘要/Abstract

摘要：

目的: 研究松材线虫生防真菌伊氏线虫菌（EV）碳氮条件下表型和毒力基因表达差异，为培养高毒力菌株提供依据。方法: 分别选取碳、氮培养基培养EV，测定生长速度及产孢量。收获菌丝体并提取RNA进行建库和差异分析。结合经FDR法校正后的P值及以2为底的倍数变化的对数的绝对值（|log₂FoldChange|）判断差异表达的显著性。结果: EV在氮培养条件下生长速度更快，且基因表达的总量和特异表达的数量均高于碳培养条件下表达的数量。氮组相对碳组显著差异表达的基因共有7 138个，其中3 571个显著上调，3 567个显著下调；474个基因在氮组中特异表达，295个基因在碳组中特异表达，且氮组特异表达的基因涉及杀线虫基因的数量高于碳组。经过聚类分析，差异基因表达水平变化趋势分为4个类群，其中，在氮组表达远高于碳组表达的基因数量为165个；在碳组表达远高于氮组表达的基因数量仅有65个。枯草杆菌蛋白酶及毒素合成相关基因在氮组中显著上调表达，其中枯草杆菌蛋白酶在氮组中表达量为相对于碳组表达的2.29~363.52倍。结论: 碳、氮培养基对EV生防真菌的转录具有显著影响，氮培养条件下表达的总基因数量和特异表达的基因数量高于碳培养条件下的基因表达。具有杀灭和侵染线虫作用的枯草杆菌蛋白酶、毒素合成相关基因在氮培养下显著上调。可为高毒力EV菌株的培养、基因功能研究和菌株改良提供重要依据。

关键词: 松材线虫, 生防真菌, 伊氏线虫真菌, 转录组学

Abstract:

Objective: Pine wilt disease has been intensifying in China in recent years, and its pathogenic factor is pine wood nematode (Bursaphelenchus xylophilus), and it is a globally recognized quarantine pest. Esteya vermicola (EV) is an important biocontrol fungus infesting the pine wood nematode. The lunate spores produced by EV can infect and kill the pine wood nematode, thus EV has a good application prospect in the biological control of the pine wood nematodes. How to increase the growth rate, sporulation ability, and the virulence of EV to the pine wood nematode through cultivation, and then apply it to the field biological control is an important problem that needs to be solved urgently. Method: In this study, EV was cultured in carbon and nitrogen medium respectively, and the growth rate and spore production were determined. The mycelia were harvested and RNA was extracted for library construction and differential analysis. The corrected P-value (P_adj) and the absolute value of the logarithm of the base 2 fold change (|log₂FoldChange|) were used to judge the significance of the differential expression. Result: EV fungus grew fast under nitrogen culture conditions, and the total number of expressed genes and specifically expressed genes of EV fungi under nitrogen culture conditions were higher than those under carbon culture conditions. A total of 7 138 genes were significantly differently expressed in the nitrogen group compared to the carbon group, of which 3 571 genes were significantly up-regulated, and 3 567 genes were significantly down-regulated. There were 474 genes specifically expressed in the nitrogen group and 295 genes specifically expressed in the carbon group, and the number of genes specifically expressed in the nitrogen group involved nematicidal genes was greater than that in the carbon group. After cluster analysis, the variation trend of differential gene expression levels was divided into 4 clusters, among which there were 165 genes expressed much higher in the nitrogen group than in the carbon group; and 65 genes expressed much higher in the carbon group than in the nitrogen group. The expression of subtilisin and toxin synthesis-related genes involved in the activity of lethal nematodes and in the process of infecting nematodes were significantly up-regulated in the nitrogen group. The expression of subtilisin in the nitrogen group was 2.29-363.52 times higher relative to that in the carbon group. Conclusion: Carbon and nitrogen media have significant effects on the transcription of EV biocontrol fungi. The total number of genes and specifically expressed genes of EV fungi under nitrogen culture conditions are higher than those under carbon culture conditions. Subtilisin and toxin synthesis-related genes with nematicidal effects are significantly up-regulated under nitrogen culture. The research results will provide an important theoretical basis for the cultivation, gene function research and strain improvement of highly virulent EV strains, and then lay a foundation for improving the control efficacy of EV biocontrol fungi.

Key words: pine wood nematode, biological control, Esteya vermicola, transcriptomics

中图分类号:

S718.7

贺然,王瑞珍,应玥,曲良建,张永安. 伊氏线虫真菌碳氮条件下的表型和毒力基因表达差异[J]. 林业科学, 2021, 57(4): 107-115.

Ran He,Ruizhen Wang,Yue Ying,Liangjian Qu,Yong'an Zhang. Phenotypic and Virulence Gene Expression Difference of Esteya vermicola, A Biocontrol Fungus for Pine Wood Nematode under Carbon and Nitrogen Conditions[J]. Scientia Silvae Sinicae, 2021, 57(4): 107-115.

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基因家族Gene family	基因数量Gene number
基因家族Gene family	N组N group	C组C group
短链脱氢酶家族Short-chain dehydrogenase	9	5
酰胺酶Amidase	5	2
真菌特异性转录因子结构域Fungal specific transcription factor domain	15	5
糖基水解酶Glycosyl hydrolase 1 domain	5	2
膜转运蛋白Major facilitator superfamily transporter 1	46	19
NAD结合域NAD-binding domains	6	0
细胞色素P450	10	2
肽酶家族M20Peptidase family M20	1	1
枯草杆菌蛋白酶Peptidase_S8(Subtilase)	3	0
蛋白激酶结构域Protein kinase domain	5	4
糖转运蛋白Sugar transporter	32	5

基因家族 Gene family	类群1基因个数 Cluster 1 number	类群2基因个数 Cluster 2 number
短链脱氢酶家族Short-chain dehydrogenase	7	2
真菌特异性转录因子结构域Fungal specific transcription factor domain	4	0
膜转运蛋白MFS1Major facilitator superfamily transporter 1	8	3
钙蛋白酶Calpain	1	0
丝氨酸羧肽酶S28Serine carboxypeptidase S28	1	0
枯草杆菌蛋白酶Peptidase_S8(Subtilase)	2	0
糖转运蛋白Sugar transporter	10	5

基因编号 Gene id	差异倍数的log₂值 log₂FoldChange	校正的P值 P_adj	肽酶家族 Peptidase family
ZGLK4627	8.51	0.00E+00	S8
ZGLK1913	7.68	6.30E-174	S8
ZGLK3896	4.15	3.27E-66	S8
ZGLK1367	4.02	1.03E-91	S8
ZGLK1021	3.75	6.00E-94	S8
ZGLK1483	3.31	6.81E-17	S8
novel.315	3.08	2.53E-29	S8
ZGLK3512	2.83	3.33E-49	S8
ZGLK4767	2.56	3.86E-32	S8
ZGLK3672	2.33	6.06E-20	S8
ZGLK1029	2.17	1.10E-06	S8
ZGLK7350	1.70	1.32E-75	S8
ZGLK3094	1.20	1.88E-36	S8
ZGLK1168	-0.96	2.40E-02	S8
ZGLK2199	3.18	4.23E-65	S28
ZGLK4188	1.84	1.04E-09	S28
ZGLK5105	6.22	8.97E-186	S28

基因编号 Gene_id	差异倍数的对数值 log₂FoldChange	校正的P值 P_adj	注释到的基因功能 Annotated gene function	PHI编号 PHI_id	PHI注释到的突变表型 Mutant phenotype
ZGLK3633	4.48	9.85E-110	CaE-EAKt	133	LP-GDi
ZGLK0769	3.68	9.73E-127	CaE-EAKt	133	LP-GDi
ZGLK4572	3.64	4.10E-101	RTtB	2315	IV-Oe
ZGLK4189	2.99	1.13E-34	RTtB	2315	IV-Oe
ZGLK3112	2.73	6.35E-45	RTtB	2315	RV-GDe
ZGLK2791	2.68	1.43E-07	RTtB	2315	RV-GDe
ZGLK1171	2.42	9.63E-43	RTtB	2315	IV-Oe
ZGLK6482	2.27	2.60E-97	AFtB	508	LP-GDi
ZGLK4979	2.21	8.45E-19	AMtB	160	LP-GDi
ZGLK5521	1.76	4.72E-20	RTtB	2315	RV-GDe
ZGLK2782	1.74	2.92E-12	RTtB	2315	IV-Oe
ZGLK5292	1.65	3.36E-46	RTtB	2315	IV-Oe
ZGLK6243	1.62	7.08E-15	PolS	55	RV-GDi
ZGLK1943	1.51	1.22E-14	RTtB	2315	RV-GDe
ZGLK1888	1.38	7.61E-08	RTtB	2315	IV-Oe
ZGLK6653	1.27	4.54E-12	AKtB	2832	LP-GDe
ZGLK2807	1.05	1.36E-16	AFtB	509	LP-GDi
ZGLK7429	1.02	5.33E-08	PolS	40	RV-GDi
ZGLK0285	0.81	5.16E-03	RTtB	2315	IV-Oe
ZGLK7585	0.69	3.47E-20	RTtB	2315	RV-GDe
ZGLK4528	0.65	2.95E-04	RTtB	2315	IV-Oe
ZGLK8291	0.62	1.15E-10	ProMARTXt	3354	RV-GDe
ZGLK0925	-0.41	1.88E-02	RTtB	2315	RV-GDe
ZGLK1334	-0.61	2.80E-02	RTtB	2315	IV-Oe
ZGLK6815	-1.11	2.93E-12	HCtB	97	RV-GDi
ZGLK2055	-1.40	1.47E-30	RTtB	2315	IV-Oe
ZGLK1081	-1.45	2.13E-14	PolS	55	RV-GDi
ZGLK4421	-1.67	3.82E-07	CaE-EAKt	PHI: 133	LP-GDi

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