甜菜抗病品种产生抗性的土壤微生物机理

doi:10.11924/j.issn.1000-6850.casb2020-0441

中国农学通报 ›› 2021, Vol. 37 ›› Issue (15): 78-86.doi: 10.11924/j.issn.1000-6850.casb2020-0441

所属专题：资源与环境；农业生态

• 资源·环境·生态·土壤·气象 • 上一篇下一篇

甜菜抗病品种产生抗性的土壤微生物机理

刘洪¹^,²(), 董元华¹, 隋跃宇³, 李建刚¹()

¹中国科学院南京土壤研究所,土壤环境与污染修复重点实验室,南京 210008
²中国科学院大学,北京 100049
³中国科学院东北地理与农业生态研究所,黑土区农业生态重点实验室,哈尔滨 150081

收稿日期:2020-09-08 修回日期:2020-10-09 出版日期:2021-05-25 发布日期:2021-05-18
通讯作者: 李建刚
作者简介:刘洪,男,1993年出生,湖北赤壁人,在读博士,研究方向：植物土传病害的营养生态调控研究。通信地址：210008 江苏省南京市北京东路71号中国科学院南京土壤研究所,Tel：025-86881370,E-mail： liuhong@issas.ac.cn。
基金资助:
国家重点研发计划项目“土壤退化对农业主要有害生物发生影响机制”(2017YFD0200604);,“连作障碍抑制作物对养分吸收利用机理与消减技术”(2016YFD0200305);国家自然科学基金项目“连作番茄青枯病发生的动态过程及土壤生态学机制”(41977055)

Soil Microbial Mechanism of Disease Resistant Sugar Beet Variety

Liu Hong¹^,²(), Dong Yuanhua¹, Sui Yueyu³, Li Jiangang¹()

¹CAS Key Laboratory of Soil Environment and Pollution Remediation, Institute of Soil Science, Chinese Academy of Sciences, Nanjing 210008
²University of Chinese Academy of Sciences, Beijing 100049
³Key Laboratory of Mollisols Agroecology, Northeast Institute of Geography and Agro-ecology, Chinese Academy of Sciences, Harbin 150081

Received:2020-09-08 Revised:2020-10-09 Online:2021-05-25 Published:2021-05-18
Contact: Li Jiangang

摘要/Abstract

摘要：

本研究以甜菜和根腐病为研究对象,分析了不同品种以及不同发病程度甜菜中土壤微生物群落组成、结构以及功能的变化,以期获得抗性品种、发病程度和根际微生物相互间的关系,揭示抗病品种的土壤微生物机制。利用抗病型和感病型两种甜菜品种作为研究对象,并从2种品种中分别选取了发病轻和发病重的甜菜根际土壤样品,通过Illumina MiSeq高通量测序技术对根际土壤细菌和真菌群落进行测定。结果发现：发病较轻的甜菜根际土壤微生物（细菌和真菌）和抗病型甜菜根际土壤真菌的多样性相对较高。NMDS分析表明甜菜品种能显著影响土壤真菌的群落结构,而发病程度则能同时明显改变细菌与真菌的群落结构。在根际微生物富集方面,抗病型甜菜根际富集了假单胞菌(Pseudomonas)、节杆菌(Arthrobacter)、芽孢杆菌(Bacillus)等有益细菌,而感病型甜菜中则富集了较多的病原微生物-尖孢镰刀菌(Fusarium oxysporum)。另外,发病较轻样品中富集了较多的未分类的酸杆菌纲属、芽孢杆菌(Bacillus)、红色杆菌属(Rubrobacter)、未分类的放线菌纲属、链霉菌属(Streptomyces)、类诺卡氏属(Nocardioides)等有益细菌。除此以外,FUNGuild功能预测表明,感病型甜菜和发病较重样品中检测到更多的植物病原菌。抗病品种和健康植株根际微生物虽然在种类上不同,但是其根际均聚集了大量的有益微生物,而感病型品种和发病严重植株则更容易在根围定殖病原微生物。抗病品种的抗病机理之一是植物生长过程中招募了更多的有益细菌作为抵御病原菌的侵染第一道防线。本研究从土壤微生物组的角度对抗病品种抗性机制进行了阐明,充实了抗病品种抗性产生的理论机制。

关键词: 抗性育种, 植物病害, 细菌群落, 真菌群落, 高通量测序

Abstract:

This study took sugar beet and its root rot as the research objects, and analyzed the changes of soil microbial community composition, structure and function of different sugar beet varieties with different degrees of disease, so as to obtain the relationship among resistant varieties, degree of disease and rhizosphere microorganisms, and reveal the soil microbial mechanism of disease-resistant varieties. In this paper, two kinds of sugar beet varieties including the disease-resistant and disease-susceptible types were employed, and two different sugar beet varieties with low and high disease severity were separately selected to measure bacteria and fungi communities in their rhizosphere by Illumina MiSeq high-throughput sequencing technology. The results showed that the rhizosphere microbial (bacteria and fungi) diversity of sugar beet with lower disease symptom were relatively higher than that with higher disease severity, at the same time, the fungal diversity of disease-resistant sugar beet rhizosphere soil was higher than that in disease-sensitive types. NMDS analysis demonstrated that resistance breeding could significantly affect the community structure of soil fungi, and the community structure of both bacteria and fungi could be notably distinguished from different disease status. In terms of the enrichment of rhizosphere microorganisms, disease-resistant sugar beets enriched some beneficial bacteria such as Pseudomonas, Arthrobacter and Bacillus, while susceptible sugar beets enriched more plant pathogenic microorganisms-Fusarium oxysporum. In addition, the samples with lower disease severity tended to have more beneficial bacteria, including unclassified Acidobacteria, Bacillus, Rubrobacter, unclassified Actinomycetes, Streptomyces, and Nocardioides. Furthermore, FUNGuild functional prediction showed that more plant pathogens were detected in susceptible sugar beets and samples with higher disease severity. In conclusion, although disease-resistant varieties and healthy plants differ in microbial species, a large number of beneficial microorganisms gather in their rhizosphere, while disease-susceptible types and the plants with higher disease severity are more likely to be colonized by pathogenic microorganisms around the roots. One of the microbial mechanism of resistance formation in a disease-resistant sugar beet variety is that plants recruit more beneficial bacteria as the first line to defense against pathogen infection when the plants grow. This study clarifies the resistance mechanism of disease-resistant varieties from the perspective of soil microbiome and enriches the theoretical mechanism of resistance generation of disease-resistant varieties.

Key words: resistance breeding, plant pathogen, bacterial community, fungal community, high-throughput sequencing

中图分类号:

S332
S154.3

刘洪, 董元华, 隋跃宇, 李建刚. 甜菜抗病品种产生抗性的土壤微生物机理[J]. 中国农学通报, 2021, 37(15): 78-86.

Liu Hong, Dong Yuanhua, Sui Yueyu, Li Jiangang. Soil Microbial Mechanism of Disease Resistant Sugar Beet Variety[J]. Chinese Agricultural Science Bulletin, 2021, 37(15): 78-86.

图/表 7

参考文献 34

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统计指标	抗病品种(PT)		感病品种(ST)
统计指标	发病轻(PTL)	发病重(PTH)	发病轻(STL)	发病重(STH)
pH	6.55±0.02d	6.91±0.04b	6.69±0.04c	7.03±0.02a
有机碳/%	1.56±0.05a	1.52±0.02ab	1.51±0.03ab	1.43±0.01c
全氮/%	0.149±0.001b	0.160±0.001a	0.146±0.002bc	0.143±0.002c
全磷/%	0.973±0.053a	0.800±0.003b	0.794±0.043b	0.800±0.032b
全钾/%	0.947±0.027b	0.905±0.006b	0.893±0.002b	1.063±0.051a
硝态氮/(mg/kg)	4.08±0.02c	6.18±0.02b	3.93±0.01d	7.36±0.04a
铵态氮/(mg/kg)	0.52±0.08a	0.38±0.02b	0.27±0.04b	0.36±0.04b
有效磷/(mg/kg)	21.77±0.08a	8.37±0.08c	12.10±0.08b	8.99±0.97c
有效钾/(mg/kg)	27.63±0.68c	47.30±0.52a	26.73±1.08c	39.53±0.58b

统计指标	抗病品种(PT)		感病品种(ST)
统计指标	发病轻(PTL)	发病重(PTH)	发病轻(STL)	发病重(STH)
pH	6.55±0.02d	6.91±0.04b	6.69±0.04c	7.03±0.02a
有机碳/%	1.56±0.05a	1.52±0.02ab	1.51±0.03ab	1.43±0.01c
全氮/%	0.149±0.001b	0.160±0.001a	0.146±0.002bc	0.143±0.002c
全磷/%	0.973±0.053a	0.800±0.003b	0.794±0.043b	0.800±0.032b
全钾/%	0.947±0.027b	0.905±0.006b	0.893±0.002b	1.063±0.051a
硝态氮/(mg/kg)	4.08±0.02c	6.18±0.02b	3.93±0.01d	7.36±0.04a
铵态氮/(mg/kg)	0.52±0.08a	0.38±0.02b	0.27±0.04b	0.36±0.04b
有效磷/(mg/kg)	21.77±0.08a	8.37±0.08c	12.10±0.08b	8.99±0.97c
有效钾/(mg/kg)	27.63±0.68c	47.30±0.52a	26.73±1.08c	39.53±0.58b

微生物	品种	病情	Richness	Shannon	Chao 1	Faith_pd
细菌	抗病品种(PT)	发病轻(PTL)	930±12a	8.35±0.05a	974±14a	44.41±1.21a
	抗病品种(PT)	发病重(PTH)	906±12a	8.06±0.11a	989±18a	44.18±1.20a
	感病品种(ST)	发病轻(STL)	892±7a	8.09±0.16a	947±10a	44.67±0.39a
	感病品种(ST)	发病重(STH)	924±5a	8.22±0.03a	970±4a	42.60±0.33a
真菌	抗病品种(PT)	发病轻(PTL)	723±16a	6.27±0.32a	898±3.52a	124.27±2.92a
	抗病品种(PT)	发病重(PTH)	580±44b	5.58±0.34a	725±39b	107.70±8.71a
	感病品种(ST)	发病轻(STL)	653±44ab	6.17±0.51a	780±34ab	116.53±6.39a
	感病品种(ST)	发病重(STH)	564±24b	4.95±0.49a	740±29b	105.37±3.27a

微生物	品种	病情	Richness	Shannon	Chao 1	Faith_pd
细菌	抗病品种(PT)	发病轻(PTL)	930±12a	8.35±0.05a	974±14a	44.41±1.21a
	抗病品种(PT)	发病重(PTH)	906±12a	8.06±0.11a	989±18a	44.18±1.20a
	感病品种(ST)	发病轻(STL)	892±7a	8.09±0.16a	947±10a	44.67±0.39a
	感病品种(ST)	发病重(STH)	924±5a	8.22±0.03a	970±4a	42.60±0.33a
真菌	抗病品种(PT)	发病轻(PTL)	723±16a	6.27±0.32a	898±3.52a	124.27±2.92a
	抗病品种(PT)	发病重(PTH)	580±44b	5.58±0.34a	725±39b	107.70±8.71a
	感病品种(ST)	发病轻(STL)	653±44ab	6.17±0.51a	780±34ab	116.53±6.39a
	感病品种(ST)	发病重(STH)	564±24b	4.95±0.49a	740±29b	105.37±3.27a

微生物	处理	PERMANOVA			MRPP		ANOSIM
微生物	处理	F	R²	P	δ	P	R	P
细菌	所有样品	4.1178	0.6069	0.001	0.2837	0.001	0.5957	0.001
	品种	1.3314	0.1175	0.238	0.3829	0.135	0.06481	0.176
	致病状态	6.4952	0.39376	0.007	0.3184	0.005	0.6204	0.004
真菌	所有样品	2.5362	0.4875	0.002	0.4951	0.001	0.6296	0.001
	品种	1.3677	0.1203	0.181	0.5751	0.117	0.1296	0.119
	致病状态	3.5073	0.2597	0.006	0.5321	0.003	0.5333	0.002

甜菜抗病品种产生抗性的土壤微生物机理

Soil Microbial Mechanism of Disease Resistant Sugar Beet Variety

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