Effect of Gastrodiae elata-Phallus impudicus sequential planting pattern on soil microbial community structure.
10.19540/j.cnki.cjcmm.20191204.106
- Author:
Jiao XU
1
;
Xiao-Hong OU
1
;
Wei-Ke JIANG
1
;
Qing-Song YUAN
1
;
Yan-Hong WANG
1
;
Jie YANG
1
;
Da-Hui LIU
2
;
Xiao WANG
3
;
Guang-Wen ZHANG
4
;
Cheng PAN
4
;
Tao ZHOU
1
Author Information
1. Guizhou University of Traditional Chinese Medicine Guiyang 550025, China.
2. Hubei University of Chinese Medicine Wuhan 430065, China.
3. Shandong Analysis and Test Center Jinan 250014, China.
4. Guizhou Wumeng Fungi Industry Co., Ltd. Dafang 551600, China.
- Publication Type:Journal Article
- Keywords:
Armillaria;
Gastrodiae elata;
Phallus impudicus;
soil microbial
- MeSH:
Agaricales/growth & development*;
Bacteria/classification*;
Fungi/classification*;
Gastrodia/microbiology*;
Microbiota;
Rhizosphere;
Soil Microbiology
- From:
China Journal of Chinese Materia Medica
2020;45(3):463-471
- CountryChina
- Language:Chinese
-
Abstract:
Gastrodia elata is a heterotrophic plant that needed to be symbiotic with Armillaria. The obstacle of continuous cropping in G. elata is serious during the G. elata cultivation, and the mechanism of obstacle in G. elata continuous cropping had not been solved. The planting of G. elata-Phallus impudicus is a new sequential planting pattern adopted in Guizhou province, but the effect of the cultivation on soil microbial community structure is still unclear. In this study, we collected four soil samples for the research including the soil without planted G. elata as control(CK), rhizosphere soil samples tightly adhering to the G. elata surface(GE), rhizosphere soil samples tightly adhering to Armillaria which was symbiotic with G. elata(AGE), the rhizosphere soil of P. impudicus planting after G. elata cultivation(PI). In order to explore the mechanism, the research study on the soil of G. elata-P. impudicus by using ITS and 16 S rDNA high-throughput sequencing technologies to detect soil microbial community structure including fungi and bacteria in the soil of CK, AGE, GE and PI. OTU clustering and PCA analysis of soil samples showed that the soil microbial diversity was relatively similar in AGE and GE. And the soil microbial in PI and CK clustered together. The results showed that AGE and GE had similar soil microbial diversity, as well as PI and CK. Compared with CK, the soil microbial diversity and abundance in AGE and GE were significantly increased. But the microbial diversity and abundance decreased in PI compared with AGE and GE. The annotation indicated that the abundance of Basidiomycota, Acidobacteria and Chloroflexi decreased, and that of Ascomycota, Zygomycota and Proteobacteria increased in AGE and GE compared with CK. In contrast to AGE and GE, PI was the opposite. The abundance of Basidiomycota, Acidobacteria and Chloroflexi increased in PI compared with AGE and GE. The abundance of microorganisms in the soil of PI and CK was similar. In addition, the co-culture of Armillaria and P. impudicus indicated that P. impudicus had obvious antagonistic effects on the growth of Armillaria. Therefore, it is speculated that the mechanism of G. elata-P. impudicus planting pattern related to the change of soil microbial. And we supposed that P. impudicus might inhibit the growth of Armillaria and change the soil microbial community structure and the abundance of soil microbial. And the soil microbial community structure was restored to a state close to that of uncultivated G. elata. Thus, the structure of soil microbial community planting G. elata could be restored by P. impudicus planting.