Open Access
Microbial community overlap between the phyllosphere and rhizosphere of three plants from Yongxing Island, South China Sea
Author(s) -
Bao Lijun,
Cai Wenyang,
Cao Jianxi,
Zhang Xiaofen,
Liu Jinhong,
Chen Hao,
Wei Yuansong,
Zhuang Xuliang,
Zhuang Guoqiang,
Bai Zhihui
Publication year - 2020
Publication title -
microbiologyopen
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.881
H-Index - 36
ISSN - 2045-8827
DOI - 10.1002/mbo3.1048
Subject(s) - rhizosphere , phyllosphere , biology , diazotroph , botany , microbiome , microbial population biology , microorganism , bacteria , ecology , nitrogen fixation , bioinformatics , genetics
Abstract Phyllosphere and rhizosphere are unique and wide‐ranging habitats that harbor various microbial communities, which influence plant growth and health, and the productivity of the ecosystems. In this study, we characterized the shared microbiome of the phyllosphere and rhizosphere among three plants ( Ipomoea pes‐caprae , Wedelia chinensis , and Cocos nucifera ), to obtain an insight into the relationships between bacteria (including diazotrophic bacteria) and fungi, present on these host plants. Quantitative PCR showed that the abundances of the microbiome in the soil samples were significantly higher than those in the phyllosphere samples, though there was an extremely low abundance of fungi in bulk soil. High‐throughput sequencing showed that the alpha‐diversity of bacteria and fungi was higher in the rhizosphere than the phyllosphere samples associated with the same plant, while there was no obvious shift in the alpha‐diversity of diazotrophic communities between all the tested phyllosphere and soil samples. Results of the microbial composition showed that sample‐specific bacteria and fungi were found among the phyllosphere and rhizosphere of the different host plants. About 10%–27% of bacteria, including diazotrophs, and fungi overlapped between the phyllosphere and the rhizosphere of these host plants. No significant difference in microbial community structure was found among the tested rhizosphere samples, and soil properties had a higher influence on the soil microbial community structures than the host plant species.