Skip to main content
eScholarship
Open Access Publications from the University of California

Nearly a decade-long repeatable seasonal diversity patterns of bacterioplankton communities in the eutrophic Lake Donghu (Wuhan, China).

  • Author(s): Yan, Qingyun
  • Stegen, James C
  • Yu, Yuhe
  • Deng, Ye
  • Li, Xinghao
  • Wu, Shu
  • Dai, Lili
  • Zhang, Xiang
  • Li, Jinjin
  • Wang, Chun
  • Ni, Jiajia
  • Li, Xuemei
  • Hu, Hongjuan
  • Xiao, Fanshu
  • Feng, Weisong
  • Ning, Daliang
  • He, Zhili
  • Van Nostrand, Joy D
  • Wu, Liyou
  • Zhou, Jizhong
  • et al.

Published Web Location

https://doi.org/10.1111/mec.14151
Abstract

Uncovering which environmental factors govern community diversity patterns and how ecological processes drive community turnover are key questions related to understand the community assembly. However, the ecological mechanisms regulating long-term variations of bacterioplankton communities in lake ecosystems remain poorly understood. Here we present nearly a decade-long study of bacterioplankton communities from the eutrophic Lake Donghu (Wuhan, China) using 16S rRNA gene amplicon sequencing with MiSeq platform. We found strong repeatable seasonal diversity patterns in terms of both common (detected in more than 50% samples) and dominant (relative abundance >1%) bacterial taxa turnover. Moreover, community composition tracked the seasonal temperature gradient, indicating that temperature is a key environmental factor controlling observed diversity patterns. Total phosphorus also contributed significantly to the seasonal shifts in bacterioplankton composition. However, any spatial pattern of bacterioplankton communities across the main lake areas within season was overwhelmed by their temporal variabilities. Phylogenetic analysis further indicated that 75%-82% of community turnover was governed by homogeneous selection due to consistent environmental conditions within seasons, suggesting that the microbial communities in Lake Donghu are mainly controlled by niche-based processes. Therefore, dominant niches available within seasons might be occupied by similar combinations of bacterial taxa with modest dispersal rates throughout different lake areas.

Main Content
Current View