Frontiers in Microbiology (May 2024)

Response of microbial diversity and function to the degradation of Barkol Saline Lake

  • Yong-Hong Liu,
  • Yong-Hong Liu,
  • Lei Gao,
  • Hong-Chen Jiang,
  • Bao-Zhu Fang,
  • Yin Huang,
  • Li Li,
  • Shuai Li,
  • Rashidin Abdugheni,
  • Wen-Hui Lian,
  • Jing-Yi Zhang,
  • Zhen-Dong Yang,
  • Osama Abdalla Abdelshafy Mohamad,
  • Osama Abdalla Abdelshafy Mohamad,
  • Wen-Jun Li,
  • Wen-Jun Li

DOI
https://doi.org/10.3389/fmicb.2024.1358222
Journal volume & issue
Vol. 15

Abstract

Read online

Barkol Lake, a shrinking hypersaline lake situated in the northeast of Xinjiang, China, has experienced the exposure of its riverbed and the gradual drying up of its original sediment due to climate change and human activities, resulting in the formation of alkaline soils. These changes have correspondingly altered the physicochemical characteristics of the surrounding environment. Microorganisms play a crucial role, with special functioning involved in various nutrient cycling and energy transfer in saline lake environments. However, little is known about how the microbial community dynamics and metabolic functions in this shrinking saline lake relate to the degradation process. To address this knowledge gap, a cultivation-independent method of amplicon sequencing was used to identify and analyze the microbial community and its potential ecological functions in the sediment and degraded area. The microbial community diversity was found to be significantly lower in the degraded areas than in the sediment samples. The Pseudomonadota was dominant in Barkol Saline Lake. The abundance of Desulfobacterota and Bacillota in the degraded areas was lower than in the lake sediment, while Pseudomonadota, Acidobacteriota, and Actinobacteriota showed an opposite trend. The βNTI showed that microbial community assembly was primarily associated with deterministic processes in Barkol Saline Lake ecosystems and stochastic processes at the boundary between sediment and degraded areas. Functional predictions showed that sulfur metabolism, particularly sulfate respiration, was much higher in sediment samples than in the degraded areas. Overall, these findings provided a possible perspective for us to understand how microorganisms adapt to extreme environments and their role in saline lakes under environmental change.

Keywords