Thermodynamically favorable reactions shape the archaeal community affecting bacterial community assembly in oil reservoirs.

Jie-Yu Zhao,Yong Nie,Yiming Jiang,Bing Hu,Yan Li,Yue-Qin Tang,Xiao-Lei Wu,Jan Dolfing,Chang-Qiao Chi,Jianmin Xing

doi:10.1016/j.scitotenv.2021.146506

Abstract

Microbial community assembly mechanisms are pivotal for understanding the ecological functions of microorganisms in biogeochemical cycling in Earth's ecosystems, yet rarely investigated in the context of deep terrestrial ecology. Here, the microbial communities in the production waters collected from water injection wells and oil production wells across eight oil reservoirs throughout northern China were determined and analyzed by proportional distribution analysis and null model analysis. A 'core' microbiota consisting of three bacterial genera, including Arcobacter, Pseudomonas and Acinetobacter, and eight archaeal genera, including Archaeoglobus, Methanobacterium, Methanothermobacter, unclassified Methanobacteriaceae, Methanomethylovorans, Methanoculleus, Methanosaeta and Methanolinea, was found to be present in all production water samples. Canonical correlation analysis reflected that the core archaea were significantly influenced by temperature and reservoir depth, while the core bacteria were affected by the combined impact of the core archaea and environmental factors. Thermodynamic calculations indicate that bioenergetic constraints are the driving force that governs the enrichment of two core archaeal guilds, aceticlastic methanogens versus hydrogenotrophic methanogens, in low- and high-temperature oil reservoirs, respectively. Collectively, our study indicates that microbial community structures in wells of oil reservoirs are structured by the thermodynamic window of opportunity, through which the core archaeal communities are accommodated directly followed by the deterministic recruiting of core bacterial genera, and then the stochastic selection of some other microbial members from local environments. Our study enhances the understanding of the microbial assembly mechanism in deep terrestrial habitats. Meanwhile, our findings will support the development of functional microbiota used for bioremediation and bioaugmentation in microbial enhanced oil recovery.

Highlights

Microorganisms are present in most habitats on the earth and play fundamental roles in global biogeochemical cycles, shaping the entire environment of the planet [1]
Our results show that some core bacterial and archaeal species were universally existent in all samples regardless of the spatial distances, while some other members were locally unique, and that the functional archaeal distribution was in accord with rational thermodynamic constraints, indicating that both deterministic and stochastic processes occurred during the microbial community assembly and that the intrinsic assembly mechanism likely leads toward a thermodynamic window of opportunity
Spatial variations in physical and geochemical conditions in petroleum reservoirs In this study, a total of 50 water samples were collected for microbial community analysis from eight injection wells and 42 production wells in eight blocks of various oilfields in northern China, including Dagang Oilfield Block Yangerzhuang (DGD), Daqing Oilfield Northern Block II (DQN), Huabei Oilfield Block Menggulin (HBM) and Block XIX (HBB), Liaohe Oilfield Block A12 (LHA), Shengli Oilfield Block Zhan III (SLZ), and Xinjiang Oilfield Block VI (XJT) and Block VII (XJQ)

Summary

Introduction

Microorganisms are present in most habitats on the earth and play fundamental roles in global biogeochemical cycles, shaping the entire environment of the planet [1]. Community assembly mechanisms are essential for understanding the ecological functions of microorganisms in biogeochemical cycling in Earth’s ecosystems [2,3,4] Both deterministic and stochastic processes play important roles in community assembly [5,6]. The deterministic processes involve niche-based mechanisms, including microbial interactions and environmental filtering, while the stochastic processes include random births, deaths, colonization, extinction, and speciation [7] How these two processes shape the microbial community together is still unclear. Acetotrophic methanogens rather than hydrogenotrophic methanogens were predominant in the anaerobic microbial communities under high caron dioxide (CO2) partial pressure, because aceticlastic methanogenesis was thermodynamically easier than the syntrophic acetate oxidation linked with hydrogenotrophic methanogenesis under this condition [11]. It is still unknown what the basic force is to build up microbial communities in nature and how it drives the assembly of microbial communities

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Discussion

Conclusion