Genome-resolved metagenomics of Venice Lagoon surface sediment bacteria reveals high biosynthetic potential and metabolic plasticity as successful strategies in an impacted environment

IF 5.8 2区 生物学 Q1 MARINE & FRESHWATER BIOLOGY
Elisa Banchi, Erwan Corre, Paola Del Negro, Mauro Celussi, Francesca Malfatti
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Abstract

Abstract Bacteria living in sediments play essential roles in marine ecosystems and deeper insights into the ecology and biogeochemistry of these largely unexplored organisms can be obtained from ‘omics’ approaches. Here, we characterized metagenome-assembled-genomes (MAGs) from the surface sediment microbes of the Venice Lagoon (northern Adriatic Sea) in distinct sub-basins exposed to various natural and anthropogenic pressures. MAGs were explored for biodiversity, major marine metabolic processes, anthropogenic activity-related functions, adaptations at the microscale, and biosynthetic gene clusters. Starting from 126 MAGs, a non-redundant dataset of 58 was compiled, the majority of which (35) belonged to (Alpha- and Gamma-) Proteobacteria. Within the broad microbial metabolic repertoire (including C, N, and S metabolisms) the potential to live without oxygen emerged as one of the most important features. Mixotrophy was also found as a successful lifestyle. Cluster analysis showed that different MAGs encoded the same metabolic patterns (e.g . , C fixation, sulfate oxidation) thus suggesting metabolic redundancy. Antibiotic and toxic compounds resistance genes were coupled, a condition that could promote the spreading of these genetic traits. MAGs showed a high biosynthetic potential related to antimicrobial and biotechnological classes and to organism defense and interactions as well as adaptive strategies for micronutrient uptake and cellular detoxification. Our results highlighted that bacteria living in an impacted environment, such as the surface sediments of the Venice Lagoon, may benefit from metabolic plasticity as well as from the synthesis of a wide array of secondary metabolites, promoting ecosystem resilience and stability toward environmental pressures.
威尼斯泻湖表层沉积物细菌的基因组解析宏基因组学揭示了在受影响的环境中具有高生物合成潜力和代谢可塑性的成功策略
生活在沉积物中的细菌在海洋生态系统中起着至关重要的作用,通过“组学”方法可以更深入地了解这些大部分未被探索的生物的生态学和生物地球化学。在这里,我们从威尼斯泻湖(亚得里亚海北部)暴露于各种自然和人为压力的不同子盆地的表面沉积物微生物中表征了宏基因组组装基因组(MAGs)。探讨了mag的生物多样性、主要海洋代谢过程、人类活动相关功能、微尺度适应和生物合成基因簇。从126个MAGs开始,编译了58个非冗余数据集,其中大部分(35个)属于(Alpha-和Gamma-) Proteobacteria。在广泛的微生物代谢库(包括碳、氮和硫代谢)中,无氧生存的潜力成为最重要的特征之一。混合营养也被认为是一种成功的生活方式。聚类分析表明,不同的mag编码相同的代谢模式(例如;C固定,硫酸盐氧化),因此表明代谢冗余。抗生素和有毒化合物的抗性基因是偶联的,这种情况可以促进这些遗传性状的传播。MAGs在抗菌和生物技术、生物防御和相互作用以及微量营养素吸收和细胞解毒的适应策略方面显示出很高的生物合成潜力。我们的研究结果强调,生活在受影响环境中的细菌,如威尼斯泻湖的表面沉积物,可能受益于代谢可塑性以及各种次生代谢物的合成,促进生态系统对环境压力的恢复力和稳定性。
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来源期刊
Marine Life Science & Technology
Marine Life Science & Technology MARINE & FRESHWATER BIOLOGY-
CiteScore
9.60
自引率
10.50%
发文量
58
期刊介绍: Marine Life Science & Technology (MLST), established in 2019, is dedicated to publishing original research papers that unveil new discoveries and theories spanning a wide spectrum of life sciences and technologies. This includes fundamental biology, fisheries science and technology, medicinal bioresources, food science, biotechnology, ecology, and environmental biology, with a particular focus on marine habitats. The journal is committed to nurturing synergistic interactions among these diverse disciplines, striving to advance multidisciplinary approaches within the scientific field. It caters to a readership comprising biological scientists, aquaculture researchers, marine technologists, biological oceanographers, and ecologists.
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