Microbial dynamics in Manaus river, Brazil

Microbial journal Pub Date : 2023-11-18 DOI:10.59411/fwas7t80

Ricardo Lucas

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Abstract

Rivers, which are vital ecosystems that support a variety of life forms and provide many ecosystem services, have been degraded by human activities, such as urbanization, pollution, and overexploitation. Habitat restoration projects have been implemented in different parts of the world to restore the ecological health and functioning of degraded rivers. The microbial community that forms biofilms on various substrates is one of the key components of river ecosystems. Organic matter is decomposed and carbon dioxide is produced by these biofilms, which affects the oxygen levels and nutrient cycles in the water. However, the effects of habitat restoration on the biofilm microbial community are not well understood. High-throughput DNA sequencing was used in this study to compare the bacterial composition of biofilms in three types of rivers: degraded urban rivers, urban rivers with restored habitats, and forested rivers that serve as reference conditions. The following questions were aimed to be answered: (i) How is the biofilm bacterial community composition affected by habitat restoration? (ii) How does bacterial diversity change in restored rivers compared to degraded and reference rivers? (iii) What are the environmental factors that influence the biofilm bacterial community composition? It was found that water quality was improved by habitat restoration by increasing the dissolved oxygen and reducing the organic pollutants in urban rivers. A decrease in bacterial diversity and a shift in the biofilm bacterial community structure towards that of the reference forested rivers were accompanied by this. This suggests that the biofilm microbial community can be altered by habitat restoration and its role in processing organic pollutants can be enhanced. However, it was also found that there was still a significant difference in the biofilm bacterial community between the restored and reference rivers, indicating that more time and effort are needed to achieve a similar ecological quality as the natural forested rivers.

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巴西玛瑙斯河的微生物动态

河流是支持多种生命形式并提供多种生态系统服务的重要生态系统，但由于城市化、污染和过度开发等人类活动，河流已经退化。为了恢复退化河流的生态健康和功能，世界各地都实施了生境恢复项目。在各种基质上形成生物膜的微生物群落是河流生态系统的重要组成部分之一。这些生物膜分解有机物并产生二氧化碳，从而影响水中的氧气含量和营养循环。然而，人们对生境恢复对生物膜微生物群落的影响还不甚了解。本研究利用高通量 DNA 测序技术比较了三种类型河流中生物膜的细菌组成：退化的城市河流、生境恢复后的城市河流以及作为参考条件的森林河流。旨在回答以下问题：(i) 生境恢复对生物膜细菌群落组成有何影响？(ii) 与退化河流和参照河流相比，修复河流的细菌多样性有何变化？(iii) 影响生物膜细菌群落组成的环境因素有哪些？研究发现，生境恢复通过增加溶解氧和减少城市河流中的有机污染物改善了水质。随之而来的是细菌多样性的减少和生物膜细菌群落结构向参照森林河流的转变。这表明，生物膜微生物群落可以通过生境恢复而改变，其处理有机污染物的作用也可以增强。不过，研究也发现，修复后的河流与参照河流的生物膜细菌群落仍存在显著差异，这表明要达到与天然森林河流相似的生态质量，还需要更多的时间和努力。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Microbial journal

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