Exploring the metabolic potential of Aeromonas to utilise the carbohydrate polymer chitin.

IF 4.2 Q2 BIOCHEMISTRY & MOLECULAR BIOLOGY
Claudia G Tugui, Dimitry Y Sorokin, Wim Hijnen, Julia Wunderer, Kaatje Bout, Mark C M van Loosdrecht, Martin Pabst
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引用次数: 0

Abstract

Members of the Aeromonas genus are commonly found in natural aquatic ecosystems. However, they are also frequently present in non-chlorinated drinking water distribution systems. High densities of these bacteria indicate favorable conditions for microbial regrowth, which is considered undesirable. Studies have indicated that the presence of Aeromonas is associated with loose deposits and the presence of invertebrates, specifically Asellus aquaticus. Therefore, a potential source of energy in these nutrient poor environments is chitin, the structural shell component in these invertebrates. In this study, we demonstrate the ability of two Aeromonas strains, commonly encountered in drinking water distribution systems, to effectively degrade and utilize chitin as a sole carbon and nitrogen source. We conducted a quantitative proteomics study on the cell biomass and secretome from pure strain cultures when switching the nutrient source from glucose to chitin, uncovering a diverse array of hydrolytic enzymes and metabolic pathways specifically dedicated to the utilization of chitin. Additionally, a genomic analysis of different Aeromonas species suggests the general ability of this genus to degrade and utilize a variety of carbohydrate biopolymers. This study indicates the relation between the utilization of chitin by Aeromonas and their association with invertebrates such as A. aquaticus in loose deposits in drinking water distribution systems.

探索气单胞菌利用碳水化合物聚合物甲壳素的代谢潜力。
气单胞菌属成员通常存在于自然水生生态系统中。不过,它们也经常出现在不含氯的饮用水输水系统中。这些细菌的高密度表明微生物再生的有利条件,这被认为是不可取的。研究表明,气单胞菌的存在与松散沉积物和无脊椎动物(特别是水生无脊椎动物)的存在有关。因此,在这些营养不良的环境中,几丁质是一种潜在的能量来源,几丁质是这些无脊椎动物外壳的结构成分。在本研究中,我们展示了饮用水输配系统中常见的两种气单胞菌株有效降解和利用甲壳素作为唯一碳源和氮源的能力。当营养源从葡萄糖转换为甲壳素时,我们对纯菌株培养物的细胞生物量和分泌组进行了定量蛋白质组学研究,发现了一系列专门用于利用甲壳素的水解酶和代谢途径。此外,对不同气单胞菌物种的基因组分析表明,该菌属具有降解和利用各种碳水化合物生物聚合物的一般能力。这项研究表明,水单胞菌利用几丁质与饮用水输配系统中松散沉积物中的水单胞菌等无脊椎动物的关系密切。
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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来源期刊
CiteScore
6.10
自引率
0.00%
发文量
128
审稿时长
10 weeks
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