自由生活的变形虫的差异性细菌捕食可能导致饮用水系统中出现大量繁殖。

Differential Bacterial Predation by Free-Living Amoebae May Result in Blooms of in Drinking Water Systems.

作者信息

Shaheen Mohamed, Ashbolt Nicholas J

机构信息

School of Public Health, University of Alberta, Edmonton, AB T6G 1C9, Canada.

School of Environment, Science & Engineering, Southern Cross University, Lismore Campus, PO Box 157, Lismore, NSW 2480, Australia.

出版信息

Microorganisms. 2021 Jan 15;9(1):174. doi: 10.3390/microorganisms9010174.

DOI:10.3390/microorganisms9010174

PMID:33467483

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7829821/

Abstract

Intracellular growth of pathogenic in free-living amoebae (FLA) results in the critical concentrations that are problematic in engineered water systems (EWS). However, being amoeba-resistant bacteria (ARB), how spp. becomes internalized within FLA is still poorly understood. Using fluorescent microscopy, we investigated in real-time the preferential feeding behavior of three water-related FLA species, , and regarding and two strains. Although all the studied FLA species supported intracellular growth of , they avoided this bacterium to a certain degree in the presence of and mostly fed on it when the preferred bacterial food-sources were limited. Moreover, once were intracellular, it inhibited digestion of co-occurring within the same trophozoites. Altogether, based on FLA-bacteria interactions and the shifts in microbial population dynamics, we propose that FLA's feeding preference leads to an initial growth of FLA and depletion of prey bacteria, thus increases the relative abundance of and creates a "forced-feeding" condition facilitating the internalization of into FLA to initiate the cycles of intracellular multiplication. These findings imply that monitoring of FLA levels in EWS could be useful in predicting possible imminent high occurrence of .

摘要

病原体在自由生活阿米巴（FLA）内的细胞内生长会导致在工程水系统（EWS）中出现问题的临界浓度。然而，作为抗阿米巴细菌（ARB），[细菌名称] spp. 如何被内化到FLA中仍知之甚少。我们使用荧光显微镜实时研究了三种与水相关的FLA物种，即[FLA物种名称1]、[FLA物种名称2]和[FLA物种名称3]对[细菌名称1]和两种[细菌名称2]菌株的优先摄食行为。尽管所有研究的FLA物种都支持[细菌名称1]的细胞内生长，但在存在[细菌名称2]的情况下，它们在一定程度上避开了这种细菌，并且当首选的细菌食物来源有限时，大多以其为食。此外，一旦[细菌名称1]进入细胞内，它就会抑制同一滋养体内同时存在的[细菌名称2]的消化。总之，基于FLA与细菌的相互作用以及微生物种群动态的变化，我们提出FLA的摄食偏好导致FLA的初始生长和猎物细菌的消耗，从而增加了[细菌名称1]的相对丰度，并创造了一种“强制摄食”条件，促进[细菌名称1]内化到FLA中以启动细胞内繁殖周期。这些发现意味着监测EWS中的FLA水平可能有助于预测[细菌名称1]可能即将大量出现。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/61d0/7829821/161e00a8f7ae/microorganisms-09-00174-g001.jpg

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自由生活的变形虫的差异性细菌捕食可能导致饮用水系统中出现大量繁殖。

Differential Bacterial Predation by Free-Living Amoebae May Result in Blooms of in Drinking Water Systems.

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