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Legionella pneumophila response to shifts in biofilm structure mediated by hydrodynamics

Legionella pneumophila response to shifts in biofilm structure mediated by hydrodynamics
Legionella pneumophila response to shifts in biofilm structure mediated by hydrodynamics

Preventing legionellosis in water systems demands effective hydrodynamic management and biofilm mitigation. This study investigates the complex relationship between hydrodynamics (80 RPM and stagnation), biofilm mesoscale structure and Legionella pneumophila colonization, by addressing three key questions: (1) How do low flow vs stagnation conditions affect biofilm response to L. pneumophila colonization?, (2) How do biofilm structural variations mediate L. pneumophila migration across the biofilm?, and (3) Can specific hydrodynamic conditions trigger L. pneumophila entrance in a viable but nonculturable (VBNC) state? It was found that Pseudomonas fluorescens biofilms exhibit different responses to L. pneumophila based on the prevailing hydrodynamic conditions. While biofilm thickness and porosity decreased under shear (80 RPM), thickness tends to significantly increase when pre-established 80 RPM-grown biofilms are set to stagnation upon L. pneumophila spiking. Imposing stagnation after the spiking also seemed to accelerate Legionella migration towards the bottom of the biofilm. Water structures in the biofilm seem to be key to Legionella migration across the biofilm. Finally, shear conditions favoured the transition of L. pneumophila to VBNC states (∼94 %), despite the high viable cell counts (∼8 log10 CFU/cm2) found throughout the experiments. This research highlights the increased risk posed by biofilms and stagnation, emphasizing the importance of understanding the mechanisms that govern Legionella behaviour in diverse biofilm environments. These insights are crucial for developing more effective monitoring and prevention strategies in water systems.

Biofilm structural changes, VBNC, Stagnation, Legionella pneumophila migration, Flow regime
2590-2075
Silva, Ana Rosa
325c3df6-056e-4663-a0b2-a4d16589b880
Keevil, C. William
cb7de0a7-ce33-4cfa-af52-07f99e5650eb
Pereira, Ana
3ed70937-fab3-455d-9f66-d36b6da82252
Silva, Ana Rosa
325c3df6-056e-4663-a0b2-a4d16589b880
Keevil, C. William
cb7de0a7-ce33-4cfa-af52-07f99e5650eb
Pereira, Ana
3ed70937-fab3-455d-9f66-d36b6da82252

Silva, Ana Rosa, Keevil, C. William and Pereira, Ana (2025) Legionella pneumophila response to shifts in biofilm structure mediated by hydrodynamics. Biofilm, 9, [100258]. (doi:10.1016/j.bioflm.2025.100258).

Record type: Article

Abstract

Preventing legionellosis in water systems demands effective hydrodynamic management and biofilm mitigation. This study investigates the complex relationship between hydrodynamics (80 RPM and stagnation), biofilm mesoscale structure and Legionella pneumophila colonization, by addressing three key questions: (1) How do low flow vs stagnation conditions affect biofilm response to L. pneumophila colonization?, (2) How do biofilm structural variations mediate L. pneumophila migration across the biofilm?, and (3) Can specific hydrodynamic conditions trigger L. pneumophila entrance in a viable but nonculturable (VBNC) state? It was found that Pseudomonas fluorescens biofilms exhibit different responses to L. pneumophila based on the prevailing hydrodynamic conditions. While biofilm thickness and porosity decreased under shear (80 RPM), thickness tends to significantly increase when pre-established 80 RPM-grown biofilms are set to stagnation upon L. pneumophila spiking. Imposing stagnation after the spiking also seemed to accelerate Legionella migration towards the bottom of the biofilm. Water structures in the biofilm seem to be key to Legionella migration across the biofilm. Finally, shear conditions favoured the transition of L. pneumophila to VBNC states (∼94 %), despite the high viable cell counts (∼8 log10 CFU/cm2) found throughout the experiments. This research highlights the increased risk posed by biofilms and stagnation, emphasizing the importance of understanding the mechanisms that govern Legionella behaviour in diverse biofilm environments. These insights are crucial for developing more effective monitoring and prevention strategies in water systems.

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More information

Accepted/In Press date: 24 January 2025
e-pub ahead of print date: 24 January 2025
Published date: 30 June 2025
Keywords: Biofilm structural changes, VBNC, Stagnation, Legionella pneumophila migration, Flow regime

Identifiers

Local EPrints ID: 498765
URI: http://eprints.soton.ac.uk/id/eprint/498765
DOI: doi:10.1016/j.bioflm.2025.100258
ISSN: 2590-2075
PURE UUID: 3d1315b6-3eae-42d3-98d8-ba5fd65f3d98
ORCID for C. William Keevil: ORCID iD orcid.org/0000-0003-1917-7706

Catalogue record

Date deposited: 27 Feb 2025 18:08
Last modified: 22 Aug 2025 01:49

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Contributors

Author: Ana Rosa Silva
Author: C. William Keevil ORCID iD
Author: Ana Pereira

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