Discriminating multi-species populations in biofilms with peptide nucleic acid fluorescence in situ hybridization (PNA FISH)
Discriminating multi-species populations in biofilms with peptide nucleic acid fluorescence in situ hybridization (PNA FISH)
Background: ur current understanding of biofilms indicates that these structures are typically composed of many different microbial species. However, the lack of reliable techniques for the discrimination of each population has meant that studies focusing on multi-species biofilms are scarce and typically generate qualitative rather than quantitative data.
Methodology/principal findings: we employ peptide nucleic acid fluorescence in situ hybridization (PNA FISH) methods to quantify and visualize mixed biofilm populations. As a case study, we present the characterization of Salmonella enterica/Listeria monocytogenes/Escherichia coli single, dual and tri-species biofilms in seven different support materials. Ex-situ, we were able to monitor quantitatively the populations of ~56 mixed species biofilms up to 48 h, regardless of the support material. In situ, a correct quantification remained more elusive, but a qualitative understanding of biofilm structure and composition is clearly possible by confocal laser scanning microscopy (CLSM) at least up to 192 h. Combining the data obtained from PNA FISH/CLSM with data from other established techniques and from calculated microbial parameters, we were able to develop a model for this tri-species biofilm. The higher growth rate and exopolymer production ability of E. coli probably led this microorganism to outcompete the other two [average cell numbers (cells/cm2) for 48 h biofilm: E. coli 2,1×108 (±2,4×107); L. monocytogenes 6,8×107 (±9,4×106); and S. enterica 1,4×106 (±4,1×105)]. This overgrowth was confirmed by CSLM, with two well-defined layers being easily identified: the top one with E. coli, and the bottom one with mixed regions of L. monocytogenes and S. enterica.
Significance: while PNA FISH has been described previously for the qualitative study of biofilm populations, the present investigation demonstrates that it can also be used for the accurate quantification and spatial distribution of species in polymicrobial communities. Thus, it facilitates the understanding of interspecies interactions and how these are affected by changes in the surrounding environment
e14786-[13pp]
Almeida, Carina
08bcd2c4-bb43-482c-a3ed-517f5d1b9abf
Azevedo, Nuno F.
24c4eb52-0c98-443b-881f-7a1449c9ac26
Santos, Sílvio
e78b6369-3551-44e1-b04d-941808265bc2
Keevil, Charles W.
cb7de0a7-ce33-4cfa-af52-07f99e5650eb
Vieira, Maria J.
d972e877-d85b-488c-8b0f-358f79d2fa29
29 March 2011
Almeida, Carina
08bcd2c4-bb43-482c-a3ed-517f5d1b9abf
Azevedo, Nuno F.
24c4eb52-0c98-443b-881f-7a1449c9ac26
Santos, Sílvio
e78b6369-3551-44e1-b04d-941808265bc2
Keevil, Charles W.
cb7de0a7-ce33-4cfa-af52-07f99e5650eb
Vieira, Maria J.
d972e877-d85b-488c-8b0f-358f79d2fa29
Almeida, Carina, Azevedo, Nuno F., Santos, Sílvio, Keevil, Charles W. and Vieira, Maria J.
(2011)
Discriminating multi-species populations in biofilms with peptide nucleic acid fluorescence in situ hybridization (PNA FISH).
PLoS ONE, 6 (3), .
(doi:10.1371/journal.pone.0014786).
Abstract
Background: ur current understanding of biofilms indicates that these structures are typically composed of many different microbial species. However, the lack of reliable techniques for the discrimination of each population has meant that studies focusing on multi-species biofilms are scarce and typically generate qualitative rather than quantitative data.
Methodology/principal findings: we employ peptide nucleic acid fluorescence in situ hybridization (PNA FISH) methods to quantify and visualize mixed biofilm populations. As a case study, we present the characterization of Salmonella enterica/Listeria monocytogenes/Escherichia coli single, dual and tri-species biofilms in seven different support materials. Ex-situ, we were able to monitor quantitatively the populations of ~56 mixed species biofilms up to 48 h, regardless of the support material. In situ, a correct quantification remained more elusive, but a qualitative understanding of biofilm structure and composition is clearly possible by confocal laser scanning microscopy (CLSM) at least up to 192 h. Combining the data obtained from PNA FISH/CLSM with data from other established techniques and from calculated microbial parameters, we were able to develop a model for this tri-species biofilm. The higher growth rate and exopolymer production ability of E. coli probably led this microorganism to outcompete the other two [average cell numbers (cells/cm2) for 48 h biofilm: E. coli 2,1×108 (±2,4×107); L. monocytogenes 6,8×107 (±9,4×106); and S. enterica 1,4×106 (±4,1×105)]. This overgrowth was confirmed by CSLM, with two well-defined layers being easily identified: the top one with E. coli, and the bottom one with mixed regions of L. monocytogenes and S. enterica.
Significance: while PNA FISH has been described previously for the qualitative study of biofilm populations, the present investigation demonstrates that it can also be used for the accurate quantification and spatial distribution of species in polymicrobial communities. Thus, it facilitates the understanding of interspecies interactions and how these are affected by changes in the surrounding environment
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Published date: 29 March 2011
Organisations:
Centre for Biological Sciences
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Local EPrints ID: 209293
URI: http://eprints.soton.ac.uk/id/eprint/209293
ISSN: 1932-6203
PURE UUID: 6820511e-2609-4f17-98bb-236f6f9170bd
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Date deposited: 27 Jan 2012 11:38
Last modified: 15 Mar 2024 03:12
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Author:
Carina Almeida
Author:
Nuno F. Azevedo
Author:
Sílvio Santos
Author:
Maria J. Vieira
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