Arginine induced Streptococcus gordonii biofilm detachment using a novel 1 rotating-disc rheometry method
Arginine induced Streptococcus gordonii biofilm detachment using a novel 1 rotating-disc rheometry method
Oral diseases are one of the most common pathologies affecting human health. These diseases are typically associated with dental plaque-biofilms, through either build-up of the biofilm or dysbiosis of the microbial community. Arginine can disrupt dental plaque-biofilms, and maintain plaque homeostasis, making it an ideal therapeutic to combat the development of oral disease. Despite our understanding of the actions of arginine towards dental plaque-biofilms, it is still unclear how or if arginine effects the mechanical integrity of the dental plaque-biofilm. Here we adapted a rotating-disc rheometry assay, a method used to quantify marine biofilm fouling, to study how arginine treatment of Streptococcus gordonii biofilms influences biofilm detachment from surfaces. We demonstrate that the assay is highly sensitive at quantifying the presence of biofilm and the detachment or rearrangement of the biofilm structure as a function of shear stress. We demonstrate that arginine treatment leads to earlier detachment of the biofilm, indicating that arginine treatment weakens the biofilm, making it more susceptible to removal by shear stresses. Finally, we demonstrate that the biofilm disrupting affect is specific to arginine, and not a general property of amino acids, as S. gordonii biofilms treated with either glycine or lysine had mechanical properties similar to untreated biofilms. Our results add to the understanding that arginine targets biofilms by multifaceted mechanisms, both metabolic and physical, further promoting the potential of arginine as an active compound in dentifrices to maintain oral health.
Streptococcus gordonii, arginine, biophysical, dental plaque, mechanics, viscoelasticity
Gloag, Erin S.
36de1738-c25d-4eb7-acd3-1ad55d9a7cee
Wozniak, Daniel J.
bfa8e8e5-5929-449b-af6a-ec2d86c47eb5
Wolf, Kevin L
468b62fa-230c-4440-8113-cd9058e5d649
Masters, James G
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Amorin Daep, Carlo
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Stoodley, Paul
08614665-92a9-4466-806e-20c6daeb483f
5 November 2021
Gloag, Erin S.
36de1738-c25d-4eb7-acd3-1ad55d9a7cee
Wozniak, Daniel J.
bfa8e8e5-5929-449b-af6a-ec2d86c47eb5
Wolf, Kevin L
468b62fa-230c-4440-8113-cd9058e5d649
Masters, James G
ff956e0b-67f7-4af6-87fc-b27ae90de9bf
Amorin Daep, Carlo
91743b1f-721a-4e3c-9ead-e900c5870b81
Stoodley, Paul
08614665-92a9-4466-806e-20c6daeb483f
Gloag, Erin S., Wozniak, Daniel J., Wolf, Kevin L, Masters, James G, Amorin Daep, Carlo and Stoodley, Paul
(2021)
Arginine induced Streptococcus gordonii biofilm detachment using a novel 1 rotating-disc rheometry method.
Frontiers in Cellular and Infection Microbiology, 11, [784388].
(doi:10.3389/fcimb.2021.784388).
Abstract
Oral diseases are one of the most common pathologies affecting human health. These diseases are typically associated with dental plaque-biofilms, through either build-up of the biofilm or dysbiosis of the microbial community. Arginine can disrupt dental plaque-biofilms, and maintain plaque homeostasis, making it an ideal therapeutic to combat the development of oral disease. Despite our understanding of the actions of arginine towards dental plaque-biofilms, it is still unclear how or if arginine effects the mechanical integrity of the dental plaque-biofilm. Here we adapted a rotating-disc rheometry assay, a method used to quantify marine biofilm fouling, to study how arginine treatment of Streptococcus gordonii biofilms influences biofilm detachment from surfaces. We demonstrate that the assay is highly sensitive at quantifying the presence of biofilm and the detachment or rearrangement of the biofilm structure as a function of shear stress. We demonstrate that arginine treatment leads to earlier detachment of the biofilm, indicating that arginine treatment weakens the biofilm, making it more susceptible to removal by shear stresses. Finally, we demonstrate that the biofilm disrupting affect is specific to arginine, and not a general property of amino acids, as S. gordonii biofilms treated with either glycine or lysine had mechanical properties similar to untreated biofilms. Our results add to the understanding that arginine targets biofilms by multifaceted mechanisms, both metabolic and physical, further promoting the potential of arginine as an active compound in dentifrices to maintain oral health.
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Gloag_Rotating-disc_Front cell infect microbiol-main
- Accepted Manuscript
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Gloag_Rotating-disc_Front cell infect microbiol-supp
More information
Accepted/In Press date: 21 October 2021
e-pub ahead of print date: 5 November 2021
Published date: 5 November 2021
Additional Information:
Copyright © 2021 Gloag, Wozniak, Wolf, Masters, Daep and Stoodley.
Keywords:
Streptococcus gordonii, arginine, biophysical, dental plaque, mechanics, viscoelasticity
Identifiers
Local EPrints ID: 452538
URI: http://eprints.soton.ac.uk/id/eprint/452538
ISSN: 2235-2988
PURE UUID: ba64c162-29cb-4168-a7da-687f48bccc5e
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Date deposited: 11 Dec 2021 11:26
Last modified: 17 Mar 2024 03:18
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Contributors
Author:
Erin S. Gloag
Author:
Daniel J. Wozniak
Author:
Kevin L Wolf
Author:
James G Masters
Author:
Carlo Amorin Daep
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