Bacterial neuraminidase facilitates mucosal infection by participating in biofilm production
Grace Soong, … , Liang Tong, Alice Prince
Grace Soong, … , Liang Tong, Alice Prince
Published August 1, 2006
Citation Information: J Clin Invest. 2006;116(8):2297-2305. https://doi.org/10.1172/JCI27920.
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Research Article Microbiology

Bacterial neuraminidase facilitates mucosal infection by participating in biofilm production

Abstract

Many respiratory pathogens, including Hemophilus influenzae, Streptococcus pneumoniae, and Pseudomonas aeruginosa, express neuraminidases that can cleave α2,3-linked sialic acids from glycoconjugates. As mucosal surfaces are heavily sialylated, neuraminidases have been thought to modify epithelial cells by exposing potential bacterial receptors. However, in contrast to neuraminidase produced by the influenza virus, a role for bacterial neuraminidase in pathogenesis has not yet been clearly established. We constructed a mutant of P. aeruginosa PAO1 by deleting the PA2794 neuraminidase locus (Δ2794) and tested its virulence and immunostimulatory capabilities in a mouse model of infection. Although fully virulent when introduced i.p., the Δ2794 mutant was unable to establish respiratory infection by i.n. inoculation. The inability to colonize the respiratory tract correlated with diminished production of biofilm, as assessed by scanning electron microscopy and in vitro assays. The importance of neuraminidase in biofilm production was further demonstrated by showing that viral neuraminidase inhibitors in clinical use blocked P. aeruginosa biofilm production in vitro as well. The P. aeruginosa neuraminidase has a key role in the initial stages of pulmonary infection by targeting bacterial glycoconjugates and contributing to the formation of biofilm. Inhibiting bacterial neuraminidases could provide a novel mechanism to prevent bacterial pneumonia.

Authors

Grace Soong, Amanda Muir, Marisa I. Gomez, Jonathan Waks, Bharat Reddy, Paul Planet, Pradeep K. Singh, Yukihiro Kanetko, Matthew C. Wolfgang, Yu-Shan Hsiao, Liang Tong, Alice Prince

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Figure 6

Comparison of biofilm production by PAO1 and Δ2794.

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Comparison of biofilm production by PAO1 and Δ2794. (A and B) Biofilm pr...
(A and B) Biofilm production by bacterial strains detected by crystal violet staining. (A) PAO1 and Δ2794 each with either empty control vector (white bars) or cloned nanA (black bars) and (B) PAK, Δ2794 PAK, Δ2794 PAK + neuraminidase locus (Δ2794 + nanA), and Δ2794 PAK plus empty control vector are shown. **P < 0.01, ***P < 0.001, #P < 0.0001 versus PAO1 + vector (A) or PAK (B). (C) Fluorescence microscope images (top row) and profiles (bottom row) of biofilm production in a flow cell. Compared with PAO1, Δ2794 formed less differentiated and flattened layers. The Δ2794 + nanA complemented mutant showed restored, differentiated clumps of cells, while the Δ2794 mutant plus control vector did not. (D) Light microscope images of biofilms produced under more dynamic conditions using a rotating disc reactor that uses removable discs attached to a rotor in a chemostat. The disc rotation produces high-shear forces. High-shear conditions can accentuate deficiencies in attachment and matrix integrity. White, fluffy material is biofilm. The lack of biofilm formation by the mutant could be caused by defective matrix synthesis. (E) Bacteria expressing GFP (106) were incubated with confluent monolayers of 16HBE airway epithelial cells for 5 hours and visualized by confocal microscopy.