Abstract
The Legionella pneumophila TF3/1 mutant of the Corby strain, which possesses a point mutation in the active site of the O-acetyltransferase, synthesized the polysaccharide chain with a reduced degree of substitution with O-acetyl groups. The mutant did not produce a high-molecular-weight lipopolysaccharide (LPS) fraction above 12 kDa. The disturbances in LPS synthesis have an effect on the composition of other macromolecules (lipids and proteins), as indicated by differences in the infrared absorption spectra between the L. pneumophila Corby strain and its TF3/1 mutant. The wild-type strain contained less N+–CH3 and C-N groups as well as more CH3 groups than the mutant. The fatty acid composition showed that the wild type strain synthesized more branched acyl residues (a15:0, i16:0, and a17:0), a less unsaturated acid (16:1), and a straight-chain acid (18:0) than the mutant. The mutant synthesized approximately twice more a long-chain fatty acid (20:0) than the wild type. The main differences in the phospholipids between both strains were found in the classes of phosphatidylcholines and phosphatidylglycerols (PG). Substantial differences in the cell surface topography of these bacteria and their nanomechanical properties were shown by atomic force microscopy (AFM). The wild type strain had no undulated surface and produced numerous vesicles. In the case of the mutant type, the vesicles were not numerous, but there were grooves on the cell surface. The average roughness of the cell surface of the mutant was approximately twofold higher than in the wild-type strain. In turn, the wild-type strain exhibited much better adhesive properties than the mutant. The kinetic study of the interaction between the L. pneumophila strains and Acanthamoeba castellanii monitored by Förster resonance energy transfer revealed a pronounced difference, i.e., almost instantaneous and highly efficient binding of the L. pneumophila Corby strain to the amoeba surface, followed by penetration into the amoeba cells. This process was clearly not as efficient in the case of the mutant. The results point to LPS and, in particular, to the length of the polysaccharide fraction as an important L. pneumophila determinant involved in the process of adhesion to the host cell.
Highlights
Legionella pneumophila is an intracellular pathogen and the main causative agent of Legionnaires’ disease – a severe and often fatal pneumonia
The lipopolysaccharide (LPS) localized in the outer membrane is the predominant molecule on the cell surface of these bacteria that contributes to the cell surface properties in an exceptionally important way
FTIR spectroscopy was used to analyze the components of L. pneumophila cells (Corby strain and TF3/1 strain)
Summary
Legionella pneumophila is an intracellular pathogen and the main causative agent of Legionnaires’ disease – a severe and often fatal pneumonia. One case of human-to-human transmission of L. pneumophila has been reported (Correia et al, 2016), the vast majority of evidence indicates that human infection (sporadic cases or epidemic outbreaks) is most frequently caused through inhalation of bacteria-contaminated water distributed as a water-air aerosol by air-conditioning systems, cooling towers, industrial and medical facilities, and sanitary network devices (van Heijnsbergen et al, 2015). The bacteria infect both mammalian cells (alveolar macrophages) and environmental hosts, such as amoeba. The lipopolysaccharide (LPS) localized in the outer membrane is the predominant molecule on the cell surface of these bacteria that contributes to the cell surface properties in an exceptionally important way
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