Genome-Based Analysis of Virulence Factors and Biofilm Formation in Novel Strains Isolated from Household Appliances

Overview

Journal Microorganisms

Specialty Microbiology

Date 2022 Dec 23

PMID 36557761

Authors

Annika Kiel

Ines Creutz

Christian Ruckert

Bernhard Peter Kaltschmidt

Andreas Hutten

Karsten Niehaus

Tobias Busche

Barbara Kaltschmidt

Christian Kaltschmidt

Affiliations

Soon will be listed here.

Abstract

In household washing machines, opportunistic pathogens such as are present, which represent the household as a possible reservoir for clinical pathogens. Here, four novel strains, isolated from different sites of household appliances, were investigated regarding their biofilm formation. Only two isolates showed strong surface-adhered biofilm formation. In consequence of these phenotypic differences, we performed whole genome sequencing using Oxford Nanopore Technology together with Illumina MiSeq. Whole genome data were screened for the prevalence of 285 virulence- and biofilm-associated genes as well as for prophages. Linking biofilm phenotypes and parallelly appearing gene compositions, we assume a relevancy of the quorum sensing system and the phage-encoded bacteriophage control infection gene , which was found on integrated phi297 DNA in all biofilm-forming isolates. Additionally, only the isolates revealing strong biofilm formation harbored the ϕCTX-like prophage Dobby, implicating a role of this prophage on biofilm formation. Investigations on clinically relevant pathogens within household appliances emphasize their adaptability to harsh environments, with high concentrations of detergents, providing greater insights into pathogenicity and underlying mechanisms. This in turn opens the possibility to map and characterize potentially relevant strains even before they appear as pathogens in society.

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