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A newly defined 'stress survival islet' assures survival of some listeria strains despite high hygiene standards in food production. Courtesy of Institute of Milk Hygiene
Listeria monocytogenes is a foodborne pathogen that colonizes and reproduces on diverse food products including cheese or meat. Without proper food hygiene, it represents a health risk. The hygiene standards in food production chains, therefore, are quite high. But Listeria is known for its ability to survive in environmental niches in which other microorganisms cannot.
The key to the bacteria's survival is its adaptability and persistence in stress situations. Certain genetic mechanisms allow L. monocytogenes to react to and block the effects of cleaning solutions and disinfectants. Researchers from the Institute of Milk Hygiene were able to decipher this function for two of the food pathogen's genes. They showed that these genes form a functional unit that ensures the bacteria's survival despite the hygiene standards in the food production industry.
Hypervariable, i.e. easily changeable, regions of the genome contain genetic inserts that help Listeria survive. "These inserts include a unit of gene sequences, the stress survival islet 1 (SSI-1), a 'genomic island' that helps the microorganisms to survive certain stress situations," explains first author Eva Harter. "Depending on the specific bacterial strain, this region accommodates one of three different gene sequences whose function, with the exception of SSI-1, had so far not been known."
The genes in the stress survival islet 1 confer the bacteria a high tolerance toward acidic, bile, salt and gastric stresses and were characterized years ago. This does not explain how the bacteria can survive the hygiene standards in the food processing industry, however, which involves different, namely alkaline and oxidative, stress situations for Listeria. The researchers therefore concentrated on two neighbouring gene sequences within the same hypervariable region and were able to identify these as the genomic islet that acts as a lifesaver for certain Listeria monocytogenes strains in these situations.
The expression of the two genes and of the proteins which they code is increased during alkaline and oxidative stress. They must therefore have a different function than the genes belonging to the SSI-1. "We were able to assign a function to the two genes. The first gene is a transcriptional regulator, which in certain situations regulates the frequency and activity of the second protein. The second is a protease, an enzyme that breaks down other proteins. Proteases help bacteria break down unfunctional proteins that are created during stress situations," says Harter.
"If the regulator is not active, then there is no protease. Without the protease, Listeria monocytogenes has a harder time compensating oxidative stress. The two genes therefore make up a functional unit, specifically the stress survival islet SSI-2," says study director Kathrin Rychli. This islet is predominantly found in L. monocytogenes strains that are specialised for food and food processing environments.
"We were able to identify a specific genome type in which the SSI-2 sequence is always present," explains Rychli. "This sequence type, ST121, is found almost exclusively in food and the food processing environment and hardly ever in clinical isolates. In strains forming part of the ST121 group, SSI-2 is highly conserved i.e. completely identical." SSI-2 thus appears to be niche-specific. Most Listeria strains found in clinical isolates do not have SSI-2." Through the discovery of the new stress survival island, the researchers, with project funding provided by the Austrian Science Fund (FWF), were able to describe an important survival strategy of foodborne Listeria. "Knowing the genetic mechanism, allows you to think about new strategies for food safety," says Rychli.
The article, "Stress Survival Islet 2, Predominantly Present in Listeria monocytogenes Strains of Sequence Type 121, is Involved in the Alkaline and Oxidative Stress Responses" by Eva Harter, Eva Maria Wagner, Andreas Zaiser, Sabrina Halecker, Martin Wagner and Kathrin Rychli was published in Applied and Environmental Microbiology.
Source: University of Veterinary Medicine, Vienna