AI Article Synopsis
- Some germs, like the one being studied, have learned to use things around them to get better at causing infections.
- A key part of their strategy is a special signal called Fatty Acids, which can reduce the germ's ability to invade the body's cells.
- When these fatty acids are present, they help the germs grow faster without being too harmful at first, allowing them to set up for a bigger attack later.
Article Abstract
The enteric pathogens have evolved to utilize elements from their surroundings to optimize their infection strategies. A common mechanism to achieve this is to employ intestinal compounds as signals to control the activity of a master regulator of virulence. () is a highly infectious entero-invasive pathogen which requires very few organisms to cause invasion of the colonic mucosa. The invasion program is controlled by the virulence master regulator VirF. Here, we show that the fatty acids commonly found in the colon can be exploited by to repress its virulence, allowing it to energetically finance its proliferation, thus increasing its pathogenicity. Colonic fatty acids such as oleic, palmitoleic and 2-hexadecenoic acid were shown to directly bind to VirF and mediate its prompt degradation. These fatty acids also disrupted the ability of VirF to bind to its target DNA, suppressing the transcription of the downstream virulence genes and significantly reducing the invasion of to colonic epithelial cells. Treatment with colonic fatty acids significantly increased the growth rate of the pathogen only under invasion-inducing conditions, showing that the reduction in the burden of virulence promotes a growth advantage. These results demonstrate the process by which can employ intestinal compounds as signals to increase its numbers at its preferred site of invasion, highlighting the mechanism by which the full spectrum of shigellosis is achieved despite a miniscule infectious dose. This highlights an elegant model of environmental adaption by to maximize the pathogenic benefit.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC10519361 | PMC |
| http://dx.doi.org/10.1080/19490976.2023.2256767 | DOI Listing |
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