麻豆淫院

Pathogens are becoming more and more resistant to antibiotics. With the goal of developing new therapeutic approaches to treat bacterial infections more effectively in the future, researchers at the Karlsruhe Institute of Technology (KIT) and the Max Planck Institute in Marburg investigated the plague-related bacterium Yersinia enterocolitica.

It employs a special infection mechanism with which it actively switches between reproductive and infectious phases. The results of the study provide new insights into the dynamics of bacterial infections and have been published in .

Bacterial pathogens such as Salmonella, Shigella or Yersinia use the type III secretion system (T3SS), a syringe-like protein structure, for targeted injection of disease-causing proteins into human cells. This injection system is crucial to bacterial ability to trigger infections, enabling Yersinia bacteria to suppress the human immune response. However, activating the T3SS comes at a price: As soon as it is active, the bacteria stop growing and can no longer reproduce and spread.

"Until now, it was unclear how Yersinia enterocolitica resolved this conflict between virulence and reproduction," said Dr. Andreas Diepold from KIT's Institute for Applied Biosciences.

Molecular switch for virulence

A research team headed by Diepold has now shown that Y. enterocolitica has a sort of density sensor. When many bacteria are present in one place, a regulatory mechanism switches the T3SS off. The secretion system remains active only in the cells at the outer edge of a colony.

"That enables the bacteria that aren't exposed to the immune system to continue reproducing," Diepold said. "This is a highly specific and reversible mechanism. As soon as the bacteria spread again, the system can be reactivated."

Key to this switching mechanism is the protein VirF, which controls T3SS formation. Higher cell density results in an increased concentration of small RNA molecules that then downregulate the protein complex, significantly reducing the activity of the entire secretion system.

Evading the immune system

The researchers also found out that not only the T3SS is deactivated but also the protein YadA, which is responsible for adhesion to cells in host organisms. As a result, the bacteria become more mobile and less apparent to the immune system. This evasion mechanism could help the bacteria reach new tissues or form new colonies in the human body.

"Our results show that Yersinia doesn't just passively react to environmental conditions. Instead, it actively switches between a virulent and a reproductive phase," Diepold said.

"This enables it to withstand the immune response and then reproduce efficiently afterward." The T3SS can be reassembled within 30 to 60 minutes.

The study provides important information not only about how bacterial infections start but also about how they proceed. "Many therapeutic approaches focus on how infections start, but we also need to know how germs behave in the body later on," Diepold said, noting that specific T3SS deactivation at high cell density is an underappreciated but potentially useful therapeutic mechanism.

In the long run, such insights could improve treatment of bacterial infections, for instance by the targeted disruption of switching mechanisms or by influencing how bacteria sense cell density.

"The more we know about these systems, the better we can counteract them," concludes Diepold.