Public release date: 19-Mar-2012 [ | E-mail | Share ]
Contact: Diana Yates diya@illinois.edu 217-333-5802 University of Illinois at Urbana-Champaign
CHAMPAIGN, lll. A new study describes how bacteria use a previously unknown means to defeat an antibiotic. The researchers found that the bacteria have modified a common "housekeeping" enzyme in a way that enables the enzyme to recognize and disarm the antibiotic.
The study appears in the Proceedings of the National Academy of Sciences.
Bacteria often engage in chemical warfare with one another, and many antibiotics used in medicine are modeled on the weapons they produce. But microbes also must protect themselves from their own toxins. The defenses they employ for protection can be acquired by other species, leading to antibiotic resistance.
The researchers focused on an enzyme, known as MccF, that they knew could disable a potent "Trojan horse" antibiotic that sneaks into cells disguised as a tasty protein meal. The bacterial antibiotic, called microcin C7 (McC7) is similar to a class of drugs used to treat bacterial infections of the skin.
"How Trojan horse antibiotics work is that the antibiotic portion is coupled to something that's fairly innocuous in this case it's a peptide," said University of Illinois biochemistry professor Satish Nair, who led the study. "So susceptible bacteria see this peptide, think of it as food and internalize it."
The meal comes at a price, however: Once the bacterial enzymes chew up the amino acid disguise, the liberated antibiotic is free to attack a key component of protein synthesis in the bacterium, Nair said.
"That is why the organisms that make this thing have to protect themselves," he said.
In previous studies, researchers had found the genes that protect some bacteria from this class of antibiotic toxins, but they didn't know how they worked. These genes code for peptidases, which normally chew up proteins (polypeptides) and lack the ability to recognize anything else.
Originally posted here:
Team discovers how bacteria resist a 'Trojan horse' antibiotic
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