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Dozens of potential new antibiotics discovered with free online app

BY Diana Yates

A new web tool speeds the discovery of drugs to kill Gram-negative bacteria, which are responsible for the vast majority of antibiotic-resistant infections and deaths. The tool also offers insights into discrete chemical changes that can convert drugs that kill other bacteria into drugs to fight Gram-negative infections. The team proved the system works by modifying a Gram-positive drug and testing it against three different Gram-negative bacterial culprits in mouse sepsis. The drug was successful against each.

Researchers report their findings in the journal Nature Microbiology.

A University of Illinois team developed a web app that can identify drug compounds that will accumulate in Gram-negative bacteria, overcoming a major hurdle in the development of new drugs to kill these dangerous pathogens. The team includes, from left, graduate student Emily Geddes, pathobiology professor Gee Lau, chemistry professor Paul Hergenrother, postdoctoral researcher Hyang Yeon Lee, and postdoctoral researcher Erica Parker.
A University of Illinois team developed a web app that can identify drug compounds that will accumulate in Gram-negative bacteria, overcoming a major hurdle in the development of new drugs to kill these dangerous pathogens. The team includes, from left, graduate student Emily Geddes, pathobiology professor Gee Lau, chemistry professor Paul Hergenrother, postdoctoral researcher Hyang Yeon Lee, and postdoctoral researcher Erica Parker.  

“It’s really hard to find new antibiotics for Gram-negative pathogens, because these bacteria have an extra membrane, an outer membrane, that’s very good at keeping antibiotics out,” said University of Illinois chemistry professor Paul Hergenrother (ACPP leader/MMG), who led the research.

The challenge is so profound that no new classes of drugs to fight Gram-negative bacteria have been approved by the Food and Drug Administration in 50 years, Hergenrother said.

“A few years ago, we discovered the molecular features that allowed an antibiotic compound to surpass this barrier,” he said. “Now, we’ve developed a tool to help others do this as well.”

The new app, called eNTRyway, can quickly evaluate potential drug compounds to determine if they have the molecular characteristics that will enable them to cross the membrane and accumulate inside Gram-negative bacteria.

Developed by graduate student Bryon Drown, the app also can point to ways of modifying existing drugs – for example, those known to work against Gram-positive bacteria – to convert them into potent killers of Gram-negative pathogens.

As a demonstration of this latter capability, postdoctoral researcher and study co-lead author Erica Parker used the tool to identify a drug already in use against Gram-positive infections that – with a basic chemical modification – could potentially be converted to fight Gram-negative bacteria. By adding a positively charged chemical group known as an amine to the drug, Parker created a compound that, further tests revealed, accumulated in Gram-negative bacteria and was effective against several types of Gram-negative infections in mice.

The process of identifying the compound and modifying it took only a few weeks, Hergenrother said.

“Keep in mind that before this, over 100 derivatives of this same compound had been made. We found them in patents and papers,” he said. “And none of these other derivatives had notable Gram-negative activity.”

Hergenrother and his colleagues have so far identified more than 60 antibiotics that are effective only against Gram-positive bacteria but can be converted into drugs to fight Gram-negative infections. These compounds kill bacteria in a variety of different ways. The newly created drug, known as Debio-1452-NH3, interferes with fatty acid synthesis in bacterial – but not mammalian – cells. 

Hergenrother said the new tool will speed the process of drug discovery to fight the burgeoning problem of antibiotic-resistant infections.

“We can use this tool to rapidly identify compounds that accumulate in Gram-negative bacteria,” he said.

The National Institutes of Health supported this research.

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