Nicotine-chomping bacteria may hold key to anti-smoking therapy
News Aug 07, 2015
A new study from scientists at The Scripps Research Institute (TSRI) explores a bacterial enzyme that might be used as a drug candidate to help people quit smoking. The research shows that this enzyme can be recreated in lab settings and possesses a number of promising characteristics for drug development.
“Our research is in the early phase of drug development process, but the study tells us the enzyme has the right properties to eventually become a successful therapeutic,” said Kim Janda, the Ely R. Callaway Jr. Professor of Chemistry and member of the Skaggs Institute for Chemical Biology at TSRI.
The new research, published online ahead of print in the Journal of the American Chemical Society, offers a possible alternative to current smoking cessation aids, which are shown to fail in at least 80 to 90 percent of smokers. The idea behind an enzyme therapy would be to seek out and destroy nicotine before it reaches the brain—depriving a person of the “reward” of nicotine that can trigger relapse into smoking.
For more than 30 years, Janda and his colleagues have struggled to create such an enzyme in the lab, but they recently ran across a potential enzyme found in nature—NicA2 from the bacteria known as Pseudomonas putida. It turns out this bacterium—originally isolated from soil in a tobacco field—consumes nicotine as its sole source of carbon and nitrogen.
“The bacterium is like a little Pac-Man,” said Janda. “It goes along and eats nicotine.”
In the new study, the TSRI researchers characterized the bacterial enzyme responsible for nicotine degradation and tested its potential usefulness as a therapeutic.
The researchers first combined serum (a component of blood) from mice with a dose of nicotine equivalent to one cigarette. When they added the enzyme, the nicotine’s half-life dropped from two to three hours to just 9 to 15 minutes. Janda said a higher dose of the enzyme—with a few chemical modifications—could reduce the half-life of nicotine even further and keep it from ever reaching the brain.
Next, the researchers subjected the enzyme to a barrage of tests to determine its practicality as a drug candidate. “It was a long shot,” said Janda. “If it didn’t have the right metrics, it would be a bust.”
The results were encouraging. The enzyme stayed stable in the lab for more than three weeks at 98 degrees Fahrenheit—which Janda said was “pretty remarkable.” Importantly, the researchers detected no toxic metabolites produced when the enzyme degraded nicotine.
“The enzyme is also relatively stable in serum, which is important for a therapeutic candidate,” said Song Xue, a TSRI graduate student and first author of the new study.
Janda said the next step is to alter the enzyme’s bacterial makeup, which will help mitigate potential immune liabilities and maximize its therapeutic potential.
“Hopefully we can improve its serum stability with our future studies so that a single injection may last up to a month,” added Xue.
Note: Material may have been edited for length and content. For further information, please contact the cited source.
Song Xue, Joel E Schlosburg, Kim D Janda A New Strategy for Smoking Cessation: Characterization of a Bacterial Enzyme for the Degradation of Nicotine. Journal of the American Chemical Society, Published Online August 3 2015. doi: 10.1021/jacs.5b06605
All in a Droplet: Atomic Resolution of ALS Protein ResolvedNews
Researchers have described atom-by-atom changes in a family of proteins linked to amyotrophic lateral sclerosis (ALS), a group of brain disorders known as frontotemporal dementia and degenerative diseases of muscle and bone.READ MORE
Pupil Size Couples to Cortical States to Protect Deep Sleep StabilityNews
Researchers have found that mice pupil size fluctuates during sleep. They also show that pupil size is a reliable indicator of sleep states.READ MORE
A Place to Think: Persistent neuronal activity in human prefrontal cortex links perception and actionNews
Neuroscientists have tracked the progress of a thought through the brain, showing clearly how the prefrontal cortex at the front of the brain coordinates activity to help us act in response to a perception.READ MORE