Research Sheds Light on How Silver Ions Kill Bacteria
FAYETTEVILLE, Ark. – The antimicrobial properties of silver have been known for centuries. While it is still a mystery as to exactly how silver kills bacteria, University of Arkansas researchers have taken a step toward better understanding the process by looking at dynamics of proteins in live bacteria at the molecular level.
Traditionally, the antimicrobial effects of silver have been measured through bioassays, which compare the effect of a substance on a test organism against a standard, untreated preparation. While these methods are effective, they typically produce only snapshots in time, said Yong Wang, assistant professor of physics and an author of the study, published in the journal Applied and Environmental Microbiology.
Instead, Wang and his colleagues used an advanced imaging technique, called “single-particle-tracking photoactivated localization microscopy,” to watch and track a particular protein found in E. coli bacteria over time.
Researchers were surprised to find that silver ions actually sped up the dynamics of the protein, opposite of what they thought would happen.
“It is known that silver ions can suppress and kill bacteria,” Wang said. “We thus expected that everything slowed down in the bacteria when treated with silver. But, surprisingly, we found that the dynamics of this protein became faster.”
The researchers observed that silver ions were causing paired strands of DNA in the bacteria to separate, and the binding between the protein and the DNA to weaken.
“Then the faster dynamics of the proteins caused by silver can be understood,” Wang said. “When the protein is bound to the DNA, it moves slowly together with the DNA, which is a huge molecule in the bacteria. In contrast, when treated with silver, the proteins fall off from the DNA, moving by themselves and thus faster.”
The observation of DNA separation caused by silver ions came from earlier work that Wang and colleagues had done with bent DNA. Their approach, now patent pending, was to put strain on DNA strands by bending them, thus making them more susceptible to interactions with other chemicals, including silver ions.
The National Science Foundation-funded study validated the idea of investigating the dynamics of single proteins in live bacteria. An approach that could help researchers understand the real-time responses of bacteria to silver nanoparticles, which have been proposed for fighting against so-called “superbugs” that are resistant to commonly prescribed antibiotics.
“What we want to do eventually is to use the new knowledge generated from this project to make better antibiotics based on silver nanoparticles,” Wang said.
About the University of Arkansas: The University of Arkansas provides an internationally competitive education for undergraduate and graduate students in more than 200 academic programs. The university contributes new knowledge, economic development, basic and applied research, and creative activity while also providing service to academic and professional disciplines. The Carnegie Foundation classifies the University of Arkansas among fewer than 2.7 percent of universities in America that have the highest level of research activity. U.S. News & World Report ranks the University of Arkansas among its top American public research universities. Founded in 1871, the University of Arkansas comprises 10 colleges and schools and maintains a low student-to-faculty ratio that promotes personal attention and close mentoring.
Contacts
Bob Whitby, science and researcher writer
University Relations
479-575-4737,
whitby@uark.edu
Yong Wang, assistant professor, Department of Physics
J. William Fulbright College of Arts and Sciences
479-575-4313,
yongwang@uark.edu