“The question we are all asking is what happens when protein synthesis goes wrong?” said Jesse Rinehart, assistant professor of cellular and molecular physiology at Yale’s West Campus and co-senior author of the paper.
Proteins are created from instructions encoded in DNA and assembled in ribosomes within the cells. However, sometimes they are not assembled correctly, and these misfolded proteins tend to aggregate, a process typified by the plaques that form in the brains of Alzheimer’s patients.
The Yale team — led by Rinehart and Dieter Söll, Sterling Professor of Molecular Biophysics and Biochemistry and professor of chemistry — showed that the antibiotic streptomycin can trigger protein aggregations in the bacterium E. coli. Using large-scale proteomics and genetic screens, they analyzed the aggregates and searched for bacterial proteins that make E. coli cells resistant to antibiotics and other threats. The researchers discovered how one of these proteins protecting the bacteria from hydrogen peroxide also suppressed the aggregation of proteins triggered by streptomycin.
“The properties of these protein aggregates are still mysterious, but here we have a glimpse of how they form and how cells escape from these aggregates in bacteria,” Söll said.
The study not only provides insight into how these protein aggregates can form, but illustrates how bacteria defend themselves against toxic threats. Such information could help scientists develop more effective antibiotics, Rinehart said.
Jiqiang Ling was the lead author of the paper. Other Yale authors included Chris Cho, Li-Tao Guo and Hans Aerni.
The work was funded by grants from the National Institute of General Medical Sciences and the National Institute of Diabetes and Digestive and Kidney Diseases
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