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Research & Development > Publication of research “Erythromycin leads to differential protein expression through differences in electrostatic and dispersion interactions with nascent proteins”

Publication of research “Erythromycin leads to differential protein expression through differences in electrostatic and dispersion interactions with nascent proteins”

On April 24th, 2018, the first author, Mr. Nguyen Hoang Linh and second author, Mr. Pham Dang Lan, researchers of Laboratory of Life Sciences at Institute for Computational Science and Technology, Ho Chi Minh City and his adviser, Professor Mai Xuan Ly, have just published a research named “Erythromycin leads to differential protein expression through differences in electrostatic and dispersion interactions with nascent proteins” on Journal of Scientific Reports.
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The antibiotic activity of erythromycin, which reversibly binds to a site within the bacterial ribosome exit tunnel, against many gram positive microorganisms indicates that it effectively inhibits the production of proteins. Similar to other macrolides, the activity of erythromycin is far from universal, as some peptides can bypass the macrolide-obstructed exit tunnel and become partially or fully synthesized. It is unclear why, at the molecular level, some proteins can be synthesized while others cannot. Here, we use steered molecular dynamics simulations to examine how erythromycin inhibits synthesis of the peptide ErmCL but not the peptide H-NS. By pulling these peptides through the exit
tunnel of the E.coli ribosome with and without erythromycin present, we find that erythromycin directly interacts with both nascent peptides, but the force required for ErmCL to bypass erythromycin is greater than that of H-NS. The largest forces arise three to six residues from their N-terminus as they start to bypass Erythromycin. Decomposing the interaction energies between erythromycin and the peptides at this point, we find that there are stronger electrostatic and dispersion interactions with the more C-terminal residues of ErmCL than with H-NS. These results suggest that erythromycin slows or stalls synthesis of ErmCL compared to H-NS due to stronger interactions with particular residue positions along the nascent protein.
 
Figure 1: An illustration of a starting simulation structure. Te ribosome (transparent cartoon), ERY (red), and nascent chain (cyan) are shown. Te black arrow indicates the pulling direction applied to the N-terminal residue of the nascent chain in the SMD simulations. Te arrow also lies along the long axis of the ribosome exit tunnel. “Exit” denotes the exit side of the tunnel.
 
Read full article here.
Author: Hoang Linh
Editor: Kim Loan

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