Malte Warias scite author profile

In each round of ribosomal translation, the translational GTPase elongation factor Tu (EF-Tu) delivers a transfer RNA (tRNA) to the ribosome. After successful decoding, EF-Tu hydrolyzes GTP, which triggers a conformational change that ultimately results in the release of the tRNA from EF-Tu. To identify the primary steps of these conformational changes and how they are prevented by the antibiotic kirromycin, we employed all-atom explicit-solvent molecular dynamics simulations of the full ribosome-EF-Tu complex. Our results suggest that after GTP hydrolysis and P i release, the loss of interactions between the nucleotide and the switch 1 loop of EF-Tu allows domain D1 of EF-Tu to rotate relative to domains D2 and D3 and leads to an increased flexibility of the switch 1 loop. This rotation induces a closing of the D1-D3 interface and an opening of the D1-D2 interface. We propose that the opening of the D1-D2 interface, which binds the CCA tail of the tRNA, weakens the crucial EF-Tu-tRNA interactions, which lowers tRNA binding affinity, representing the first step of tRNA release. Kirromycin binds within the D1-D3 interface, sterically blocking its closure, but does not prevent hydrolysis. The resulting increased flexibility of switch 1 explains why it is not resolved in kirromycin-bound structures.

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tRNA dissociation from EF-Tu after GTP hydrolysis and P_irelease: primary steps and antibiotic inhibition

Warias¹,

Grubmüller²,

Bock³

2019

Preprint

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In each round of ribosomal translation, the translational GTPase EF-Tu delivers a tRNA to the ribosome. After successful decoding, EF-Tu hydrolyses GTP, which triggers a conformational change that ultimately results in the release of the tRNA from EF-Tu. To identify the primary steps of these conformational changes and how they are prevented by the antibiotic kirromycin, we employed all-atom explicit-solvent Molecular Dynamics simulations of the full ribosome-EF-Tu complex. Our results suggest that after GTP hydrolysis and Pi release, the loss of interactions between the nucleotide and the switch 1 loop of EF-Tu allows domain D1 of EF-Tu to rotate relative to domains D2 and D3 and leads to an increased flexibility of the switch 1 loop. This rotation induces a closing of the D1-D3 interface and an opening of the D1-D2 interface. We propose that the opening of the D1-D2 interface, which binds the CCA-tail of the tRNA, weakens the crucial EF-Tu-tRNA interactions which lowers tRNA binding affinity, representing the first step of tRNA release. Kirromycin binds within the D1-D3 interface, sterically blocking its closure, but does not prevent hydrolysis. The resulting increased flexibility of switch 1 explains why it is not resolved in kirromycin-bound structures.

show abstract

tRNA Dissociation from EF-Tu After GTP Hydrolisis - Primary Steps and Antibiotic Inhibition

Warias

Grubmueller

Bock

2020

Biophysical Journal

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Malte Warias

tRNA Dissociation from EF-Tu after GTP Hydrolysis: Primary Steps and Antibiotic Inhibition

tRNA dissociation from EF-Tu after GTP hydrolysis and P_irelease: primary steps and antibiotic inhibition

tRNA Dissociation from EF-Tu After GTP Hydrolisis - Primary Steps and Antibiotic Inhibition

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Malte Warias

tRNA Dissociation from EF-Tu after GTP Hydrolysis: Primary Steps and Antibiotic Inhibition

tRNA dissociation from EF-Tu after GTP hydrolysis and Pirelease: primary steps and antibiotic inhibition

tRNA Dissociation from EF-Tu After GTP Hydrolisis - Primary Steps and Antibiotic Inhibition

Contact Info

Product

Resources

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tRNA dissociation from EF-Tu after GTP hydrolysis and P_irelease: primary steps and antibiotic inhibition