posted on 2017-08-21, 00:00authored byAmit Kumar, Debadrita Basu, Priyadarshi Satpati
In translation termination,
the eukaryotic release factor (eRF1)
recognizes mRNA stop codons (UAA, UAG, or UGA) in a ribosomal A site
and triggers release of the nascent polypeptide chain from P-site
tRNA. eRF1 is highly selective for U in the first position and a combination
of purines (except two consecutive guanines, i.e., GG) in the second
and third positions. Eukaryotes decode all three stop codons with
a single release factor eRF1, instead of two (RF1 and RF2), in bacteria.
Furthermore, unlike bacterial RF1/RF2, eRF1 stabilizes the compact
U-turn mRNA configuration in the ribosomal A site by accommodating
four nucleotides instead of three. Despite the available cryo-EM structures
(resolution ∼3.5–3.8 Å), the energetic principle
for eRF1 selectivity toward a stop codon remains a fundamentally unsolved
problem. Using cryo-EM structures of eukaryotic translation termination
complexes as templates, we carried out molecular dynamics free energy
simulations of cognate and near-cognate complexes to quantitatively
address the energetics of stop codon recognition by eRF1. Our results
suggest that eRF1 has a higher discriminatory power against sense
codons, compared to that reported earlier for RF1/RF2. The compact
mRNA formed specific intra-mRNA interactions, which itself contributed
to stop codon specificity. Furthermore, the specificity is enhanced
by the loss of protein–mRNA interactions and, most importantly,
by desolvation of the incorrect codons in the near-cognate complexes.
Our work provides a clue to how eRF1 discriminates between cognate
and near-cognate codons during protein synthesis.