AP sites in various mRNA positions cross-link to the protein uS3 in the translating mammalian ribosome.

Abasic (AP) sites in mRNAs are lesions whose accumulation in cells is linked to various neurodegenerative diseases arising from the appearance of truncated peptides due to the premature cessation of translation of these mRNAs. It is believed that the translation of AP site-containing mRNAs is stopped when the damaged codon arrives to the A site, where it is not decoded. We propose an alternative translation arrest mechanism mediated by the 40S ribosomal subunit protein uS3. Recently, it has been shown that in human 80S ribosomal complexes assembled without translation factors, uS3 cross-links to the AP site at the 3'-terminus of the mRNA, whose undamaged part is bound at the 40S subunit channel, via its peptide 55-64 exposed near the mRNA entry pore. In this study, we examined whether such cross-linking occurs during the translation of mRNA with the AP site. To this end, we used a set of synthetic mRNAs bearing the AP site inserted in the desired location in their sequences. An analysis of 80S ribosomal complexes formed with these mRNAs in a mammalian cell-free protein-synthesizing system demonstrates that AP sites do indeed cross-link to uS3 in the course of the translation. We also show that the cross-linking occurs as soon as the AP site arrives to a common favorable position relative to uS3, which is independent on its location in the mRNA. Our findings suggest that the mechanism of stopping translation of damaged mRNAs involving uS3, along with the one mentioned above, could underlie ribosome-associated mRNA quality control.

Exploring the interactions of short RNAs with the human 40S ribosomal subunit near the mRNA entry site by EPR spectroscopy.

The features of previously unexplored labile complexes of human 40S ribosomal subunits with RNAs, whose formation is manifested in the cross-linking of aldehyde derivatives of RNAs to the ribosomal protein uS3 through its peptide 55-64 located outside the mRNA channel, were studied by EPR spectroscopy methods. Analysis of subatomic 40S subunit models showed that a likely site for labile RNA binding is a cluster of positively charged amino acid residues between the mRNA entry site and uS3 peptide 55-64. This is consistent with our finding that the 3'-terminal mRNA fragment hanging outside the 40S subunit prevents the cross-linking of an RNA derivative to this peptide. To detect labile complexes of 40S subunits with RNA by DEER/PELDOR spectroscopy, an undecaribonucleotide derivative with nitroxide spin labels at terminal nucleotides was utilized. We demonstrated that the 40S subunit channel occupancy with mRNA does not affect the RNA derivative binding and that uS3 peptide 55-64 is not involved in binding interactions. Replacing the RNA derivative with a DNA one revealed the importance of ribose 2'-OH groups for the complex formation. Using the single-label RNA derivatives, the distance between the mRNA entry site and the loosely bound RNA site on the 40S subunit was estimated.

The human ribosome can interact with the abasic site in mRNA via a specific peptide of the uS3 protein located near the mRNA entry channel.

The small subunit ribosomal protein uS3 is a critically important player in the ribosome-mRNA interactions during translation and has numerous functions not directly related to protein synthesis in eukaryotes. A peculiar feature of the human uS3 protein is the ability of its fragment 55-64 exposed on the 40S subunit surface near the mRNA entry channel to form cross-links with 3'-terminal dialdehyde derivatives of various unstructured RNAs and with abasic sites in single-stranded DNAs. Here we showed that the ability of the above uS3 fragment to cross-link to abasic sites in DNAs is inherent only in mature cytoplasmic 40S subunits, but not nuclear pre-40S particles, which implies that it may be relevant to the ribosome-mRNA interplay. To clarify this issue, we investigated interactions of human ribosomes with synthetic mRNA analogues bearing an abasic site protected by a photocleavable group at the 3'-termini. We found that these mRNA analogues can form specific complexes with 80S ribosomes and 40S subunits, where the undamaged upstream part of the analogue is fixed in the mRNA binding channel by interaction with the P-site tRNA, and the downstream part located outside the ribosome is cross-linked to the uS3 fragment 55-64. The yield of cross-links of the mRNA analogues was rather high when their undamaged parts were bound to the mRNA channel prior to deprotection of the abasic site enabling its covalent attachment to the 40S subunit via the uS3 protein, but not vice versa. Based on our findings, one can assume that abasic sites, which can occur in mRNAs due to oxidative stress and ageing, are able to interact directly with the uS3 fragment exposed on the 40S subunit surface near the mRNA entry channel during translation. Consequently, the 40S subunit can be considered as a potential mRNA quality controller.