Nina Clementi scite author profile

Nucleotide modifications within RNA transcripts are found in every organism in all three domains of life. 6-methyladeonsine (m6A), 5-methylcytosine (m5C) and pseudouridine (Ψ) are highly abundant nucleotide modifications in coding sequences of eukaryal mRNAs, while m5C and m6A modifications have also been discovered in archaeal and bacterial mRNAs. Employing in vitro translation assays, we systematically investigated the influence of nucleotide modifications on translation. We introduced m5C, m6A, Ψ or 2′-O-methylated nucleotides at each of the three positions within a codon of the bacterial ErmCL mRNA and analyzed their influence on translation. Depending on the respective nucleotide modification, as well as its position within a codon, protein synthesis remained either unaffected or was prematurely terminated at the modification site, resulting in reduced amounts of the full-length peptide. In the latter case, toeprint analysis of ribosomal complexes was consistent with stalling of translation at the modified codon. When multiple nucleotide modifications were introduced within one codon, an additive inhibitory effect on translation was observed. We also identified the m5C modification to alter the amino acid identity of the corresponding codon, when positioned at the second codon position. Our results suggest a novel mode of gene regulation by nucleotide modifications in bacterial mRNAs.

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Atomic mutagenesis reveals A2660 of 23S ribosomal RNA as key to EF-G GTPase activation

Clementi

Chirkova

Puffer

et al. 2010

Nat Chem Biol

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Following ribosomal peptide bond formation, the reaction products, peptidyl-tRNA and deacylated tRNA, need to be translocated from the A- and P-sites to the P- and E-sites, respectively. This process is facilitated by the GTPase elongation factor G (EF-G). The mechanism describing how the ribosome activates GTP hydrolysis is poorly understood in molecular terms. By using an 'atomic mutagenesis' approach, which allows the manipulation of specific functional groups on 23S rRNA nucleotides in the context of the entire ribosome, we disclose the adenine exocyclic N6 amino group at A2660 of the sarcin-ricin loop as a key determinant for triggering GTP hydrolysis on EF-G. We show that the purine pi system-expanding characteristics of the exocyclic functional group at the C6 position of A2660 are essential. We propose that stacking interactions of A2660 with EF-G may act as a molecular trigger to induce repositioning of suspected functional amino acids in EF-G that in turn promote GTP hydrolysis.

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Atomic mutagenesis of stop codon nucleotides reveals the chemical prerequisites for release factor-mediated peptide release

Hoernes

Clementi

Juen

et al. 2018

Proc. Natl. Acad. Sci. U.S.A.

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SignificanceTranslation termination is a crucial process during protein synthesis. Class I release factors (RFs) are in charge of recognizing stop codons and consequently hydrolyzing the peptidyl-tRNA at the ribosomal P site. High-resolution crystal- and cryo-EM structures of RFs bound to the ribosome revealed a network of potential interactions that is formed between the mRNA and RFs; however, it remained enigmatic which interactions are critical for accurate stop codon recognition and peptide release. By using chemically modified stop codon nucleotides, the importance and the contribution of single hydrogen bonds to stop codon recognition was investigated. This approach revealed a detailed picture of chemical groups defining a stop codon and contributing to the discrimination against sense codons during prokaryotic and eukaryotic translation termination.

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Nina Clementi

Nucleotide modifications within bacterial messenger RNAs regulate their translation and are able to rewire the genetic code

Atomic mutagenesis reveals A2660 of 23S ribosomal RNA as key to EF-G GTPase activation

Atomic mutagenesis of stop codon nucleotides reveals the chemical prerequisites for release factor-mediated peptide release

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