Project description:Oxazolidinone and pleuromutilin antibiotics are currently used in the treatment of staphylococcal infections. Although both antibiotics inhibit protein synthesis and have overlapping binding regions on 23S rRNA, the potential for cross-resistance between the two classes through target site mutations has not been thoroughly examined. Mutants of Staphylococcus aureus resistant to linezolid were selected and found to exhibit cross-resistance to tiamulin, a member of the pleuromutilin class of antibiotics. However, resistance was unidirectional because mutants of S. aureus selected for resistance to tiamulin did not exhibit cross-resistance to linezolid. This contrasts with the recently described PhLOPS(A) phenotype, which confers resistance to both oxazolidinones and pleuromutilins. The genotypes responsible for the phenotypes we observed were examined. Selection with tiamulin resulted in recovery of mutants with changes in the single-copy rplC gene (Gly155Arg, Ser158Leu, or Arg149Ser), whereas selection with linezolid led to recovery of mutants with changes (G2576U in 23S rRNA) in all five copies of the multicopy operon rrn. In contrast, cross-resistance to linezolid was exhibited by tiamulin-resistant mutants generated in a single-copy rrn knockout strains of Escherichia coli, illustrating that the copy number of 23S rRNA is the limiting factor in the selection of 23S rRNA tiamulin-resistant mutants. The interactions of linezolid and tiamulin with the ribosome were modeled to seek explanations for resistance to both classes in the 23S rRNA mutants and the lack of cross-resistance between tiamulin and linezolid following mutation in rplC.

Project description:The ribosome is an ancient macromolecular machine responsible for the synthesis of all proteins in all living organisms. Here we demonstrate that the ribosomal peptidyl transferase center (PTC) is supported by a framework of magnesium microclusters (Mg(2+)-muc's). Common features of Mg(2+)-muc's include two paired Mg(2+) ions that are chelated by a common bridging phosphate group in the form Mg((a))(2+)-(O1P-P-O2P)-Mg((b))(2+). This bridging phosphate is part of a 10-membered chelation ring in the form Mg((a))(2+)-(OP-P-O5'-C5'-C4'-C3'-O3'-P-OP)-Mg((a))(2+). The two phosphate groups of this 10-membered ring are contributed by adjacent residues along the RNA backbone. Both Mg(2+) ions are octahedrally coordinated, but are substantially dehydrated by interactions with additional RNA phosphate groups. The Mg(2+)-muc's in the LSU (large subunit) appear to be highly conserved over evolution, since they are unchanged in bacteria (Thermus thermophilus, PDB entry 2J01) and archaea (Haloarcula marismortui, PDB entry 1JJ2). The 2D elements of the 23S rRNA that are linked by Mg(2+)-muc's are conserved between the rRNAs of bacteria, archaea and eukarya and in mitochondrial rRNA, and in a proposed minimal 23S-rRNA. We observe Mg(2+)-muc's in other rRNAs including the bacterial 16S rRNA, and the P4-P6 domain of the tetrahymena Group I intron ribozyme. It appears that Mg(2+)-muc's are a primeval motif, with pivotal roles in RNA folding, function and evolution.

Project description:Phylogenetic reconstruction of ribosomal history suggests that the ribonucleoprotein complex originated in structures supporting RNA decoding and ribosomal mechanics. A recent study of accretion of ancestral expansion segments of rRNA, however, contends that the large subunit of the ribosome originated in its peptidyl transferase center (PTC). Here I re-analyze the rRNA insertion data that supports this claim. Analysis of a crucial three-way junction connecting the long-helical coaxial branch that supports the PTC to the L1 stalk and its translocation functions reveals an incorrect branch-to-trunk insertion assignment that is in conflict with the PTC-centered accretion model. Instead, the insertion supports the ancestral origin of translocation. Similarly, an insertion linking a terminal coaxial trunk that holds the L7-12 stalk and its GTPase center to a seven-way junction of the molecule again questions the early origin of the PTC. Unwarranted assumptions, dismissals of conflicting data, structural insertion ambiguities, and lack of phylogenetic information compromise the construction of an unequivocal insertion-based model of macromolecular accretion. Results prompt integration of phylogenetic and structure-based models to address RNA junction growth and evolutionary constraints acting on ribosomal structure.

Project description:Tiamulin is a pleuromutilin antibiotic that is used in veterinary medicine. The recently published crystal structure of a tiamulin-50S ribosomal subunit complex provides detailed information about how this drug targets the peptidyl transferase center of the ribosome. To promote rational design of pleuromutilin-based drugs, the binding of the antibiotic pleuromutilin and three semisynthetic derivatives with different side chain extensions has been investigated using chemical footprinting. The nucleotides A2058, A2059, G2505, and U2506 are affected in all of the footprints, suggesting that the drugs are similarly anchored in the binding pocket by the common tricyclic mutilin core. However, varying effects are observed at U2584 and U2585, indicating that the side chain extensions adopt distinct conformations within the cavity and thereby affect the rRNA conformation differently. An Escherichia coli L3 mutant strain is resistant to tiamulin and pleuromutilin, but not valnemulin, implying that valnemulin is better able to withstand an altered rRNA binding surface around the mutilin core. This is likely due to additional interactions made between the valnemulin side chain extension and the rRNA binding site. The data suggest that pleuromutilin drugs with enhanced antimicrobial activity may be obtained by maximizing the number of interactions between the side chain moiety and the peptidyl transferase cavity.

Project description:In this work, the three-dimensional (3D) structure of the ancestral Peptidyl Transferase Center (PTC) built by concatamers of ancestral sequences of tRNAs was reconstructed, and its possible interactions with tRNAs molecules were analyzed. The 3D structure of the ancestral PTC was also compared with the current PTC of T. thermophilus. Docking experiments between the ancestral PTC and tRNAs suggest that in the origin of the translation system, the PTC functioned as an adhesion center for tRNA molecules. The approximation of tRNAs charged with amino acids to the PTC permitted peptide synthesis without the need of a genetic code.

Project description:We report the context-specific activity of two peptidyl transferase targeting antibiotics, chloramphenicol and linezolid. By generating ribosome profiling data in the presence or absence of either chloramphenicol or linezolid we mapped the relative change of ribosome density induced by these antibiotics. We find that both inhibitors preferentially arrest ribosomes that carry either an alanine, serine, or threonine in the penultimate (-1) position of the nascent peptide chain. Additionally ribosomes that carry a glycine in either the P site (0) or A-site (+1) counteract the inhibitory activity of both inhibitors. The context-specific action of chloramphenicol illuminates the operation of the mechanism of inducible resistance that relies on programmed drug-induced translation arrest. In addition, our findings expose the functional interplay between the nascent chain and the peptidyl transferase center.

Project description:During protein synthesis, the ribosome catalyzes peptide-bond formation. Biochemical and structural studies revealed that conserved nucleotides in the peptidyl-transferase center (PTC) and its proximity may play a key role in peptide-bond formation; the exact mechanism involved remains unclear. To more precisely define the functional importance of the highly conserved residues, we used a systematic genetic method, which we named SSER (systematic selection of functional sequences by enforced replacement), that allowed us to identify essential nucleotides for ribosomal function from randomized rRNA libraries in Escherichia coli cells. These libraries were constructed by complete randomization of the critical regions in and around the PTC. The selected variants contained natural rRNA sequences from other organisms and organelles as well as unnatural functional sequences; hence providing insights into the functional roles played by these essential bases and suggesting how the universal catalytic mechanism of peptide-bond formation could evolve in all living organisms. Our results highlight essential bases and interactions, which are shaping the PTC architecture and guiding the motions of the tRNA terminus from the A to the P site, found to be crucial not only for the formation of the peptide bond but also for nascent chain elongation.

Project description:The fungal arginine attenuator peptide (AAP) is encoded by a regulatory upstream open reading frame (uORF). The AAP acts as a nascent peptide within the ribosome tunnel to stall translation in response to arginine (Arg). The effect of AAP and Arg on ribosome peptidyl transferase center (PTC) function was analyzed in Neurospora crassa and wheat germ translation extracts using the transfer of nascent AAP to puromycin as an assay. In the presence of a high concentration of Arg, the wild-type AAP inhibited PTC function, but a mutated AAP that lacked stalling activity did not. While AAP of wild-type length was most efficient at stalling ribosomes, based on primer extension inhibition (toeprint) assays and reporter synthesis assays, a window of inhibitory function spanning four residues was observed at the AAP's C terminus. The data indicate that inhibition of PTC function by the AAP in response to Arg is the basis for the AAP's function of stalling ribosomes at the uORF termination codon. Arg could interfere with PTC function by inhibiting peptidyltransferase activity and/or by restricting PTC A-site accessibility. The mode of PTC inhibition appears unusual because neither specific amino acids nor a specific nascent peptide chain length was required for AAP to inhibit PTC function.

Project description:We combine genetic perturbation with cryo-electron microscopy (cryo-EM) to establish the mechanism of PTC maturation during human mitoribosome biogenesis. Cryo-EM structures of large mitoribosomal subunit (mtLSU) assembly intermediates purified from GTPBP6-deficient cells reveal that GTPBP5 acts in concert with the methyltransferase domain of the NSUN4-MTERF4 complex to facilitate PTC folding. Addition of recombinant GTPBP6 to these assembly intermediates provides the structural basis for subsequent GTPBP6-mediated late PTC maturation and suggests a sequential order of mtLSU biogenesis. Finally, cryo-EM analysis of 55S mitoribosomes treated with GTPBP6 explains how this protein can adopt a dual role in ribosome biogenesis and recycling. Taken together, these results provide the molecular basis for PTC maturation and establish a hierarchical model for late mitoribosome biogenesis.

Project description:As nascent polypeptide chains are synthesized, they pass through a tunnel in the large ribosomal subunit. Interaction between specific nascent chains and the ribosomal tunnel is used to induce translational stalling for the regulation of gene expression. One well-characterized example is the Escherichia coli SecM (secretion monitor) gene product, which induces stalling to up-regulate translation initiation of the downstream secA gene, which is needed for protein export. Although many of the key components of SecM and the ribosomal tunnel have been identified, understanding of the mechanism by which the peptidyl transferase center of the ribosome is inactivated has been lacking. Here we present a cryo-electron microscopy reconstruction of a SecM-stalled ribosome nascent chain complex at 5.6 Å. While no cascade of rRNA conformational changes is evident, this structure reveals the direct interaction between critical residues of SecM and the ribosomal tunnel. Moreover, a shift in the position of the tRNA-nascent peptide linkage of the SecM-tRNA provides a rationale for peptidyl transferase center silencing, conditional on the simultaneous presence of a Pro-tRNA(Pro) in the ribosomal A-site. These results suggest a distinct allosteric mechanism of regulating translational elongation by the SecM stalling peptide.