Bacterial ribosomes stalled at the 3' end of malfunctioning messenger RNAs can be rescued by transfer-messenger RNA (tmRNA)-mediated trans-translation. The SmpB protein forms a complex with the tmRNA, and the transfer-RNA-like domain (TLD) of the tmRNA then enters the A site of the ribosome. Subsequently, the TLD-SmpB module is translocated to the P site, a process that is facilitated by the elongation factor EF-G, and translation is switched to the mRNA-like domain (MLD) of the tmRNA. Accurate loading of the MLD into the mRNA path is an unusual initiation mechanism. Despite various snapshots of different ribosome-tmRNA complexes at low to intermediate resolution, it is unclear how the large, highly structured tmRNA is translocated and how the MLD is loaded. Here we present a cryo-electron microscopy reconstruction of a fusidic-acid-stalled ribosomal 70S-tmRNA-SmpB-EF-G complex (carrying both of the large ligands, that is, EF-G and tmRNA) at 8.3 Å resolution. This post-translocational intermediate (TI(POST)) presents the TLD-SmpB module in an intrasubunit ap/P hybrid site and a tRNA(fMet) in an intrasubunit pe/E hybrid site. Conformational changes in the ribosome and tmRNA occur in the intersubunit space and on the solvent side. The key underlying event is a unique extra-large swivel movement of the 30S head, which is crucial for both tmRNA-SmpB translocation and MLD loading, thereby coupling translocation to MLD loading. This mechanism exemplifies the versatile, dynamic nature of the ribosome, and it shows that the conformational modes of the ribosome that normally drive canonical translation can also be used in a modified form to facilitate more complex tasks in specialized non-canonical pathways.
The crystal structures of the universal translation-initiation inhibitors edeine and pactamycin bound to ribosomal 30S subunit have revealed that edeine induces base pairing of G693:C795, residues that constitute the pactamycin binding site. Here, we show that base pair formation by addition of edeine inhibits tRNA binding to the P site by preventing codon-anticodon interaction and that addition of pactamycin, which rebreaks the base pair, can relieve this inhibition. In addition, edeine induces translational misreading in the A site, at levels comparable to those induced by the classic misreading antibiotic streptomycin. Binding of pactamycin between residues G693 and C795 strongly inhibits translocation with a surprising tRNA specificity but has no effect on translation initiation, suggesting that reclassification of this antibiotic is necessary. Collectively, these results suggest that the universally conserved G693:C795 residues regulate tRNA binding at the P site of the ribosome and influence translocation efficiency.
Our understanding of the process of translation has progressed rapidly since the availability of highly resolved structures for the ribosome. A wealth of information has emerged in terms of both RNA and protein structure and the interplay between them. This has prompted us to revisit the astonishing "treasure trove" of functional data regarding the ribosome that has accumulated over the past decades. Here we try a systematic synopsis of these ribosomal functions in light of the cryo-electron microscopic structures (resolution >7 A) and the atomic x-ray structures (>2.4 A) of the ribosome.
In order to identify the amino acid residues necessary for the selective recognition of the mRNA cap structure by human eukaryotic initiation factor-4E (eIF-4E), which plays a central role in the first step of mRNA translation, we prepared recombinant wild-type and fourteen mutant forms and compared their cap-binding abilities by affinity chromatography. By the direct expression of a synthetic gene encoding human eIF-4E as the soluble form in Escherichia coli and the application on a 7-methylguanosine-5'-triphosphate-Sepharose 4B cap affinity column, pure recombinant eIF-4E was prepared; the optimum pH for the binding of the mRNA cap was 7.5. Among the amino acid residues conserved among various eIF-4E species, each of 14 functional residues was replaced with a nonpolar amino acid (alanine or leucine). All mutant eIF-4E genes, which were constructed by site-directed niutagenesis, were expressed in the same way as the wild type, and their cap-binding abilities were compared with that of the wild type. Consequently, all eight tryptophan residues, Glu103, and two histidine residues at positions 37 and 200 in human recombinant eIF-4E were suggested to be important for the recognition of the mRNA cap structure through direct interaction and/or indirect contributions. Indirect contributions included the construction of the overall protein structure, especially the cap-binding pocket.Keywords: human eIF-4E ; m'G(5')ppp ; mRNA cap structure ; site-directed mutagenesis ; cap binding.Many eukaryotic mRNAs have a common cap structure [m7G(5')ppp(5')N, where N is any nucleotide] at the 5'-terminal portion and its structure plays important roles in stabilizing the mRNA structure and facilitating mRNA binding to ribosomes during initiation [l-31. To allow for the efficient translation of mRNA, however, an interaction is required between the cap structure and eukaryotic initiation factor (eIF)-4 polypeptides consisting of eIF-4A, eIF-4B, eIF-4E, and eIF-4y 143. eIF-4E, which corresponds to the smallest subunit of eIF-4F, has been shown to bind specifically to the mRNA cap structure and has an important function in the first step of protein synthesis; it appears to play a key role in the regulation of translation via phosphorylation [5 -71. Furthermore, recent studies have indicated that eIF-4E participates in the regulation of translation through the interaction with 4E-BP [8].The amino acid sequences of eIF-4Es from yeast [9], human [lo], mouse [ I l l , rabbit 1121, wheat germ [13], and Drosophila [14] have already been reported. Human eIF-4E is a polypeptide of about 25 kDa that contains eight tryptophan residues and its amino acid residues have been remarkably conserved in number and position during evolution among human, mouse, yeast, rabbit, wheat, and Drosophila, which probably reflects the importance for the recognition of the mRNA cap structure [15]. From fluorescence studies at various pH values, however, histidineCorrespondt.nce to T. Ishida, Department of Physical Chemistry, Osaka University of Pharmaceutical Scie...
Class I genomic clones of the quail (Coturnix japonica) major histocompatibility complex (MhcCoja) were isolated and characterized. Two clusters spanning the 90.8 kilobase (kb) and 78.2 kb class I gene regions were defined by overlapping cosmid clones and found to contain at least twelve class I loci. However, unlike in the chicken Mhc, no evidence for the existence of any Coja class II gene was obtained in these two clusters. Based on comparative analysis of the genomic sequences with those of the cDNA clones, Coja-A, Coja-B, Coja-C, and Coja-D (Shiina et al. 1999), these twelve loci were assigned to represent one Coja-A gene, two Coja-B genes (Coja-B1 and -B2), four Coja-C genes (Coja-C1-C4), four Coja-D genes (Coja-D1-D4), and one new Coja-E gene. A class I gene-rich segment of 24.6 kb in which five of these genes (Coja-B1, -B2, -D1, -D2 and -E) are densely packed were sequenced by the shotgun strategy. All of these five class I genes are very compact in size [2089 base pairs (bp)-2732 bp] and contain no apparent genetic defect for functional expression. A transporter associated with the antigen processing (TAP) gene was identified in this class I gene-rich segment. These results suggest that the quail class I region is physically separated from the class II region and characterized by a large number of the expressible class I loci (at least seven) in contrast to the chicken Mhc, where the class I and class II regions are not clearly differentiated and only at most three expressed class I loci so far have been recognized.
Psoriasis vulgaris is associated with the HLA-Cw6 and Cw7 antigens. We have previously narrowed down the critical region most likely to contain the psoriasis vulgaris gene to 111 kb spanning 89 kb to 200 kb telomeric of the HLA-C locus by microsatellite mapping. This segment includes three known genes (POU5F1, SC1 and S) and four new expressed genes. Among them, SC1 (TCF19) is the cell growth regulated gene possibly with trans-activator activity. Since psoriasis vulgaris is a common skin disorder characterized by hyperproliferation of epidermal cells, it is tempting to speculate that the SCI gene is one of the strong candidate genes responsible for the development of psoriasis vulgaris. Here, we investigated genetic polymorphisms in the SC1 gene by direct DNA sequencing and polymerase chain reaction-single-strand conformation polymorphism (PCR-SSCP) techniques. Three single nucleotide polymorphisms in exon 2, two of which are accompanied by amino-acid substitutions, were identified. Further, one 4-bp deletion polymorphism was detected around the acceptor site of the lariat-shaped structure necessary for RNA splicing in intron 2. No significant difference in the dimorphic or haplotypic distribution at these four polymorphic sites was observed between the patients with psoriasis vulgaris and healthy controls. This suggests that the susceptible gene for psoriasis vulgaris is not the SC1 gene itself, although a unique homozygous haplotype was identified in the patients.
To test the structure of tmRNA in solution, crosslinking experiments were performed which showed two sets of cross-links in two different domains of tmRNA. Site-directed mutagenesis was used to search for tmRNA nucleotide bases that might form a functional analogue of a codon^anticodon duplex to be recognized by the ribosomal A-site. We demonstrate that nucleotide residues U85 and A86 from tmRNA are significant for tmRNA function and propose that they are involved in formation of a tmRNA element playing a central role in A-site recognition. These data are discussed in the frame of a hypothetical model that suggests a general scheme for the interaction of tmRNA with the ribosome and explains how it moves through the ribosome. ß
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