Summary
How pseudouridylation (Ψ), the most common and evolutionarily conserved modification of rRNA, regulates ribosome activity is poorly understood. Medically, Ψ is important because the rRNA Ψ synthase, DKC1, is mutated in X-linked Dyskeratosis Congenita (X-DC) and Hoyeraal-Hreidarsson syndrome (HH). Here we characterize ribosomes isolated from a yeast strain where Cbf5p, the yeast homologue of DKC1, is catalytically impaired through a D95A mutation (cbf5-D95A). Ribosomes from cbf5-D95A cells display decreased affinities for tRNA binding to the A- and P-sites as well as the cricket paralysis virus IRES (Internal Ribosome Entry Site), which interacts with both the P- and E-sites of the ribosome. This biochemical impairment in ribosome activity manifests as decreased translational fidelity and IRES-dependent translational initiation, which are also evident in mouse and human cells deficient for DKC1 activity. These findings uncover specific roles for Ψ modification in ribosome-ligand interactions that are conserved in yeast, mouse, and humans.
T box bacterial genes utilize a riboswitch mechanism to regulate gene expression at the transcriptional level. Complementary base pairing of the 5'-untranslated mRNA with uncharged cognate tRNA stabilizes formation of an antiterminator element and permits complete transcription. In the absence of tRNA, a mutually exclusive RNA terminator element forms and results in transcription termination. This regulatory mechanism requires divalent metal ions at the antitermination event. The structural effects of Mg(2+) binding to antiterminator model RNA were investigated to ascertain if this requirement is due to the presence of a specific metal ion binding site in the antiterminator. Spectroscopic analysis identified the presence of a hydrated, diffuse Mg(2+) binding site. The results indicate that the mechanistic requirement for divalent metal ions is not due to Mg(2+)-induced pre-formation of a functional antiterminator receptor; rather, Mg(2+) binds in a helical region of high phylogenetic sequence conservation adjacent to the tRNA binding site.
The T box antiterminator RNA element is an important component of the T box riboswitch that controls the transcription of vital genes in many Gram-positive bacteria. A series of 1,4-disubstituted 1,2,3-triazoles was screened in a fluorescence-monitored thermal denaturation assay to identify ligands that altered the stability of antiterminator model RNA. Several ligands were identified that significantly increased or decreased the melting temperature (Tm) of the RNA. The results indicate that this series of triazole ligands can alter the stability of antiterminator model RNA in a structure-dependent manner.
The T box transcription antitermination regulatory system, found in Gram-positive bacteria, is dependent on a complex set of interactions between uncharged tRNA and the 5′-untranslated mRNA leader region of the regulated gene. One of these interactions involves the base pairing of the acceptor end of cognate tRNA with four bases in a 7 nt bulge of the antiterminator RNA. In vitro selection of randomized tRNA binding to Bacillus subtilis tyrS antiterminator model RNAs was used to determine what, if any, sequence trends there are for binding beyond the known base pair complementarity. The model antiterminator RNAs were selected for the wild-type tertiary fold of tRNA. While there were no obvious sequence correlations between the selected tRNAs, there were correlations between certain tertiary structural elements and binding efficiency to different antiterminator model RNAs. In addition, one antiterminator model selected primarily for a kissing tRNA T loop–antiterminator bulge interaction, while another antiterminator model resulted in no such selection. The selection results indicate that, at the level of tertiary structure, there are ideal matches between tRNAs and antiterminator model RNAs consistent with in vivo observations and that additional recognition features, beyond base pair complementarity, may play a role in the formation of the complex.
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