Identification of novel nuclear export factors for mRNA and the 40S preribosome in S. cerevisiae
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We have isolated a cold-sensitive mutant of Saccharomyces cerevisiae in which there is a deficit of 60S ribosomal subunits. Cold sensitivity and the assembly defect are recessive and cosegregate, defining a single essential gene that we designated DRS1 (deficiency of ribosomal subunits). The wild-type DRS1 gene was cloned by complementation of the cold-sensitive phenotype of drs1. Sequence analysis reveals a high degree of similarity to a family of proteins that are thought to function as ATP-dependent RNA helicases. Pulse-chase analysis of ribosomal RNA synthesis and processing indicates that the drs1 mutant accumulates the 27S precursor of the mature 25S rRNA. These results suggest that, as in pre-mRNA splicing, RNA helicase activities are involved in ribosomal RNA processing.
RNA Helicase A
Degradosome
Eukaryotic Ribosome
5.8S ribosomal RNA
Ribosomal protein
5S ribosomal RNA
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Many non-coding RNAs form structures that interact with cellular machinery to control gene expression. A central goal of molecular and synthetic biology is to uncover design principles linking RNA structure to function to understand and engineer this relationship. Here we report a simple, high-throughput method called in-cell SHAPE-Seq that combines in-cell probing of RNA structure with a measurement of gene expression to simultaneously characterize RNA structure and function in bacterial cells. We use in-cell SHAPE-Seq to study the structure–function relationship of two RNA mechanisms that regulate translation in Escherichia coli. We find that nucleotides that participate in RNA–RNA interactions are highly accessible when their binding partner is absent and that changes in RNA structure due to RNA–RNA interactions can be quantitatively correlated to changes in gene expression. We also characterize the cellular structures of three endogenously expressed non-coding RNAs: 5S rRNA, RNase P and the btuB riboswitch. Finally, a comparison between in-cell and in vitro folded RNA structures revealed remarkable similarities for synthetic RNAs, but significant differences for RNAs that participate in complex cellular interactions. Thus, in-cell SHAPE-Seq represents an easily approachable tool for biologists and engineers to uncover relationships between sequence, structure and function of RNAs in the cell.
Riboswitch
Nucleic acid structure
RNA Silencing
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Ribosomal protein L1 from Saccharomyces cerevisiae binds 5S rRNA and can be released from intact 60S ribosomal subunits as an L1-5S ribonucleoprotein (RNP) particle. To understand the nature of the interaction between L1 and 5S rRNA and to assess the role of L1 in ribosome assembly and function, we cloned the RPL1 gene encoding L1. We have shown that RPL1 is an essential single-copy gene. A conditional null mutant in which the only copy of RPL1 is under control of the repressible GAL1 promoter was constructed. Depletion of L1 causes instability of newly synthesized 5S rRNA in vivo. Cells depleted of L1 no longer assemble 60S ribosomal subunits, indicating that L1 is required for assembly of stable 60S ribosomal subunits but not 40S ribosomal subunits. An L1-5S RNP particle not associated with ribosomal particles was detected by coimmunoprecipitation of L1 and 5S rRNA. This pool of L1-5S RNP remained stable even upon cessation of 60S ribosomal subunit assembly by depletion of another ribosomal protein, L16. Preliminary results suggest that transcription of RPL1 is not autogenously regulated by L1.
Ribosomal protein
5S ribosomal RNA
50S
23S ribosomal RNA
30S
5.8S ribosomal RNA
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The small subunit (SSU) processome, a large ribonucleoprotein particle, organizes the assembly of the eukaryotic small ribosomal subunit by coordinating the folding, cleavage, and modification of nascent pre-ribosomal RNA (rRNA). Here, we present the cryo-electron microscopy structure of the yeast SSU processome at 5.1-angstrom resolution. The structure reveals how large ribosome biogenesis complexes assist the 5' external transcribed spacer and U3 small nucleolar RNA in providing an intertwined RNA-protein assembly platform for the separate maturation of 18S rRNA domains. The strategic placement of a molecular motor at the center of the particle further suggests a mechanism for mediating conformational changes within this giant particle. This study provides a structural framework for a mechanistic understanding of eukaryotic ribosome assembly in the model organism Saccharomyces cerevisiae.
ribosome biogenesis
Eukaryotic Ribosome
Small nucleolar RNA
5.8S ribosomal RNA
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Inhibition of protein synthesis by an efficiently expressed mutation in the yeast 5.8S ribosomal RNA
Recent studies on the inhibition of protein synthesis by specific anti 5.8S rRNA oligonucleotides strongly suggested that this RNA plays an important role in eukaryotic ribosome function. To evaluate this possibility further, a ribosomal DNA transcription unit from Schizosaccharomyces pombe was cloned into yeast shuttle vectors with copy numbers ranging from 2 to approximately 90 per cell; to allow direct detection of expressed RNA and to disrupt the function of the 5.8S rRNA molecule, a five base insertion was made in a universally conserved GAAC sequence. The altered mobility of the mutant RNA was readily detected by gel electrophoresls and analyses indicated that mutant RNA transcription reflected the ratio of plasmid to endogenous rDNA. The highest copy number plasmid resulted in about 40 – 50% mutant RNA. This mutant RNA was readily integrated into the ribosome structure resulting in an in vivo ribosome population which was also about 40 – 50% mutant; the rates of growth and protein synthesis were equally reduced by approximately 40%. A comparable level of inhibition in protein synthesis was demonstrated in vitro and polyribosomal profiles revealed a consistent increase in size. Subsequent RNA analyses indicated a normal distribution of mutant RNA in both monoribosomes and polyribosomes, but elevated tRNA levels in mutant polyribosomes. Additional mutations in alternate GAAC sequences revealed similar but cumulative effects on both protein synthesis and polyribosome profiles. Taken together, these results suggest little or no effect on initiation but provide in vivo evidence of a functional role for the 5.8S rRNA in protein elongation.
5.8S ribosomal RNA
Polysome
Transcription
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5.8S ribosomal RNA
Cleavage (geology)
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5.8S ribosomal RNA
RNA polymerase I
Cleavage (geology)
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Summary The Has1 protein, a member of the DEAD‐box family of ATP‐dependent RNA helicases in Saccharomyces cerevisiae , has been found by different proteomic approaches to be associated with 90S and several pre‐60S ribosomal complexes. Here, we show that Has1p is an essential trans‐ acting factor involved in 40S ribosomal subunit biogenesis. Polysome analyses of strains genetically depleted of Has1p or carrying a temperature‐sensitive has1‐1 mutation show a clear deficit in 40S ribosomal subunits. Analyses of pre‐rRNA processing by pulse‐chase labelling, Northern hybridization and primer extension indicate that these strains form less 18S rRNA because of inhibition of processing of the 35S pre‐rRNA at the early cleavage sites A 0 , A 1 and A 2 . Moreover, processing of the 27SA 3 and 27SB pre‐rRNAs is delayed in these strains. Therefore, in addition to its role in the biogenesis of 40S ribosomal subunits, Has1p is required for the optimal synthesis of 60S ribosomal subunits. Consistent with a role in ribosome biogenesis, Has1p is localized to the nucleolus. On sucrose gradients, Has1p is associated with a high‐molecular‐weight complex sedimenting at positions equivalent to 60S and pre‐60S ribosomal particles. A mutation in the ATP‐binding motif of Has1p does not support growth of a has1 null strain, suggesting that the enzymatic activity of Has1p is required in ribosome biogenesis. Finally, sequence comparisons suggest that Has1p homologues exist in all eukaryotes, and we show that a has1 null strain can be fully complemented by the Candida albicans homologue.
ribosome biogenesis
Ribosomal protein
Eukaryotic Ribosome
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The gene for subunit II of cytochrome oxidase (CoII) from bovine mitochondria has been cloned behind a T7 promoter and the corresponding mRNA synthesized in vitro. The RNA transcribed from this vector has a single nucleotide 5' to the start AUG and, thus, corresponds closely to the native mRNA. It binds to the small 28 S ribosomal subunit of bovine mitochondria but not to the large (39 S) subunit or to 55 S ribosomes. The binding occurs readily in the absence of auxiliary initiation factors or initiator tRNA. The complex formed appears to contain 1 mRNA/28 S subunit. The observed binding is specific for mRNA since neither tRNA nor ribosomal RNA can act as competitive inhibitors. The interaction of the mRNA with the 28 S subunit does not require an AUG codon near the 5' end and constructs containing 5' leaders of more than 100 nucleotides still bind efficiently. About 5% of the bound mRNA is protected from digestion by T1 RNase. The protected fragments do not arise from a specific region of the mRNA since they hybridize to several restriction fragments of the cloned CoII gene.
Mitochondrial ribosome
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Small cytoplasmic RNA (scRNA; 271 nucleotides) is an abundant and stable RNA of the gram-positive bacterium Bacillus subtilis. To investigate the function of scRNA in B. subtilis cells, we developed a strain that is dependent on isopropyl-beta-D-thiogalactopyranoside for scRNA synthesis by fusing the chromosomal scr locus with the spac-1 promoter by homologous recombination. Depletion of the inducer leads to a loss of scRNA synthesis, defects in protein synthesis and production of alpha-amylase and beta-lactamase, and eventual cell death. The loss of the scRNA gene in B. subtilis can be complemented by the introduction of human signal recognition particle 7S RNA, which is considered to be involved in protein transport, or Escherichia coli 4.5S RNA. These results provide further evidence for a functional relationship between B. subtilis scRNA, human signal recognition particle 7S RNA, and E. coli 4.5S RNA.
Signal recognition particle
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