Project description:This SuperSeries is composed of the SubSeries listed below.

Project description:To produce mature ribosomal RNAs (rRNAs), polycistronic rRNA transcripts are cleaved in an ordered series of events. We have uncovered the molecular basis for the ordering of two essential cleavage steps at the 3'-end of 18S rRNA. Using in vitro and in vivo structure probing, RNA binding and cleavage experiments, and yeast genetics, we demonstrate that a conserved RNA sequence in the spacer region between the 18S and 5.8S rRNAs base-pairs with the decoding site of 18S rRNA in early assembly intermediates. Nucleolar cleavage at site A(2) excises this sequence element, leading to a conformational switch in pre-18S rRNA, by which the ribosomal decoding site is formed. This conformational switch positions the nuclease Nob1 for cytoplasmic cleavage at the 3'-end of 18S rRNA and is required for the final maturation step of 18S rRNA in vivo and in vitro. More generally, our data show that the intrinsic ability of RNA to form stable structural switches is exploited to order and regulate RNA-dependent biological processes.

Project description:The function of the U3 small nucleolar ribonucleoprotein (snoRNP) is central to the events surrounding pre-rRNA processing, as evidenced by the severe defects in cleavage of pre-18S rRNA precursors observed upon depletion of the U3 RNA and its unique protein components. Although the precise function of each component remains unclear, since U3 snoRNA levels remain unchanged upon genetic depletion of these proteins, it is likely that the proteins themselves have significant roles in the cleavage reactions. Here we report the identification of two previously undescribed protein components of the U3 snoRNP, representing the first snoRNP components identified by using the two-hybrid methodology. By screening for proteins that physically associate with the U3 snoRNP-specific protein, Mpp10p, we have identified Imp3p (22 kDa) and Imp4p (34 kDa) (named for interacting with Mpp10p). The genes encoding both proteins are essential in yeast. Genetic depletion reveals that both proteins are critical for U3 snoRNP function in pre-18S rRNA processing at the A0, A1, and A2 sites in the pre-rRNA. Both Imp proteins associate with Mpp10p in vivo, and both are complexed only with the U3 snoRNA. Conservation of RNA binding domains between Imp3p and the S4 family of ribosomal proteins suggests that it might associate with RNA directly. However, as with other U3 snoRNP-specific proteins, neither Imp3p nor Imp4p is required for maintenance of U3 snoRNA integrity. Imp3p and Imp4p are therefore novel protein components specific to the U3 snoRNP with critical roles in pre-rRNA cleavage events.

Project description:Stem cells are regulated by transcriptional networks controlling pluripotency and differentiation. How basic cellular processes like splicing or protein synthesis regulate stem cell function is less well understood. Here, we show that the RNA binding protein HTATSF1 controls protein synthesis by controlling several independent RNA processing steps during ribosome biogenesis. In a complex with ribosomal RNA transcription and processing factors, HTATSF1 regulates ribosomal RNA abundance. By binding to the U2snRNP complex, HTATSF1 also controls intron removal specifically in ribosomal protein transcripts. HTATSF1-mediated control of protein synthesis is essential for the transition from the naïve pre-implantation epiblast to the primed post-implantation epiblast, a stage of low protein synthesis levels, and during further differentiation towards neuroectoderm. Our results identify coordinated regulation of ribosomal RNA and protein biosynthesis by HTATSF1 as an essential mechanism to mediate protein synthesis control during early stages of mammalian embryogenesis.

Project description:Stem cells are regulated by transcriptional networks controlling pluripotency and differentiation. How basic cellular processes like splicing or protein synthesis regulate stem cell function is less well understood. Here, we show that the RNA binding protein HTATSF1 controls protein synthesis by controlling several independent RNA processing steps during ribosome biogenesis. In a complex with ribosomal RNA transcription and processing factors, HTATSF1 regulates ribosomal RNA abundance. By binding to the U2snRNP complex, HTATSF1 also controls intron removal specifically in ribosomal protein transcripts. HTATSF1-mediated control of protein synthesis is essential for the transition from the naïve pre-implantation epiblast to the primed post-implantation epiblast, a stage of low protein synthesis levels, and during further differentiation towards neuroectoderm. Our results identify coordinated regulation of ribosomal RNA and protein biosynthesis by HTATSF1 as an essential mechanism to mediate protein synthesis control during early stages of mammalian embryogenesis.

Project description:Stem cells are regulated by transcriptional networks controlling pluripotency and differentiation. How basic cellular processes like splicing or protein synthesis regulate stem cell function is less well understood. Here, we show that the RNA binding protein HTATSF1 controls protein synthesis by controlling several independent RNA processing steps during ribosome biogenesis. In a complex with ribosomal RNA transcription and processing factors, HTATSF1 regulates ribosomal RNA abundance. By binding to the U2snRNP complex, HTATSF1 also controls intron removal specifically in ribosomal protein transcripts. HTATSF1-mediated control of protein synthesis is essential for the transition from the naïve pre-implantation epiblast to the primed post-implantation epiblast, a stage of low protein synthesis levels, and during further differentiation towards neuroectoderm. Our results identify coordinated regulation of ribosomal RNA and protein biosynthesis by HTATSF1 as an essential mechanism to mediate protein synthesis control during early stages of mammalian embryogenesis.

Project description:Analysis of processing, assembly, and function of higher eukaryotic ribosomal RNA (rRNA) has been hindered by the lack of an expression system that enables rRNA to be modified and then examined functionally. Given the potential usefulness of such a system, we have developed one for mammalian 18S rRNA. We inserted a sequence tag into expansion segment 3 of mouse 18S rRNA to monitor expression and cleavage by hybridization. Mutations were identified that confer resistance to pactamycin, allowing functional analysis of 40S ribosomal subunits containing synthetic 18S rRNAs by selectively blocking translation from endogenous (pactamycin-sensitive) subunits. rRNA constructs were suitably expressed in transfected cells, shown to process correctly, incorporate into ≈ 15% of 40S subunits, and function normally based on various criteria. After rigorous analysis, the system was used to investigate the importance of sequences that flank 18S rRNA in precursor transcripts. Although deletion analysis supported the requirement of binding sites for the U3 snoRNA, it showed that a large segment of the 5' external transcribed spacer and the entire first internal transcribed spacer, both of which flank 18S rRNA, are not required. The success of this approach opens the possibility of functional analyses of ribosomes, with applications in basic research and synthetic biology.

Project description:The main components of the essential cellular process of eukaryotic ribosome biogenesis are highly conserved from yeast to humans. Among these, the U3 Associated Proteins (UTPs) are a small subunit processome subcomplex that coordinate the first two steps of ribosome biogenesis in transcription and pre-18S processing. While we have identified the human counterparts of most of the yeast Utps, the homologs of yeast Utp9 and Bud21 (Utp16) have remained elusive. In this study, we find that NOL7 is the likely ortholog of Bud21. Previously described as a tumour suppressor through regulation of antiangiogenic transcripts, we now show that NOL7 is required for early pre-rRNA accumulation and pre-18S rRNA processing in human cells. These roles lead to decreased protein synthesis and induction of the nucleolar stress response upon NOL7 depletion. Beyond Bud21's nonessential role in yeast, we establish human NOL7 as an essential UTP that is necessary to maintain both early pre-rRNA levels and processing.

Project description:Rcl1 is an essential nucleolar protein required for U3 snoRNA-guided pre-rRNA processing at sites flanking the 18S rRNA sequence. A potential catalytic role for Rcl1 during pre-rRNA cleavage has been suggested based on its primary structure similarity to RNA 3'-terminal phosphate cyclase (Rtc) enzymes, which perform nucleotidyl transfer and phosphoryl transfer reactions at RNA ends. Here, we report the 2.6 Å crystal structure of a biologically active yeast Rcl1, which illuminates its modular 4-domain architecture and overall homology with RNA cyclases while revealing numerous local differences that account for why Rtcs possess metal-dependent adenylyltransferase activity and Rcls do not. A conserved oxyanion-binding site in Rcl1 was highlighted for possible catalytic or RNA-binding functions. However, the benign effects of mutations in and around the anion site on Rcl1 activity in vivo militate against such a role.

Project description:Yeast Rcl1 is a potential endonuclease that mediates pre-RNA cleavage at the A2-site to separate 18S rRNA from 5.8S and 25S rRNAs. However, the biological function of Rcl1 in opisthokonta is poorly defined. Moreover, there is no information regarding the exact positions of 18S pre-rRNA processing in zebrafish. Here, we report that zebrafish pre-rRNA harbours three major cleavage sites in the 5'ETS, namely -477nt (A'-site), -97nt (A0-site) and the 5'ETS and 18S rRNA link (A1-site), as well as two major cleavage regions within the ITS1, namely 208-218nt (site 2) and 20-33nt (site E). We also demonstrate that depletion of zebrafish Rcl1 mainly impairs cleavage at the A1-site. Phenotypically, rcl1-/- mutants exhibit a small liver and exocrine pancreas and die before 15 days post-fertilization. RNA-seq analysis revealed that the most significant event in rcl1-/- mutants is the up-regulated expression of a cohort of genes related to ribosome biogenesis and tRNA production. Our data demonstrate that Rcl1 is essential for 18S rRNA maturation at the A1-site and for digestive organogenesis in zebrafish. Rcl1 deficiency, similar to deficiencies in other ribosome biogenesis factors, might trigger a common mechanism to upregulate the expression of genes responsible for ribosome biogenesis.