Project description:Biomolecular condensates are key features of intracellular compartmentalization. As the most prominent nuclear condensate in eukaryotes, the nucleolus is a multiphase liquid-like structure where ribosomal RNAs (rRNAs) are transcribed and processed, undergoing multiple maturation steps to form the small and large ribosomal subunits (SSU and LSU). However, how rRNA processing is coupled to the layered nucleolar organization is poorly understood due to a lack of tools to precisely monitor and perturb nucleolar rRNA processing dynamics. Here, we developed two complementary approaches to spatiotemporally map rRNA processing and engineer de novo nucleoli. Using sequencing in parallel with imaging, we found that rRNA processing steps are spatially segregated, with sequential maturation of rRNA required for its outward movement through nucleolar phases. By generating synthetic nucleoli in cells through an engineered rDNA plasmid system, we show that defects in SSU processing can alter the ordering of nucleolar phases, resulting in inside-out nucleoli and preventing rRNA outflux, while LSU precursors are necessary to build the outermost layer of the nucleolus. These findings demonstrate how rRNA is both a scaffold and substrate for the nucleolus, with rRNA acting as a programmable blueprint for the multiphase architecture that facilitates assembly of an essential molecular machine.

Project description:Ribosome small subunit (SSU) is assembled by the SSU processome which contains approximately 70 non-ribosomal protein factors. The biochemical mechanism for the SSU processome in 18S rRNA processing and maturation has been extensively studied, however, how the SSU processome components enter to the nucleolus has not been systematically investigated. Here we checked the nucleolar localization of 50 human SSU processome components and find that UTP3 and other 24 proteins enter to the nucleolus autonomously. For the remaining 25 proteins we find that UTP3/SAS10 assists the nucleolar localization of five proteins, namely MPP10, UTP25, EMG1 and two UTP-B components UTP12 and UTP13, and this ferry function of UTP3 is conserved in zebrafish. We also find that knockdown of human UTP3 impairs the cleavage at A0-site while loss-of-function of either utp3/sas10 or utp13/tbl3 in zebrafish causes an accumulation of the processed products containing the 5′ETS, supporting the crucial role of UTP3 in mediating the 5′ETS processing and degradation. Moreover, UTP3 directly interacts with and delivers EXOSC10 into the nucleolus, suggesting that UTP3 may play a direct role in recruiting the nuclear exosome to the SSU processome for degradation of the processed 5′ETS. These findings lay the ground for studying the mechanism of cytoplasm-to-nucleolus trafficking of the SSU processome components and the multifaceted roles of UTP3 during pre-rRNA processing.

Project description:Ribosome biogenesis, which takes place mainly in the nucleolus, involves coordinated expression of pre-ribosomal RNAs (pre-rRNAs) and ribosomal proteins, pre-rRNA processing, and subunit assembly with the aid of numerous assembly factors. Our previous study showed that the Arabidopsis thaliana protein arginine methyltransferase AtPRMT3 regulates pre-rRNA processing; however, the underlying molecular mechanism remains unknown. Here, we report that AtPRMT3 interacts with Ribosomal Protein S2 (RPS2), facilitating processing of the 90S/Small Subunit (SSU) processome and repressing nucleolar stress. We isolated an intragenic suppressor of atprmt3-2, which rescues the developmental defects of atprmt3-2 while produces a putative truncated AtPRMT3 protein bearing the entire N-terminus but lacking an intact enzymatic activity domain. We further identified RPS2 as an interacting partner of AtPRMT3, and found that loss-of-function rps2a2b mutants were phenotypically reminiscent of atprmt3, showing pleiotropic developmental defects and aberrant pre-rRNA processing. RPS2B binds directly to pre-rRNAs in the nucleus, and such binding is enhanced in atprmt3-2. Consistently, multiple components of the 90S/SSU processome were more enriched by RPS2B in atprmt3-2, which accounts for early pre-rRNA processing defects and results in nucleolar stress. Collectively, our study uncovered a novel mechanism by which AtPRMT3 cooperates with RPS2B to facilitate the dynamic assembly/disassembly of the 90S/SSU processome during ribosome biogenesis and repress nucleolar stress.

Project description:NOL12 5'-3' exoribonucleases, conserved among eukaryotes, play important roles in pre-rRNA processing, ribosome assembly and export. The most well-described yeast counterpart, Rrp17, is required for maturation of 5.8 and 25S rRNAs, whereas human hNOL12 is crucial for the separation of the large (LSU) and small (SSU) ribosome subunit rRNA precursors. In this study we demonstrate that plant AtNOL12 is also involved in rRNA biogenesis, specifically in the processing of the LSU rRNA precursor, 27S pre-rRNA. Importantly, the absence of AtNOL12 alters the expression of many ribosomal protein and ribosome biogenesis genes. These changes could potentially exacerbate rRNA biogenesis defects, or, conversely, they might stem from the disturbed ribosome assembly caused by delayed pre-rRNA processing. Moreover, exposure of the nol12 mutant to stress factors, including heat and pathogen Pseudomonas syringae, enhances the observed molecular phenotypes, linking pre-rRNA processing to stress response pathways. The aberrant rRNA processing, dependent on AtNOL12, could impact ribosome function, as suggested by improved mutant resistance to ribosome-targeting antibiotics. Despite extensive studies, the pre-rRNA processing pathway in plants remains insufficiently characterized. Our investigation reveals the involvement of AtNOL12 in the maturation of rRNA precursors, correlating this process to stress response in Arabidopsis. These findings contribute to a more comprehensive understanding of plant ribosome biogenesis.

Project description:The transcription factor BMAL1 is a core element of the circadian clock that contributes to cyclic control of genes transcribed by RNA polymerase II. By using biochemical cellular fractionation and immunofluorescence analyses we reveal a previously uncharacterized nucleolar localization for BMAL1. We used an unbiased approach to determine the BMAL1 interactome by mass spectrometry and identified NOP58 as a prominent nucleolar interactor. NOP58, a core component of the box C/D small nucleolar ribonucleoprotein complex, associates with Snord118 to control specific pre-ribosomal RNA (rRNA) processing steps. These results suggest a non-canonical role of BMAL1 in rRNA regulation. Indeed, we show that BMAL1 controls NOP58-associated Snord118 nucleolar levels and cleavage of unique pre-rRNA intermediates. Our findings identify an unsuspected function of BMAL1 in the nucleolus that appears distinct from its canonical role in the circadian clock system

Project description:Yeast large ribosomal subunit (LSU) precursors are subject to substantial changes in protein composition during their maturation due to coordinated transient interactions with a large number of ribosome biogenesis factors and due to the assembly of ribosomal proteins. These compositional changes go along with stepwise processing of LSU rRNA precursors and with specific rRNA folding events, as revealed by recent cryo-electron microscopy analyses of late nuclear and cytoplasmic LSU precursors. Here we aimed to analyze changes in the spatial rRNA surrounding of selected ribosomal proteins during yeast LSU maturation. For this we combined a recently developed tethered tertiary structure probing approach with both targeted and high-throughput readout strategies. Several structural features of late LSU precursors were faithfully detected by this procedure. In addition, the obtained data let us suggest that early rRNA precursor processing events are accompanied by a global transition from a flexible to a spatially restricted rRNA conformation. For intermediate LSU precursors, a number of structural hallmarks could be addressed which include the fold of the internal transcribed spacer between 5.8S rRNA and 25S rRNA, the orientation of the central protuberance and the spatial organization of the interface between LSU rRNA domains I and III.

Project description:Pluripotent stem cells have been shown to have unique nuclear properties, e.g., hyperdynamic chromatin and large, condensed nucleoli. However, the contribution of the latter unique nucleolar character to pluripotency has not been well understood. Here, we show fibrillarin (FBL), a critical methyltransferase for ribosomal RNA (rRNA) processing in nucleoli, as one of the proteins highly expressed in pluripotent embryonic stem (ES) cells. Stable expression of FBL in ES cells prolonged the pluripotent state of mouse ES cells cultured in the absence of leukemia inhibitory factor (LIF). Analyses using deletion mutants and a point mutant revealed that the methyltransferase activity of FBL regulates stem cell pluripotency. Knock down of this gene led to significant delays in rRNA processing, growth inhibition, and apoptosis in mouse ES cells. Interestingly, both partial knock down of FBL and treatment with actinomycin D, an inhibitor for rRNA synthesis, induced the expression of differentiation markers in the presence of LIF and promoted stem cell differentiation into neuronal lineages. Moreover, we identified p53 signaling as the regulatory pathway for pluripotency and differentiation of ES cells. These results suggest that proper activity of rRNA production in nucleoli is a novel factor for the regulation of pluripotency and differentiation ability of ES cells. Tc-inducible FBL-knock down ES cells were cultured for 2 days with or without Tc in the presence of LIF. These 2 conditions were analysed transcription profile.

Project description:The nucleolus is a membraneless organelle responsible for ribosome biogenesis, perinuclear heterochromatin formation, and genome stability regulation. However, how cell fate decision occurs, including early embryonic development, ESC differentiation, and tumorigenesis, remains poorly understood at the nucleolar level. It has been observed that large nucleoli and rDNA hyperactivity are common in pluripotent stem cells and tumor cells, while the nucleolus shrinks and rDNA transcriptional activity decrease during lineage commitment. iPSCs nucleolar size and rDNA transcriptional activity are greater than that before reprogramming. It remains unclear how and when the differentiated cell nucleoli convert to the stem cell nucleoli during iPSC reprogramming.In this study, we found that nucleolar remodeling, manifested as enlarged nucleolus, activation of rDNA transcription, enhanced activity of nucleolar organizing regions (NORs), and conversion of reticular nucleolar ultrastructure into low-granular, is an early and stage-specific event that occurs during iPSCs reprogramming. Our study highlights the importance of rDNA transcriptional activity in the early stages of iPSC reprogramming, which is crucial for nucleolar remodeling and regaining stemness. Interfering rDNA transcription hinders nucleolar remodeling, which has disastrous consequences for chromatin remodeling in early stage of iPSC reprogramming and iPSCs establishment. Moreover, our results revealed a nucleolar regulation on chromatin accessibility during iPSC reprogramming and identified some candidate genes (Mybl2, Bard1 and other chromosome related genes) that might be associated with iPSC reprogramming, which may apply to nucleolar remodeling in other cell fated decision.

Project description:The nucleolus is a membraneless organelle responsible for ribosome biogenesis, perinuclear heterochromatin formation, and genome stability regulation. However, how cell fate decision occurs, including early embryonic development, ESC differentiation, and tumorigenesis, remains poorly understood at the nucleolar level. It has been observed that large nucleoli and rDNA hyperactivity are common in pluripotent stem cells and tumor cells, while the nucleolus shrinks and rDNA transcriptional activity decrease during lineage commitment. iPSCs nucleolar size and rDNA transcriptional activity are greater than that before reprogramming. It remains unclear how and when the differentiated cell nucleoli convert to the stem cell nucleoli during iPSC reprogramming.In this study, we found that nucleolar remodeling, manifested as enlarged nucleolus, activation of rDNA transcription, enhanced activity of nucleolar organizing regions (NORs), and conversion of reticular nucleolar ultrastructure into low-granular, is an early and stage-specific event that occurs during iPSCs reprogramming. Our study highlights the importance of rDNA transcriptional activity in the early stages of iPSC reprogramming, which is crucial for nucleolar remodeling and regaining stemness. Interfering rDNA transcription hinders nucleolar remodeling, which has disastrous consequences for chromatin remodeling in early stage of iPSC reprogramming and iPSCs establishment. Moreover, our results revealed a nucleolar regulation on chromatin accessibility during iPSC reprogramming and identified some candidate genes (Mybl2, Bard1 and other chromosome related genes) that might be associated with iPSC reprogramming, which may apply to nucleolar remodeling in other cell fated decision.

Project description:The nucleolus composes hundreds of proteins that play distinct roles in ribosomal RNA (rRNA) processing within Fibrillar Center/Dense Fibrillar Component (FC/DFC) units and ribosome assembly in Granular Component (GC). The sub-nucleolar localization of most proteins and how their unique localization facilitates rRNA processing have remained elusive. By screening 200 nucleolar candidate proteins with high-resolution, live-cell microscopy, we identified a previously undescribed sub-nucleolar compartment, named the periphery of DFC (PDFC). Among the 12 proteins identified in PDFC, URB1 (unhealthy ribosome biogenesis 1) is required for PDFC organization and proper 3' end processing of 47S pre-rRNA. URB1 binds between the 28S rRNA and the 3' external transcribed spacer (3' ETS) to ensure 3' ETS removal, which occurs at the DFC/PDFC boundary. Loss of URB1 leads to accumulation of aberrant 3' ETS-retained 32S pre-rRNA variants, which activates exosome-dependent nucleolar surveillance. This causes decreased 28S rRNA production, reduced cell proliferation and retarded mouse embryonic pre-implementation development. Furthermore, urb1 depletion results in developmental craniofacial disorder in zebrafish, which can be at least partially rescued by further depleting exosome components. Together, this study provides new insights into functional sub-nucleolar organizations, identifies a physiologically essential step in rRNA maturation and emphasizes the exosome-dependent pre-rRNA surveillance pathway.