A pre-ribosomal RNA interaction network involving snoRNAs and the Rok1 helicase

Martin, Roman; Hackert, Philipp; Ruprecht, Maike; Simm, Stefan; Brüning, Lukas; Mirus, Oliver; Sloan, Katherine E.; Kudla, Grzegorz; Schleiff, Enrico; Bohnsack, Markus T.

doi:10.1261/rna.044669.114

Cited by 47 publications

(64 citation statements)

References 40 publications

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“…As snoRNA-rRNA interactions are destabilized by helicases upon binding to pre-rRNA, SPLASH analysis in yeast cells that overexpress the helicase Prp43 mutant (Bohnsack et al, 2009;Martin et al, 2002) (prp43-T123A; Figure S6D) was used to identify additional transient snoRNA-rRNA interactions that are important for rRNA biogenesis. The essential H/ACA box snR30 was previously found to be released from 18S rRNA by the Rok1 helicase and is required for 35S cleavage and release of the 18S rRNA precursor (Martin et al, 2014). In our analysis, we identified snR30-18S rRNA interactions in the Prp43 mutant but not in the wild-type ( Figure 5E), suggesting that either multiple helicases can work on the same snoRNA substrate(s) to facilitate their release from rRNA or that Prp43 is required for Rok1 to unwind snR30 from the preribosome.…”

Section: Long-range Intramolecular Rna Interactions Define Distinct Cmentioning

confidence: 99%

In Vivo Mapping of Eukaryotic RNA Interactomes Reveals Principles of Higher-Order Organization and Regulation

et al. 2016

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Identifying pairwise RNA-RNA interactions is key to understanding how RNAs fold and interact with other RNAs inside the cell. We present a high-throughput approach, sequencing of psoralen crosslinked, ligated, and selected hybrids (SPLASH), that maps pairwise RNA interactions in vivo with high sensitivity and specificity, genome-wide. Applying SPLASH to human and yeast transcriptomes revealed the diversity and dynamics of thousands of long-range intra- and intermolecular RNA-RNA interactions. Our analysis highlighted key structural features of RNA classes, including the modular organization of mRNAs, its impact on translation and decay, and the enrichment of long-range interactions in noncoding RNAs. Additionally, intermolecular mRNA interactions were organized into network clusters and were remodeled during cellular differentiation. We also identified hundreds of known and new snoRNA-rRNA binding sites, expanding our knowledge of rRNA biogenesis. These results highlight the underexplored complexity of RNA interactomes and pave the way to better understanding how RNA organization impacts biology.

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Section: Long-range Intramolecular Rna Interactions Define Distinct Cmentioning

confidence: 99%

In Vivo Mapping of Eukaryotic RNA Interactomes Reveals Principles of Higher-Order Organization and Regulation

et al. 2016

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“…Nonetheless, a mismatch at the site of methylation within a conserved guide-target complementarity implies that the interaction may be beneficial but that the modification is either not needed or harmful to the function of the target RNA. Studies in yeast that use cross-linking to detect RNA-RNA interactions support this hypothesis (39,40).…”

Section: Prediction and Analysis Of C/d Box Srna Methylation Targetsmentioning

confidence: 91%

Methylation guide RNA evolution in archaea: structure, function, and genomic organization of 110 C/D box sRNA families across sixPyrobaculumspecies

Lui

Uzilov

Bernick

et al. 2017

Preprint

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“…To date, 21 RNA helicases have been suggested to act during the process of ribosome biogenesis in yeast with eight implicated in SSU maturation, ten in LSU biogenesis and three in the assembly of both subunits [20]. A wealth of research has provided information on the binding sites and potential functions of many of these RNA helicases [21][22][23][24][25][26][27][28][29][30][31][32][33], with several RNA helicases implicated in promoting the release of specific snoRNPs from early pre-ribosomal particles [21,22,26,27,30,31] and others suggested to catalyse pre-rRNA rearrangements that induce formation of mature rRNA conformations facilitating the recruitment of RPs and/or AFs [23,32,34]. However, in the case of other RNA helicases that have been found associated with pre-ribosomal particles, little is known about the timing of their association, the interactions they make within pre-ribosomes and what contribution their activity makes to the assembly process.…”

Section: Introductionmentioning

confidence: 99%

“…The most prominent example is the G-patch proteins, which contain a glycinerich domain via which they associate with and regulate the activity of the DEAH box helicases Prp43 and Prp2 [40][41][42][43][44]. During ribosome assembly, Prp43 mediates the release of a specific subset of snoRNPs from early pre-LSU particles, a function which has been linked to the G-patch protein Gno1 (Pxr1) [27,45]. In addition, Prp43 is suggested to remodel cytoplasmic pre-SSU particles to facilitate cleavage at the 3ʹ end of the 18S rRNA and the G-patch protein Pfa1 (Sqs1) has been linked to this function [27,28,46].…”

Section: Introductionmentioning

confidence: 99%

“…During ribosome assembly, Prp43 mediates the release of a specific subset of snoRNPs from early pre-LSU particles, a function which has been linked to the G-patch protein Gno1 (Pxr1) [27,45]. In addition, Prp43 is suggested to remodel cytoplasmic pre-SSU particles to facilitate cleavage at the 3ʹ end of the 18S rRNA and the G-patch protein Pfa1 (Sqs1) has been linked to this function [27,28,46]. Alongside the G-patch proteins, a family of cofactors dedicated to regulation of eIF4A-like RNA helicases and characterized by the presence of a 'middle of eIF4G' (MIF4G) domain has been described ( [47] and reviewed in [35,48]).…”

Section: Introductionmentioning

confidence: 99%

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Sgd1 is an MIF4G domain-containing cofactor of the RNA helicase Fal1 and associates with the 5’ domain of the 18S rRNA sequence

Gallesio¹,

Hackert²,

Bohnsack³

et al. 2020

RNA Biology

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Assembly of eukaryotic ribosomal subunits is a complex and dynamic process involving the action of more than 200 transacting assembly factors. Although recent cryo-electron microscopy structures have provided information on architecture of several pre-ribosomal particles and the binding sites of many AFs, the RNA and protein interactions of many other AFs not captured in these snapshots still remain elusive. RNA helicases are key regulators of structural rearrangements within pre-ribosomal complexes and here we have analysed the eIF4A-like RNA helicase Fal1 and its putative cofactor Sgd1. Our data show that these proteins interact directly via the MIF4G domain of Sgd1 and that the MIF4G domain of Sgd1 stimulates the catalytic activity of Fal1 in vitro. The catalytic activity of Fal1, and the interaction between Fal1 and Sgd1, are required for efficient pre-rRNA processing at the A 0 , A 1 and A 2 sites. Furthermore, Sgd1 co-purifies the early small subunit biogenesis factors Lcp5 and Rok1, suggesting that the Fal1-Sgd1 complex likely functions within the SSU processome. In vivo crosslinking data reveal that Sgd1 binds to helix H12 of the 18S rRNA sequence and we further demonstrate that this interaction is formed by the C-terminal region of the protein, which is essential for its function in ribosome biogenesis.

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A pre-ribosomal RNA interaction network involving snoRNAs and the Rok1 helicase

Cited by 47 publications

References 40 publications

In Vivo Mapping of Eukaryotic RNA Interactomes Reveals Principles of Higher-Order Organization and Regulation

In Vivo Mapping of Eukaryotic RNA Interactomes Reveals Principles of Higher-Order Organization and Regulation

Methylation guide RNA evolution in archaea: structure, function, and genomic organization of 110 C/D box sRNA families across sixPyrobaculumspecies

Sgd1 is an MIF4G domain-containing cofactor of the RNA helicase Fal1 and associates with the 5’ domain of the 18S rRNA sequence

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