Sander Granneman scite author profile

The U3 small nucleolar ribonucleoprotein (snoRNP) plays an essential role in ribosome biogenesis but, like many RNA-protein complexes, its architecture is poorly understood. To address this problem, binding sites for the snoRNP proteins Nop1, Nop56, Nop58, and Rrp9 were mapped by UV cross-linking and analysis of cDNAs. Cross-linked protein-RNA complexes were purified under highly-denaturing conditions, ensuring that only direct interactions were detected. Recovered RNA fragments were amplified after linker ligation and cDNA synthesis. Cross-linking was successfully performed either in vitro on purified complexes or in vivo in living cells. Cross-linking sites were precisely mapped either by Sanger sequencing of multiple cloned fragments or direct, high-throughput Solexa sequencing. Analysis of RNAs associated with the snoRNP proteins revealed remarkably high signal-to-noise ratios and identified specific binding sites for each of these proteins on the U3 RNA. The results were consistent with previous data, demonstrating the reliability of the method, but also provided insights into the architecture of the U3 snoRNP. The snoRNP proteins were also cross-linked to pre-rRNA fragments, with preferential association at known sites of box C/D snoRNA function. This finding demonstrates that the snoRNP proteins directly contact the pre-rRNA substrate, suggesting roles in snoRNA recruitment. The techniques reported here should be widely applicable to analyses of RNA-protein interactions.ribosome synthesis ͉ RNA modification ͉ RNA processing ͉ RNP structure ͉ yeast P roteomic approaches have identified many factors involved in ribosome synthesis in yeast, but we still lack detailed understanding of the architecture of the preribosomes and small nucleolar ribonucleoprotein (snoRNP) complexes that are required for their maturation. Several methods have been described that allow identification of protein-RNA interaction sites in native particles. RNA immunoprecipitation uses formaldehyde to cross-link RNA to proteins (1, 2). Caveats of this method are that formaldehyde also cross-links proteins to proteins and the immunoprecipitation step is performed under semidenaturing conditions, so a positive result does not demonstrate direct RNA-protein interaction, and the spatial resolution of the technique is low. Moreover, formaldehyde and other chemical cross-linkers may not enter the cores of large complexes. This problem can be avoided by cross-linking proteins and RNA with UV light, and several techniques have been reported (3-7).UV-induced protein-RNA cross-links can be detected by primer extension analysis on the RNA and by MALDI-MS on the protein (4). These approaches can detect cross-links on both protein and RNA but primer extension mapping on long RNAs is not practical without prior knowledge of the approximate cross-linking site and MS analyses require up to 50 pmol of RNP (5). The cross-linking and immunoprecipitation (CLIP) method identified protein-RNA interaction sites in mammalian cells by cloning of the covalentlya...

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RNA polymerase I transcription and pre-rRNA processing are linked by specific SSU processome components

Gallagher¹,

Dunbar²,

Granneman³

et al. 2004

Genes Dev.

221

313

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Sequential events in macromolecular biosynthesis are often elegantly coordinated. The small ribosomal subunit (SSU) processome is a large ribonucleoprotein (RNP) required for processing of precursors to the small subunit RNA, the 18S, of the ribosome. We have found that a subcomplex of SSU processome proteins, the t-Utps, is also required for optimal rRNA transcription in vivo in the yeast Saccharomyces cerevisiae. The t-Utps are ribosomal chromatin (r-chromatin)-associated, and they exist in a complex in the absence of the U3 snoRNA. Transcription is required neither for the formation of the subcomplex nor for its r-chromatin association. The t-Utps are associated with the pre-18S rRNAs independent of the presence of the U3 snoRNA. This association may thus represent an early step in the formation of the SSU processome. Our results indicate that rRNA transcription and pre-rRNA processing are coordinated via specific components of the SSU processome.

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Identification of Bacteriophage-Encoded Anti-sRNAs in Pathogenic Escherichia coli

et al. 2014

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SummaryIn bacteria, Hfq is a core RNA chaperone that catalyzes the interaction of mRNAs with regulatory small RNAs (sRNAs). To determine in vivo RNA sequence requirements for Hfq interactions, and to study riboregulation in a bacterial pathogen, Hfq was UV crosslinked to RNAs in enterohemorrhagic Escherichia coli (EHEC). Hfq bound repeated trinucleotide motifs of A-R-N (A-A/G-any nucleotide) often associated with the Shine-Dalgarno translation initiation sequence in mRNAs. These motifs overlapped or were adjacent to the mRNA sequences bound by sRNAs. In consequence, sRNA-mRNA duplex formation will displace Hfq, promoting recycling. Fifty-five sRNAs were identified within bacteriophage-derived regions of the EHEC genome, including some of the most abundant Hfq-interacting sRNAs. One of these (AgvB) antagonized the function of the core genome regulatory sRNA, GcvB, by mimicking its mRNA substrate sequence. This bacteriophage-encoded “anti-sRNA” provided EHEC with a growth advantage specifically in bovine rectal mucus recovered from its primary colonization site in cattle.

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