Secondary Structures of rRNAs from All Three Domains of Life

Petrov, Anton S.; Bernier, Chad R.; Gulen, Burak; Waterbury, Chris C.; Hershkovits, Eli; Hsiao, Chiaolong; Harvey, Stephen C.; Hud, Nicholas V.; Fox, George E.; Wartell, Roger M.; Williams, Loren Dean

doi:10.1371/journal.pone.0088222

Cited by 137 publications

(139 citation statements)

References 32 publications

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“…Thompson and Hearst combined the in solution psoralen crosslinking, 2D gel purification, photoreversal and enzymatic sequencing to discover 13 basepaired regions in the E. coli 16S rRNA (Figure 1G) (Thompson and Hearst, 1983). While most of the duplexes from crosslinking are consistent with the evolutionary model built by Noller and Woese and the crystal structure model (Noller and Woese, 1981; Petrov et al, 2014), a few of them could be artifacts of in vitro folding (see review by (Sergiev et al, 2001; Whirl-Carrillo et al, 2002)). Nevertheless, these heroic efforts demonstrated the possibility of using psoralen to study complex RNAs.…”

Section: Historical Use Of Psoralen To Analyze Rna Structures and Intsupporting

confidence: 66%

The RNA Base-Pairing Problem and Base-Pairing Solutions

Chang

2018

Cold Spring Harb Perspect Biol

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RNA molecules are folded into structures and complexes to carry out a wide variety of functions. Determination of RNA structures and their interactions is a fundamental problem in RNA biology. Most RNA molecules in living cells are large and dynamic, posing unique challenges to structure analysis. Here we review progress in RNA structure analysis, focusing on methods that employ the “crosslink, proximally ligate and sequence” principle for high-throughput detection of base-pairing interactions in living cells. Beginning with a comparison of commonly used methods in structure determination and a brief historical account of psoralen crosslinking studies, we highlight the important features of crosslinking methods and new biological insights into RNA structures and interactions from recent studies. Further improvement of these crosslinking methods and application to previously intractable problems will shed new light on the mechanisms of the “modern RNA world”.

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Section: Historical Use Of Psoralen To Analyze Rna Structures and Intsupporting

confidence: 66%

The RNA Base-Pairing Problem and Base-Pairing Solutions

Chang

2018

Cold Spring Harb Perspect Biol

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“…Asterisks indicate the 28S rRNA regions that interact with 5.8S rRNA. (B) The putative secondary structures for maternal-and somatic-type 5.8S rRNA and their interactions with the equivalent 28S rRNAs are shown (Petrov et al 2014). The region that undergoes the conformational switch and interacts with ribosome-dissociating factors is highlighted in light green (Graifer et al 2005).…”

Section: Structural and Functional Implications Of The Lsu Rrna Typesmentioning

confidence: 99%

“…The 18S conserved "sticky regions" (four major regions that are in ESs 3S, 6S, 7S, 12S, and two minor in front of the ESs 3S and 6S) were adapted from Pánek et al (2013). Zebrafish rRNAs secondary structures and structural domains were modeled after the 3D ribosome structure of Homo sapiens (http://apollo.chemistry.gatech.edu/RibosomeGallery) (Petrov et al 2014).…”

Section: Rrna Annotation and Secondary Structuresmentioning

confidence: 99%

Expression of distinct maternal and somatic 5.8S, 18S, and 28S rRNA types during zebrafish development

Locati

Pagano

Girard

et al. 2017

RNA

127

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There is mounting evidence that the ribosome is not a static translation machinery, but a cell-specific, adaptive system. Ribosomal variations have mostly been studied at the protein level, even though the essential transcriptional functions are primarily performed by rRNAs. At the RNA level, oocyte-specific 5S rRNAs are long known for Xenopus. Recently, we described for zebrafish a similar system in which the sole maternal-type 5S rRNA present in eggs is replaced completely during embryonic development by a somatic-type. Here, we report the discovery of an analogous system for the 45S rDNA elements: 5.8S, 18S, and 28S. The maternal-type 5.8S, 18S, and 28S rRNA sequences differ substantially from those of the somatic-type, plus the maternal-type rRNAs are also replaced by the somatic-type rRNAs during embryogenesis. We discuss the structural and functional implications of the observed sequence differences with respect to the translational functions of the 5.8S, 18S, and 28S rRNA elements. Finally, in silico evidence suggests that expansion segments (ES) in 18S rRNA, previously implicated in ribosome-mRNA interaction, may have a preference for interacting with specific mRNA genes. Taken together, our findings indicate that two distinct types of ribosomes exist in zebrafish during development, each likely conducting the translation machinery in a unique way.

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“…Each structure is experimentally determined by X-ray diffraction or Cryo-EM. This figure is reproduced from Petrov et al 2014b (Petrov et al 2013(Petrov et al , 2014a from four species of varying complexity. rRNA domains are indicated by color.…”

Section: Water In-water Outmentioning

confidence: 99%

The Ribosome Challenge to the RNA World

2015

Self Cite

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An RNA World that predated the modern world of polypeptide and polynucleotide is one of the most widely accepted models in origin of life research. In this model, the translation system shepherded the RNA World into the extant biology of DNA, RNA, and protein. Here, we examine the RNA World Hypothesis in the context of increasingly detailed information available about the origins, evolution, functions, and mechanisms of the translation system. We conclude that the translation system presents critical challenges to RNA World Hypotheses. Firstly, a timeline of the RNA World is problematic when the ribosome is incorporated. The mechanism of peptidyl transfer of the ribosome appears distinct from evolved enzymes, signaling origins in a chemical rather than biological milieu. Secondly, we have no evidence that the basic biochemical toolset of life is subject to substantive change by Darwinian evolution, as required for the transition from the RNA world to extant biology. Thirdly, we do not see specific evidence for biological takeover of ribozyme function by protein enzymes. Finally, we can find no basis for preservation of the ribosome as ribozyme or the universality of translation, if it were the case that other information transducing ribozymes, such as ribozyme polymerases, were replaced by protein analogs and erased from the phylogenetic record. We suggest that an updated model of the RNA World should address the current state of knowledge of the translation system.

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Secondary Structures of rRNAs from All Three Domains of Life

Cited by 137 publications

References 32 publications

The RNA Base-Pairing Problem and Base-Pairing Solutions

The RNA Base-Pairing Problem and Base-Pairing Solutions

Expression of distinct maternal and somatic 5.8S, 18S, and 28S rRNA types during zebrafish development

The Ribosome Challenge to the RNA World

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