Pyrimidine motif triple helix in the
            <i>Kluyveromyces lactis</i>
            telomerase RNA pseudoknot is essential for function in vivo

Cash, Darian D.; Cohen-Zontag, Osnat; Kim, Nak-Kyoon; Shefer, Kinneret; Brown, Yogev; Ulyanov, Nikolai B.; Tzfati, Yehuda; Feigon, Juli

doi:10.1073/pnas.1309590110

Cited by 59 publications

(74 citation statements)

References 55 publications

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“…1), however, mutations in this region in the context of larger yeast telomerase RNAs have resulted in only a slight decrease in activity in vivo and in vitro (Lin et al 2004;Shefer et al 2007;Qiao and Cech 2008). These base triples have been previously proposed based on thermodynamic characterization and were observed in Kluyveromyces lactis (Liu et al 2012;Cash et al 2013) and their main function is likely to favor pseudoknot formation and stability without directly contributing to catalysis.…”

Section: Resultsmentioning

confidence: 98%

Refined secondary-structure models of the core of yeast and human telomerase RNAs directed by SHAPE

Niederer

Zappulla

2014

RNA

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Telomerase catalyzes the addition of nucleotides to the ends of chromosomes to complete genomic DNA replication in eukaryotes and is implicated in multiple diseases, including most cancers. The core enzyme is composed of a reverse transcriptase and an RNA subunit, which provides the template for DNA synthesis. Despite extensive divergence at the sequence level, telomerase RNAs share several structural features within the catalytic core, suggesting a conserved enzyme mechanism. We have investigated the structure of the core of the human and yeast telomerase RNAs using SHAPE, which interrogates flexibility of each nucleotide. We present improved secondary-structure models, refined by addition of five base triples within the yeast pseudoknot and an alternate pairing within the human-specific element J2a.1 in the human pseudoknot, both of which have implications for thermodynamic stability. We also identified a potentially structured CCC region within the template that may facilitate substrate binding and enzyme mechanism. Overall, the SHAPE findings reveal multiple similarities between the Saccharomyces cerevisiae and Homo sapiens telomerase RNA cores.

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Section: Resultsmentioning

confidence: 98%

Refined secondary-structure models of the core of yeast and human telomerase RNAs directed by SHAPE

Niederer

Zappulla

2014

RNA

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“…3C), where the loop 1-stem 2 base pairs stack on stem 1. Triple helices formed between loop 1 and stem 2 at the junction between the two stems of an H-type pseudoknot are a frequent feature in, for example, telomerase pseudoknots (41,42) and other riboswitches (33-35, 43, 44).…”

Section: Resultsmentioning

confidence: 99%

“…In the NMR conditions (60 mM KCl, 3 mM CaCl 2 ; pH 6.3), the riboswitch construct used for NMR (WT) has a K D of 75 ± 10 nM, and the full-length riboswitch including P1 (WT+P1) has a slightly weaker K D of 220 ± 30 nM. Deletion of residues 36-49 [ΔP4 (36)(37)(38)(39)(40)(41)(42)(43)(44)(45)(46)(47)(48)(49)], which include all of P4 and the two flanking C residues, from the NMR construct decreased the binding affinity by 20-fold, to 2,000 ± 300 nM. A similar result (K D = 2,000 nM) was obtained from 2-aminopurine fluorescence measurements on the Spn preQ 1 -II riboswitch with only P4 deleted (equivalent residues 37-48) (40).…”

Section: Resultsmentioning

confidence: 99%

“…Examination of NMR spectra of ΔP4 (36)(37)(38)(39)(40)(41)(42)(43)(44)(45)(46)(47)(48)(49) showed that deletion of P4 stabilizes P3 base pairs; imino proton resonances for the top five of the six base pairs of P3 were seen in the absence of preQ 1 (Fig. S4B), whereas in the WT construct only A55-U14, G54-U15, and G53-C16 base pairs were observed (Fig.…”

Section: Resultsmentioning

confidence: 99%

“…Two hundred initial structures of preQ 1 riboswitch bound to preQ 1 were calculated using Xplor-NIH 2.9.8 starting from an extended, unfolded RNA oligomer using NOE distance and dihedral angle restraints, quantified as described previously (33,41,42), following standard Xplor protocols. The 100 lowest-energy structures were further refined.…”

Section: Methodsmentioning

confidence: 99%

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Structural determinants for ligand capture by a class II preQ ₁ riboswitch

Kang

Eichhorn²,

Feigon

2014

Proc. Natl. Acad. Sci. U.S.A.

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Prequeuosine (preQ 1 ) riboswitches are RNA regulatory elements located in the 5′ UTR of genes involved in the biosynthesis and transport of preQ 1 , a precursor of the modified base queuosine universally found in four tRNAs. The preQ 1 class II (preQ 1 -II) riboswitch regulates preQ 1 biosynthesis at the translational level. We present the solution NMR structure and conformational dynamics of the 59 nucleotide Streptococcus pneumoniae preQ 1 -II riboswitch bound to preQ 1 . Unlike in the preQ 1 class I (preQ 1 -I) riboswitch, divalent cations are required for high-affinity binding. The solution structure is an unusual H-type pseudoknot featuring a P4 hairpin embedded in loop 3, which forms a three-way junction with the other two stems. 13 C relaxation and residual dipolar coupling experiments revealed interhelical flexibility of P4. We found that the P4 helix and flanking adenine residues play crucial and unexpected roles in controlling pseudoknot formation and, in turn, sequestering the Shine-Dalgarno sequence. Aided by divalent cations, P4 is poised to act as a "screw cap" on preQ 1 recognition to block ligand exit and stabilize the binding pocket.Comparison of preQ 1 -I and preQ 1 -II riboswitch structures reveals that whereas both form H-type pseudoknots and recognize preQ 1 using one A, C, or U nucleotide from each of three loops, these nucleotides interact with preQ 1 differently, with preQ 1 inserting into different grooves. Our studies show that the preQ 1 -II riboswitch uses an unusual mechanism to harness exquisite control over queuosine metabolism.R iboswitches are functional noncoding RNA elements often found at the 5′ end of genes that bind to effector molecules, usually metabolites, to attenuate gene expression (1-8). They generally contain two modular elements, an aptamer that binds directly to a cognate ligand, followed by an expression platform that carries out the regulatory function. Ligand binding induces a conformational rearrangement in the aptamer domain, which is transduced to the expression platform, turning gene expression on or off at the transcription or translation level.Structural studies of diverse riboswitches bound to their cognate ligands have revealed that they have evolved various strategies for high-affinity and specific binding between RNA receptors and ligands. In general, the aptamer domain enfolds the ligand, forming a highly complex 3D conformation using a host of tertiary interactions, including base triples, kink turns, ribose zippers, A-minor motifs, loop-loop interactions, and pseudoknots (9-11). Some riboswitches require divalent cations for ligand binding (9, 12-16), whereas in others divalent cations stabilize the bound state (17-21). Some ligands, including S-adenosyl methionine (22), S-adenosyl homocysteine (22, 23), cyclic di-GMP (24, 25), and prequeuosine (preQ 1 ) (26, 27), have more than one class of riboswitch, with each class adopting a different 3D fold to achieve recognition of the same ligand.Two classes of riboswitches that bind preQ 1 , a precursor t...

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Ein stabil protoniertes Adenin‐Nukleotid mit einem extrem verschobenen pK_a‐Wert stabilisiert die Tertiärstruktur eines GTP‐bindenden RNA‐Aptamers

et al. 2016

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RNA-Tertiärstrukturmotive werden durch viele verschiedene Wasserstoffbrücken stabilisiert. Protonierte Aund C-Nukleotide werden normalerweise nicht als geeignete Bausteine fürsolcheMotive betrachtet, da ihre pK a -Werte weit vom physiologischen pH-Wert entfernt sind. Hier beschreiben wir die NMR-Struktur eines in vitro selektierten GTP-bindenden RNA-Aptamers gebunden an GTP mit einer sehr komplexen Tertiärstruktur.Esenthält ein neuartiges,durch ein protoniertes As tabilisiertes Basenquartett. Aufgrund der besonderen strukturellen Umgebung innerhalb des Basenquartetts im GTP-Komplex ist der pK a -Wert fürd ie Protonierung dieses A-Nukleotides im Vergleichz um pK a -Wert fürA -Nukleotide in einzelsträngiger RNAu mm ehr als fünf pH-Einheiten verschoben. Dies ist die grçßte bisher beschriebene Verschiebung des pK a -Wertes füre in Ai ns trukturierten Nukleinsäuren. Sowohl die Vorfaltung der RNAa ls auchd ie Ligandenbindung tragen zu dieser Verschiebung des pK a -Wertes bei.

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Pyrimidine motif triple helix in the Kluyveromyces lactis telomerase RNA pseudoknot is essential for function in vivo

Cited by 59 publications

References 55 publications

Refined secondary-structure models of the core of yeast and human telomerase RNAs directed by SHAPE

Refined secondary-structure models of the core of yeast and human telomerase RNAs directed by SHAPE

Structural determinants for ligand capture by a class II preQ ₁ riboswitch

Ein stabil protoniertes Adenin‐Nukleotid mit einem extrem verschobenen pK_a‐Wert stabilisiert die Tertiärstruktur eines GTP‐bindenden RNA‐Aptamers

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Pyrimidine motif triple helix in the Kluyveromyces lactis telomerase RNA pseudoknot is essential for function in vivo

Cited by 59 publications

References 55 publications

Refined secondary-structure models of the core of yeast and human telomerase RNAs directed by SHAPE

Refined secondary-structure models of the core of yeast and human telomerase RNAs directed by SHAPE

Structural determinants for ligand capture by a class II preQ 1 riboswitch

Ein stabil protoniertes Adenin‐Nukleotid mit einem extrem verschobenen pKa‐Wert stabilisiert die Tertiärstruktur eines GTP‐bindenden RNA‐Aptamers

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Product

Resources

About

Structural determinants for ligand capture by a class II preQ ₁ riboswitch

Ein stabil protoniertes Adenin‐Nukleotid mit einem extrem verschobenen pK_a‐Wert stabilisiert die Tertiärstruktur eines GTP‐bindenden RNA‐Aptamers