Matthew J. Plantinga scite author profile

Bulged-G motifs are ubiquitous internal RNA loops that provide specific recognition sites for proteins and RNAs. To establish the common and distinctive features of the motif we determined the structures of three variants and compared them with related structures. The variants are 27-nt mimics of the sarcin/ricin loop (SRL) from Escherichia coli 23S ribosomal RNA that is an essential part of the binding site for elongation factors (EFs). The wild-type SRL has now been determined at 1.04 A resolution, supplementing data obtained before at 1.11 A and allowing the first calculation of coordinate error for an RNA motif. The other two structures, having a viable (C2658U*G2663A) or a lethal mutation (C2658G*G2663C), were determined at 1.75 and 2.25 A resolution, respectively. Comparisons reveal that bulged-G motifs have a common hydration and geometry, with flexible junctions at flanking structural elements. Six conserved nucleotides preserve the fold of the motif; the remaining seven to nine vary in sequence and alter contacts in both grooves. Differences between accessible functional groups of the lethal mutation and those of the viable mutation and wild-type SRL may account for the impaired elongation factor binding to ribosomes with the C2658G*G2663C mutation and may underlie the lethal phenotype.

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Linkage between Substrate Recognition and Catalysis during Cleavage of Sarcin/Ricin Loop RNA by Restrictocin

Korennykh

Plantinga

Correll

et al. 2007

Biochemistry

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Restrictocin is a site-specific endoribonuclease that inactivates ribosomes by cleaving the sarcin/ricin loop (SRL) of 23S-28S rRNA. Here we present a kinetic and thermodynamic analysis of the SRL cleavage reaction based on monitoring the cleavage of RNA oligonucleotides (2-27-mers). Restrictocin binds to a 27-mer SRL model substrate (designated wild-type SRL) via electrostatic interactions to form a nonspecific ground state complex E:S. At pH 6.7, physical steps govern the reaction rate: the wild-type substrate reacts at a partially diffusion-limited rate, and a faster-reacting SRL, containing a 3'-sulfur atom at the scissile phosphate, reacts at a fully diffusion-limited rate (k2/K1/2 = 1.1 x 10(9) M-1 s-1). At pH 7.4, the chemical step apparently limits the SRL cleavage rate. After the nonspecific binding step, restrictocin recognizes the SRL structure, which imparts 4.3 kcal/mol transition state stabilization relative to a single-stranded RNA. The two conserved SRL modules, bulged-G motif and GAGA tetraloop, contribute at least 2.4 and 1.9 kcal/mol, respectively, to the recognition. These findings suggest a model of SRL recognition in which restrictocin contacts the GAGA tetraloop and the bulged guanosine of the bulged-G motif to progress from the nonspecific ground state complex (E:S) to the higher-energy-specific complex (E.S) en route to the chemical transition state. Comparison of restrictocin with other ribonucleases revealed that restrictocin exhibits a 10(3)-10(6)-fold smaller ribonuclease activity against single-stranded RNA than do the restrictocin homologues, non-structure-specific ribonucleases T1 and U2. Together, these findings show how structural features of the SRL substrate facilitate catalysis and provide a mechanism for distinguishing between cognate and noncognate RNA.

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Telomerase Suppresses Formation of ALT-Associated Single-Stranded Telomeric C-Circles

Plantinga

Pascarelli

Merkel

et al. 2013

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Telomere maintenance is an essential characteristic of cancer cells, most commonly achieved by activation of telomerase. Telomeres can also be maintained by a recombination-based mechanism, alternative lengthening of telomeres (ALT). Cells using ALT are characterized by the presence of ALT-associated promyelocytic leukemia (PML) bodies (APB), long, heterogeneously sized telomeres, extrachromosomal telomeric circular DNA, and elevated telomeric recombination. Consistent with other reports, we found that liposarcomas containing APBs, but lacking telomerase expression, always contained C-rich circles (C-circles), and these C-circles were never present in the absence of APBs, indicating a tight link between these features in ALT cells. However, a rare subgroup of tumors showing evidence of telomere maintenance by both telomerase and ALT did not contain C-circles. To test the hypothesis that telomerase expression disrupts the tight link between APBs and C-circles, we used ALT cell lines that were engineered to express telomerase. Introduction of telomerase activity in these ALT cells resulted in, on average, shorter telomeres with retention of APBs. However, at high passage, the level of C-circles was significantly reduced, which was paralleled by a switch from C-strand overhangs to G-strand overhangs. We propose that by extending critically short telomeres in these cells, telomerase is disrupting a key step in the ALT pathway necessary for production and/or maintenance of C-circles. Mol Cancer Res; 11(6); 557-67. Ó2013 AACR.

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