Nathan Boyd scite author profile

Riboswitches are complex folded RNA domains found in non-coding regions of mRNA that regulate gene expression upon small molecule binding. Recently, Breaker and coworkers reported a tandem aptamer riboswitch (VCI-II) that binds glycine cooperatively. Here, we use hydroxyl radical footprinting and small-angle x-ray scattering (SAXS) to study the conformations of this tandem aptamer as a function of Mg 2+ and glycine concentration. We fit a simple three-state thermodynamic model that describes the energetic coupling between magnesium-induced folding and glycine binding. Furthermore, we characterize the structural conformations of each of the three states: In low salt with no magnesium present, the VCI-II construct has an extended overall conformation, presumably representing unfolded structures. Addition of millimolar concentrations of Mg 2+ in the absence of glycine leads to a significant compaction and partial folding as judged by hydroxyl radical protections. In the presence of millimolar Mg 2+ concentrations, the tandem aptamer binds glycine cooperatively. The glycine binding transition involves a further compaction, additional tertiary packing interactions and further uptake of magnesium ions relative to the state in high Mg 2+ but no glycine. Employing density reconstruction algorithms, we obtain low resolution 3-D structures for all three states from the SAXS measurements. These data provide a first glimpse into the structural conformations of the VCI-II aptamer, establish rigorous constraints for further modeling, and provide a framework for future mechanistic studies.

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Base-pair neutral homozygotes can be discriminated by calibrated high-resolution melting of small amplicons

Gundry

Dobrowolski

Martín

et al. 2008

Nucleic Acids Research

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Genotyping by high-resolution melting analysis of small amplicons is homogeneous and simple. However, this approach can be limited by physical and chemical components of the system that contribute to intersample melting variation. It is challenging for this method to distinguish homozygous G::C from C::G or A::T from T::A base-pair neutral variants, which comprise ∼16% of all human single nucleotide polymorphisms (SNPs). We used internal oligonucleotide calibrators and custom analysis software to improve small amplicon (42–86 bp) genotyping on the LightScanner®. Three G/C (PAH c.1155C>G, CHK2 c.1-3850G>C and candidate gene BX647987 c.261+22,290C>G) and three T/A (CPS1 c.3405-29A>T, OTC c.299-8T>A and MSH2 c.1511-9A>T) human single nucleotide variants were analyzed. Calibration improved homozygote genotyping accuracy from 91.7 to 99.7% across 1105 amplicons from 141 samples for five of the six targets. The average Tm standard deviations of these targets decreased from 0.067°C before calibration to 0.022°C after calibration. We were unable to generate a small amplicon that could discriminate the BX647987 c.261+22,290C>G (rs1869458) SNP, despite reducing standard deviations from 0.086°C to 0.032°C. Two of the sites contained symmetric nearest neighbors adjacent to the SNPs. Unexpectedly, we were able to distinguish these homozygotes by Tm even though current nearest neighbor models predict that the two homozygous alleles would be identical.

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Motions of the Substrate Recognition Duplex in a Group I Intron Assessed by Site-Directed Spin Labeling

et al. 2009

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The Tetrahymena group I intron recognizes its oligonucleotide substrate in a two-step process. First, a substrate recognition duplex, called the P1 duplex, is formed. The P1 duplex then docks into the pre-folded ribozyme core by forming tertiary contacts. P1 docking controls both the rate and the fidelity of substrate cleavage, and has been extensively studied as a model for the formation of RNA tertiary structure. However, previous work has been limited to study millisecond or slower motions. Here we investigated nanosecond P1 motions in the context of the ribozyme using site-directed spin labeling (SDSL) and electron paramagnetic resonance (EPR) spectroscopy. A nitroxide spin label (R5a) was covalently attached to a specific site of the substrate oligonucleotide, the labeled substrate was bound to a pre-folded ribozyme to form the P1 duplex, and X-band EPR spectroscopy was used to monitor nitroxide motions in the 0.1 – 50 nanosecond regime. Using substrates that favor the docked or the undocked states, it was established that R5a was capable of reporting P1 duplex motions. Using R5a-labeled substrates it was found that the J1/2 junction connecting P1 to the ribozyme core controls nanosecond P1 mobility in the undocked state. This may account for previous observations that J1/2 mutations weaken substrate binding and give rise to cryptic cleavage. This study establishes the use of SDSL to probe nanosecond dynamic behaviors of individual helices within large RNA and RNA/protein complexes. This approach may help in understanding the relationship between RNA structure, dynamics, and function.

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Low specificity of metal ion binding in the metal ion core of a folded RNA

Travers¹,

Boyd²,

Herschlag³

2007

RNA

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The structure and activity of nucleic acids depend on their interactions with metal ions. Fundamental to these interactions is the degree of specificity observed between the metal ions and nucleic acids, and a complete description of nucleic acid folding requires that we understand the nature of the interactions with metal ions, including specificity. The prior demonstration that high concentrations of monovalent cations prevent nonspecific association of divalent ions with nucleic acids provides a novel and powerful means to examine site-specific metal ion binding isolated from complicating effects of the ion atmosphere. Using these high monovalent cation solution conditions we have monitored the affinity of a series of divalent metal ions for two sitespecific metal ion binding sites in the P4-P6 domain of the Tetrahymena group I intron ribozyme. The metal ion core of this highly structured RNA binds two divalent metal ions under these conditions. Despite multiple metal ion-RNA interactions observed in the X-ray crystallographic structure of P4-P6 RNA at the metal ion binding sites, these sites exhibit low specificity among Mn 2+ , Mg 2+ , Ca 2+ , Ni 2+ , and Zn 2+ . Nevertheless, the largest divalent metal ions tested, Sr 2+ and Ba 2+ , were excluded from binding, exhibiting affinities at least two orders of magnitude weaker than observed for the other metal ions. Thus, a picture emerges of two metal ion binding sites, each with a high tolerance for metal ions with different properties but also with limits to accommodation. These limits presumably arise from steric or electrostatic features of the metal ion binding sites.

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Nathan Boyd

Structural Transitions and Thermodynamics of a Glycine-Dependent Riboswitch from Vibrio cholerae

Base-pair neutral homozygotes can be discriminated by calibrated high-resolution melting of small amplicons

Motions of the Substrate Recognition Duplex in a Group I Intron Assessed by Site-Directed Spin Labeling

Low specificity of metal ion binding in the metal ion core of a folded RNA

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