Structural Basis of the Highly Efficient Trapping of the HIV Tat Protein by an RNA Aptamer

AbstractAn RNA aptamer containing two binding sites exhibits extremely high affinity to the HIV Tat protein. We have determined the structure of the aptamer complexed with two argininamide molecules. Two adjacent U:A:U base triples were formed, which widens the major groove to make space for the two argininamide molecules. The argininamide molecules bind to the G bases through hydrogen bonds. The binding is stabilized through stacking interactions. The structure of the aptamer complexed with a Tat-derived arginine-rich peptide was also characterized. It was suggested that the aptamer structure is similar for both complexes and that the aptamer interacts with two different arginine residues of the peptide simultaneously at the two binding sites, which could explain the high affinity to Tat

Intra-Accumbens Injection of a Dopamine Aptamer Abates MK-801-Induced Cognitive Dysfunction in a Model of Schizophrenia

Systemic administration of the noncompetitive NMDA-receptor antagonist, MK-801, has been proposed to model cognitive deficits similar to those seen in patients with schizophrenia. The present work investigated the ability of a dopamine-binding DNA aptamer to regulate these MK-801-induced cognitive deficits when injected into the nucleus accumbens. Rats were trained to bar press for chocolate pellet rewards then randomly assigned to receive an intra-accumbens injection of a DNA aptamer (200 nM; n = 7), tris buffer (n = 6) or a randomized DNA oligonucleotide (n = 7). Animals were then treated systemically with MK-801 (0.1 mg/kg) and tested for their ability to extinguish their bar pressing response. Two control groups were also included that did not receive MK-801. Data revealed that injection of Tris buffer or the random oligonucleotide sequence into the nucleus accumbens prior to treatment with MK-801 did not reduce the MK-801-induced extinction deficit. Animals continued to press at a high rate over the entire course of the extinction session. Injection of the dopamine aptamer reversed this MK-801-induced elevation in lever pressing to levels as seen in rats not treated with MK-801. Tests for activity showed that the aptamer did not impair locomotor activity. Results demonstrate the in vivo utility of DNA aptamers as tools to investigate neurobiological processes in preclinical animal models of mental health disease

Rational in silico design of aptamers for organophosphates based on the example of paraoxon

The file attached to this record is the author's final peer reviewed version. The Publisher's final version can be found by following the DOI link.Poisoning by organophosphates (OPs) takes one of the leading places in the total number of exotoxicoses. Detoxication of OPs at the first stage of the poison entering the body could be achieved with the help of DNA- or RNA-aptamers, which are able to bind poisons in the bloodstream. The aim of the research was to develop an approach to rational in silico design of aptamers for OPs based on the example of paraoxon. From the published sequence of an aptamer binding organophosphorus pesticides, its threedimensional model has been constructed. The most probable binding site for paraoxon was determined by molecular docking and molecular dynamics (MD) methods. Then the nucleotides of the binding site were mutated consequently and the values of free binding energy have been calculated using MD trajectories and MM-PBSA approach. On the basis of the energy values, two sequences that bind paraoxon most efficiently have been selected. The value of free binding energy of paraoxon with peripheral anionic site of acetylcholinesterase (AChE) has been calculated as well. It has been revealed that the aptamers found bind paraoxon more effectively than AChE. The peculiarities of paraoxon interaction with the aptamers nucleotides have been analyzed. The possibility of improving in silico approach for aptamer selection is discussed

Structure and Thermodynamics of Drug-RNA Aptamer Interactions

The published manuscript is available at EurekaSelect via http://www.eurekaselect.com/openurl/content.php?genre=article&doi=10.2174/1389557511313040001This mini-review will provide an overview on the recent studies of structure and thermodynamics of RNA aptamers that target drug molecules. These aptamers are studied to provide insight into RNA drug interactions. This interaction is important due to the many roles RNA plays in cell biology

Function and dynamics of aptamers: A case study on the malachite green aptamer

Aptamers are short single-stranded nucleic acids that can bind to their targets with high specificity and high affinity. To study aptamer function and dynamics, the malachite green aptamer was chosen as a model. Malachite green (MG) bleaching, in which an OH- attacks the central carbon (C1) of MG, was inhibited in the presence of the malachite green aptamer (MGA). The inhibition of MG bleaching by MGA could be reversed by an antisense oligonucleotide (AS) complementary to the MGA binding pocket. Computational cavity analysis of the NMR structure of the MGA-MG complex predicted that the OH- is sterically excluded from the C1 of MG. The prediction was confirmed experimentally using variants of the MGA with changes in the MG binding pocket. This work shows that molecular reactivity can be reversibly regulated by an aptamer-AS pair based on steric hindrance. In addition to demonstrate that aptamers could control molecular reactivity, aptamer dynamics was studied with a strategy combining molecular dynamics (MD) simulation and experimental verification. MD simulation predicted that the MG binding pocket of the MGA is largely pre-organized and that binding of MG involves reorganization of the pocket and a simultaneous twisting of the MGA terminal stems around the pocket. MD simulation also provided a 3D-structure model of unoccupied MGA that has not yet been obtained by biophysical measurements. These predictions were consistent with biochemical and biophysical measurements of the MGA-MG interaction including RNase I footprinting, melting curves, thermodynamic and kinetic constants measurement. This work shows that MD simulation can be used to extend our understanding of the dynamics of aptamer-target interaction which is not evident from static 3D-structures. To conclude, I have developed a novel concept to control molecular reactivity by an aptamer based on steric protection and a strategy to study the dynamics of aptamer-target interaction by combining MD simulation and experimental verification. The former has potential application in controlling metabolic reactions and protein modifications by small reactants and the latter may serve as a general approach to study the dynamics of aptamer-target interaction for new insights into mechanisms of aptamer-target recognition

Exploring Ligand Structure and Thermodynamics of the Malachite Green RNA Aptamer

RNA aptamers are in vitro sequences of RNA that have a high affinity for their target ligand. They have applications in therapeutics, biosensors and molecular machines. While the practical applications of aptamers are increasing, it is important to study their structure and thermodynamics to improve the understanding of these molecular tools. The malachite green aptamer (MGA) provides a model system to study the interactions between aptamer and ligand that do not involve hydrogen bonding between ligand and receptor. While the original application of this aptamer was abandoned, study of the MGA binding pocket revealed an electronegative environment that was harnessed for catalysis. MGA binding also supported the notion that aptamers bind by adaptive binding. Adaptive binding is the ability of molecules to mold themselves around the structure of a ligand thereby incorporating it into their three-dimensional fold. To further expand our understanding of MGA binding and to clarify conflicting reports of affinities, we conducted isothermal calorimetry binding studies. The results reveal that the entropy of complex formation plays a large role in determining binding affinity and ligand specificity. This data combined with previous structural studies show that metal ions are required to stabilize the complexes with non-native ligands, whereas, the complex with the original selection target is stable at low salt and in the absence of divalent metal ions. Next, competitive binding studies using isothermal titration calorimetry were conducted with the aim of understanding the adaptive nature of RNA. The results of these studies reveal that there are limits to the adaptability of the aptamer. Binding of one type of ligand reduces the affinity of the aptamer pocket to a differently shaped ligand, even if this second ligand has a significantly higher affinity. The ability of MGA to change ligand preference based on buffer conditions, and the previously reported catalysis suggested that RNA may have a potential supporting multiple functions in the same molecule. To investigate this possibility we attempted to select an aptamer that supports both ligand binding and catalysis. By conducting both a DNA and RNA selection we hoped to add to the iv collection of DNA and RNA aptamers selected for the same target. There are currently too few of these to determine if any correlation can be made between DNA and RNA sequences that bind the same target. The target of the selection was fluorescein diacetate (FDA), which was chosen with the aim that it would allow the exploration of the inherent potential of the selected aptamer to cleave FDA to fluorescein. The RNA selection proved to be more successful and an attempt was made to characterize the binding of the aptamer to its target fluorescein diacetate. Unfortunately there were complications with the binding assays, but future work is proposed that should address the issues. In order to expand the MGA catalytic repertoire attempts were made to synthesize new ligands that could exploit the catalytic potential of the MGA binding pocket. Unfortunately these attempts were unsuccessful, however further attempts are recommended. The MGA used in this study was transcribed in vitro using T7 RNA polymerase. This process is known to add extra nucleotides to the end of the transcription product. Attempts were made to eliminate the n+1 product by introducing a ribozyme or DNAzyme. These were met with difficulties resulting in low yield, however mass spectrometry revealed that n and n+1 MGA bind to ligand. This, along with secondary structure prediction suggests that MGA n+1 behaves the same as n. Overall, the results presented here provide insights into the capabilities of RNA aptamers with respect to ligand binding and catalysis