Elucidation of Nucleic Acid–Drug Interactions by Tandem Mass Spectrometry

Hari, Yvonne; Nyakas, Adrien; Stucki, Stephanie; Schürch, Stefan

doi:10.2533/chimia.2014.164

Cited by 3 publications

(4 citation statements)

References 25 publications

(33 reference statements)

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“…Historic MS-based approaches for identifying small molecules that bind to nucleic acid focused on direct MS detection of nucleic acid–small molecule complexes. 120 -126 These include approaches such as MASS (multitarget affinity/specificity screening) 127 and DOLCE-MS (detection of oligonucleotide ligand complexes by ESI-MS). 128 Limitations due to buffer restraints (MS interferers, i.e., K + and Mg + ), RNA size, and the need for high mass resolution and accurate mass detection hinder the use of these approaches for general large-scale screening for small molecules targeting RNA.…”

Section: Label-free Methods For Identifying Rna Bindersmentioning

confidence: 99%

Target-Directed Approaches for Screening Small Molecules against RNA Targets

et al. 2020

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RNA molecules have a variety of cellular functions that can drive disease pathologies. They are without a doubt one of the most intriguing yet controversial small-molecule drug targets. The ability to widely target RNA with small molecules could be revolutionary, once the right tools, assays, and targets are selected, thereby defining which biomolecules are targetable and what constitutes drug-like small molecules. Indeed, approaches developed over the past 5–10 years have changed the face of small molecule–RNA targeting by addressing historic concerns regarding affinity, selectivity, and structural dynamics. Presently, selective RNA–protein complex stabilizing drugs such as branaplam and risdiplam are in clinical trials for the modulation of SMN2 splicing, compounds identified from phenotypic screens with serendipitous outcomes. Fully developing RNA as a druggable target will require a target engagement-driven approach, and evolving chemical collections will be important for the industrial development of this class of target. In this review we discuss target-directed approaches that can be used to identify RNA-binding compounds and the chemical knowledge we have today of small-molecule RNA binders.

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Section: Label-free Methods For Identifying Rna Bindersmentioning

confidence: 99%

Target-Directed Approaches for Screening Small Molecules against RNA Targets

et al. 2020

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“…63, 66 Labile modified nucleosides can yield strong neutral loss pathways that dominate the MS/MS spectrum (Table 1). Figure 7 illustrates the effect of labile modifications on mass spectral data.…”

Section: Developments In Techniques and Instrumentationmentioning

confidence: 99%

“…53 As the number of MS/MS investigations of modified RNAs has increased, modification-specific fragmentation patterns have been observed in several cases. 63,66 Labile modified nucleosides can yield strong neutral loss pathways that dominate the MS/MS spectrum (Table 1). Fig.…”

Section: Tandem Mass Spectrometrymentioning

confidence: 99%

Mass spectrometry of modified RNAs: recent developments

Wetzel

Limbach

2016

Analyst

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A common feature of ribonucleic acids (RNAs) is that they can undergo a variety of chemical modifications. As nearly all of these chemical modifications result in an increase in the mass of the canonical nucleoside, mass spectrometry has long been a powerful approach for identifying and characterizing modified RNAs. Over the past several years, significant advances have been made in method development and software for interpreting tandem mass spectra resulting in approaches that can yield qualitative and quantitative information on RNA modifications, often at the level of sequence specificity. We discuss these advances along with instrumentation developments that have increased our ability to extract such information from relatively complex biological samples. With the increasing interest in how these modifications impact the epitranscriptome, mass spectrometry will continue to play an important role in bioanalytical investigations revolving around RNA.

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“…The research of the interaction between toxic drugs and DNA has enabled to elucidate the implications in DNA structural modifications, and the mechanistic and cytotoxic aspects of the drugs physiological action. Different methods, such as AFM , capillary and gel electrophoresis , fluorescence , FTIR , tandem mass , NMR , Raman , UV‐Visible spectroscopies, surface plasmon resonance , viscosimetry and electrochemistry have been applied.…”

Section: Introductionmentioning

confidence: 99%

Antileishmanial Drug Miltefosine‐dsDNA Interaction in situ Evaluation with a DNA‐Electrochemical Biosensor

Machini

Oliveira-Brett

2017

Electroanalysis

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Leishmaniasis is one of the most important parasitic neglected disease. The electrochemical evaluation of the antileishmanial drug miltefosine-dsDNA interaction was investigated in incubated solutions and using dsDNA-electrochemical biosensors, following the changes in the oxidation peaks of guanosine and adenosine residues, and the occurrence of the free guanine residues, electrochemical signal. The electrochemical behaviour of miltefosine was also investigated, at a glassy carbon electrode, using cyclic, differential pulse and square wave voltammetry and no electrochemical redox processes were observed. The interaction mechanism of miltefosinedsDNA occurs in two ways: independent of the dsDNA sequence, and leading to the condensation/aggregation of DNA strands, producing a rigid miltefosine-dsDNA complex structure, and a preferential interaction between the guanine hydrogen atoms in the CÀG base pair and miltefosine, causing the release of guanine residues detected on the electrode surface. Miltefosine did not induce oxidative damage to DNA in the experimental conditions used.

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Elucidation of Nucleic Acid–Drug Interactions by Tandem Mass Spectrometry

Cited by 3 publications

References 25 publications

Target-Directed Approaches for Screening Small Molecules against RNA Targets

Target-Directed Approaches for Screening Small Molecules against RNA Targets

Mass spectrometry of modified RNAs: recent developments

Antileishmanial Drug Miltefosine‐dsDNA Interaction in situ Evaluation with a DNA‐Electrochemical Biosensor

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