Magnetic Microbead Affinity Selection Screening (MagMASS) of Botanical Extracts for Inhibitors of 15-Lipoxygenase

Rush, Michael D.; Walker, Elisabeth M.; Burton, Tristesse; Breemen, Richard B. van

doi:10.1021/acs.jnatprod.6b00693

Cited by 19 publications

(18 citation statements)

References 23 publications

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“…Rush et al 56 used MagMASS to screen a series of North American prairie plants for inhibitors of the anti‐inflammation target 15‐lipoxygenase 45 . This work was significant in that it described the application of mass spectrometry metabolomics software (in this case XCMS online, Scripps Institute) 57 to facilitate the automation of AS‐MS data processing.…”

Section: Magnetic Microbead Affinity Selection Screeningmentioning

confidence: 99%

“…54 In a variation of MagMASS, solution-phase receptors were incubated with a mixture of ligands and then immobilized on magnetic microbeads for separation from the unbound compounds. 55 Rush et al 56 used MagMASS to screen a series of North American prairie plants for inhibitors of the anti-inflammation target 15-lipoxygenase. 45 This work was significant in that it described the application of mass spectrometry metabolomics software (in this case XCMS online, Scripps Institute) 57 to facilitate the automation of AS-MS data processing.…”

Section: Magnetic Microbead Affinity Selection Screeningmentioning

confidence: 99%

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Affinity selection–mass spectrometry for the discovery of pharmacologically active compounds from combinatorial libraries and natural products

Muchiri

Breemen

2020

J Mass Spectrom

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Invented to address the high‐throughput screening (HTS) demands of combinatorial chemistry, affinity selection–mass spectrometry (AS‐MS) utilizes binding interactions between ligands and receptors to isolate pharmacologically active compounds from mixtures of small molecules and then relies on the selectivity, sensitivity, and speed of mass spectrometry to identify them. No radiolabels, fluorophores, or chromophores are required. Although many variations of AS‐MS have been devised, three approaches have emerged as the most flexible, productive, and popular, and they differ primarily in how ligand–receptor complexes are separated from nonbinding compounds in the mixture. These are pulsed ultrafiltration (PUF) AS‐MS, size exclusion chromatography (SEC) AS‐MS, and magnetic microbead affinity selection screening (MagMASS). PUF and SEC AS‐MS are solution‐phase screening approaches, and MagMASS uses receptors immobilized on magnetic microbeads. Because pools of compounds are screened using AS‐MS, each containing hundreds to thousands of potential ligands, hundreds of thousands of compounds can be screened per day. AS‐MS is also compatible with complex mixtures of chemically diverse natural products in extracts of botanicals and fungi and microbial cultures, which often contain fluorophores and chromophores that can interfere with convention HTS. Unlike conventional HTS, AS‐MS may be used to discover ligands binding to allosteric as well as orthosteric receptor sites, and AS‐MS has been useful for discovering ligands to targets that are not easily incorporated into conventional HTS such as membrane‐bound receptors.

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Section: Magnetic Microbead Affinity Selection Screeningmentioning

confidence: 99%

Section: Magnetic Microbead Affinity Selection Screeningmentioning

confidence: 99%

Affinity selection–mass spectrometry for the discovery of pharmacologically active compounds from combinatorial libraries and natural products

Muchiri

Breemen

2020

J Mass Spectrom

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“…Whereas a detailed review of drug discovery applications using ligand fishing is beyond the scope of this discussion, , it is worth noting that this conceptual approach has been interpreted and applied in diverse ways, including within the field of natural products. ,− Notwithstanding these accounts, we noted the relative dearth of reports pertaining to the utilization of DNA as a biological target in ligand-fishing-based studies despite its favorable history as a focal point for biomedical interventions. − Considering our group’s collaborative interests in the discovery of natural products that selectively inhibit different types of pediatric and triple-negative breast cancers, − we found this point intriguing given the expansive role that DNA-targeting agents have played in the field of cancer chemotherapy. − For these reasons, our goal was to develop a ligand-fishing system that could be used for the detection and identification of DNA-binding molecules from natural product mixtures. In this report, we describe our efforts to implement a natural product drug discovery pipeline using an ultrafiltration-based assay system linked with hyphenated mass spectrometry to seamlessly detect, dereplicate, and, in some cases, identify compounds from complex mixtures of natural products.…”

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An Integrated Strategy for the Detection, Dereplication, and Identification of DNA-Binding Biomolecules from Complex Natural Product Mixtures

et al. 2020

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A fundamental factor in natural product drug discovery programs is the necessity to identify the active component(s) from complex chemical mixtures. Whereas this has traditionally been accomplished using bioassay-guided fractionation, we questioned whether alternative techniques could supplement and, in some cases, even supplant this approach. We speculated that a combination of ligand-fishing methods and modern analytical tools (e.g., LC-MS and online natural product databases) offered a route to enhance natural product drug discovery. Herein, a candidate solution referred to as the lickety-split ligand-affinity-based molecular angling system (LLAMAS) is described. This approach utilizes an ultrafiltration-based LC-PDA-MS/MS-guided DNAbinding assay in combination with the (i) Global Natural Products Social Molecular Networking, (ii) Dictionary of Natural Products, and (iii) SciFinder platforms to identify DNA binders in complex chemical mixtures. LLAMAS was initially vetted in tests using known small-molecule DNA binders and then optimized to a 96-well plate-based format. A set of 332 plant samples used in traditional Chinese medicine was screened for DNA-binding activity with LLAMAS, resulting in the identification of seven DNAbinding molecules, including berberine (12), palmatine (13), coptisine (14), fangchinoline (15), tetrandrine (16), daurisoline (17), and dauricine (18). These results demonstrate that LLAMAS is an effective natural product discovery platform for the efficient identification and dereplication of DNA-binding molecules from complex mixtures.N atural products are an important source of therapeutic drug leads due to the incredible diversity of their structures and bioactivities. 1−3 Many of the success stories to emerge from natural product drug development are legendary: the discovery of the antibiotic penicillin in 1928, 4 the identification and subsequent clinical approval of the anticancer drug Taxol (paclitaxel) in 1992, 5 the development of the antimalarial drug artemisinin (a discovery that was acknowledged by the 2015 Nobel Prize in Physiology or Medicine), 6 and more. 7 These milestones in drug discovery established natural products as an unparalleled resource for identifying therapeutically useful compounds to combat a wide range of diseases.Strikingly, a majority of these and other iconic natural products that are used as medicines 1,8,9 were discovered using the well-established, yet powerful technique known as bioassay-guided purification. 10,11 This approach relies on subjecting mixtures of compounds (e.g., extracts and fractions) to iterative steps of fractionation and biological testing with the

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“…Indirect AS–MS methods involve a four-step process (Figure ): (1) incubation of a target biomolecule, such as a protein, with a pool of small molecules, often hundreds or thousands; (2) separation of nonbinding compounds from the protein–ligand complexes; (3) dissociation of the protein–ligand complexes, and (4) identification of the ligands by MS. The different AS–MS methods mainly differ in how the protein–ligand complexes and the small molecules in solution are separated, some approaches include ultrafiltration, − immobilized protein AS, , magnetic beads, , and size-exclusion chromatography. − …”

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confidence: 99%

“…(3) dissociation of the protein−ligand complexes, and (4) identification of the ligands by MS. The different AS−MS methods mainly differ in how the protein−ligand complexes and the small molecules in solution are separated, 15 some approaches include ultrafiltration, 16−18 immobilized protein AS, 19,20 magnetic beads, 21,22 and size-exclusion chromatography. 23−31 Optimizing experimental conditions to distinguish highaffinity ligands from low-affinity ones is an essential step in AS−MS screening.…”

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confidence: 99%

Solving the Competitive Binding Equilibria between Many Ligands: Application to High-Throughput Screening and Affinity Optimization

2020

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Modern small-molecule drug discovery relies on the selective targeting of biological macromolecules by low-molecular weight compounds. Therefore, the binding affinities of candidate drugs to their targets are key for pharmacological activity and clinical use. For drug discovery methods where multiple drug candidates can simultaneously bind to the same target, a competition is established, and the resulting equilibrium depends on the dissociation constants and concentration of all the species present. Such coupling between all equilibrium-governing parameters complicates analysis and development of improved mixture-based, high-throughput drug discovery techniques. In this work, we present an iterative computational algorithm to solve coupled equilibria between an arbitrary number of ligands and a biomolecular target that is efficient and robust. The algorithm does not require the estimation of initial values to rapidly converge to the solution of interest. We explored binding equilibria under ligand/receptor conditions used in mixture-based library screening by affinity selection–mass spectrometry (AS–MS). Our studies support a facile method for affinity-ranking hits. The ranking method involves varying the receptor-to-ligand concentration ratio in a pool of candidate ligands in two sequential AS–MS analyses. The ranking is based on the relative change in bound ligand concentration. The method proposed does not require a known reference ligand and produces a ranking that is insensitive to variations in the concentration of individual compounds, thereby enabling the use of unpurified compounds generated by mixture-based combinatorial synthesis techniques.

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Magnetic Microbead Affinity Selection Screening (MagMASS) of Botanical Extracts for Inhibitors of 15-Lipoxygenase

Cited by 19 publications

References 23 publications

Affinity selection–mass spectrometry for the discovery of pharmacologically active compounds from combinatorial libraries and natural products

Affinity selection–mass spectrometry for the discovery of pharmacologically active compounds from combinatorial libraries and natural products

An Integrated Strategy for the Detection, Dereplication, and Identification of DNA-Binding Biomolecules from Complex Natural Product Mixtures

Solving the Competitive Binding Equilibria between Many Ligands: Application to High-Throughput Screening and Affinity Optimization

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