A Small-Molecule Approach to Bypass In Vitro Selection of New Aptamers: Designer Pre-Ligands Turn Baby Spinach into Sensors for Reactive Inorganic Targets.
Tushar AggarwalLiming WangBryan GutierrezHakan GuvenHuseyin ErguvenEnver Cagri IzguPublished in: bioRxiv : the preprint server for biology (2023)
Fluorescent light-up aptamer (FLAP) systems are promising biosensing platforms that can be genetically encoded. Here, we describe how a single FLAP that works with specific organic ligands can detect multiple, structurally unique, non-fluorogenic, and reactive inorganic targets. We developed 4- O -functionalized benzylidene imidazolinones as pre-ligands with suppressed fluorescent binding interactions with the RNA aptamer Baby Spinach. Inorganic targets, hydrogen sulfide (H 2 S) or hydrogen peroxide (H 2 O 2 ), can specifically convert these pre-ligands into the native benzylidene imidazolinones, and thus be detected with Baby Spinach. Adaptation of this approach to live cells opened a new opportunity for top-down construction of whole-cell sensors: Escherichia coli transformed with a Baby Spinach-encoding plasmid and incubated with pre-ligands generated fluorescence in response to exogenous H 2 S or H 2 O 2 . Our approach eliminates the requirement of in vitro selection of a new aptamer sequence for molecular target detection, allows for the detection of short-lived targets, thereby advancing FLAP systems beyond their current capabilities. Leveraging the functional group reactivity of small molecules can lead to cell-based sensors for inorganic molecular targets, exploiting a new synergism between synthetic organic chemistry and synthetic biology.
Keyphrases
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- hydrogen peroxide
- escherichia coli
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- sensitive detection
- quantum dots
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- living cells
- cell therapy
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- induced apoptosis
- loop mediated isothermal amplification
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- magnetic nanoparticles
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- mass spectrometry
- cell cycle arrest
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