A Small-Molecule Approach to Bypass In Vitro Selection of New Aptamers: Designer Pre-Ligands Turn Baby Spinach into Sensors for Reactive Inorganic Targets.

IF 1.1 4区生物学 Q4 PARASITOLOGY

Helminthologia Pub Date : 2023-12-13 DOI:10.1101/2023.07.29.551132

Tushar Aggarwal, Liming Wang, Bryan Gutierrez, Hakan Guven, Huseyin Erguven, Enver Cagri Izgu

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引用次数: 0

Abstract

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 (H₂S) or hydrogen peroxide (H₂O₂), 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 H₂S or H₂O₂. 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.

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绕过体外筛选新抗配体的小分子方法：设计预配体将小菠菜变成反应性无机目标的传感器。

荧光增亮拟合物（FLAP）系统是一种可以进行基因编码的前景广阔的生物传感平台。在这里，我们描述了与特定有机配体配合使用的单个 FLAP 如何检测多个结构独特、无氟和反应性无机目标。我们开发了 4- O-官能化的苯亚咪唑啉酮作为前配体，与 RNA 合体 "菠菜宝宝 "具有抑制荧光结合的相互作用。无机目标物硫化氢（H 2 S）或过氧化氢（H 2 O 2）可将这些前配体特异性地转化为原生的亚苄基咪唑啉酮，从而用 Baby Spinach 进行检测。将这种方法应用于活细胞为自上而下构建全细胞传感器提供了新的机会：用菠菜宝宝编码质粒转化大肠杆菌，并与前配体培养，在外源 H 2 S 或 H 2 O 2 的作用下产生荧光。我们的方法无需体外选择用于分子目标检测的新适配体序列，允许检测短寿命目标，从而使 FLAP 系统超越了其现有能力。利用小分子的官能团反应性，可以开发出基于细胞的无机分子目标传感器，利用合成有机化学和合成生物学之间的新协同作用。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Helminthologia 生物-动物学

CiteScore

1.80

自引率

0.00%

发文量

审稿时长

>12 weeks

期刊介绍： Helminthologia (HELMIN), published continuously since 1959, is the only journal in Europe that encompasses the individual and collaborative efforts of scientists working on a different topics of human, veterinary and plant helminthology. The journal responsibility is to enrich the theoretical and practical knowledge in very specific areas and thus contribute to the advancements in human and veterinary medicine and agronomy. Taking the advantage of comprehensive and multidisciplinary approaches journal still maintains its original spirit and is principal source of fresh scientific information regarding helminths, endoparasites and plant parasites. Addressing the most up-to date topics journal gained rightful and exceptional place next to the other high-quality scientific journals publishing in its field.