In this study, a novel magnetic separation-based multiple systematic evolution of ligands by exponential enrichment (SELEX) was applied to select aptamers simultaneously against three kinds of marine biotoxins, including domoic acid (DA), saxitoxin (STX), and tetrodotoxin (TTX). Magnetic reduced graphene oxide (MRGO) was prepared to adsorb unbound ssDNAs and simplify the separation step. In the multiple SELEX, after the initial twelve rounds of selection against mixed targets and the subsequent four respective rounds of selection against each single target, the three resulting ssDNA pools were cloned, sequenced, and analyzed. Several aptamer candidates were selected and subjected to the binding affinity and specificity test. Finally, DA-06 ( K = 62.07 ± 19.97 nM), TTX-07 ( K = 44.12 ± 15.38 nM), and STX-41 ( K = 61.44 ± 23.18 nM) showed high affinity and good specificity for DA, TTX, and STX, respectively. They were also applied to detect and quantify DA, TTX, and STX successfully. The other two multitarget aptamers, DA-01 and TTX-27, were also obtained, which can bind with either DA or TTX. These aptamers provide alternative recognition molecules to antibodies for biosensor applications.
A highly selective electrochemiluminescent biosensor for the detection of target nephrotoxic toxin, ochratoxin A (OTA), was developed using a DNA aptamer as the recognition element and N-(4-aminobutyl)-N-ethylisoluminol (ABEI) as the signal-producing compound. The electrochemiluminescent aptamer biosensor was fabricated by immobilizing aptamer complementary DNA 1 sequence onto the surface of a gold-nanoparticle (AuNP)-modified gold electrode. ABEI-labeled aptamer DNA 2 sequence hybridized to DNA 1 and was utilized as an electrochemiluminescent probe. A decreased electrochemiluminescence (ECL) signal was generated upon aptamer recognition of the target OTA, which induced the dissociation of DNA 2 (ABEI-labeled aptamer electrochemiluminescent probe) from DNA 1 and moved it far away from the electrode surface. Under the optimal conditions, the decreased ECL intensity was proportional to an OTA concentration ranging from 0.02 to 3.0 ng mL(-1), with a detection limit of 0.007 ng mL(-1). The relative standard deviation was 3.8% at 0.2 ng mL(-1) (n = 7). The proposed method has been applied to measure OTA in naturally contaminated wheat samples and validated by an official method. This work demonstrates the combination of a highly binding aptamer with a highly sensitive ECL technique to design an electrochemiluminescent biosensor, which is a very promising approach for the determination of small-molecule toxins.
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