A Target-Lighted dsDNA-Indicator for High-Performance Monitoring of

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A Target-Lighted dsDNA-Indicator for High-Performance Monitoring of Mercury Pollution and Its Antagonists Screening Zhihe Qing, Lixuan Zhu, Xiaoxuan Li, Sheng Yang, Zhen Zou, JingRu Guo, Zhong Cao, and Ronghua Yang Environ. Sci. Technol., Just Accepted Manuscript • DOI: 10.1021/acs.est.7b02858 • Publication Date (Web): 25 Sep 2017 Downloaded from http://pubs.acs.org on September 28, 2017

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A Target-Lighted dsDNA-Indicator for High-Performance

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Monitoring of Mercury Pollution and Its Antagonists

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Screening

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Zhihe Qing,a,b,§,* Lixuan Zhu,a,§ Xiaoxuan Li,a Sheng Yang,a,b Zhen Zou,a,b Jingru

5

Guo,a Zhong Cao,a Ronghua Yang,a,b,*

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a

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Transportation, Hunan Provincial Engineering Research Center for Food Processing

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of Aquatic Biotic Resources, School of Chemistry and Biological Engineering,

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Changsha University of Science and Technology, Changsha 410114, P. R. China.

Hunan Provincial Key Laboratory of Materials Protection for Electric Power and

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b

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Chemistry and Chemical Engineering, Molecular Science and Biomedicine

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Laboratory, Hunan University, Changsha 410082, P. R. China.

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§

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*To whom correspondence should be addressed:

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E-mail: [email protected]; [email protected]; Fax: +86-731-88822523.

State Key Laboratory of Chemo/Biosensing and Chemometrics, College of

Z.Q. and L.Z. as the co-first authors contributed equally to this work.

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ABSTRACT

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As well known, the excessive discharge of heavy-metal mercury not only destroys

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the ecological environment, bust also leads to severe damage of human health after

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ingestion via drinking and bioaccumulation of food chains, and mercury ion (Hg2+) is

27

designated as one of most prevalent toxic metal ions

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high-performance monitoring of mercury pollution is necessary. Functional nucleic

29

acids have been widely used as recognition probes in biochemical sensing. In this

30

work,

31

iodine)-9H-carbazol -9-yl)] butanoate (EBCB), has been synthesized and found as a

32

target-lighted DNA fluorescent indicator. As a proof-of-concept, Hg2+ detection was

33

carried out based on EBCB and Hg2+-mediated conformation transformation of a

34

designed DNA probe. By comparison with conventional nucleic acid indicators,

35

EBCB held excellent advantages, such as minimal background interference and

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maximal sensitivity. Outstanding detection capabilities were displayed, especially

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including simple operation (add-and-read manner), ultra-rapidity (30 s), and low

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detection limit (0.82 nM). Furthermore, based on these advantages, the potential for

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high-performance screening of mercury antagonists was also demonstrated by the

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fluorescence change of EBCB. Therefore, we believe that this work is meaningful in

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pollution monitoring, environment restoration and emergency treatment, and may

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pave a way to apply EBCB as an ideal signal transducer for development of

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high-performance sensing strategies.

a

carbazole

derivative,

in drinking water. Thus, the

ethyl-4-[3,6-bis(1-methyl-4-vinylpyridium

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INTRODUCTION

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By virtue of its excellent physicochemical properties, including programmable

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coding, easy synthesis, functional stability, and outstanding recognition ability (e.g.

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Watson-Crick

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configuration matching), deoxyribonucleic acid (DNA) has been not only the carrier

50

of genetic information, but also an ideal candidate for constructing molecule probes,

51

such as molecular beacon (MB), DNAzyme and aptamer.[1-7] As well known, the

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signal conversion of DNA probes is mainly based on the transformation between

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different DNA conformations, and is always one of the concern focuses in

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constructing DNA probes.[8-12]

base-pairing,

DNA–metal

base-pairing

and

target-induced

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In the signal generation of DNA probe-based sensors, the fluorescent method has

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attracted most attention because of its multiformity, fast analysis speed and high

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sensitivity. One strategy is based on labeling technique of fluorescent dye. In this

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strategy, dyes (fluorophore and/or quencher) are labeled at the specific sites of DNA

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probes, and then the signal generation is accompanied with the recognition events

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between targets and dye-labeled DNA probes. The labeling-based strategy is widely

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used for biochemical analysis, but extensive design and modification are always

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required to prepare probes, and time-consuming optimization is generally needed to

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obtain ideal sensing performance. Another alternative strategy is dependent on

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fluorescent intercalating indicators,[13-18] which can spontaneously bind nucleic acids,

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as a label-free fluorescent strategy. Despite the simplicity and convenience of

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indicator-based methods, several deficiencies are always involved, such as high

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background interference and low sensitivity, which stem from the strong

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self-fluorescence of indicators, and/or the nonspecific fluorescence enhancement

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induced by both ssDNA and dsDNA, lacking absolute selectivity for a certain DNA

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conformation. The improving of the sensing performance, in the nucleic acid

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indicator-based sensing, is generally dependent on additional processing, such as

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enzyme-catalyzed signal amplification and nanomaterials-mediated background

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suppression.[19-22] Thus, it is of challenge and significance to synthesize and screen a

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DNA

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target-dependent lighting of fluorescence with

conformation-specific

indicator

for

biochemical

sensing,

achieving

minimal background interference.

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In this work, we were inspired to synthesize and screen a target-lighted DNA

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fluorescent indicator for highly-effective biochemical sensing. As a proof-of-concept,

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mercury ion (Hg2+), which can result in severe damage of human health after

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ingestion via drinking and bioaccumulation of food chains, and is the most poisonous

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heavy metal in drinking water,[23-25] was chosen as the model target, thymine-rich

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(T-rich) DNA was designed as the probe, thymine-Hg2+-thymine (T-Hg-T)

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base-paring was designed to mediate the probe transformation from fully-melted

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ssDNA to double-stranded or hairpin DNA.[26-28] As shown in the Figure 1, when

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conventional indicators were used to monitor the target-induced probe conformation

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transformation, there was high background interference for target detection, because

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of their strong self-fluorescence or lacking of DNA conformation selectivity in

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fluorescence lighting; and additional processing (e.g. nanomaterials-mediated

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background suppression) was needed to improve sensing performance. Attractively,

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when

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iodine)-9H-carbazol -9-yl)] butanoate (EBCB) was synthesized and used to monitor

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the target-induced probe conformation transformation, little self-fluorescence of

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EBCB and negligible effect from single-stranded probe was found, and strong

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fluorescence signal was detected from target-mediated dsDNA, resulting in minimal

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background interference and high sensitivity for target sensing. Because the lighting

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of EBCB fluorescence was completely dependent on the addition of the target, it was

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rationally named as a target-lighted DNA fluorescent indicator. By virtue of its

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minimal background interference and high sensitivity, EBCB was further exploited

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for the screening of mercury antagonists, which are desirable for emergency treatment

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and environment restoration.

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a

carbazole

derivative,

ethyl-4-[3,6-bis(1-methyl-4-vinylpyridium

EXPERIMENTAL SECTION

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Chemicals and Apparatus. All DNA sequences used in this work are listed in

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Table S1 and were purchased in Sangon Biotech Co., Ltd. (Shanghai). The

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fluorescence

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iodine)-9H-carbazol-9-yl)] butanoate (EBCB) was synthesized following our previous

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method (Figure S1).[29] Conventional nucleic acid indicators, gold view (GV), SYBR

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gold (SG), SYBR green I (SGI), and ethidium bromide (EB) were purchased from

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Dingguo Biotechnology CO., Ltd (Beijing, China). 3-(N-morpholino) propanesulfonic

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acid (MOPS), Hg(NO3)2 and other inorganic salts were obtained from Sinopharm

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Chemical Reagent Co., Ltd. (China). The MOPS buffer contained 10 mM MOPS, 150

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mM NaNO3 and 1mM Mg(NO3)2 (pH 7.2). Solutions were prepared using ultrapure

indicator,

ethyl-4-[3,6-bis(1-methyl-4-vinylpyridium

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water which was produced by a Millipore purification system (18.2 MQ resistivity).

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All pH measurements were carried out by a model 868 pH meter (Orion). The

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fluorescence spectra were carried on fluorospectrophotometer systems (PTI ASOC-10,

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Photo Technology International, Birmingham, NJ, USA).

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Screening Target-Lighted DNA-Indicators. In order to screen an ideal

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target-lighted DNA fluorescent indicator, various fluorescence dyes, including EBCB,

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GV, SG, SGI and EB, were used to monitor the Hg2+-mediated conformation change

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of thymine-rich DNA (T20). Typically, 250 nM T20 and 500 nM EBCB were mixed

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in 500 µL MOPS buffer solution (pH 7.2), then 10 µM Hg2+ was added into the above

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solution and incubated for 5 min. The signal-to-background ratio was determined by

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measuring the fluorescence intensities of the mixtures of EBCB and DNA in the

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absence and presence of Hg2+. Similarly, conventional nucleic acid indicators were

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also investigated respectively, according to the method mentioned above. Their

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fluorescence spectra were recorded on a PTI ASOC-10 Fluorescence System, with

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their maximum excitation wavelength, 470 nm for EBCB, 490 nm for SG, 495 nm for

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SGI, 495 nm for GV, 500 nm for EB.

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Monitoring Mercury Pollution. A single-stranded DNA with thymine-rich tails

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and the ideal target-lighted DNA fluorescent indicator, EBCB, were applied to direct

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detection of mercury pollution. Detailedly, 100 nM EBVB and 100 nM probe were

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added into a MOPS buffer of 500 µL, to form the EBCB/probe system. The

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fluorescence titrations were carried out via gradually adding the stock solution of

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Hg2+ in an incremental fashion. Other metal ions (10 equiv.), including Li+, K+, Ag+,

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CH3Hg+, Mg2+, Ca2+, Sr2+, Ba2+, Mn2+, Pb2+, Zn2+, Cu2+, Cd2+, Co2+, Ni2+, Sn2+, Cr3+,

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Al3+ and Fe3+, were used to investigate the selectivity of EBCB/probe toward the Hg2+

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detection.

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For the monitoring of mercury pollution in real samples, we collected two kinds of

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real water including lake water and river water from Taozi Lake beside Yuelu

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mountain and Xiangjiang River, respectively. The lake water and river water were

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filtered by a 0.22-µm syringe filter to remove insoluble material. The analytes were

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prepared by spiked real water samples without or with Hg2+ of different concentration

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levels. The detection procedure was the same as that mentioned above,all detections

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were repeated three times. The measured fluorescence intensities were used to assess

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recovery rates and standard deviations corresponding to different samples. In addition,

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for comparison, the samples were also detected by a classic method (inductively

145

coupled plasma mass spectrometry, ICP-MS), and the consistency between methods

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were evaluated.

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Screening Mercury Antagonists. To further explore the applications of our

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proposed strategy, the screening of mercury antagonists was carried out. Several

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model molecules were screened for their ability to chelate Hg2+ in aqueous solution.

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Samples were prepared by adding 100 nM HP-4T and 100 nM EBCB in 500 µL

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MOPS buffer solutions, followed by the addition of 1.0 µM Hg2+. Subsequently,

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model molecules of different concentrations, including potassium iodide (KI),

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magnesium nitrate (Mg(NO3)2), glucose, L-glutamic acid (Glu) and glutathione

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(GSH), were introduced into above system for the reaction with Hg2+, respectively.

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Finally, the antagonism effect of each antagonist on Hg2+ could be directly determined

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by the decay of fluorescence intensity. The spectra of EBCB were recorded in the

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emission wavelength from 500 to 700 nm with excitation at 470 nm.

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RESULTS AND DISCUSSION

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Screening a Target-Lighted DNA Fluorescent Indicator. As well known,

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intercalating indicators of nucleic acid have been intensely exploited and widely

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applied in biochemical sensing in past years, and contributions from them to label-free

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detection strategies have been made in some degree. However, it is unavoidable that

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some limitations, such as high background interference and low sensitivity, are still

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remained to be solved in sensing, because of strong self-fluorescence of conventional

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indicators and lack of high specificity in discriminating nucleic acid conformations.

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Improved methods to achieve high-performance sensing were always dependent on

167

additional processing, such as nanomaterial-mediated background suppression and

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enzyme-catalyzed signal amplification. Thus, it is desirable to synthesize and screen a

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DNA conformation-specific indicator, realizing target-dependent lighting of

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fluorescence with low-background interference and high sensitivity.

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Firstly, to realize target-dependent lighting of fluorescence, different DNA

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fluorescent indicators were used to monitor the target-mediated DNA conformation

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transformation. As a proof-of-concept, a poisonous and environment- contaminative

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target, mercury ion (Hg2+), was chosen as the model target, thymine-Hg2+-thymine

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(T-Hg-T) base-paring was designed to mediate the conformation transformation of a

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thymine-rich DNA from fully-melted ssDNA (T20) to dsDNA (T20-Hg2+-T20). As 8

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shown in Figure 2A and B, conventional nucleic acid indicators either don’t response

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to T20 and T20-Hg2+-T20 with strong self-fluorescence(e.g. goldview, GV), or

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response to both T20 and T20-Hg2+-T20 without absolute specificity in discriminating

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nucleic acid conformations(e.g. SYBR gold, SG). In these cases, it is not difficult to

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find that there is obvious background interference for Hg2+ sensing, leading to low

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sensitivity. Attractively, one can find that EBCB displays negligible self-fluorescence,

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little effect on its fluorescence is observed from single-stranded T20, and high

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fluorescence is observed in the presence of T20 and Hg2+ (Figure 2 C), indicating

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low-background interference and high sensitivity for Hg2+ sensing. For direct

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demonstration of detection performance, the signal-to-background ratio (F/ F0) was

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introduced (Figure 2 D), where F0 was the fluorescence intensity of each indicator in

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the presence of T20 but not Hg2+, F was that in the presence of T20 and Hg2+. It is

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obvious that an outstanding signal-to-background ratio was displayed for Hg2+

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sensing when EBCB was used as the signal reporter. Thus, EBCB has been screened

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as an ideal target-lighted dsDNA fluorescent indicator, and holds great potential for

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application in nucleic acid conformation transformation-mediated biochemical

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sensing.

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Subsequently, the mechanism of interaction between EBCB and double-stranded

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T20-Hg2+-T20 was further investigated. From the UV-Vis absorption spectra of

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EBCB/T20 system (Figure S2), one can see that there was obvious hypochromism and

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redshift with the increase of Hg2+ concentration. This was because of the formation of

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double-stranded T20-Hg2+-T20 with the addition of Hg2+ and the intercalating action

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of EBCB in the newly-formed T20-Hg2+-T20, in accordance with the fact that an

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electronic interaction between the intercalator and dsDNA bases results in the

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absorption hypochromism and redshift of the intercalator.30 Furthermore, the effect on

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the fluorescence enhancement from the electrostatic interaction between the

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negatively charged phosphate backbone of DNA and EBCB was also investigated.

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With the gradually increase of sodium chloride (NaCl) concentration in the

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EBCB/T20-Hg2+-T20 system, there is negligible change in fluorescence intensity

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(Figure S3), indicating that the electrostatic interaction between the negatively

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charged phosphate backbone of T20-Hg2+-T20 and EBCB has no effect on the

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target-dependent

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intercalating-dependent

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T20-Hg2+-T20 maybe contribute to the high DNA-conformation specificity and high

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sensitivity of Hg2+ detection.

fluorescence

enhancement

interaction

between

of

EBCB.

EBCB

Thus,

and

this

high

double-stranded

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High-Performance Monitoring of Mercury Pollution. After the screening of

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EBCB as an ideal target-lighted dsDNA fluorescent indicator, it was used for the

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monitoring of Hg2+, and a single-stranded DNA with thymine-rich tails was designed

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as the probe. When in the absence of Hg2+, the probe was in a fully-melted state, and

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EBCB was non-fluorescent; after the addition of Hg2+, the probe was mediated into a

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hairpin conformation with a stem of ten base-pairs and a loop of four cytosine

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nucleotides, and EBCB would be lighted by the double-stranded stem of the hairpin

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conformation (Figure 3A). A good feasibility was demonstrated for Hg2+ monitoring

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with very low background interference (Figure 3B), and the signal response was very

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rapid with an enough detectable signal in several seconds (Figure 3C), when EBCB

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was used as the signal reporter, and 30 s was chosen as the detection time (inset in

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Figure 3C and Figure S4). In comparison, when conventional indicators were used

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instead of EBCB, obvious interference from self-fluorescence and the effect of

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single-stranded probe on dyes could be observed (Figure S5). Thus, a much higher

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signal-to-background ratio was obtained by EBCB than other indicators.

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To get better performance for Hg2+ detection by applying EBCB, some conditions

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were optimized by the manner of signal-to-background ratio (F/F0). First, because the

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regulation of counterweight between the stem and the loop of a hairpin probe is the

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key to achieve high-performance detection, the probe DNA sequence with different

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numbers of T-Hg-T base-pairs in the stem was optimized. As shown in Figures S3 and

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Figures 3D, the sequence, HP-4T, which could form hairpin conformation with four

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T–Hg2+–T base-pairs admixed in its stem, was selected as the optimal detection probe.

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Then, buffer pH, operation temperature, and assistant magnesium ion (Mg2+)

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concentration were optimized. As shown in Figure S7-9, pH 7.2 and 25 oC were

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chosen as the optimal buffer pH and operation temperature, which is approximate to

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ambient condition and convenient for detection operation; 1 mM Mg2+ in buffer was

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optimized to assist Hg2+ detection.

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Under optimal conditions, EBCB/HP-4T was used for Hg2+ detection. First,

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EBCB/HP-4T fluorescence emission, responding to different concentrations of Hg2+,

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was recorded. As shown in Figure 4A, with the increasing of Hg2+ concentration, the

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fluorescence

emission

peak

of

EBCB

climbs

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Hg2+-concentration-dependent transformation of probe conformation. The relationship

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between signal-to-background ratio (F/F0) and Hg2+ concentration was plotted in

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Figure S10, where F was the fluorescence intensity at 550 nm in the presence of Hg2+

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of corresponding concentration, F0 was that of the blank. A good detection

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performance was displayed, with a linear detection range from 2 to 120 nM and a

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detection limit of 0.82 nM (inset in Figure S10). This high-sensitivity was due to the

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target-lighted manner of EBCB, with little background interference. Then, the

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selectivity for Hg2+ sensing was also investigated, as shown in Figure S11, a unique

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emission peak of EBCB was induced by the introduction of Hg2+, and no response to

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other ions; compared to the blank, a much higher signal-to-background ratio (F/F0)

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was displayed for Hg2+, while little change was resulted in by other ions, and an

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enough response could be detected after mixing other ions with Hg2+ (Figure 4B). In

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addition, the selectivity was investigated when in the presence of competitive ions of

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different concentrations (Figure S12), no interference was detected from competitive

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ions even at a much higher concentration (1 mM). Thus, a high selectivity was

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demonstrated for Hg2+ detection in this sensing strategy, this was because of the

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specific coordination between thymine and Hg2+.[26,27] To directly display advantages

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of this strategy, Hg2+ detection methods which were recently reported were

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summarized in Table 1. The detection capability of our strategy not only meets the

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requirement for Hg2+ detection in drinking water whose maximum level of Hg2+ is 10

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nM permitted by US Environmental Protection Agency (EPA),[31,32] but also superior

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to the developed methods, especially in simple operation, ultra-rapidity and low

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detection limit. 19,23,24,33-37

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Finally, the practical application for monitoring mercury pollution was investigated,

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different Hg2+-spiked water samples (including river and lake water) were

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simultaneously detected by our approach and a classic method (inductively coupled

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plasma mass spectrometry, ICP-MS), and the recovery percent and the consistency

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between methods were calculated to evaluate the detection performance. As shown in

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Table 2, high consistencies and satisfactory recoveries were achieved, indicating that

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the our strategy was reliable for the monitoring of Hg2+ from real water samples,

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especially significant for Hg2+ detection in drink water.

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Screening Mercury Antagonists. As well known, the ecological environment can

275

be destroyed by excessive emission of heavy metal ions, and severe damage to human

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health can be resulted in by over-ingestion of toxic ions. Thus, it is strongly necessary

277

to obtain potent antagonists of a toxic substance, for emergency treatment and

278

environment restoration.[25,38] Here, by virtue of its typical properties, including

279

minimal background interference, high sensitivity and rapid response, the proposed

280

strategy was further exploited to screen antagonists of Hg2+. If in the presence of an

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antagonist in the detected water system, the antagonist would bind with Hg2+ to form

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a stable complex, resulting in decreasement of dissociative Hg2+, disfavoring the

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conformation transformation of the probe, and dropping off the fluorescence intensity

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of EBCB. Thus, the antagonism effect can be evaluated by the fluorescence change.

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As the proof-of-concept, several model molecules were used and screened,

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including inorganic salt (KI and Mg(NO3)2), monosaccharide (glucose), amino acid

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(aminoglutaric acid, Glu) and small peptide (glutathione, GSH). After incubation of

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each model molecule with Hg2+ for 5 min, the probe HP-4T and EBCB were added

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into the above system, and fluorescence was measured. As shown in Figure 5A, one

290

can see that there was little effect on the fluorescence from Mg(NO3)2, glucose and

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Glu, while obvious decline of fluorescence intensity can be observed when KI and

292

GSH were used, indicating strong antagonism effect from KI and GSH against Hg2+.

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Then, the concentration-dependent antagonism was also investigated (Figure S13 and

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Figure 5B), with the concentration increasing of model molecules, negligible change

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of fluorescence intensity could be detected when Glu were used, while significant

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decreasement of fluorescence intensity could be observed when the antagonists KI and

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GSH were used; and a stronger antagonism from KI was implied with a large slope of

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descent than that from GSH. Therefore, these results demonstrated that this proposed

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strategy not only can used for high-performance detection of Hg2+, but also can be

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applied for the effective screening of mercury antagonists, due to its rapid response,

301

minimal background interference and high sensitivity.

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ASSOCIATED CONTENT

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Supporting Information

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More experimental results and figures as noted in text, including the sequence

305

information of DNA used in this study, the synthetic route of EBCB, UV-Vis

306

absorption spectra, effect of ionic strength on fluorescence enhancement, the

307

optimization of conditions, et. al. This material is available free of charge via the

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Internet at http://pubs.acs.org. 14

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AUTHOR INFORMATION

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Corresponding Author

311 312

* E-mail: [email protected]; [email protected]. Author Contributions

313

§

314

Notes

315

316

Z.Q. and L.Z. as the co-first authors contributed equally to this work.

The authors declare no competing financial interest.

ACKNOWLEDGMENT

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We are grateful for the financial support through the National Natural Science

318

Foundation of China (21605008, 21575018, 21505006), the Hunan Provincial Natural

319

Science Foundation (2016JJ3001), the Scientific Research Fund of Hunan Provincial

320

Education Department (16C0032, 16C0033), the Open Fund of State Key Laboratory

321

of Chemo/Biosensing and Chemometrics of Hunan University (2015003) and Hunan

322

Provincial Engineering Research Center for Food Processing of Aquatic Biotic

323

Resources (2016GCZX04).

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TOC/Abstract Art

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Figures and Tables

464 (A) conventional fluorescent indicators background interference



ssDNA





target (◆)

dsDNA

nanomaterials

target (◆)

background suppression (B) the target-lighted indicator, EBCB minimal background





465



target (◆)

dsDNA

ssDNA

466

Figure 1. DNA conformation transformation-mediated sensing based on different

467

indicators. (A) Conventional indicators generally display high background

468

interference, and additional processing (e.g. nanomaterials-mediated background

469

suppression) was exploited to improve detection performance; (B) while EBCB was

470

here synthesized and found as a target-lighted DNA fluorescent indicator, with

471

minimal background interference and high sensitivity.

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478 479 480 481

.6 .4 .2 550 600 650 Wavelength / nm

700

EBCB+T20+Hg EBCB+T20 EBCB

2+

.6

.2 0.0 500

550

600

650

700

Wavelength / nm

50 40 30

.4

20

.2

10 0

700

V

550 600 650 Wavelength / nm

G

0.0 500

.4

B

.8

.6

F / F0

Normalized fluorescence

1.0

.8

(D)

(C)

SG+T20+Hg2+ SG+T20 SG

C

0.0 500

1.0

EB

.8

GV+T20+Hg2+ GV+T20 GV

SG

1.0

(B) Normalized fluorescence

Normalized fluorescence

(A)

482 483

Figure 2. Monitoring the Hg2+-mediated T20 conformation transformation by

484

different DNA fluorescent indicators: (A) Gold View (GV), (B) SYBR Gold (SG), (C)

485

EBCB. (D) Direct demonstration of the monitoring capability by the manner of

486

signal-to-background ratio (F/ F0), where F0 was the fluorescence intensity of each

487

indicator in the presence of T20 but not Hg2+, F was that in the presence of T20 and

488

Hg2+.

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(A)

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(B) EBVB+DNA+Hg2+ EBCB+DNA EBCB

Fluorescence

1e+6

—

Hg 2+ ( )

30 s

N

6e+5

N

4e+5

N

2e+5

550

650

700

(D)

12

1e+6

10 Hg2+ HP-4T EBCB buffer

-7 T

HP

HP

5T

4T

P-

P-

3T

250 500 750 1000

-6 T

0 H

0

4 2

620 640 660

0

6

H

4e+5



8

P-

6e+5

H

8e+5

F / F0

Fluorescence

600

Wavelength / nm

(C)

495

+

EtO

= probe with T-rich tails

2e+5

-

O

0

= EBCB

=

8e+5

Time / s

496

Figure 3. (A) Schematic representation for high-performance monitoring of mercury

497

pollution based on EBCB and T-Hg-T-mediated conformation transformation of DNA

498

probe with thymine-rich tails. (B) Fluorescence spectra of EBCB under different

499

conditions. The structure of EBCB is shown and the inset is the fluorescence image

500

(left: without Hg2+, right: with Hg2+) under ultraviolet radiation, good feasibility was

501

verified for Hg2+ detection. (C) Real-time monitoring of the fluorescence of EBCB,

502

with the successive addition of reagents. The inset shows the amplified range with an

503

enlarged x axis from 615 to 665 s, ultrafast response to Hg2+ was demonstrated. (D)

504

Optimization of probe sequence by the manner of signal-to-background ratio (F/F0).

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(A) Fluorescence

1.6e+6

500 nM

1.2e+6 [Hg 2+]

8.0e+5 4.0e+5

0

0.0 550 600 650 Wavelength¡¡/nm

(B) 15 F / F0

12

700

without Hg2+ add Hg2+

9 6 3 bla nk Li K Ag Mg Ca Sr Ba Mn Pb Zn Cu Cd Co N Sni Al Fe CH Cr 3 Hg

0 510 511

Figure 4. (A) Fluorescence spectra of EBCB responding to Hg2+ of different

512

concentrations. (B) Selectivity investigation by the manner of signal-to-background

513

ratio (F/ F0), where F0 was the fluorescence intensity of EBCB (100 nM) in the

514

presence of HP-4T (100 nM), and F was that with the addition of each ion. The

515

concentration of Hg2+ was 100 nM, and other ions were at 1 µM.

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524 525

Table 1. .Comparison of Our Proposed Method with Recently Reported Hg2+

526

Detection Methods.

527

strategy

detection time / min

detection limit /nM

Ref.

nitrogen-doped carbon quantum dots

NM&

230

31

HCR- and GO-based fluorescent sensor

140

0.3

19

5

10

32

20

7.2

33

20

0.15

34

40

0.024

35

NM&

125

23

60

11

24

0.5

0.82

this work

photoinduced electron transfer fluorescent probe BSA-stabilized Pt nanozyme for peroxidase mimetics cationic polymer/DNA interaction coupling hairpin DNA-scaffolded silver nanoclusters with ExoIII-assisted target recycling amplification thioether-based fluorescent covalent organic framework diketopyrrolopyrrole amphiphile-based micelle-like fluorescent nanoparticles target-lighted DNA-indicator 528

&

The detection time is not mentioned in the article.

529 530 531 532 533 534 535 536 537 538 539 540

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541 542

Table 2. Evaluation of Monitoring Mercury Pollution in Different real Water

543

Samples. sample river water

lake water

detected (nM)

ICP-MS

recovery

consistency

(meana ±SDb)

(nM)

(%)c

(%)d

0

5.47±0.0134

6.05

25

33.00±2.2429

35.35

110.10

93.34

50

53.01±4.5660

58.92

95.07

89.97

75

77.46±5.2903

81.37

95.98

95.20

100

102.99±7.7688

96.67

97.52

106.54

0

8.98±0.0446

8.08

25

30.87±0.1256

30.90

87.60

99.92

50

57.22±1.9666

62.50

96.49

91.56

75

82.05±3.0620

80.79

97.43

101.56

100

99.00±5.7475

102.06

90.03

97.01

spiked (nM)

90.54

111.06

544

a

Mean value of three-repeated detections. bStandard deviation. cRecovery percent

545

which was calculated by the formula (Cd-C0)/Cs, where C0 was the concentration of

546

the no-spiked sample measured by our approach, Cs was the spiked concentration, and

547

Cd was the concentration in each spiked sample measured by our approach.

548

d

549

the concentration measured by our approach, CICP-MS was that measured by ICP-MS.

Consistency percent which was calculated by the formula Cd/CICP-MS, where Cd was

550 551 552 553 554 555 556 557

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(A) Black Glu Mg(NO3)2

Fluorescence

1.6e+6 1.2e+6

glucose GSH KI

8.0e+5 4.0e+5 0.0 500

Normalized fluorescence

(B)

560

550 600 650 Wavelength / nm

700

1.0 .8

Glu GSH KI Glu

.6 .4 GSH KI

.2 0.0 0

2 4 6 [antagonist] / µM

8

561

Figure 5. Screening mercury antagonists by the proposed strategy. (A) Fluorescence

562

spectra of EBCB and HP-4T after the incubation of Hg2+ (1.0 µM) with different

563

model molecules. (B) Demonstration of concentration-dependent antagonism. The

564

fluorescence intensity of the EBCB/HP-4T system in the presence of 1.0 µM Hg2+

565

was normalized as 1.0.

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