Conjugated cationic polymer-assisted amplified fluorescent biosensor for protein detection via terminal protection of small molecule-linked DNA and graphene oxide

文献类型: 外文期刊

第一作者: Zhang, Zhen

作者: Zhang, Zhen;Xia, Xiaoyang;Xiang, Xia;Huang, Fenghong;Han, Ling

作者机构:

关键词: Protein biosensor;Conjugated cationic polymer;Signal amplification;Terminal protection;Graphene oxide

期刊名称:SENSORS AND ACTUATORS B-CHEMICAL ( 影响因子:7.46; 五年影响因子:6.743 )

ISSN:

年卷期:

页码:

收录情况: SCI

摘要: Highlights ? A conjugated cationic polymer (PFP)-assisted protein detection assay is developed based on TPSMLD and GO. ? The strategy contains signal conversion and the generation of PFP-induced fluorescence resonance energy transfer. ? This sensor offers a simple, highly sensitive and selective method for protein detection. Abstract A sensitive and selective protein biosensor was proposed based on cationic conjugated polymer (PFP)-induced signal amplification with the aid of terminal protection of small molecule-linked DNA (TPSMLD) and graphene oxide (GO). The DNA probe labeled with fluorescein (FAM, P2) had a complementary sequence to the small molecule modified single-stranded DNA (P1). Taking streptavidin (SA) as the target protein, P1 labeled with biotin was digested to small nucleotide fragments by exonuclease I (Exo I) without SA. Upon adding PFP to P2-GO complex, weak fluorescence resonance energy transfer (FRET) from PFP to FAM-induced fluorescence signal was observed owing to the equal affinity for P2 and PFP toward GO. In the presence of SA, P1 was protected from the digestion of Exo I due to the specific binding between SA and biotin, releasing P2 from GO surface by hybridization to form double-stranded DNA (dsDNA). In this case, the addition of PFP led to obvious FRET signal because of strong electrostatic interactions between dsDNA and PFP. By monitoring the change of FRET signal, SA could be quantified. Compared to the strategy without PFP, the introduction of PFP showed an enhanced sensitivity with a detection limit of 1.6ngmL?1 for SA detection. Also, folate reporter was detected based on this platform with a good linear relationship, demonstrating the generality of this design. ]]>

分类号: TP212.2

  • 相关文献

[1]Sensitive detection of multiple mycotoxins by SPRi with gold nanoparticles as signal amplification tags. Hu, Weihua,Chen, Hongming,Zhang, Hilanhuan,He, Guangli,Li, Xin,Li, Chang Ming,Hu, Weihua,Chen, Hongming,Zhang, Hilanhuan,He, Guangli,Li, Xin,Li, Chang Ming,Hu, Weihua,Chen, Hongming,Zhang, Hilanhuan,He, Guangli,Li, Xin,Li, Chang Ming,Hu, Weihua,Zhang, Xiaoxing,Liu, Yang.

[2]Design of nuclease-based target recycling signal amplification in aptasensors. Yan, Mengmeng,Bai, Wenhui,Zhu, Chao,Huang, Yafei,Yan, Jiao,Chen, Ailiang,Yan, Mengmeng,Bai, Wenhui,Zhu, Chao,Huang, Yafei,Yan, Jiao,Chen, Ailiang,Huang, Yafei,Yan, Jiao.

[3]A bare-eye based one-step signal amplified semiquantitative immunochromatographic assay for the detection of imidacloprid in Chinese cabbage samples. Fang, Qingkui,Wang, Limin,Cheng, Qi,Cai, Jia,Wang, Yulong,Yang, Mingming,Hua, Xiude,Liu, Fengquan,Liu, Fengquan.

[4]Simple colorimetric DNA detection based on hairpin assembly reaction and target-catalytic circuits for signal amplification. Ma, Cuiping,Li, Zhaoxin,Wang, Qingyin,Ma, Cuiping,Wang, Wenshuo,Cao, Lijie.

[5]Label-free DNA Y junction for bisphenol A monitoring using exonuclease III-based signal protection strategy. Chen, Junhua,Zhou, Shungui.

[6]Facile fabrication of graphene oxide loaded with silver nanoparticles as antifungal materials. Cui, Jianghu,Yang, Yunhua,Zheng, Mingtao,Liu, Yingliang,Xiao, Yong,Lei, Bingfu,Chen, Wei. 2014

[7]Preparation of Tetraethylenepentamine Modified Magnetic Graphene Oxide for Adsorption of Dyes from Aqueous Solution. Tang, Xiaosheng,Tang, Xiaosheng,Tang, Xiaosheng,Tang, Ping,Liu, Liangliang,Tang, Ping. 2018

[8]Graphene oxide modulates root growth of Brassica napus L. and regulates ABA and IAA concentration. Cheng, Fan,Liu, Yu-Feng,Xie, Ling-Li,Yuan, Cheng-Fei,Xu, Ben-Bo,Lu, Guang-Yuan,Zhang, Xue-Kun.

[9]Preparation of Carriers Based on ZnO Nanoparticles Decorated on Graphene Oxide (GO) Nanosheets for Efficient Immobilization of Lipase from Candida rugosa. Zhang, Shan,Shi, Jie,Deng, Qianchun,Zheng, Mingming,Wan, Chuyun,Zheng, Chang,Li, Ya,Huang, Fenghong.

[10]Chemical instability of graphene oxide following exposure to highly reactive radicals in advanced oxidation processes. Wang, Zhaohui,Sun, Linyan,Yang, Fei,Feng, Min,Liu, Jianshe,Wang, Zhaohui,Lou, Xiaoyi.

[11]Enhanced Performance of Magnetic Graphene Oxide-Immobilized Laccase and Its Application for the Decolorization of Dyes. Chen, Jing,Leng, Juan,Yang, Xiai,Liao, Liping,Liu, Liangliang,Xiao, Aiping.

[12]Solid-phase purification and extraction for the determination of trace neonicotinoid pesticides in tea infusion. Zhang, Minglu,Chen, Hongping,Zhu, Li,Wang, Chuanpi,Ma, Guicen,Liu, Xin,Zhang, Minglu,Chen, Hongping,Zhu, Li,Wang, Chuanpi,Ma, Guicen,Liu, Xin.

[13]Graphene Oxides Decorated with Carnosine as an Adjuvant To Modulate Innate Immune and Improve Adaptive Immunity in Vivo. Meng, Chunchun,Li, Chuanfeng,Chen, Zongyan,Qiu, Xusheng,Ding, Chan,Liu, Guangqing,Zhi, Xiao,Li, Chao,Chen, Di,Cui, Daxiang,Ding, Chan,Liu, Guangqing,Ma, Lijun,Lu, Hongmin.

[14]Ultrasmall Graphene Oxide Supported Gold Nanoparticles as Adjuvants Improve Humoral and Cellular Immunity in Mice. Cao, Yuhua,Ma, Yufei,Zhang, Mengxin,Wang, Haiming,Tu, Xiaolong,Shen, He,Dai, Jianwu,Zhang, Zhijun,Cao, Yuhua,Zhang, Mengxin,Tu, Xiaolong,Shen, He,Wang, Haiming,Guo, Huichen.

[15]One-pot synthesis of magnetic zeolitic imidazolate framework/grapheme oxide composites for the extraction of neonicotinoid insecticides from environmental water samples. Cao, Xiaolin,Jiang, Zejun,Wang, Shanshan,Hong, Sihui,Li, Hui,Shao, Yong,She, Yongxin,Wang, Jing,Jin, Fen,Jin, Maojun. 2017

[16]p-Phenylenediamine Functionalized Magnetic Graphene Oxide for the Removal of Congo Red from Wastewater. Tang, Ping,Si, Shihui,Tang, Ping,Liu, Liangliang,Tang, Xiaosheng,Tang, Xiaosheng. 2016

[17]Enhanced Proliferation and Osteogenic Differentiation of Mesenchymal Stem Cells on Graphene Oxide-Incorporated Electrospun Poly(lactic-co-glycolic acid) Nanofibrous Mats. Luo, Yu,Shen, He,Cao, Yuhua,Huang, Jie,Zhang, Mengxin,Dai, Jianwu,Zhang, Zhijun,Luo, Yu,Shi, Xiangyang,Fang, Yongxiang,Dai, Jianwu,Fang, Yongxiang. 2015

[18]Graphene-based Biosensors for Biomolecules Detection. Zheng, Qing,Wu, Hao,Wang, Nan,Ding, Kejian,Ma, Yuehui,Guang, Weijun,Yan, Rui,Wang, Junzhong.

[19]Adsorption kinetics, isotherms and thermodynamics of Cr(III) on graphene oxide. Yang, Shuang,Pei, Zhiguo,Li, Chunmei,Lv, Jitao,Xie, Jieli,Wen, Bei,Zhang, Shuzhen,Li, Lingyun.

[20]Adsorption and removal of bisphenol A from aqueous solution by p-phenylenediamine-modified magnetic graphene oxide. Tang, Xiaosheng,Tang, Xiaosheng,Tang, Ping,Liu, Liangliang,Tang, Ping,Si, Shihui. 2017

作者其他论文 更多>>

微信小程序