Detection of low-abundance point mutations by competitive strand assisted endonuclease IV signal amplification system

Fei Xiong; Chuan-zhen Liu; Wang-qiang Li; Zi-qiang Dong; Jie Zhang

doi:10.1007/s11596-017-1808-7

Current Medical Science ›› 2017, Vol. 37 ›› Issue (5) : 803 -806. DOI: 10.1007/s11596-017-1808-7

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Detection of low-abundance point mutations by competitive strand assisted endonuclease IV signal amplification system

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Abstract

Genetic mutations are important molecular biomarkers for cancer diagnosis and surveillance. Therefore, the development of methods for mutation detection characterized with straightforward, highly specific and sensitive to low-level mutations within various sequence contexts is extremely needed. Although some of the currently available methods have shown very encouraging results, their discrimination efficiency is still very low. Herein, we demonstrate a fluorescent probe coupled with blocker and property of melting temperature discrimination, which is able to identify the presence of known or unknown single-base variations at abundances down to 0.1% within 20 min. The discrimination factors between the perfect-match target and single-base mismatched target are determined to be 10.15–38.48. The method is sequence independent, which assures a wide range of application. The new method would be an ideal choice for high-throughput in vitro diagnosis and precise clinical treatment.

Keywords

low-abundance point mutation / competitive DNA probe / endonuclease IV / melting temperature discrimination

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Fei Xiong, Chuan-zhen Liu, Wang-qiang Li, Zi-qiang Dong, Jie Zhang. Detection of low-abundance point mutations by competitive strand assisted endonuclease IV signal amplification system. Current Medical Science, 2017, 37(5): 803-806 DOI:10.1007/s11596-017-1808-7

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References

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[1]	WaltzTL, MarrasS, RochfordG, et al. . Development of a molecular-beacon assay to detect the G(1896)A precore mutation in hepatitis B virus-infected individuals. J Clin Microbiol, 2005, 43(1): 254-258 PMID: 15634980 PMCID: 540133

[2]	WangL, YangCJ, MedleyCD, et al. . Locked nucleic acid molecular beacons. J Am ChemSoc, 2005, 127(45): 15664-15665

[3]	TyagiS, KramerFR. Molecular beacons: Probes that Fluoresce upon hybridization. Nature Biotechnol, 1996, 14(3): 303-308

[4]	SuX, ZhangC, ZhaoM. Discrimination of the false-positive signals of molecular beacons by combination of heat inactivation and using single walled carbon nanotubes. Biosens Bioelectron, 2011, 26(8): 3596-3601 PMID: 21382709

[5]	ZhangC, SuX, LiangY, et al. . A transformer of molecular beacon for sensitive and real-time detection of phosphatases with effective inhibition of the false positive signals. Biosens Bioelectron, 2011, 28(1): 13-16 PMID: 21821409

[6]	ZhengJ, YangR, ShiM, et al. . Rationally designed molecular beacons for bioanalytical and biomedical applications. Chem Soc Rev, 2015, 44(10): 3036-3055 PMID: 25777303 PMCID: 4431697

[7]	HuS, TangW, ZhaoY, et al. . Ultra-specific discrimination of single-nucleotide mutations using sequestration-assisted molecular beacons. Chem Sci, 2017, 8(2): 1021-1026 PMID: 28451240

[8]	XiaoX, WuT, XuL, et al. . A branch-migration based fluorescent probe for straightforward, sensitive and specific discrimination of DNA mutations. Nucleic Acids Res, 2017, 45(10): e90 PMID: 28201758 PMCID: 5449635

[9]	ChenSX, ZhangDY, SeeligG. Conditionally fluorescent molecular probes for detecting single base changes in double-stranded DNA. Nature Chem, 2013, 5(9): 782-789

[10]	SuX, XiaoXJ, ZhangC, et al. . Nucleic acid fluorescent probes for biological sensing. Applied Spectroscopy, 2012, 66(11): 1249-1261 PMID: 23146180

[11]	KolpashchikovDM. Binary probes for nucleic acid analysis. Chem Rev, 2010, 110(8): 4709-4723 PMID: 20583806

[12]	LudererR, VerheulA, KortlandtW. Rapid detection of the factor V Leiden mutation by real-time PCR with TaqMan minor groove binder probes. Clin Chem, 2004, 50(4): 787-788 PMID: 15044351

[13]	StöhrK, HäfnerB, NolteO, et al. . Species-specific identification of mycobacterial 16S rRNA PCR amplicons using smart probes. Anal Chem, 2005, 77(22): 7195-7203 PMID: 16285666

[14]	LiuP, LiangH, XueL, et al. . Potential clinical significance of plasma-based KRAS mutation analysis using the COLD-PCR/Taq Man (R)-MGB probe genotyping method. Exp Therap Med, 2012, 4(1): 109-112

[15]	KieslingT, CoxK, DavidsonEA, et al. . Sequence specific detection of DNA using nicking endonuclease signal amplification (NESA). Nucleic Acids Res, 2007, 35(18): e117 PMID: 17827214 PMCID: 2094061

[16]	XiaoX, ZhangC, SuX, et al. . A universal mismatch-directed signal amplification platform for ultra-selective and sensitive DNA detection under mild isothermal conditions. Chem Sci, 2012, 3(7): 2257-2261

[17]	XiaoX, SongC, ZhangC, et al. . Ultra-selective and sensitive DNA detection by a universal apurinic/apyrimidinic probe-based endonuclease IV signal amplification system. Chem Commun, 2012, 48(14): 1964-1966

[18]	XiaoX, LiuY, ZhaoM. Endonuclease IV discriminates mismatches next to the apurinic/apyrimidinic site in DNA strands: constructing DNA sensing platforms with extremely high selectivity. Chem Commun, 2013, 49(27): 2819-2821

[19]	HosfieldDJ, GuanY, HaasBJ, et al. . Structure of the DNA repair enzyme endonuclease IV and its DNA complex: double-nucleotide flipping at abasic sites and three-metal-ion catalysis. Cell, 1999, 98(3): 397-408 PMID: 10458614

[20]	XuJ, LiL, ChenN, et al. . Endonuclease IV based competitive DNA probe assay for differentiation of low-abundance point mutations by discriminating stable single-base mismatches. Chem Commun, 2017, 53(68): 9422-9425