Label-free detection of nucleic acids by turn-on and turn-off G-quadruplex-mediated fluorescence

In this study we have used two fluorescent probes, tetrakis(diisopropylguanidino)-zinc-phthalocyanine (Zn-DIGP) and N-methylmesoporphyrin IX (NMM), to monitor the reassembly of “split” G-quadruplex probes on hybridization with an arbitrary “target” DNA. According to this approach, each split probe is designed to contain half of a G-quadruplex-forming sequence fused to a variable sequence that is complementary to the target DNA. Upon mixing the individual components, both base-pairing interactions and G-quadruplex fragment reassembly result in a duplex–quadruplex three-way junction that can bind to fluorescent dyes in a G-quadruplex-specific way. The overall fluorescence intensities of the resulting complexes were dependent on the formation of proper base-pairing interactions in the duplex regions, and on the exact identity of the fluorescent probe. Compared with samples lacking any “target” DNA, the fluorescence intensities of Zn-DIGP-containing samples were lower, and the fluorescence intensities of NMM-containing samples were higher on addition of the target DNA. The resulting biosensors based on Zn-DIGP are therefore termed “turn-off” whereas the biosensors containing NMM are defined as “turn-on”. Both of these biosensors can detect target DNAs with a limit of detection in the nanomolar range, and can discriminate mismatched from perfectly matched target DNAs. In contrast with previous biosensors based on the peroxidase activity of heme-bound split G-quadruplex probes, the use of fluorescent dyes eliminates the need for unstable sensing components (H2O2, hemin, and ABTS). Our approach is direct, easy to conduct, and fully compatible with the detection of specific DNA sequences in biological fluids. Having two different types of probe was highly valuable in the context of applied studies, because Zn-DIGP was found to be compatible with samples containing both serum and urine whereas NMM was compatible with urine, but not with serum-containing samples.

[1]  K. Plaxco,et al.  Sensitive and selective amplified fluorescence DNA detection based on exonuclease III-aided target recycling. , 2010, Journal of the American Chemical Society.

[2]  Weiwei Guo,et al.  Highly sequence-dependent formation of fluorescent silver nanoclusters in hybridized DNA duplexes for single nucleotide mutation identification. , 2010, Journal of the American Chemical Society.

[3]  Chun-Yang Zhang,et al.  Single quantum dot-based nanosensor for multiple DNA detection. , 2010, Analytical chemistry.

[4]  S. Neidle,et al.  Structure-specific recognition of quadruplex DNA by organic cations: influence of shape, substituents and charge. , 2007, Biophysical chemistry.

[5]  Yalin Tang,et al.  Verification of specific G-quadruplex structure by using a novel cyanine dye supramolecular assembly: I. recognizing mixed G-quadruplex in human telomeres. , 2009, Chemical communications.

[6]  M. Hejazi,et al.  Electrochemical detection of short sequences of hepatitis C 3a virus using a peptide nucleic acid-assembled gold electrode. , 2010, Analytical biochemistry.

[7]  Sarah W. Burge,et al.  Quadruplex DNA: sequence, topology and structure , 2006, Nucleic acids research.

[8]  Huixiang Li,et al.  DNA sequence detection using selective fluorescence quenching of tagged oligonucleotide probes by gold nanoparticles. , 2004, Analytical chemistry.

[9]  Sanjay Tyagi,et al.  Molecular Beacons: Probes that Fluoresce upon Hybridization , 1996, Nature Biotechnology.

[10]  P. Lou,et al.  Detection of quadruplex DNA structures in human telomeres by a fluorescent carbazole derivative. , 2004, Analytical chemistry.

[11]  Weihong Tan Molecular Engineering of DNA: Molecular Beacons , 2009 .

[12]  Dik‐Lung Ma,et al.  Platinum(II) complexes with dipyridophenazine ligands as human telomerase inhibitors and luminescent probes for G-quadruplex DNA. , 2009, Journal of the American Chemical Society.

[13]  Xiang Zhou,et al.  Highly effective colorimetric and visual detection of nucleic acids using an asymmetrically split peroxidase DNAzyme. , 2008, Journal of the American Chemical Society.

[14]  唐亚林 Verification of specific G-quadruplex structure by using a novel cyanine dye supramolecular assembly: II. The binding characterization with specific intramolecular G-quadruplex and the recognizing mechanism , 2010 .

[15]  Young Jun Seo,et al.  Quencher-free molecular beacons: a new strategy in fluorescence based nucleic acid analysis. , 2008, Chemical Society reviews.

[16]  Weihong Tan,et al.  Molecular assembly of superquenchers in signaling molecular interactions. , 2005, Journal of the American Chemical Society.

[17]  Dmitry M. Kolpashchikov,et al.  Binary probes for nucleic acid analysis. , 2010, Chemical reviews.

[18]  Robert Häner,et al.  A highly sensitive, excimer-controlled molecular beacon. , 2010, Angewandte Chemie.

[19]  J. Mergny,et al.  Ethidium derivatives bind to G-quartets, inhibit telomerase and act as fluorescent probes for quadruplexes. , 2001, Nucleic acids research.

[20]  Hui Li,et al.  Ultrasensitive electrochemical detection for DNA arrays based on silver nanoparticle aggregates. , 2010, Analytical chemistry.

[21]  A. Phan,et al.  Propeller-type parallel-stranded G-quadruplexes in the human c-myc promoter. , 2004, Journal of the American Chemical Society.

[22]  L. Hurley,et al.  The dynamic character of the G-quadruplex element in the c-MYC promoter and modification by TMPyP4. , 2004, Journal of the American Chemical Society.

[23]  P. Lai,et al.  Dimeric gold nanoparticle assembly for detection and discrimination of single nucleotide mutation in Duchenne muscular dystrophy. , 2010, Biosensors & bioelectronics.

[24]  Yongqiang Cheng,et al.  Self-aggregation of oligonucleotide-functionalized gold nanoparticles and its applications for highly sensitive detection of DNA. , 2010, Chemical communications.

[25]  N. Luedtke,et al.  Guanidinium-modified phthalocyanines as high-affinity G-quadruplex fluorescent probes and transcriptional regulators. , 2009, Angewandte Chemie.

[26]  D. Kolpashchikov Split DNA enzyme for visual single nucleotide polymorphism typing. , 2008, Journal of the American Chemical Society.

[27]  D. Kolpashchikov,et al.  Real-time SNP analysis in secondary-structure-folded nucleic acids. , 2010, Angewandte Chemie.

[28]  Itamar Willner,et al.  Lighting Up Biochemiluminescence by the Surface Self‐Assembly of DNA–Hemin Complexes , 2004, Chembiochem : a European journal of chemical biology.

[29]  J. Mergny,et al.  Engineering bisquinolinium/thiazole orange conjugates for fluorescent sensing of G-quadruplex DNA. , 2009, Angewandte Chemie.

[30]  M. Pumera,et al.  Rapid, sensitive, and label-free impedimetric detection of a single-nucleotide polymorphism correlated to kidney disease. , 2010, Analytical chemistry.

[31]  P. Bolton,et al.  Fluorescent dyes specific for quadruplex DNA. , 1998, Nucleic acids research.

[32]  Shizuka Nakayama,et al.  Colorimetric split G-quadruplex probes for nucleic acid sensing: improving reconstituted DNAzyme's catalytic efficiency via probe remodeling. , 2009, Journal of the American Chemical Society.

[33]  W. Russ Algar,et al.  The application of quantum dots, gold nanoparticles and molecular switches to optical nucleic-acid diagnostics , 2009 .

[34]  Laurence H. Hurley,et al.  Structures, folding patterns, and functions of intramolecular DNA G-quadruplexes found in eukaryotic promoter regions. , 2008, Biochimie.