Amplified DNA Detection Sensitivity Using Streptavidin－Biotinylated Protein Complex： Characterization by Electrochemical Impedance Spectroscopy

Thioi-terminated oligonucleotide was immobilized to gold sur-face by self-assembly method. A novel amplification strategy was introduced for improving the sensitivity of DNA hybridiza-tion using biotin labeled protein-streptavidin network complex. This complex can be formed in a cross-linking network of molecules so that the amplification of the response signal will be realized due to the big molecular size of the complex. It could be proved from the impedance technique that this amplification strategy caused dramatic improvement of the detection sensitivi-ty. These results give significant advances in the generality and sensitivity as it is applied to biosensing.     

Signal amplification by allosteric catalysis

In this article we unify a series of recent studies on bio- and chemosensors under a single signaling strategy: signal amplification by allosteric catalysis (SAAC). The SAAC strategy mimics biological signal transduction processes, where molecular recognition between an external signal and a protein receptor is allosterically transduced into catalytically amplified chemical information (usually second messengers). Several recent biosensing and chemosensing studies apply this nature-inspired strategy by using engineered allosteric enzymes, ribozymes, or regulatable organic catalysts. The factors pertinent to achieving high sensitivity and specificity in SAAC strategies are analyzed. The authors believe that these early studies from a variety of research groups have opened up a new venue for the development of sensing technologies where molecular recognition and catalysis can be coupled for practical purposes.     

One-step, multiplexed fluorescence detection of microRNAs based on duplex-specific nuclease signal amplification

Traditional molecular beacons, widely applied for detection of nucleic acids, have an intrinsic limitation on sensitivity, as one target molecule converts only one beacon molecule to its fluorescent form. Herein, we take advantage of the duplex-specific nuclease (DSN) to create a new signal-amplifying mechanism, duplex-specific nuclease signal amplification (DSNSA), to increase the detection sensitivity of molecular beacons (Taqman probes). DSN nuclease is employed to recycle the process of target-assisted digestion of Taqman probes, thus, resulting in a significant fluorescence signal amplification through which one target molecule cleaves thousands of probe molecules. We further demonstrate the efficiency of this DSNSA strategy for rapid direct quantification of multiple miRNAs in biological samples. Our experimental results showed a quantitative measurement of sequence-specific miRNAs with the detection limit in the femtomolar range, nearly 5 orders of magnitude lower than that of conventional molecular beacons. This amplification strategy also demonstrated a high selectivity for discriminating differences between miRNA family members. Considering the superior sensitivity and specificity, as well as the multiplex and simple-to-implement features, this method promises a great potential of becoming a routine tool for simultaneously quantitative analysis of multiple miRNAs in tissues or cells, and supplies valuable information for biomedical research and clinical early diagnosis.     

Enzymatic cleavage and mass amplification strategy for small molecule detection using aptamer-based fluorescence polarization biosensor

Fluorescence polarization (FP) assays incorporated with fluorophore-labeled aptamers have attracted great interest in recent years. However, detecting small molecules through the use of FP assays still remains a challenge because small-molecule binding only results in negligible changes in the molecular weight of the fluorophore-labeled aptamer. To address this issue, we herein report a fluorescence polarization (FP) aptamer assay that incorporates a novel signal amplification strategy for highly sensitive detection of small molecules. In the absence of adenosine, our model target, free FAM-labeled aptamer can be digested by nuclease, resulting in the release of FAM-labeled nucleotide segments from the dT-biotin/streptavidin complex with weak background signal. However, in the presence of target, the FAM-labeled aptamer–target complex protects the FAM-labeled aptamer from nuclease cleavage, allowing streptavidin to act as a molar mass amplifier. The resulting increase in molecular mass and FP intensity of the aptamer–target complex provides improved sensitivity for concentration measurement. The probe could detect adenosine from 0.5 μM to 1000 μM, with a detection limit of 500 nM, showing that the sensitivity of the probe is superior to aptamer-based FP approaches previously reported for adenosine. Importantly, FP could resist environmental interferences, making it useful for complex biological samples without any tedious sample pretreatments. Our results demonstrate that this dual-amplified, aptamer-based strategy can be used to design fluorescence polarization probes for rapid, sensitive, and selective measurement of small molecules in complicated biological environment.     

Development of an efficient signal amplification strategy for label-free enzyme immunoassay using two site-specific biotinylated recombinant proteins

Constructing a recombinant protein between a reporter enzyme and a detector protein to produce a homogeneous immunological reagent is advantageous over random chemical conjugation. However, the approach hardly recombines multiple enzymes in a difunctional fusion protein, which results in insufficient amplification of the enzymatic signal, thereby limiting its application in further enhancement of analytical signal. In this study, two site-specific biotinylated recombinant proteins, namely, divalent biotinylated alkaline phosphatase (AP) and monovalent biotinylated ZZ domain, were produced by employing the Avitag–BirA system. Through the high streptavidin (SA)–biotin interaction, the divalent biotinylated APs were clustered in the SA–biotin complex and then incorporated with the biotinylated ZZ. This incorporation results in the formation of a functional macromolecule that involves numerous APs, thereby enhancing the enzymatic signal, and in the production of several ZZ molecules for the interaction with immunoglobulin G (IgG) antibody. The advantage of this signal amplification strategy is demonstrated through ELISA, in which the analytical signal was substantially enhanced, with a 32-fold increase in the detection sensitivity compared with the ZZ–AP fusion protein approach. The proposed immunoassay without chemical modification can be an alternative strategy to enhance the analytical signals in various applications involving immunosensors and diagnostic chips, given that the label-free IgG antibody is suitable for the ZZ protein.     

Self-locked aptamer probe mediated cascade amplification strategy for highly sensitive and selective detection of protein and small molecule

In this work, a novel self-locked aptamer probe mediated cascade amplification strategy has been constructed for highly sensitive and specific detection of protein. First, the self-locked aptamer probe was designed with three functions: one was specific molecular recognition attributed to the aptamer sequence, the second was signal transduction owing to the transduction sequence, and the third was self-locking through the hybridization of the transduction sequence and part of the aptamer sequence. Then, the aptamer sequence specific recognized the target and folded into a three-way helix junction, leading to the release of the transduction sequence. Next, the 3’-end of this three-way junction acted as primer to trigger the strand displacement amplification (SDA), yielding a large amount of primers. Finally, the primers initiated the dual-exponential rolling circle amplification (DE-RCA) and generated numerous G-quadruples sequences. By inserting the fluorescent dye N-methyl mesoporphyrin IX (NMM), enhanced fluorescence signal was achieved. In this strategy, the self-locked aptamer probe was more stable to reduce the interference signals generated by the uncontrollable folding in unbounded state. Through the cascade amplification of SDA and DE-RCA, the sensitivity was further improved with a detection limit of 3.8 × 10⁻¹⁶ mol/L for protein detection. Furthermore, by changing the aptamer sequence of the probe, sensitive and selective detection of adenosine has been also achieved, suggesting that the proposed strategy has good versatility and can be widely used in sensitive and selective detection of biomolecules.     

A sensitive, label free electrochemical aptasensor for ATP detection

A sensitive, label free electrochemical aptasensor for small molecular detection has been developed in this work based on gold nanoparticles (AuNPs) amplification. This aptasensor was fabricated as a tertiary hybrid DNA-AuNPs system, which involved the anchored DNA (ADNA) immobilized on gold electrode, reporter DNA (RDNA) tethered with AuNPs and target-responsive DNA (TRDNA) linking ADNA and RDNA. Electrochemical signal is derived from chronocoulometric interrogation of [Ru(NH₃)₆]³⁺ (RuHex) that quantitatively binds to surface-confined DNA via electrostatic interaction. Using adenosine triphosphate (ATP) as a model analyte and ATP-binding aptamer as a model molecular reorganization element, the introduction of ATP triggers the structure switching of the TRDNA to form aptamer-ATP complex, which results in the dissociation of the RDNA capped AuNPs (RDNA-AuNPs) and release of abundant RuHex molecules trapped by RDNA-AuNPs. The incorporation of AuNPs in this strategy significantly enhances the sensitivity because of the amplification of electrochemical signal by the RDNA-AuNPs/RuHex system. Under optimized conditions, a wide linear dynamic range of 4 orders of magnitude (1 nM-10 μM) was reached with the minimum detectable concentration at sub-nanomolar level (0.2 nM). Those results demonstrate that our nanoparticles-based amplification strategy is feasible for ATP assay and presents a potential universal method for other small molecular aptasensors.     

2D NMR Trace Analysis by Continuous Hyperpolarization at High Magnetic Field

Nuclear magnetic resonance is often the technique of choice in chemical analysis because of its sensitivity to molecular structure, quantitative character, and straightforward sample preparation. However, determination of trace analytes in complex mixtures is generally limited by low sensitivity and extensive signal overlap. Here, we present an approach for continuous hyperpolarization at high magnetic field that is based on signal amplification by reversible exchange (SABRE) and can be straightforwardly incorporated in multidimensional NMR experiments. This method was implemented in a 2D correlation experiment that allows detection and quantification of analytes at nanomolar concentration in complex solutions.     

Unit cloning and amplification as novel and universal strategies for complex vector construction and small DNA fragment preparation

With a novel and universal strategy for the cloning of multiple DNA fragments, a complex synthetic vector (pVEC100), harboring the target DNA fragments in conventional 100‐bp DNA ladder, was constructed for efficient and large‐scale production of 100‐bp DNA marker through bacteria fermentation, plasmid extraction and restrictive digestion. Since the restrictive digestion of complex vectors yields insufficient small DNA fragments, an innovative PCR model was developed as an alternative. The PCR model comprised a specially designed template vector and a unit amplification model for producing groups of small DNA fragments. The unit amplification model improved the efficiency of the PCR protocol and made it more economical and easier for small DNA fragment amplification. The approach presented in this paper – a unit cloning model for constructing complex synthetic vectors combined with the modular design of unit amplification by PCR – is a powerful method for preparing small DNA fragments of DNA molecular weight standards.     

Pressure controllable aptamers picking strategy by targets competition

Selection of aptamers with high affinity and good specificity requires multiple rounds of alternating steps of separation and PCR amplification.Herein,we proposed a novel high-efficiency aptamers picking strategy:One-round pressure controllable selection(OPCS).OPCS integrates four types of screening superiority,high-efficiency separation,one-round selection and PCR amplification,synchronous negative selection and targets competition.The controllable screening pressure can be achieved through two approaches,balanced competition by the regulation of protein concentration,and dominant competition by introducing a predatory protein with high concentration.In OPCS process,two proteins were co-incubated with one ssDNA library,and each protein bound its favorable sequences specifically and formed protein-ss D NA complex re spectively.Meanwhile,one protein could supply/sufferthe picking pressure of affinity and specificity to/from another,which eliminated weakly bound or unbound sequences for each other.Two complexes could be separated and collected conveniently,and aptamers for two proteins obtained synchronously with high affinity and good specificity.This strategy not only provides a more effective way for aptamers selection,but shows great potential in other ligands or drugs selection.     

Combining ligation reaction and capillary gel electrophoresis to obtain reliable long DNA probes

New DNA amplification methods are continuously developed for sensitive detection and quantification of specific DNA target sequences for, e.g. clinical, environmental or food applications. These new applications often require the use of long DNA oligonucleotides as probes for target sequences hybridization. Depending on the molecular technique, the length of DNA probes ranges from 40 to 450 nucleotides, solid-phase chemical synthesis being the strategy generally used for their production. However, the fidelity of chemical synthesis of DNA decreases for larger DNA probes. Defects in the oligonucleotide sequence result in the loss of hybridization efficiency, affecting the sensitivity and selectivity of the amplification method. In this work, an enzymatic procedure has been developed as an alternative to solid-phase chemical synthesis for the production of long oligonucleotides. The enzymatic procedure for probe production was based on ligation of short DNA sequences. Long DNA probes were obtained from smaller oligonucleotides together with a short sequence that acts as bridge stabilizing the molecular complex for DNA ligation. The ligation reactions were monitored by capillary gel electrophoresis with laser-induced fluorescence detection (CGE-LIF) using a bare fused-silica capillary. The capillary gel electrophoresis-LIF method demonstrated to be very useful and informative for the characterization of the ligation reaction, providing important information about the nature of some impurities, as well as for the fine optimization of the ligation conditions (i.e. ligation cycles, oligonucleotide and enzyme concentration). As a result, the yield and quality of the ligation product were highly improved. The in-lab prepared DNA probes were used in a novel multiplex ligation-dependent genome amplification (MLGA) method for the detection of genetically modified maize in samples. The great possibilities of the whole approach were demonstrated by the specific and sensitive detection of transgenic maize at percentages lower than 1%.     

A Water-Gated Organic Thin-Film Transistor for Glyphosate Detection: A Comparative Study with Fluorescence Sensing

This work reports the design of a highly sensitive solid-state sensor device based on a water-gated organic thin-film transistor (WG-OTFT) for the selective detection of herbicide glyphosate (GlyP) in water. A competitive assay among carboxylate-functionalized polythiophene, Cu²⁺, and GlyP was employed as a sensing mechanism. Molecular recognition phenomena and electrical double layer (EDL) (at the polymer/water interface) originated from the field-effect worked cooperatively to amplify the sensitivity for GlyP. The limit of detection of WG-OTFT (0.26 ppm) was lower than that of a fluorescence sensor chip (0.95 ppm) which is the conventional sensing method. In contrast to the previously reported insulated molecular wires to block interchain interactions, molecular aggregates under the field-effect has shown to be effective for amplification of sensitivity through “intra”- and “inter”-molecular wire effects. The opposite strategy in this study could pave the way for fully utilizing the sensing properties of polymer-based solid-state sensor devices.     

Ultrasensitive Fluorescence Determination of Adenosine Deaminase using DNA-Templated Silver Nanoclusters and Isothermal Amplification

Highly sensitive determination of proteins is essential to biomedical research and clinical diagnosis. Here a new fluorescence strategy for protein assays is reported that utilizes the exponential amplification reaction and silver nanocluster label-free architecture. Superior sensitivity was obtained for adenosine deaminase with a detection limit of 0.8 milliunit per liter. This method was employed for the determination of adenosine deaminase in human serum. The method displayed high selectivity for adenosine deaminase compared to other proteins, thus providing a promising alternative to standard approaches for the determination of proteins.     

A novel signal-amplified electrochemical aptasensor based on supersandwich G-quadruplex DNAzyme for highly sensitive cancer cell detection

A novel electrochemical biosensor for cancer cell detection was developed based on aptamer-based competition and supersandwich G-quadruplex DNAzyme amplification strategy. Due to the stronger affinity between the aptamer and cancer cells than that with its complementary oligonucleotide, the complementary oligonucleotide will be facilely replaced. As a consequence, we can detect cancer cells indirectly by detecting the releasing DNA which is proportional to the concentration of K562 cells. Through the supersandwich G-quadruplex DNAzyme amplification strategy, the sensitivity can be dramatically enhanced with detection limit down to 14 cells.     

Catalytic Molecular Imaging of MicroRNA in Living Cells by DNA‐Programmed Nanoparticle Disassembly

Molecular imaging is an essential tool for disease diagnostics and treatment. Direct imaging of low‐abundance nucleic acids in living cells remains challenging because of the relatively low sensitivity and insufficient signal‐to‐background ratio of conventional molecular imaging probes. Herein, we report a class of DNA‐templated gold nanoparticle (GNP)–quantum dot (QD) assembly‐based probes for catalytic imaging of cancer‐related microRNAs (miRNA) in living cells with signal amplification capacity. We show that a single miRNA molecule could catalyze the disassembly of multiple QDs with the GNP through a DNA‐programmed thermodynamically driven entropy gain process, yielding significantly amplified QD photoluminescence (PL) for miRNA imaging. By combining the robust PL of QDs with the catalytic amplification strategy, three orders of magnitude improvement in detection sensitivity is achieved in comparison with non‐catalytic imaging probe, which enables facile and accurate differentiation between cancer cells and normal cells by miRNA imaging in living cells.     

Dendritic-like streptavidin/alkaline phosphatase nanoarchitectures for amplified electrochemical sensing of DNA sequences

This study describes the development and characterization of a novel dendritic-like signal amplification pathway. Such an analytical strategy relies on the use of streptavidin and biotinylated alkaline phosphatase, which can be simply and conveniently self-assembled to build nanoarchitectures rich in enzyme labels.The performance of this enzyme-based amplification route was demonstrated in connection with the electrochemical sensing of DNA sequences. Compared to the commercially available streptavidin-conjugated alkaline phosphatase labels, a single generation of the streptavidin/biotinylated alkaline phosphatase assembly allowed a 15-20-fold enhancement of the electroanalytical signals. The higher sensitivity allowed by the dendritic-like route was attributed to the lower steric hindrance of the proteins employed for this amplification path. As low as 50 pmol/L of a 388-bp-long amplicon identifying Salmonella spp. was easily detected. The experimental results additionally demonstrated that the sensitivity of the method could be further increased in a linear fashion with the number of protein-enzyme generations.     

Advanced Immobilization and Amplification for High Performance Protein Chips

With the success of high-throughput DNA microarrays, protein biochips have been intensively investigated and broadly used in bioscience research, clinic diagnosis, drug discovery, and other applications. However, there is great need to significantly improve the sensitivity of protein chips, especially in early diagnosis. A major challenge of improving sensitivity is that protein detection does not have an effective amplification method, such as PCR for DNA microarrays. Construction of unique biofilms for efficient immobilization of protein probes and innovation of new amplification schemes could play a critical role in performance improvement of protein biochips. With dramatic developments in microfabrication, nanotechnologies, and biotechnologies, enormous progress has been made, particularly in improving biosensing sensitivity. This article reviews new advances in protein biochip technologies with emphasis on novel approaches for efficient probe immobilization and nanomaterials-assisted signal amplification for high performance protein chips. Prominent progress in integration of protein microarrays with microfluidic platforms is briefly discussed. The major challenges and perspectives on the future of protein biochips are also addressed.     

Toehold-mediated nonenzymatic amplification circuit on graphene oxide fluorescence switching platform for sensitive and homogeneous microRNA detection

A novel graphene oxide (GO) fluorescence switch-based homogenous system has been developed to solve two problems that are commonly encountered in conventional GO-based biosensors. First, with the assistance of toehold-mediated nonenzymatic amplification (TMNA), the sensitivity of this system greatly surpasses that of previously described GO-based biosensors, which are always limited to the nM range due to the lack of efficient signal amplification. Second, without enzymatic participation in amplification, the unreliability of detection resulting from nonspecific desorption of DNA probes on the GO surface by enzymatic protein can be avoided. Moreover, the interaction mechanism of the double-stranded TMNA products contains several single-stranded toeholds at two ends and GO has also been explored with combinations of atomic force microscopy imaging, zeta potential detection, and fluorescence assays. It has been shown that the hybrids can be anchored to the surface of GO through the end with more unpaired bases, and that the other end, which has weaker interaction with GO, can escape GO adsorption due to the robustness of the central dsDNA structures. We verified this GO fluorescence switch-based detection system by detecting microRNA 21, an overexpressed non-encoding gene in a variety of malignant cells. Rational design of the probes allowed the isothermal nonenzymatic reaction to achieve more than 100-fold amplification efficiency. The detection results showed that our strategy has a detection limit of 10 pM and a detection range of four orders of magnitude.     

Charge-Transfer versus Charge-Separated Triplet Excited States of [ReI(dmp)(CO)3(His124)(Trp122)]+ in Water and in Modified Pseudomonas aeruginosa Azurin Protein

A computational investigation of the triplet excited states of a rhenium complex electronically coupled with a tryptophan side chain and bound to an azurin protein is presented. In particular, by using high-level molecular modeling, evidence is provided for how the electronic properties of the excited-state manifolds strongly depend on coupling with the environment. Indeed, only upon explicitly taking into account the protein environment can two stable triplet states of metal-to-ligand charge transfer or charge-separated nature be recovered. In addition, it is also demonstrated how the rhenium complex plus tryptophan system in an aqueous environment experiences too much flexibility, which prevents the two chromophores from being electronically coupled. This occurrence disables the formation of a charge-separated state. The successful strategy requires a multiscale approach of combining molecular dynamics and quantum chemistry. In this context, the strategy used to parameterize the force fields for the electronic triplet states of the metal complex is also presented.     

Label‐Free Detection of MicroRNA: Two‐Step Signal Enhancement with a Hairpin‐Probe‐Based Graphene Fluorescence Switch and Isothermal Amplification

A label‐free approach with multiple enhancement of the signal for microRNA detection has been introduced. The key idea of this strategy is achieved by taking advantage of a novel graphene oxide (GO)/intercalating dye based fluorescent hairpin probe (HP) and an isothermal polymerization reaction. In this paper, we used microRNA‐21 (mir‐21) as the target to examine the desirable properties of this assay. When the target, as a “trigger”, was hybridized with the HP and caused a conformation change, an efficient isothermal polymerization reaction was activated to achieve the first step of the “signal” amplification. After incubation with the platform of GO/intercalating dye, the formed complex of DNA interacted with the high‐affinity dye and then detached from the surface of the GO, a process that was accompanied by distinguishable fluorescence recovery. Further signal enhancement has been accomplished by a mass of intercalating dye inserting into the minor groove of the long duplex replication product. Due to the efficient and multiple amplification steps, this approach exerted a substantial enhancement in sensitivity and could be used for rapid and selective detection of Mir‐21 at attomole levels. Proof‐of‐concept evidence has been provided for the proposed cost‐effective strategy; thus, this strategy could expand the application of GO‐material‐based bioanalysis for nucleic acid studies.