Synergistic stabilization of nucleic acid assembly by oligo-N3'-->P5' phosphoramidate modification and additions of comb-type cationic copolymers

One-step isothermal RNA detection with LNA-modified MNAzymes chaperoned by cationic copolymer

RNA detection permits early diagnosis of several infectious diseases and cancers, which prevent propagation of diseases and improve treatment efficacy. However, standard technique for RNA detection such as reverse transcription-quantitative polymerase chain reaction has complicated procedure and requires well-trained personnel and specialized lab equipment. These shortcomings limit the application for point-of-care analysis which is critical for rapid and effective disease management. The multicomponent nucleic acid enzymes (MNAzymes) are one of the promising biosensors for simple, isothermal and enzyme-free RNA detection. Herein, we demonstrate simple yet effective strategies that significantly enhance analytical performance of MNAzymes. The addition of the cationic copolymer and structural modification of MNAzyme significantly enhanced selectivity and activity of MNAzymes by 250 fold and 2,700 fold, respectively. The highly simplified RNA detection system achieved a detection limit of 73 fM target concentration without additional amplification. The robustness of MNAzyme in the presence of non-target RNA was also improved. Our finding opens up a route toward the development of an alternative rapid, sensitive, isothermal, and protein-free RNA diagnostic tool, which expected to be of great clinical significance.

2'-O,4'-C-ethylene bridged nucleic acid modification enhances pyrimidine motif triplex-forming ability under physiological condition

Since pyrimidine motif triplex DNA is unstable at physiological neutral pH, triplex stabilization at physiological neutral pH is important for improvement of its potential to be applied to various methods in vivo, such as repression of gene expression, mapping of genomic DNA and gene-targeted mutagenesis. For this purpose, we studied the thermodynamic and kinetic effects of a chemical modification, 2'-O,4'-C-ethylene bridged nucleic acid (ENA) modification of triplex-forming oligonucleotide (TFO), on pyrimidine motif triplex formation at physiological neutral pH. Thermodynamic investigations indicated that the modification achieved more than 10-fold increase in the binding constant of the triplex formation. The increased number of the modification in TFO enhanced the increased magnitude of the binding constant. On the basis of the obtained thermodynamic parameters, we suggested that the remarkably increased binding constant by the modification may result from the increased stiffness of TFO in the unbound state. Kinetic studies showed that the considerably decreased dissociation rate constant resulted in the observed increased binding constant by the modification. We conclude that ENA modification of TFO could be a useful chemical modification to promote the triplex formation under physiological neutral condition, and may advance various triplex formation-based methods in vivo.

Chemical modification of triplex-forming oligonucleotide to promote pyrimidine motif triplex formation at physiological pH

Extreme instability of pyrimidine motif triplex DNA at physiological pH severely limits its use in wide variety of potential applications, such as artificial regulation of gene expression, mapping of genomic DNA, and gene-targeted mutagenesis in vivo. Stabilization of pyrimidine motif triplex at physiological pH is, therefore, crucial for improving its potential in various triplex-formation-based strategies in vivo. To this end, we investigated the effect of 3'-amino-2'-O,4'-C-methylene bridged nucleic acid modification of triplex-forming oligonucleotide (TFO), in which 2'-O and 4'-C of the sugar moiety were bridged with the methylene chain and 3'-O was replaced by 3'-NH, on pyrimidine motif triplex formation at physiological pH. The modification not only significantly increased the thermal stability of the triplex but also increased the binding constant of triplex formation about 15-fold. The increased magnitude of the binding constant was not significantly changed when the number and position of the modification in TFO changed. The consideration of the observed thermodynamic parameters suggested that the increased rigidity of the modified TFO in the free state resulting from the bridging of different positions of the sugar moiety with an alkyl chain and the increased hydration of the modified TFO in the free state caused by the introduction of polar nitrogen atoms may significantly increase the binding constant at physiological pH. The study on the TFO viability in human serum showed that the modification significantly increased the resistance of TFO against nuclease degradation. This study presents an effective approach for designing novel chemically modified TFOs with higher binding affinity of triplex formation at physiological pH and higher nuclease resistance under physiological condition, which may eventually lead to progress in various triplex-formation-based strategies in vivo.

Interrupted 2'-o,4'-C-aminomethylene bridged nucleic acid modification enhances pyrimidine motif triplex-forming ability and nuclease resistance under physiological condition

Due to instability of pyrimidine motif triplex DNA at physiological pH, triplex stabilization at physiological pH is crucial in improving its potential in various triplex formation-based strategies in vivo, such as regulation of gene expression, mapping of genomic DNA, and gene-targeted mutagenesis. To this end, we investigated the effect of our previously reported chemical modification, 2'-O,4'-C-aminomethylene bridged nucleic acid (2',4'- BNA(NC)) modification, introduced into interrupted and continuous positions of triplex-forming oligonucleotide (TFO) on pyrimidine motif triplex formation at physiological pH. The interrupted 2',4'-BNA(NC) modifications of TFO increased the binding constant of the triplex formation at physiological pH by more than 10-fold, and significantly increased the nuclease resistance of TFO. On the other hand, the continuous 2',4'-BNA(NC) modification of TFO showed lower ability to promote the triplex formation at physiological pH than the interrupted 2',4'-BNA(NC) modifications of TFO, and did not significantly change the nuclease resistance of TFO. Selection of the interruptedly 2',4'-BNA(NC)-modified positions in TFO was more favorable for achieving the higher binding affinity of the pyrimidine motif triplex formation at physiological pH and the higher nuclease resistance of TFO than that of the continuously 2',4'-BNA(NC)-modified positions in TFO. We conclude that the interrupted 2',4'-BNA(NC) modification of TFO could be a key chemical modification to enhance pyrimidine motif triplex-forming ability and nuclease resistance under physiological condition, and may eventually lead to progress in various triplex formation-based strategies in vivo.

2'-O,4'-C-aminomethylene-bridged nucleic acid modification with enhancement of nuclease resistance promotes pyrimidine motif triplex nucleic acid formation at physiological pH

Due to the instability of pyrimidine motif triplex DNA at physiological pH, triplex stabilization at physiological pH is crucial in improving its potential in various triplex-formation-based strategies in vivo, such as gene expression regulation, genomic DNA mapping, and gene-targeted mutagenesis. To this end, we investigated the thermodynamic and kinetic effects of our previously reported chemical modification, 2'-O,4'-C-aminomethylene-bridged nucleic acid (2',4'-BNA(NC)) modification of triplex-forming oligonucleotide (TFO), on triplex formation at physiological pH. The thermodynamic analyses indicated that the 2',4'-BNA(NC) modification of TFO increased the binding constant of the triplex formation at physiological pH by more than 10-fold. The number and position of the 2',4'-BNA(NC) modification in TFO did not significantly affect the magnitude of the increase in the binding constant. The consideration of the observed thermodynamic parameters suggested that the increased rigidity and the increased degree of hydration of the 2',4'-BNA(NC)-modified TFO in the free state relative to the unmodified TFO may enable the significant increase in the binding constant. Kinetic data demonstrated that the observed increase in the binding constant by the 2',4'-BNA(NC) modification resulted mainly from the considerable decrease in the dissociation rate constant. The TFO stability in human serum showed that the 2',4'-BNA(NC) modification significantly increased the nuclease resistance of TFO. Our results support the idea that the 2',4'-BNA(NC) modification of TFO could be a key chemical modification to achieve higher binding affinity and higher nuclease resistance in the triplex formation under physiological conditions, and may lead to progress in various triplex-formation-based strategies in vivo.

Synergistic stabilization of nucleic acid assembly by 2'-O,4'-C-methylene-bridged nucleic acid modification and additions of comb-type cationic copolymers

Stabilization of nucleic acid assemblies, such as duplex and triplex, is quite important for their wide variety of potential applications. Various stabilization methods, including molecular designs of chemically modified nucleotides and hybrid stabilizers, and combinations of different stabilization methods have been developed to increase stability of nucleic acid assemblies. However, combinations of two stabilizing methods have not always yielded desired synergistic effects. In the present study, to propose a strategy for selection of a rational combination of stabilizing methods, we demonstrate synergistic stabilization of triplex by 2'-O,4'-C-methylene-bridged nucleic acid (2',4'-BNA) modification of triplex-forming oligonucleotide and addition of poly(l-lysine)-graft-dextran copolymer [poly(l-lysine) grafted with hydrophilic dextran side chains]. Each of these methods increased the binding constant for triplex formation by nearly 2 orders of magnitude. However, their kinetic contributions were quite distinct. The copolymer increased the association rate constant, whereas the 2',4'-BNA modification decreased the dissociation rate constant for triplex stabilization. The combination of both stabilizing methods increased the binding constant by nearly 4 orders of magnitude. Kinetic analyses revealed that the successful synergistic stabilization resulted from kinetic complementarity between increased association rate constants by the copolymer and decreased dissociation rate constants by the 2',4'-BNA modification. The stabilizing effect of one stabilization method did not alter that of the other stabilization method. We propose that kinetic analyses of each stabilizing effect permit selection of a rational combination of stabilizing methods for successful synergy in stabilizing nucleic acid assemblies.

Spectroscopic investigation of cationic comb-type copolymers/DNA interaction: interpolyelectrolyte complex enhancement synchronized with DNA hybridization

We have demonstrated that cationic comb-type copolymers consisting of a polycation backbone and abundant grafts of water-soluble polymers stabilize DNA hybrids. Furthermore, the copolymers were found to accelerate strand exchange reaction between a double-stranded DNA and its complementary single-stranded DNA. In this article, we investigated the effects of PLL-g-Dex on base pairs of a self-complementary DNA octamer, d(GGAATTCC). The soluble interpolyelectrolyte complex (IPEC) between the DNA and copolymer allowed us to characterize the complex by using spectroscopic methods under physiological ionic condition. Chemical shifts of nucleobase proton signals were not changed by PLL-g-Dex. Furthermore, the copolymer slightly changed the von't Hoff DeltaH accompanying the helix-coil transition of the octamer. These results indicated that the base pairs of the duplex DNA in the IPEC were not perturbed by the polycationic copolymer. It was obviously shown by temperature dependencies of proton and phosphorus NMR spectra that DNA/copolymer interaction was considerably enhanced in response to ds DNA formation. An increase in the density and total number of DNA negative charges upon hybrid formation likely caused the higher affinity of the copolymer with the ds form over that of the copolymer with the ss form. The IPEC formation of CCCs with DNA, however, seems highly sensitive to the coil-helix transition of the DNA.

Survey of the year 2005 commercial optical biosensor literature

We identified 1113 articles (103 reviews, 1010 primary research articles) published in 2005 that describe experiments performed using commercially available optical biosensors. While this number of publications is impressive, we find that the quality of the biosensor work in these articles is often pretty poor. It is a little disappointing that there appears to be only a small set of researchers who know how to properly perform, analyze, and present biosensor data. To help focus the field, we spotlight work published by 10 research groups that exemplify the quality of data one should expect to see from a biosensor experiment. Also, in an effort to raise awareness of the common problems in the biosensor field, we provide side-by-side examples of good and bad data sets from the 2005 literature.