Optical absorption assay for strand-exchange reactions in unlabeled nucleic acids

DNA Self-assembly Catalyzed by Artificial Agents

Nucleic acids have been shown to be versatile molecules and engineered to produce various nanostructures. However, the poor rate of these uncatalyzed nucleic acid reactions has restricted the development and applications. Herein, we reported a novel finding that DNA self-assembly could be nonenzymatically catalyzed by artificial agents with an increasing dissociation rate constant K2. The catalytic role of several artificial agents in DNA self-assembly was verified by real-time fluorescent detection or agarose gel electrophoresis. We found that 20% PEG 200 could significantly catalyze DNA self-assembly and increase the reaction efficiency, such as linear hybridization chain reaction (HCR) and exponential hairpin assembly (EHA). Therefore, we foresee that a fast and efficient DNA self-assembly in structural DNA nanotechnology will be desirable.

Sr(2+) induces unusually stable d(GGGTGGGTGGGTGGG) quadruplex dimers

Guanine-rich sequences are able to form quadruplexes consisting of G-quartet structural units. Quadruplexes play an important role in the regulation of gene expression and have therapeutic and biotechnological potential. The HIV-1 integrase inhibitor, (GGGT)4 , and its variants demonstrate unusually high thermal stability. This property has been exploited in the use of quadruplex formation to drive various endergonic reactions of nucleic acids such as isothermal DNA amplification. Quadruplex stability is mainly determined by cations, which specifically bind into the inner core of the structure. In the present work, we report a systematic study of a variant of the HIV-1 integrase inhibitor, GGGTGGGTGGGTGGG (G3T), in the presence of alkali and alkaline-earth cations. We show that Sr(2+) -G3T is characterized by the highest thermal stability and that quadruplex formation requires only one Sr(2+) ion that binds with low micromolar affinity. These concentrations are sufficient to drive robust isothermal quadruplex priming DNA amplification reaction. The Sr(2+) -quadruplexes are also able to form unusually stable dimers through end-to-end stacking. The multimerization can be induced by a combination of quadruplex forming cations (i.e., K(+) or Sr(2+) ) and non-specific Mg(2+) .

Isothermal amplification of DNA using quadruplex primers with fluorescent pteridine base analogue 3-methyl isoxanthopterin

We previously developed a method, known as quadruplex priming amplification (QPA), which greatly simplifies DNA amplification and quantification assays. QPA employs specific primers based on GGGTGGGTGGGTGGG (G3T) sequence, which upon polymerase elongation spontaneously dissociates from the target and folds into a stable quadruplex. Fluorescent nucleotide analogs, when incorporated into these primers, emit light upon quadruplex formation and permit simple, specific, and sensitive quantification without the attachment of probe molecules. Here, we studied optical [fluorescence and circular dichroism (CD)] and thermodynamic properties of the G3T sequence and variants incorporating 3-methylisoxanthopterin (3MI), a highly fluorescent nucleotide analog suitable for QPA. CD studies demonstrate that the incorporation of 3MI does not change the overall tertiary structure of G3T; however, thermal unfolding experiments revealed that it significantly destabilizes the quadruplex. Enzymatic studies revealed that Taq and Bst are practically unable to incorporate any nucleotides opposite to template 3MI. Based on this knowledge, we designed QPA assays with truncated targets that demonstrate efficient amplification around 55°C. Overall, these studies suggest that 3MI-based QPA is a useful assay for DNA amplification and detection.

RNAPattMatch: a web server for RNA sequence/structure motif detection based on pattern matching with flexible gaps

Searching for RNA sequence-structure patterns is becoming an essential tool for RNA practitioners. Novel discoveries of regulatory non-coding RNAs in targeted organisms and the motivation to find them across a wide range of organisms have prompted the use of computational RNA pattern matching as an enhancement to sequence similarity. State-of-the-art programs differ by the flexibility of patterns allowed as queries and by their simplicity of use. In particular-no existing method is available as a user-friendly web server. A general program that searches for RNA sequence-structure patterns is RNA Structator. However, it is not available as a web server and does not provide the option to allow flexible gap pattern representation with an upper bound of the gap length being specified at any position in the sequence. Here, we introduce RNAPattMatch, a web-based application that is user friendly and makes sequence/structure RNA queries accessible to practitioners of various background and proficiency. It also extends RNA Structator and allows a more flexible variable gaps representation, in addition to analysis of results using energy minimization methods. RNAPattMatch service is available at http://www.cs.bgu.ac.il/rnapattmatch. A standalone version of the search tool is also available to download at the site.

Thermal stability of quadruplex primers for highly versatile isothermal DNA amplification

Quadruplex priming amplification (QPA) allows isothermal amplification of nucleic acids with improved yield and simplified detection. This assay is based on a DNA quadruplex, GGGTGGGTGGGTGGG (G3T), which in the presence of specific cations possesses unusually high thermal stability. QPA employs truncated G3T sequences as primers, which upon polymerase elongation, self-dissociate from the binding site and allow the next round of priming without thermal unfolding of amplicons. The rate of amplification strongly depends on the thermal stability of the primer/primer binding site (PBS) complex and to date QPA has been demonstrated to work over a narrow temperature range. To expand the capabilities of QPA, in the present study, we studied the fold and thermodynamic properties of the wild-type G3T and variants containing sequence modifications or extensions at the 5'-end. Circular dichroism studies demonstrate that the substitution of thymidines by other nucleotides or GC addition at the 5'-end does not change the parallel fold of G3T. Thermal unfolding experiments revealed that purine bases incorporated at loop positions and 5'-end dinucleotide extension significantly destabilize the quadruplex, while loop pyrimidines have almost no effect. Overall, the results of these studies suggest that linear isothermal QPA can be performed over a wide temperature range to accommodate both thermophilic and mesophilic DNA polymerases.

Isothermal quadruplex priming amplification for DNA-based diagnostics

We previously developed a method, known as quadruplex priming amplification (QPA), which permits isothermal amplification of DNA. The assay is based on a DNA quadruplex formed by the GGGTGGGTGGGTGGG (G3T) sequence. G3T has three unique properties that are fundamental for QPA; (i) G3T forms a quadruplex with significantly more favorable thermodynamics than the corresponding DNA duplexes; (ii) removal of guanines at the 3'-end inhibits quadruplex formation; and (iii) incorporated fluorescent nucleotides, such as 2-aminopurine (2AP) or 6-methylisoxanthopterin (6MI), which are quenched by neighboring nucleotides, regain maximum emission upon quadruplex formation. New model studies carried out here with primers missing one, two and three guanines reveal that the driving force for QPA comes from the difference in thermal stability between the primer/template and the product complexes. Primers missing one and two guanines are able to self-dissociate from the template upon elongation, whereas QPA is not observed when the primer lacks three 3'-nucleotides. QPA reaches its maximum rate at temperatures slightly higher than the T(m) of the primer/template complex and is more efficient in the presence of only dGTP. QPA-based assays also revealed that Taq is able to incorporate thymidines opposite template 2AP, while no significant incorporation was observed opposite template 6MI.

Quadruplex formation as a molecular switch to turn on intrinsically fluorescent nucleotide analogs

Quadruplexes are involved in the regulation of gene expression and are part of telomeres at the ends of chromosomes. In addition, they are useful in therapeutic and biotechnological applications, including nucleic acid diagnostics. In the presence of K⁺ ions, two 15-mer sequences d(GGTTGGTGTGGTTGG) (thrombin binding aptamer) and d(GGGTGGGTGGGTGGG) (G3T) fold into antiparallel and parallel quadruplexes, respectively. In the present study, we measured the fluorescence intensity of one or more 2-aminopurine or 6-methylisoxanthopterin base analogs incorporated at loop-positions of quadruplex forming sequences to develop a detection method for DNA sequences in solution. Before quadruplex formation, the fluorescence is efficiently quenched in all cases. Remarkably, G3T quadruplex formation results in emission of fluorescence equal to that of a free base in all three positions. In the case of thrombin binding aptamer, the emission intensity depends on the location of the fluorescent nucleotides. Circular dichroism studies demonstrate that the modifications do not change the overall secondary structure, whereas thermal unfolding experiments revealed that fluorescent analogs significantly destabilize the quadruplexes. Overall, these studies suggest that quadruplexes containing fluorescent nucleotide analogs are useful tools in the development of novel DNA detection methodologies.

G-quadruplex-forming oligonucleotide conjugated to magnetic nanoparticles: synthesis, characterization, and enzymatic stability assays

In the present work, we report the conjugation of superparamagnetic nanoparticles to a fluorescently labeled oligodeoxyribonucleotide (ODN) able to fold into stable unimolecular guanine quadruple helix under proper ion conditions by means of its thrombin-binding aptamer (TBA) sequence. The novel modified ODN, which contained a fluorescent dU(Py) unit at 3'-end and a 12-amino-dodecyl spacer (C(12)-NH(2)) at 5' terminus, was characterized by ESI-MS and optical spectroscopy (UV, CD, fluorescence), and analyzed by RP-HPLC chromatography and electrophoresis. From CD and fluorescence experiments, we verified that dU(Py) and C(12)-NH(2) incorporation does not interfere with the conformational stability of the G-quadruplex. Subsequently, the conjugation of the pyrene-labeled ODN with the magnetite particles was performed, and the ODN-conjugated nanoparticles were studied through optical spectroscopy (UV, CD, fluorescence) and by enzymatic and chemical assays. We found that the nanoparticles enhanced the stability of the TBA ODN to enzymatic degradation. Finally, we evaluated the amount of the TBA-conjugated nanoparticles immobilized on a magnetic separator in view of the potential use of the nanosystem for the magnetic capture of thrombin from complex mixtures.

HIV-integrase aptamer folds into a parallel quadruplex: a thermodynamic study

Short guanine-rich sequences have a tendency to form quadruplexes that are stabilized by G-quartets with specific cation coordination. Quadruplexes are part of telomeres at the ends of chromosomes and play an important role in the regulation of gene expression. In addition, there is a strong interest in the therapeutic and biotechnological potential of quadruplex oligonucleotides. The HIV-integrase aptamer, d(GGGT)(4), demonstrated unusually favorable van't Hoff thermodynamics, and based on NMR studies the aptamer was proposed to fold into an antiparallel structure. Here we probed an apparent discrepancy between the NMR structure and the quadruplex topology suggested by circular dichroism (CD). Systematic thermodynamic analyses of d(GGGT)(4) and variants containing sequence modifications or missing specific nucleotides are consistent with a parallel quadruplex fold. CD studies carried out over a wide concentration range did not support a possible structural transition upon increasing strand concentration. Taken together, both optical and thermodynamic studies performed here strongly support a parallel fold for the d(GGGT)(4) aptamer.

Mining Functional Elements in Messenger RNAs: Overview, Challenges, and Perspectives

Eukaryotic messenger RNA (mRNA) contains not only protein-coding regions but also a plethora of functional cis-elements that influence or coordinate a number of regulatory aspects of gene expression, such as mRNA stability, splicing forms, and translation rates. Understanding the rules that apply to each of these element types (e.g., whether the element is defined by primary or higher-order structure) allows for the discovery of novel mechanisms of gene expression as well as the design of transcripts with controlled expression. Bioinformatics plays a major role in creating databases and finding non-evident patterns governing each type of eukaryotic functional element. Much of what we currently know about mRNA regulatory elements in eukaryotes is derived from microorganism and animal systems, with the particularities of plant systems lagging behind. In this review, we provide a general introduction to the most well-known eukaryotic mRNA regulatory motifs (splicing regulatory elements, internal ribosome entry sites, iron-responsive elements, AU-rich elements, zipcodes, and polyadenylation signals) and describe available bioinformatics resources (databases and analysis tools) to analyze eukaryotic transcripts in search of functional elements, focusing on recent trends in bioinformatics methods and tool development. We also discuss future directions in the development of better computational tools based upon current knowledge of these functional elements. Improved computational tools would advance our understanding of the processes underlying gene regulations. We encourage plant bioinformaticians to turn their attention to this subject to help identify novel mechanisms of gene expression regulation using RNA motifs that have potentially evolved or diverged in plant species.

Self-dissociative primers for nucleic acid amplification and detection based on DNA quadruplexes with intrinsic fluorescence

We have developed a new method, quadruplex priming amplification, to greatly simplify nucleic acid amplification and real-time quantification assays. The method relies on specifically designed guanine-rich primers, which after polymerase elongation are capable of spontaneous dissociation from target sites and forming DNA quadruplex. The quadruplex is characterized by significantly more favorable thermodynamics than the corresponding DNA duplexes. As a result, target sequences are accessible for the next round of priming and DNA amplification proceeds under isothermal conditions with improved product yield. In addition, the quadruplex formation is accompanied by an increase in intrinsic fluorescence of the primers, allowing simple and accurate detection of product DNA.

Computational identification of riboswitches based on RNA conserved functional sequences and conformations

Riboswitches are cis-acting genetic regulatory elements within a specific mRNA that can regulate both transcription and translation by interacting with their corresponding metabolites. Recently, an increasing number of riboswitches have been identified in different species and investigated for their roles in regulatory functions. Both the sequence contexts and structural conformations are important characteristics of riboswitches. None of the previously developed tools, such as covariance models (CMs), Riboswitch finder, and RibEx, provide a web server for efficiently searching homologous instances of known riboswitches or considers two crucial characteristics of each riboswitch, such as the structural conformations and sequence contexts of functional regions. Therefore, we developed a systematic method for identifying 12 kinds of riboswitches. The method is implemented and provided as a web server, RiboSW, to efficiently and conveniently identify riboswitches within messenger RNA sequences. The predictive accuracy of the proposed method is comparable with other previous tools. The efficiency of the proposed method for identifying riboswitches was improved in order to achieve a reasonable computational time required for the prediction, which makes it possible to have an accurate and convenient web server for biologists to obtain the results of their analysis of a given mRNA sequence. RiboSW is now available on the web at http://RiboSW.mbc.nctu.edu.tw/.

Riboswitch RNAs: using RNA to sense cellular metabolism

Riboswitches are RNA elements that undergo a shift in structure in response to binding of a regulatory molecule. These elements are encoded within the transcript they regulate, and act in cis to control expression of the coding sequence(s) within that transcript; their function is therefore distinct from that of small regulatory RNAs (sRNAs) that act in trans to regulate the activity of other RNA transcripts. Riboswitch RNAs control a broad range of genes in bacterial species, including those involved in metabolism or uptake of amino acids, cofactors, nucleotides, and metal ions. Regulation occurs as a consequence of direct binding of an effector molecule, or through sensing of a physical parameter such as temperature. Here we review the global role of riboswitch RNAs in bacterial cell metabolism.

Computational genes: a tool for molecular diagnosis and therapy of aberrant mutational phenotype

Background

A finite state machine manipulating information-carrying DNA strands can be used to perform autonomous molecular-scale computations at the cellular level.

Results

We propose a new finite state machine able to detect and correct aberrant molecular phenotype given by mutated genetic transcripts. The aberrant mutations trigger a cascade reaction: specific molecular markers as input are released and induce a spontaneous self-assembly of a wild type protein or peptide, while the mutational disease phenotype is silenced. We experimentally demostrated in in vitro translation system that a viable protein can be autonomously assembled.

Conclusion

Our work demostrates the basic principles of computational genes and particularly, their potential to detect mutations, and as a response thereafter administer an output that suppresses the aberrant disease phenotype and/or restores the lost physiological function.

Core requirements of the adenine riboswitch aptamer for ligand binding

The adenine riboswitch aptamer, the A box, positively regulates gene expression upon adenine binding. To provide insight into structure-function relationships, important for the adenine riboswitch aptamer, we have created alignments for six aptamer sequences that reveal the core requirements. In addition, 2-aminopurine (2AP) binding studies have been used to test the consensus sequence derived from the alignment. Overall, the consensus secondary structure is consistent with 2AP binding studies. However, a position in the core, previously identified as variable, shows restriction in nucleotide sequence. Furthermore, this restriction is found to be related with the ligand specificity of the riboswitch. The implications of this relationship for the riboswitch gene regulation mechanism are discussed.

The HIV-1 central DNA flap region contains a "flapping" third strand

Due to the discontinuous nature of HIV-1 plus-strand DNA synthesis, a 99-nt plus-strand overhang termed the "central DNA flap" is present near the center of the proviral DNA prior to integration. The flap appears to have stabilizing and/or protective effects on viral DNA, which has been hypothesized to be due to a specific conformation adopted by the three-stranded region. The 5' end of the flap sequence is very purine rich and has the potential to adopt different secondary structures (e.g., duplex, triplex or quadruplex). In the present work, circular dichroism spectroscopy and thermal unfolding techniques were used to characterize an 89-nt long DNA sequence designed to mimic the three-stranded region at the 5' end of HIV-1 proviral DNA. The effect of addition of the HIV-1 nucleocapsid protein (NC) on the nucleic acid structure was also examined. Although, guanine-rich short oligonucleotides derived from the DNA flap demonstrated CD spectra characteristic to parallel quadruplexes, this analysis reveals that the extended 89-nt construct folds into a canonical duplex with a "flapping" third strand both in the absence and presence of NC.

A real-time assay for monitoring nucleic acid cleavage by quadruplex formation

Direct and straightforward methods to follow nucleic acid cleavage are needed. A spectrophotometric quadruplex formation assay (QFA) was developed, which allows real-time monitoring of site-specific cleavage of nucleic acids. QFA was applied to study both protein and nucleic acid restriction enzymes, and was demonstrated to accurately determine Michaelis–Menten parameters for the cleavage reaction catalyzed by EcoRI. QFA can be used to study the mechanisms of protein–nucleic acid recognition. QFA is also a useful tool for dissecting individual nicking rates of a double-stranded cleavage.

Unfolding of DNA quadruplexes induced by HIV-1 nucleocapsid protein

The human immunodeficiency virus type 1 nucleocapsid protein (NC) is a nucleic acid chaperone that catalyzes the rearrangement of nucleic acids into their thermodynamically most stable structures. In the present study, a combination of optical and thermodynamic techniques were used to characterize the influence of NC on the secondary structure, thermal stability and energetics of monomolecular DNA quadruplexes formed by the sequence d(GGTTGGTGTGGTTGG) in the presence of K⁺ or Sr²⁺. Circular dichroism studies demonstrate that NC effectively unfolds the quadruplexes. Studies carried out with NC variants suggest that destabilization is mediated by the zinc fingers of NC. Calorimetric studies reveal that NC destabilization is enthalpic in origin, probably owing to unstacking of the G-quartets upon protein binding. In contrast, parallel studies performed on a related DNA duplex reveal that under conditions where NC readily destabilizes and unfolds the quadruplexes, its effect on the DNA duplex is much less pronounced. The differences in NC's ability to destabilize quadruplex versus duplex is in accordance with the higher ΔG of melting for the latter, and with the inverse correlation between nucleic acid stability and the destabilizing activity of NC.