Catalytic DNAs that harness violet light to repair thymine dimers in a DNA substrate

Spectroscopic Investigation of Na+-Dependent Conformational Changes of a Cyclobutane Pyrimidine Dimer-Repairing Deoxyribozyme

UV1C is an enzymatically active DNA sequence (deoxyribozyme, DNAzyme) that functions as a cyclobutane pyrimidine dimer (CPD) photolyase. UV1C forms parallel guanine quadruplexes (G-quadruplexes) with a DNA substrate in the presence of 240 mM Na+, the structure of which is important for the enzymatic activity. To investigate the repair mechanism of CPD by UV1C, we designed light-induced Fourier transform infrared (FTIR) spectroscopy. Prior to FTIR measurements, circular dichroism (CD) spectroscopy was conducted to determine the Na+ concentration at which the most G-quadruplexes were formed. We found that UV1C also forms a hybrid G-quadruplex structure at over 500 mM Na+. By assuming a concentration equilibrium between G-quadruplexes and Na+, 1.3 and 1.8 Na+ were found to bind to parallel and hybrid G-quadruplexes, respectively. The hybrid G-quadruplex form of UV1C was also suggested to exhibit photolyase activity. Light-induced FTIR spectra recorded upon the photorepair of CPD by UV1C were compared for parallel G-quadruplex-rich and hybrid G-quadruplex-rich samples. Spectral variations were indicative of structural differences in parallel and hybrid G-quadruplexes before and after CPD cleavage. Differences were also observed when compared to the CPD repair spectrum by CPD photolyase. The spectral differences during CPD repair by either protein or DNAzyme suggest the local environment of the substrates, the surrounding protein, or the aqueous solution.

Sensing ultrashort electronic coherent beating at conical intersections by single-electron pulses

SignificanceIn a theoretical study, we present an ultrafast technique for probing time-dependent molecular charge densities. An ultrafast optical pump first brings the molecule into an electronic nonstationary state. This is followed by coherent inelastic scattering of a broadband single-electron probe pulse with a variable delay T, which is detected spectrally. The technique is applied to reveal phase-sensitive background-free coherent electron beating in the conical intersection passage in uracil and reveals the otherwise elusive coherent beating of strongly coupled electrons and nuclei.

Probing of Nucleic Acid Structures, Dynamics, and Interactions With Environment-Sensitive Fluorescent Labels

Fluorescence labeling and probing are fundamental techniques for nucleic acid analysis and quantification. However, new fluorescent probes and approaches are urgently needed in order to accurately determine structural and conformational dynamics of DNA and RNA at the level of single nucleobases/base pairs, and to probe the interactions between nucleic acids with proteins. This review describes the means by which to achieve these goals using nucleobase replacement or modification with advanced fluorescent dyes that respond by the changing of their fluorescence parameters to their local environment (altered polarity, hydration, flipping dynamics, and formation/breaking of hydrogen bonds).

Nucleic acids: function and potential for abiogenesis

The emergence of functional cooperation between the three main classes of biomolecules - nucleic acids, peptides and lipids - defines life at the molecular level. However, how such mutually interdependent molecular systems emerged from prebiotic chemistry remains a mystery. A key hypothesis, formulated by Crick, Orgel and Woese over 40 year ago, posits that early life must have been simpler. Specifically, it proposed that an early primordial biology lacked proteins and DNA but instead relied on RNA as the key biopolymer responsible not just for genetic information storage and propagation, but also for catalysis, i.e. metabolism. Indeed, there is compelling evidence for such an 'RNA world', notably in the structure of the ribosome as a likely molecular fossil from that time. Nevertheless, one might justifiably ask whether RNA alone would be up to the task. From a purely chemical perspective, RNA is a molecule of rather uniform composition with all four bases comprising organic heterocycles of similar size and comparable polarity and pK a values. Thus, RNA molecules cover a much narrower range of steric, electronic and physicochemical properties than, e.g. the 20 amino acid side-chains of proteins. Herein we will examine the functional potential of RNA (and other nucleic acids) with respect to self-replication, catalysis and assembly into simple protocellular entities.

DNA's Encounter with Ultraviolet Light: An Instinct for Self-Preservation?

Photochemical modification is the major class of environmental damage suffered by DNA, the genetic material of all free-living organisms. Photolyases are enzymes that carry out direct photochemical repair (photoreactivation) of covalent pyrimidine dimers formed in DNA from exposure to ultraviolet light. The discovery of catalytic RNAs in the 1980s led to the "RNA world hypothesis", which posits that early in evolution RNA or a similar polymer served both genetic and catalytic functions. Intrigued by the RNA world hypothesis, we set out to test whether a catalytic RNA (or a surrogate, a catalytic DNA) with photolyase activity could be contemplated. In vitro selection from a random-sequence DNA pool yielded two DNA enzymes (DNAzymes): Sero1C, which requires serotonin as an obligate cofactor, and UV1C, which is cofactor-independent and optimally uses light of 300-310 nm wavelength to repair cyclobutane thymine dimers within a gapped DNA substrate. Both Sero1C and UV1C show multiple turnover kinetics, and UV1C repairs its substrate with a quantum yield of ∼0.05, on the same order as the quantum yields of certain classes of photolyase enzymes. Intensive study of UV1C has revealed that its catalytic core consists of a guanine quadruplex (G-quadruplex) positioned proximally to the bound substrate's thymine dimer. We hypothesize that electron transfer from photoexcited guanines within UV1C's G-quadruplex is responsible for substrate photoreactivation, analogous to electron transfer to pyrimidine dimers within a DNA substrate from photoexcited flavin cofactors located within natural photolyase enzymes. Though the analogy to evolution is necessarily limited, a comparison of the properties of UV1C and Sero1C, which arose out of the same in vitro selection experiment, reveals that although the two DNAzymes comparably accelerate the rate of thymine dimer repair, Sero1C has a substantially broader substrate repertoire, as it can repair many more kinds of pyrimidine dimers than UV1C. Therefore, the co-opting of an amino acid-like cofactor by a nucleic acid enzyme in this case contributes functional versatility rather than a greater rate enhancement. In recent work on UV1C, we have succeeded in shifting its action spectrum from the UVB into the blue region of the spectrum and determined that although it catalyzes both repair and de novo formation of thymine dimers, UV1C is primarily a catalyst for thymine dimer repair. Our work on photolyase DNAzymes has stimulated broader questions about whether analogous, purely nucleotide-based photoreactivation also occurs in double-helical DNA, the dominant form of DNA in living cells. Recently, a number of different groups have reported that this kind of repair is indeed operational in DNA duplexes, i.e., that there exist nucleotide sequences that actively protect, by way of photoreactivation (rather than by simply preventing their formation), pyrimidine dimers located proximal to them. Nucleotide-based photoreactivation thus appears to be a salient, if unanticipated, property of DNA and RNA. The phenomenon also offers pointers in the direction of how in primordial evolution-in an RNA world-early nucleic acids may have protected themselves from structural and functional damage wrought by ultraviolet light.

Aptamer-integrated DNA nanostructures for biosensing, bioimaging and cancer therapy

The combination of nanostructures with biomolecules leading to the generation of functional nanosystems holds great promise for biotechnological and biomedical applications. As a naturally occurring biomacromolecule, DNA exhibits excellent biocompatibility and programmability. Also, scalable synthesis can be readily realized through automated instruments. Such unique properties, together with Watson-Crick base-pairing interactions, make DNA a particularly promising candidate to be used as a building block material for a wide variety of nanostructures. In the past few decades, various DNA nanostructures have been developed, including one-, two- and three-dimensional nanomaterials. Aptamers are single-stranded DNA or RNA molecules selected by Systematic Evolution of Ligands by Exponential Enrichment (SELEX), with specific recognition abilities to their targets. Therefore, integrating aptamers into DNA nanostructures results in powerful tools for biosensing and bioimaging applications. Furthermore, owing to their high loading capability, aptamer-modified DNA nanostructures have also been altered to play the role of drug nanocarriers for in vivo applications and targeted cancer therapy. In this review, we summarize recent progress in the design of aptamers and related DNA molecule-integrated DNA nanostructures as well as their applications in biosensing, bioimaging and cancer therapy. To begin with, we first introduce the SELEX technology. Subsequently, the methodologies for the preparation of aptamer-integrated DNA nanostructures are presented. Then, we highlight their applications in biosensing and bioimaging for various targets, as well as targeted cancer therapy applications. Finally, we discuss several challenges and further opportunities in this emerging field.

DNA Repair by DNA: The UV1C DNAzyme Catalyzes Photoreactivation of Cyclobutane Thymine Dimers in DNA More Effectively than Their de Novo Formation

UV1C, a 42-nt DNA oligonucleotide, is a deoxyribozyme (DNAzyme) that optimally uses 305 nm wavelength light to catalyze photoreactivation of a cyclobutane thymine dimer placed within a gapped, unnatural DNA substrate, TDP. Herein we show that UV1C is also capable of photoreactivating thymine dimers within an authentic single-stranded DNA substrate, LDP. This bona fide UV1C substrate enables, for the first time, investigation of whether UV1C catalyzes only photoreactivation or also the de novo formation of thymine dimers. Single-turnover experiments carried out with LDP and UV1C, relative to control experiments with LDP alone in single-stranded and double-stranded contexts, show that while UV1C does modestly promote thymine dimer formation, its major activity is indeed photoreactivation. Distinct photostationary states are reached for LDP in its three contexts: as a single strand, as a constituent of a double-helix, and as a 1:1 complex with UV1C. The above results on the cofactor-independent photoreactivation capabilities of a catalytic DNA reinforce a series of recent, unexpected reports that purely nucleotide-based photoreactivation is also operational within conventional double-helical DNA.

Catalytic DNA: Scope, Applications, and Biochemistry of Deoxyribozymes

The discovery of natural RNA enzymes (ribozymes) prompted the pursuit of artificial DNA enzymes (deoxyribozymes) by in vitro selection methods. A key motivation is the conceptual and practical advantages of DNA relative to proteins and RNA. Early studies focused on RNA-cleaving deoxyribozymes, and more recent experiments have expanded the breadth of catalytic DNA to many other reactions. Including modified nucleotides has the potential to widen the scope of DNA enzymes even further. Practical applications of deoxyribozymes include their use as sensors for metal ions and small molecules. Structural studies of deoxyribozymes are only now beginning; mechanistic experiments will surely follow. Following the first report 21 years ago, the field of deoxyribozymes has promise for both fundamental and applied advances in chemistry, biology, and other disciplines.

DNA Catalysis: The Chemical Repertoire of DNAzymes

Deoxyribozymes or DNAzymes are single-stranded catalytic DNA molecules that are obtained by combinatorial in vitro selection methods. Initially conceived to function as gene silencing agents, the scope of DNAzymes has rapidly expanded into diverse fields, including biosensing, diagnostics, logic gate operations, and the development of novel synthetic and biological tools. In this review, an overview of all the different chemical reactions catalyzed by DNAzymes is given with an emphasis on RNA cleavage and the use of non-nucleosidic substrates. The use of modified nucleoside triphosphates (dN*TPs) to expand the chemical space to be explored in selection experiments and ultimately to generate DNAzymes with an expanded chemical repertoire is also highlighted.

Optimal DNA templates for rolling circle amplification revealed by in vitro selection

Rolling circle amplification (RCA) has been widely used as an isothermal DNA amplification technique for diagnostic and bioanalytical applications. Because RCA involves repeated copying of the same circular DNA template by a DNA polymerase thousands of times, we hypothesized there exist DNA sequences that can function as optimal templates and produce more DNA amplicons within an allocated time. Herein we describe an in vitro selection effort conducted to search from a random sequence DNA pool for such templates for phi29 DNA polymerase, a frequently used polymerase for RCA. Diverse DNA molecules were isolated and they were characterized by richness in adenosine (A) and cytidine (C) nucleotides. The top ranked sequences exhibit superior RCA efficiency and the use of these templates for RCA results in significantly improved detection sensitivity. AC-rich sequences are expected to find useful applications for setting up effective RCA assays for biological sensing.

Photoreactivity of the linker region of two consecutive G-quadruplexes formed by human telomeric DNA

The photoreaction method was applied to probe the linker region of two consecutive G-quadruplexes.

Position-specific modification with imidazolyl group on10-23 DNAzyme realized catalytic activity enhancement

Nucleoside analogues with imidazolyl and histidinyl groups were synthesized for site-specific modification on the catalytic core of 10-23 DNAzyme. The distinct position-dependent effect of imidazolyl group was observed. Positive effect at A9 position was always observed. The pH- and Mg(2+)-dependence of the imidazolyl-modified DNAzymes suggested that imidazolyl group in 10-23 DNAzyme probably plays a dual role, its hydrogen bonding ability and spacial occupation play the favorable influence on the catalytic conformation of the modified DNAzymes. This research demonstrated that the catalytic performance of DNAzymes could be enhanced by incorporation of additional functional groups. Chemical modification is a feasible approach toward more efficient DNAzymes for therapeutic and biotechnological applications.

Meeting report: Fourth international meeting on G-quadruplex Nucleic Acids (Singapore, July 1-4, 2013)

The fourth international meeting on G-quadruplex Nucleic Acids was held in the Nanyang Technological University (NTU) of Singapore. Over 150 participants gathered from more than 25 countries. Over 40 talks and 100 posters summarized our current knowledge of these unusual DNA and RNA structures.