基于化学衍生-质谱技术的生物与临床样本中核酸修饰分析

除了经典碱基外,核酸(DNA和RNA)中还包含许多化学修饰。迄今为止,已经在核酸中鉴定了超过150多种化学修饰。这些化学修饰不会改变核酸的序列,但会改变它们的结构和生化特性,最终调节基因的时空表达。阐明这些修饰的功能可以促进对生命体生理调控机制的深入认识和理解。然而,核酸修饰在体内的丰度通常很低。因此,高灵敏和特异的检测方法对破译这些修饰的功能至关重要。化学衍生与质谱技术相结合对内源性低丰度核酸修饰展现出很好的分析能力。在过去几年中,研究者建立了多种基于化学衍生-质谱分析的分析方法,用于灵敏、高效地分析核酸修饰。该文总结了通过化学衍生-质谱分析方法来破译核酸修饰的最新进展,希望能促进未来对核酸修饰功能的深入研究。     

Analytical methods for locating modifications in nucleic acids

We reviewed and summarized the established methods and the breakthrough of the techniques for locating modifications in nucleic acids. In addition, we discussed the principles, applications, advantages and drawbacks of these methods.     

Deciphering nucleic acid modifications by chemical derivatization-mass spectrometry analysis

Chemical derivatization in combination with mass spectrometry (MS) analysis is a promising strategy for the sensitive and effective analysis of nucleic acid modifications. In this review, we summarize the recent advances for deciphering modifications in DNA and RNA by chemical derivatization-MS analysis.     

Ultrasensitive Direct Quantification of Nucleobase Modifications in DNA by Surface‐Enhanced Raman Scattering: The Case of Cytosine

Recognition of chemical modifications in canonical nucleobases of nucleic acids is of key importance since such modified variants act as different genetic encoders, introducing variability in the biological information contained in DNA. Herein, we demonstrate the feasibility of direct SERS in combination with chemometrics and microfluidics for the identification and relative quantification of 4 different cytosine modifications in both single‐ and double‐stranded DNA. The minute amount of DNA required per measurement, in the sub‐nanogram regime, removes the necessity of pre‐amplification or enrichment steps (which are also potential sources of artificial DNA damages). These findings show great potentials for the development of fast, low‐cost and high‐throughput screening analytical devices capable of detecting known and unknown modifications in nucleic acids (DNA and RNA) opening new windows of activity in several fields such as biology, medicine and forensic sciences.     

In Vitro Selection of Specific Ligand-binding Nucleic Acids

In vitro selection is a method that allows the simultaneous screening of very large numbers of nucleic acid molecules for a wide range of properties from binding characteristics to catalytic properties; moreover, the isolation of the very rare functional molecules becomes possible. Binding sites between proteins and nucleic acids, for example, have been evaluated by this methodology in order to gain information about protein/nucleic acid interactions. Structure and function of catalytic RNA (“ribozymes”) has been studied by in vitro selection and has led to new ribozymes with improved catalytic function. Substrate specificity of catalytic RNA has been changed and has led to a ribozyme that cleaves DNA. Other applications include the isolation of nucleic acids that bind specifically to small organic molecules and of RNA molecules that form triple helices with double-stranded DNA. In this article we discuss the background, design, and results of in vitro genetic experiments, which bridge biochemical/molecular biological and organic chemical approaches to molecular recognition.     

Cyclodextrin-Containing Polymers for Gene Delivery

Cyclodextrin-containing polymers are now being explored as vehicles for delivering nucleic acids into cells. The structures of the cyclodextrin-containing polycations affect the nucleic acid delivery efficiencies and their toxicities. Of interest is the fact that the cyclodextrin-containing polymers reveal lower toxicities than polymers that lack the cyclodextrins. The cyclodextrins endow the nucleic acid delivery vehicles with the ability to be modified by compounds that form inclusion complexes with the cyclodextrins, and these modifications can be performed without disruption of the polymer-nucleic acid interactions. Thus, cyclodextrin-containing polymers provide unique properties for gene delivery.     

Nucleic acids for recognition and catalysis: landmarks, limitations, and looking to the future

Combinatorial selection of nucleic acids has led to the discovery of novel ligands and catalysts that have implications for both chemistry and medicine. In the context of combinatorial chemistry, degenerate syntheses of nucleic acid libraries readily generate as many as 10(15) different molecules in which a small percentage exhibit interesting binding and/or catalytic properties. The primary advantage of nucleic acids is that library coding is an intrinsic property; sequential composition directly determines the activity. At low temperatures, the sequential composition of single stranded nucleic acids governs folding into irregular tertiary structures resulting in interesting activities. At higher temperatures, the same structures are unfolded and decoded by polymerases to reveal sequential information. The use of PCR (polymerase chain reaction) permits amplification and thus enrichment of the selected activity which is then regenerated chemi-enzymatically. Iterative selection and amplification result in one of the highest throughput screens conceivable whereby each molecule encodes its own activity permitting the ultimate in parallel sampling. Finally, sequence information, and by extension the chemical composition, is obtained by simple sequencing techniques obviating the need for mass spectrometric deconvolution, parallel tagging, and/or large volumes needed for viral and cell culture. This review begins with an introduction of general concepts and considerations. The potential for nucleic acids to generate tight-binding ligands is of interest to structural biologists and medicinal chemists. The therapeutic implications to medicine are also touched upon. Since combinatorially selected nucleic acids and antibodies share many conceptual similarities, their respective advantages and limitations are compared. Theoretical and practical limitations for catalyst discovery are discussed along with the use of other chemical and physical approaches to address some current catalytic shortcomings. Finally some future directions are suggested.     

Modification of Nucleic Acids by Azobenzene Derivatives and Their Applications in Biotechnology and Nanotechnology

Azobenzene has been widely used as a photoregulator due to its reversible photoisomerization, large structural change between E and Z isomers, high photoisomerization yield, and high chemical stability. On the other hand, some azobenzene derivatives can be used as universal quenchers for many fluorophores. Nucleic acid is a good candidate to be modified because it is not only the template of gene expression but also widely used for building well‐organized nanostructures and nanodevices. Because the size and polarity distribution of the azobenzene molecule is similar to a nucleobase pair, the introduction of azobenzene into nucleic acids has been shown to be an ingenious molecular design for constructing light‐switching biosystems or light‐driven nanomachines. Here we review recent advances in azobenzene‐modified nucleic acids and their applications for artificial regulation of gene expression and enzymatic reactions, construction of photoresponsive nanostructures and nanodevices, molecular beacons, as well as obtaining structural information using the introduced azobenzene as an internal probe. In particular, nucleic acids bearing multiple azobenzenes can be used as a novel artificial nanomaterial with merits of high sequence specificity, regular duplex structure, and high photoregulation efficiency. The combination of functional groups with biomolecules may further advance the development of chemical biotechnology and biomolecular engineering.     

Dynamic Reconfigurable DNA Nanostructures,Networks and Materials

DNA nanotechnology relies on the structural and functional information encoded in nucleic acids. Specifically, the sequence-guided reconfiguration of nucleic acids by auxiliary triggers provides a means to develop DNA switches, machines and stimuli-responsive materials. The present Review addresses recent advances in the construction and applications of dynamic reconfigurable DNA nanostructures, networks and materials. Dynamic transformations proceeding within engineered origami frames or between origami tiles, and the triggered dynamic reconfiguration of scaled supramolecular origami structures are addressed. The use of origami frameworks to assemble dynamic chiroplasmonic optical devices and to operate switchable chemical processes are discussed. Also, the dynamic operation of DNA networks is addressed, and the design of “smart” stimuli-responsive all-DNA materials and their applications are introduced. Future perspectives and applications of dynamic reconfigurable DNA nanostructures are presented.     

Study on suitability of KOD DNA polymerase for enzymatic production of artificial nucleic acids using base/sugar modified nucleoside triphosphates

Recently, KOD and its related DNA polymerases have been used for preparing various modified nucleic acids, including not only base-modified nucleic acids, but also sugar-modified ones, such as bridged/locked nucleic acid (BNA/LNA) which would be promising candidates for nucleic acid drugs. However, thus far, reasons for the effectiveness of KOD DNA polymerase for such purposes have not been clearly elucidated. Therefore, using mutated KOD DNA polymerases, we studied here their catalytic properties upon enzymatic incorporation of nucleotide analogues with base/sugar modifications. Experimental data indicate that their characteristic kinetic properties enabled incorporation of various modified nucleotides. Among those KOD mutants, one achieved efficient successive incorporation of bridged nucleotides with a 2'-ONHCH?CH?-4' linkage. In this study, the characteristic kinetic properties of KOD DNA polymerase for modified nucleoside triphosphates were shown, and the effectiveness of genetic engineering in improvement of the enzyme for modified nucleotide polymerization has been demonstrated.     

Implementing a two-layer feed-forward catalytic DNA circuit for enzyme-free and colorimetric detection of nucleic acids

In the present study, a highly sensitive and specific bio-sensing platform for enzyme-free and colorimetric detection of nucleic acids has been developed. The biosensor is composed of two DNA nanostructures and two fuel strands that construct the foundation of a feed-forward catalytic DNA circuit. Upon binding the target strand to a specific DNA nanostructure, the circuit is run in order that at the end a hemin-binding aptamer, with the ability to convert a colorless substrate into a colored substance is released. Based on this strategy, 4 pM of the target DNA can be easily detected in serum samples by naked eyes after only a two-hour incubation with the circuit; meanwhile, if the incubation time is extended to 3 h, the biosensor can detect 1 pM of the target DNA. Besides the elevated sensitivity, the circuit can truly discriminate a spurious target containing one nucleotide mismatch with high specificity. Overall, the enzyme-free catalytic DNA circuit can be used as a sensitive alternative method to enzyme-based biosensors for the specific and cost-effective detection of nucleic acids.     

DNA Switches: From Principles to Applications

The base sequence of nucleic acid encodes structural and functional properties into the biopolymer. Structural information includes the formation of duplexes, G‐quadruplexes, i‐motif, and cooperatively stabilized assemblies. Functional information encoded in the base sequence involves the strand‐displacement process, the recognition properties by aptamers, and the catalytic functions of DNAzymes. This Review addresses the implementation of the information encoded in nucleic acids to develop DNA switches. A DNA switch is a supramolecular nucleic acid assembly that undergoes cyclic, switchable, transitions between two distinct states in the presence of appropriate triggers and counter triggers, such as pH value, metal ions/ligands, photonic and electrical stimuli. Applications of switchable DNA systems to tailor switchable DNA hydrogels, for the controlled drug‐release and for the activation of switchable enzyme cascades, are described, and future perspectives of the systems are addressed.     

Phosphine‐Free Stille–Migita Chemistry for the Mild and Orthogonal Modification of DNA and RNA

An optimized catalyst system of [Pd₂(dba)₃] and AsPh₃ efficiently catalyzes the Stille reaction between a diverse set of functionalized stannanes and halogenated mono‐, di‐ and oligonucleotides. The methodology allows for the facile conjugation of short and long nucleic acid molecules with moieties that are not compatible with conventional chemical or enzymatic synthesis, among them acid‐, base‐, or fluoride‐labile protecting groups, fluorogenic and synthetically challenging moieties with good to near‐quantitative yields. Notably, even azides can be directly introduced into oligonucleotides and (deoxy)nucleoside triphosphates, thereby giving direct access to “clickable” nucleic acids.     

Recognition of Nucleic Acid Junctions Using Triptycene‐Based Molecules

The modulation of nucleic acids by small molecules is an essential process across the kingdoms of life. Targeting nucleic acids with small molecules represents a significant challenge at the forefront of chemical biology. Nucleic acid junctions are ubiquitous structural motifs in nature and in designed materials. Herein, we describe a new class of structure‐specific nucleic acid junction stabilizers based on a triptycene scaffold. Triptycenes provide significant stabilization of DNA and RNA three‐way junctions, providing a new scaffold for the development of nucleic acid junction binders with enhanced recognition properties. Additionally, we report cytotoxicity and cell uptake data in two human ovarian carcinoma cell lines.     

功能化核酸适体的筛选及分子识别应用

核酸适体是从寡核苷酸文库中筛选获得的一段单链寡核苷酸. 由于能与多种靶标分子高特异性结合, 核酸适体已发展成为一种新兴的分子识别工具, 广泛应用于生物医学等领域. 天然核酸文库有限的化学组成限制了核酸适体的结构和功能, 进而限制了其在分子识别中的应用. 功能化核酸适体通过引入特定的化学官能团使核酸序列具有更丰富的构象和功能, 增强其分子识别能力. 然而, 功能化核酸很难与核酸扩增方法兼容, 因而难以使用传统筛选方法进行功能化核酸的筛选. 因此, 优化筛选方法对于获得具有优异性能的功能化核酸适体至关重要. 本综述总结了功能化核酸适体的筛选方法, 并介绍了其作为分子识别工具在生物医学领域中的应用.     

DNAzymes for sensing, nanobiotechnology and logic gate applications

Catalytic nucleic acids (DNAzymes or ribozymes) are selected by the systematic evolution of ligands by exponential enrichment process (SELEX). The catalytic functions of DNAzymes or ribozymes allow their use as amplifying labels for the development of optical or electronic sensors. The use of catalytic nucleic acids for amplified biosensing was accomplished by designing aptamer-DNAzyme conjugates that combine recognition units and amplifying readout units as in integrated biosensing materials. Alternatively, "DNA machines" that activate enzyme cascades and yield DNAzymes were tailored, and the systems led to the ultrasensitive detection of DNA. DNAzymes are also used as active components for constructing nanostructures such as aggregated nanoparticles and for the activation of logic gate operations that perform computing.     

Nucleic Acid Based Logical Systems

Researchers increasingly visualize a significant role for artificial biochemical logical systems in biological engineering, much like digital logic circuits in electrical engineering. Those logical systems could be utilized as a type of servomechanism to control nanodevices in vitro, monitor chemical reactions in situ, or regulate gene expression in vivo. Nucleic acids (NA), as carriers of genetic information with well‐regulated and predictable structures, are promising materials for the design and engineering of biochemical circuits. A number of logical devices based on nucleic acids (NA) have been designed to handle various processes for technological or biotechnological purposes. This article focuses on the most recent and important developments in NA‐based logical devices and their evolution from in vitro, through cellular, even towards in vivo biological applications.     

核酸光化学生物学

光敏感基团作为光化学开关被广泛应用于各种生物过程的光调控中。特别是过去十几年内,核苷酸、寡聚核苷酸和DNA/RNA的光敏修饰策略得到了长足的发展,并在细胞信号传导和靶基因的功能调控等诸多生物学研究中发挥重要的作用。本文主要针对常用的光敏感基团、光敏感核酸及其化学生物学研究进展进行简要综述,并对未来核酸光化学生物学的研究进行了展望。