稀土氨基酸配合物与核酸的相互作用*

很多抗癌金属药物是以核酸为靶标。阐明小分子与核酸之间的相互作用对筛选具有高效选择性和低毒副作用的抗癌药物有重要意义。近年来,开发新型的具有对核酸序列特异性识别能力的抗癌药物己成为本领域的研究热点。稀土离子具有良好的磁学、光学、电学特性和配位能力,使稀土配合物成为新型药物试剂。然而,稀土离子在中性条件下易水解的特性极大地阻碍了稀土配合物对核酸分子识别的研究。近年来在近生理条件下合成的一系列镧系氨基酸配合物具有结构稳定、溶解性好等优点,解决了镧系离子易水解的问题。本文总结了目前关于镧系氨基酸配合物与核酸的相互作用及其序列选择性等方面的研究进展。     

Promotion of Double‐Duplex Invasion of Peptide Nucleic Acids through Conjugation with Nuclear Localization Signal Peptide

Pseudo‐complementary peptide nucleic acid (pcPNA), as one of the most widely used synthetic DNA analogues, invades double‐stranded DNA according to Watson–Crick rules to form invasion complexes. This unique mode of DNA recognition induces structural changes at the invasion site and can be used for a range of applications. In this paper, pcPNA is conjugated with a nuclear localization signal (NLS) peptide, and its invading activity is notably promoted both thermodynamically and kinetically. Thus, the double‐duplex invasion complex is formed promptly at low pcPNA concentrations under high salt conditions, where the invasion otherwise never occurs. Furthermore, NLS‐modified pcPNA is successfully employed for site‐selective DNA scission, and the targeted DNA is selectively cleaved under conditions that are not conducive for DNA cutters using unmodified pcPNAs. This strategy of pcPNA modification is expected to be advantageous and promising for a range of in vitro and in vivo applications.     

Toehold-Mediated Strand Displacement in a Triplex Forming Nucleic Acid Clamp for Reversible Regulation of Polymerase Activity and Protein Expression

Triplex forming oligonucleotides are used as a tool for gene regulation and in DNA nanotechnology. By incorporating artificial nucleic acids, target affinity and biological stability superior to that of natural DNA may be obtained. This work demonstrates how a chimeric clamp consisting of acyclic (L)-threoninol nucleic acid (aTNA) and DNA can bind DNA and RNA by the formation of a highly stable triplex structure. The (L)-aTNA clamp is released from the target again by the addition of a releasing strand in a strand displacement type of reaction. It is shown that the clamp efficiently inhibits Bsu and T7 RNA polymerase activity and that polymerase activity is reactivated by displacing the clamp. The clamp was successfully applied to the regulation of luciferase expression by reversible binding to the mRNA. When targeting a sequence in the double stranded plasmid, 40 % downregulation of protein expression is achieved.     

Rapid Synthesis of Propargyl-γ-Modified Peptide Nucleic Acid Monomers for Late-Stage Functionalization of Oligomers

The exceptional hybridization properties of peptide nucleic acids (PNAs) coupled with the ease of their synthesis has made this artificial nucleic acid mimetic a desirable platform for diagnostics, therapeutics and supramolecular engineering. PNA backbone modifications have been extensively explored to finetune physicochemical properties and for conjugation of functional molecules. Here, we detail the synthesis of a universal γ-propargyl-PNA backbone from serine, and its acylation with the four DNA canonical nucleobases. The availability of serine as d or l enantiomer provide simple accesses to PNA oligomers for hybridization with natural oligonucleotides or for orthogonal hybridization circuitry. We show that late-stage conjugation enables optimization of the physicochemical properties. This approach is appealing due to its orthogonality to Fmoc-SPPS, its flexibility and ease for introducing diversity by on-resin copper(I)-catalyzed azide-alkyne cycloaddition (CuAAC). We exemplified the utility of these novel monomers with PNA based hybridization chain reactions (HCRs).     

PNA: Synthetic Polyamide Nucleic Acids with Unusual Binding Properties

The astonishing discovery that peptide nucleic acids (PNAs, B=nucleobase), in spite of their drastic structural difference to natural DNA, are better nucleic acid mimetics than many other oligonucleotides has resulted in an explosion of research into this class of compounds. The synthesis, physical properties, and biological interactions of PNAs as well as their chimeras with DNA and RNA are summarized here.     

De Novo Design of Functional Oligonucleotides with Acyclic Scaffolds

In this account, we demonstrate a new methodology for the de novo design of functional oligonucleotides with the acyclic scaffolds threoninol and serinol. Four functional motifs—wedge, interstrand‐wedge, dimer, and cluster—have been prepared from natural DNA or RNA and functional base surrogates prepared from d ‐threoninol. The following applications of these motifs are described: (1) photoregulation of formation and dissociation of a DNA duplex modified with azobenzene, (2) sequence‐specific detection of DNA using a fluorescent probe, (3) formation of fluorophore assemblies that mimic quantum dots, (4) improved strand selectivity of siRNA modified with a base surrogate, and (5) in vivo tracing of the RNAi pathway. Finally, we introduce artificial nucleic acids (XNAs) prepared from d ‐threoninol and serinol functionalized with each of the four nucleobases, which have unique properties compared with other acyclic XNAs. Functional oligonucleotides designed from acyclic scaffolds will be powerful tools for both DNA nanotechnology and biotechnology.     

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.     

Stabilization of a Bimolecular Triplex by 3′‐S‐Phosphorothiolate Modifications: An NMR and UV Thermal Melting Investigation

Triplexes formed from oligonucleic acids are key to a number of biological processes. They have attracted attention as molecular biology tools and as a result of their relevance in novel therapeutic strategies. The recognition properties of single‐stranded nucleic acids are also relevant in third‐strand binding. Thus, there has been considerable activity in generating such moieties, referred to as triplex forming oligonucleotides (TFOs). Triplexes, composed of Watson–Crick (W–C) base‐paired DNA duplexes and a Hoogsteen base‐paired RNA strand, are reported to be more thermodynamically stable than those in which the third strand is DNA. Consequently, synthetic efforts have been focused on developing TFOs with RNA‐like structural properties. Here, the structural and stability studies of such a TFO, composed of deoxynucleic acids, but with 3′‐S‐phosphorothiolate (3′‐SP) linkages at two sites is described. The modification results in an increase in triplex melting temperature as determined by UV absorption measurements. ¹H NMR analysis and structure generation for the (hairpin) duplex component and the native and modified triplexes revealed that the double helix is not significantly altered by the major groove binding of either TFO. However, the triplex involving the 3′‐SP modifications is more compact. The 3′‐SP modification was previously shown to stabilise G‐quadruplex and i‐motif structures and therefore is now proposed as a generic solution to stabilising multi‐stranded DNA structures.     

Functional Xeno Nucleic Acids for Biomedical Application

Functional nucleic acids(FNAs) refer to a type of oligonucleotides with functions over the traditional genetic roles of nucleic acids, which have been widely applied in screening, sensing and imaging fields. However, the potential application of FNAs in biomedical field is still restricted by the unsatisfactory stability, biocompatibility, biodistribution and immunity of natural nucleic acids(DNA/RNA). Xeno nucleic acids(XNAs) are a kind of nucleic acid analogues with chemically modified sugar groups that possess improved biological properties, including improved biological stability, increased binding affinity, reduced immune responses, and enhanced cell penetration or tissue specificity. In the last two decades, scientists have made great progress in the research of functional xeno nucleic acids, which makes it an emerging attractive biomedical application material. In this review, we summarized the design of functional xeno nucleic acids and their applications in the biomedical field.     

Highly Stable Duplex Formation by Artificial Nucleic Acids Acyclic Threoninol Nucleic Acid (aTNA) and Serinol Nucleic Acid (SNA) with Acyclic Scaffolds

The stabilities of duplexes formed by strands of novel artificial nucleic acids composed of acyclic threoninol nucleic acid (aTNA) and serinol nucleic acid (SNA) building blocks were compared with duplexes formed by the acyclic glycol nucleic acid (GNA), peptide nucleic acid (PNA), and native DNA and RNA. All acyclic nucleic acid homoduplexes examined in this study had significantly higher thermal stability than DNA and RNA duplexes. Melting temperatures of homoduplexes were in the order of aTNA>PNA≈GNA≥SNA?RNA>DNA. Thermodynamic analyses revealed that high stabilities of duplexes formed by aTNA and SNA were due to large enthalpy changes upon formation of duplexes compared with DNA and RNA duplexes. The higher stability of the aTNA homoduplex than the SNA duplex was attributed to the less flexible backbone due to the methyl group of D ‐threoninol on aTNA, which induced clockwise winding. Unlike aTNA, the more flexible SNA was able to cross‐hybridize with RNA and DNA. Similarly, the SNA/PNA heteroduplex was more stable than the aTNA/PNA duplex. A 15‐mer SNA/RNA was more stable than an RNA/DNA duplex of the same sequence.     

The Crystal Structure of Non‐Modified and Bipyridine‐Modified PNA Duplexes

Peptide nucleic acid (PNA) is a synthetic analogue of DNA that commonly has an N‐aminoethyl glycine backbone. The crystal structures of two PNA duplexes, one containing eight standard nucleobase pairs (GGCATGCC)₂, and the other containing the same nucleobase pairs and a central pair of bipyridine ligands, have been solved with a resolution of 1.22 and 1.10 Å, respectively. The non‐modified PNA duplex adopts a P‐type helical structure similar to that of previously characterized PNAs. The atomic‐level resolution of the structures allowed us to observe for the first time specific modes of interaction between the terminal lysines of the PNA and the backbone and the nucleobases situated in the vicinity of the lysines, which are considered an important factor in the induction of a preferred handedness in PNA duplexes. Our results support the notion that whereas PNA typically adopts a P‐type helical structure, its flexibility is relatively high. For example, the base‐pair rise in the bipyridine‐containing PNA is the largest measured to date in a PNA homoduplex. The two bipyridines bulge out of the duplex and are aligned parallel to the major groove of the PNA. In addition, two bipyridines from adjacent PNA duplexes form a π‐stacked pair that relates the duplexes within the crystal. The bulging out of the bipyridines causes bending of the PNA duplex, which is in contrast to the structure previously reported for biphenyl‐modified DNA duplexes in solution, where the biphenyls are π stacked with adjacent nucleobase pairs and adopt an intrahelical geometry. This difference shows that relatively small perturbations can significantly impact the relative position of nucleobase analogues in nucleic acid duplexes.     

l-DNA Duplex Formation as a Bioorthogonal Information Channel in Nucleic Acid-Based Surface Patterning

Photolithographic in situ synthesis of nucleic acids enables extremely high oligonucleotide sequence density as well as complex surface patterning and combined spatial and molecular information encoding. No longer limited to DNA synthesis, the technique allows for total control of both chemical and Cartesian space organization on surfaces, suggesting that hybridization patterns can be used to encode, display or encrypt informative signals on multiple chemically orthogonal levels. Nevertheless, cross-hybridization reduces the available sequence space and limits information density. Here we introduce an additional, fully independent information channel in surface patterning with in situ l -DNA synthesis. The bioorthogonality of mirror-image DNA duplex formation prevents both cross-hybridization on chimeric l -/d -DNA microarrays and also results in enzymatic orthogonality, such as nuclease-proof DNA-based signatures on the surface. We show how chimeric l -/d -DNA hybridization can be used to create informative surface patterns including QR codes, highly counterfeiting resistant authenticity watermarks, and concealed messages within high-density d -DNA microarrays.     

Selective Chemical Modification to the Higher-Order Structures of Nucleic Acids

DNA and RNA can adopt a variety of stable higher-order structural motifs, including G-quadruplex (G4 s), mismatches, and bulges. Many of these secondary structures are closely related to the regulation of gene expression. Therefore, the higher-order structure of nucleic acids is one of the candidate therapeutic targets, and the development of binding molecules targeting the higher-order structure of nucleic acids has been pursued vigorously. Furthermore, as one of the methodologies for detecting the higher-order structures of these nucleic acids, developing techniques for the selective chemical modification of the higher-order structures of nucleic acids is also underway. In this personal account, we focus on the following higher-order structures of nucleic acids, double-stranded DNA containing the abasic site, T−T/U−U mismatch structure, and G-quadruplex structure, and describe the development of molecules that bind to and chemically modify these structures.     

Resonance Rayleigh scattering spectral characteristics of interaction of nucleic acids with some cationic surfactants and their analytical applications

In near neutral medium, the resonance Rayleigh scattering (RRS) intensities of an alone cationic surfactant and nucleic acid are very weak. However, when they combine with each other to form a complex, the RRS intensity of the solution is enhanced greatly. In this paper the reactions of five cationic surfactants with nucleic acids have been studied. The results show that the reaction conditions and RRS spectral characteristics of these reactions are similar, but their sensitivities are obviously different. Among them, the sensitivity of cetyldimethyl benzylammonium chloride (CDBAC) with an aryl and large molecular weight is the highest, while that of cetyl-trimethylammonium bromide (CTAB) without aryl and with small molecular weight is the lowest. The detection limits for ctDNA and yRNA of the former are 6.6 and 29.4 ng · mL-1, while that of the latter are 13.3 and 53.6 ng · mL-1. The method has better selectivity and can be applied to the determination of trace amounts of nucleic acids. Furthermore, i     

Biophysical and cellular-uptake properties of mixed-sequence pyrrolidine-amide oligonucleotide mimics

Previously we introduced the positively charged pyrrolidine-amide oligonucleotide mimics (POM), which possess a pyrrolidine ring and amide linkage in place of the sugar-phosphodiester backbone of natural nucleic acids. Short POM homo-oligomers have shown promising DNA and RNA recognition properties. However, to better understand the properties of POM and to assess their potential for use as modulators of gene expression and bioanalytical or diagnostic tools, more biologically relevant, longer, mixed-sequence oligomers need to be studied. In light of this, several mixed-sequence POM oligomers were synthesised, along with fluorescently labelled POM oligomers and a POM-peptide conjugate. UV thermal denaturation showed that mixed-sequence POMs hybridise to DNA and RNA with high affinity but slow rates of association and dissociation. The sequence specificity, influence of terminal amino acids, and the effect of pH and ionic strength on the DNA and RNA hybridisation properties of POM were extensively investigated. In addition, isothermal titration calorimetry (ITC) was used to investigate the thermodynamic parameters of the binding of a POM-peptide conjugate to DNA. Cellular uptake experiments have also shown that a fluorescently labelled POM oligomer is taken up into HeLa cells. These findings demonstrate that POM has the potential for use in a variety of applications, alongside other modified nucleic acids developed to date, such as peptide nucleic acids (PNA) and phosphoramidate morpholino oligomers (PMO).     

基于核酸分子识别的电化学分析方法与应用

核酸作为生物体遗传信息的载体以及分子生物学和生物分析化学中重要的功能分子,近年来在电化学分析中受到了越来越多的重视。本文以作者所在研究组的工作为实例,对核酸分子识别的电化学分析方法作出简要的评述,内容涉及核酸序列和基因变异的电化学分析以及核酸作为功能分子进行识别检测的电化学分析等等。     

Effects of Six‐Membered Carbohydrate Rings on Structure,Stability, and Kinetics of G‐Quadruplexes

We have evaluated the conformational, thermal, and kinetic properties of d(TGGGGT) analogues with one or five of the ribose nucleotides replaced with the carbohydrate residues hexitol nucleic acid (HNA), cyclohexenyl nucleic acid (CeNA), or altritol nucleic acid (ANA). All of the modified oligonucleotides formed G‐quadruplexes, but substitution with the six‐membered rings resulted in a mixture of G‐quadruplex structures. UV and CD melting analyses showed that the structure formed by d(TGGGGT) modified with HNA was stabilized whereas that modified with CeNA was destabilized, relative to the structure formed by the unmodified oligonucleotide. Substitution at the fourth base of the G‐tract with ANA resulted in a greater stabilization effect than substitution at the first G residue; substitution with five ANA residues resulted in significant stabilization of the G‐quadruplex. A single substitution with CeNA at the first base of the G‐tract or five substitutions with HNA resulted in striking deceleration or acceleration of G‐quadruplex formation, respectively. Our results shed light on the effect of the sugar moiety on the properties of G‐quadruplex structures.     

Oligomers with Intercalating Cytosine–Cytosine+ Base Pairs and Peptide Backbone: DNA i-Motif Analogues

Alanyl peptide nucleic acids organize in a similar manner to the DNA structure motif by stabilizing two cytosine–cytosine⁺ pairing double strands by intercalation (i-motif). These analogues demonstrate that a tetrameric arrangement of nucleobases is necessary for C–C⁺ pairing (see diagram), whereas formation of the i-motif does not depend on the ribosyl–phosphodiester backbone.