新型有机小分子DNA切割试剂的合成

根据活性基团的协同催化原理,设计合成了有机小分子核酸切割剂1-(N-胍乙基)-4-(N-羟乙基)哌嗪盐酸盐(4),并通过核磁共振和液相色谱-质谱联用技术对其结构进行了表征.利用琼糖凝胶电泳研究了pH值对其切割pUC 19 DNA效率的影响,通过自由基猝灭实验研究其切割DNA的反应类型.运用密度泛函理论,利用Gaussian软件进行了理论计算,研究其裂解DNA的反应方式.研究结果表明,在pH=7.2时化合物4的裂解效率最高,且能通过非氧化还原反应以磷酯转移的方式裂解DNA的磷酸二酯键.     

缬氨酸Schiff碱金属铜配合物对质粒DNA的切割作用

缬氨酸Schiff碱金属铜配合物(PBP-L-Val-Cu)是新合成的一类非酶类切割工具, 合成了4种类型样品分别为L-CH3 Cu, D-CH3 Cu, L-Ph Cu和D-Ph Cu. 以质粒DNA(pUC18)为材料,分别对这4种类型化合物进行核酸切割效率的研究, 得出适合的反应体系后, 通过琼脂糖凝胶电泳对反应不同时间后核酸切割产物进行检测, 最终分别得到每种化合物将超螺旋型DNA切割成为开环型DNA和直线型DNA的切割效率, 经比较得出L-CH3 Cu型的切割效率是最快的. 将直线型DNA切割产物用琼脂糖凝胶回收试剂盒进行回收, 得到的直线型切割产物可以在T4连接酶的作用下重新连接起来. 利用酶切法对切口进行检测, 结果表明, 切割作用是具有特异性的. 另外, 该化合物对质粒pNQ216也具有切割活性.     

手性钌(Ⅱ)配合物对DNA的立体选择性断裂

八面体钌(Ⅱ)多吡啶配合物与双螺旋DNA插入结合后具有较强的结合能力,并且含有一个具有氧化一还原活性的中心金属离子．它们对氧化剂相对比较稳定,但对光比较敏感,因此可利用光辐射使之产生单线态氧或羟基自由基等而使DNA裂解．此外,这些配合物具有左手∧-和右手△-两种构型,与同样具有手性的DNA作用时,存在着立体选择性结合．并且在对DNA的断裂反应中也存在一定的立体选择性,可作为不同构型DNA的结构探针．     

A New CoII Complex as a Bulge-Specific Probe for DNA

Bulge cleavage of two or three bases occurs when a DNA substrate is specifically cleaved oxidatively by [Co^II(tfa)₂(happ)] (see picture). Hydrogen peroxide is necessary for the activation of this octahedral complex, which suggests that hydroxyl radicals are the reactive species. The complex has no significant reactivity towards the corresponding sequence in a single-stranded DNA region, and it exhibits only a low affinity towards double-stranded DNA. happ=macrocyclic ligand based on 1,10-phenanthroline, tfa=trifluoroacetate.     

Oxidative DNA cleavage by copper ternary complexes of 1,10-phenanthroline and ethylenediamine-sulfonamide derivatives

Ternary copper(II) complexes (1–3) of 1,10-phenanthroline and ethylenediamine-R-sulfonamide derivatives (R = benzene, toluene and naphthalene rings) have been synthesized and characterized with the aid of X-ray diffraction and spectroscopic and electrochemical techniques. The crystal structures of the complexes show that the coordination polyhedron around copper(II) is distorted square planar. Both 1,10-phenanthroline and ethylenediamine-R-sulfonamide act as bidentate ligands. The three structures are stabilized by π–π stacking interactions. The interaction of the complexes with calf thymus DNA has been investigated by thermal denaturation studies which indicated that DNA was stabilized in the presence of the compounds. The increase in DNA stability induced by the complexes follows the order: 3 > 2 > 1. All three complexes were found to be very efficient agents of plasmid DNA cleavage in the presence of ascorbate as reducing agent. Mechanistic studies of the DNA cleavage process performed with radical scavengers show that the reactive oxygen species involved in the DNA damage are the hydroxyl radical, singlet oxygen-like species, the superoxide* and hydrogen peroxide.     

Synthesis,structure, DNA binding studies and nuclease activities of two luminescent neodymium complexes

Two neodymium(III) complexes, [Nd(Phen)(NO₃)₃(DMF)₂] (1) and [Nd(Phen)₂(NO₃)₃] (2) (phen = 1,10-phenanthroline; DMF = dimethylformamide), have been synthesized with a view to design artificial luminescent nucleases and nuclease mimics. The complexes were characterized by spectroscopic, powder, and single crystal XRD studies. The complexes, as expected, have luminescent properties. The DNA binding studies of both complexes have been carried out by spectroscopic studies e.g. electronic absorption (UV–Vis), fluorescence emission as well as viscosity measurements. The nuclease activity of the complexes has been established by gel electrophoresis using pUC19 circular plasmid DNA. The results of DNA binding as well as DNA cleavage activity and the model studies of interaction with pNPP indicate that both neodymium complexes demonstrate nuclease activity through phosphoester bond cleavage.     

Mixed-ligand oxovanadium complexes incorporating Schiff base ligands: synthesis, DNA interactions, and cytotoxicities

Three oxovanadium complexes, namely [VO(NOSAA)(bpy)] (1) (NOSAA = 2-hydroxy-5-nitrosalicylidene anthranilic acid, bpy = 2,2′-bipyridyl), [VO(NOSAA)(4,4′-dimebpy)] (2) (4,4′-dimebpy = 4,4′-dimethyl-2,2′- bipyridyl), and [VO(NOSAA)(phen)] (3) (phen = 1,10-phenanthroline), have been prepared and characterized. The binding modes and strengths of these complexes with calf thymus DNA (CT-DNA) were studied using various techniques. The chemical nuclease activities and photocleavage reactions of the complexes were also tested. All three complexes interact with CT-DNA through intercalative modes, and complex 3 possesses the largest binding affinity. All three complexes can efficiently cleave pBR322 DNA upon irradiation or under physiological conditions in the presence of H₂O₂, and complex 3 has the best cleaving ability. In vitro experimental results showed that the three complexes are cytotoxic against myeloma (Ag8.653) and gliomas (U251) cell lines and complex 3 again showed the highest efficacy.     

A Tri‐copper(II) Complex Displaying DNA‐Cleaving Properties and Antiproliferative Activity against Cancer Cells

A new disubstituted terpyridine ligand and the corresponding tri‐copper(II) complex have been prepared and characterised. The binding affinity and binding mode of this tri‐copper complex (as well as the previously reported mono‐ and di‐copper analogues) towards duplex DNA were determined by using UV/Vis spectroscopic titrations and fluorescent indicator displacement (FID) assays. These studies showed the three complexes to bind moderately (in the order of 10⁴ M ^?1) to duplex DNA (ct‐DNA and a 26‐mer sequence). Furthermore, the number of copper centres and the nature of the substituents were found to play a significant role in defining the binding mode (intercalative or groove binding). The nuclease potential of the three complexes was investigated by using circular plasmid DNA as a substrate and analysing the products by agarose‐gel electrophoresis. The cleaving activity was found to be dependent on the number of copper centres present (cleaving potency was in the order: tri‐copper>di‐copper>mono‐copper). Interestingly, the tri‐copper complex was able to cleave DNA without the need of external co‐reductants. As this complex displayed the most promising nuclease properties, cell‐based studies were carried out to establish if there was a direct link between DNA cleavage and cellular toxicity. The tri‐copper complex displayed high cytotoxicity against four cancer cell lines. Of particular interest was that it displayed high cytotoxicity against the cisplatin‐resistant MOLT‐4 leukaemia cell line. Cellular uptake studies showed that the tri‐copper complex was able to enter the cell and more importantly localise in the nucleus. Immunoblotting analysis (used to monitor changes in protein levels related to the DNA damage response pathway) and DNA‐flow cytometric studies suggested that this tri‐copper(II) complex is able to induce cellular DNA damage.     

Bioconjugated nanoparticles for DNA protection from cleavage

We have developed a novel method to protect DNA from cleavage using bioconjugated nanoparticles. Positively charged amino-modified silica nanoparticles have been directly prepared using water-in-oil microemulsion. Plasmid DNA can be easily enriched onto the positively charged nanoparticle surface, and the DNA strands are well protected from enzymatic cleavage. When incubated with nuclease enzyme for enzymatic cleavage, free plasmid DNA strands are completely cleaved, while those on the nanoparticle surfaces are intact. Our results clearly demonstrate unique properties of nanomaterials when combined with biomolecules. Our simple bionanotechnology will be highly useful in DNA separation, manipulation, and detection, and possibly in genetic engineering and gene therapy, as plasmid DNA can be protected in cellular environments without any change in its property.     

DNA affinity cleaving : Sequence specific cleavage of DNA by Distamycin-EDTA - Fe(II) and EDTA-distamycin Fe(II)

The attachment of EDTA· Fe(II) to distamycin changes the sequence specific DNA binding antibiotic into a sequence specific DNA cleaving molecule. We report the synthesis of EDTA-distamycin (ED) which has the metal chelator, EDTA, tethered to the carboxy terminus of the N-methylpyrrole tripeptide moiety of the antiobiotic, distamycin. EDTA-distamycin- Fe(II) (ED)·FeII at 10^-6M concentration efficiently cleaves pBR322 DNA (10^-5M in base pairs) in the presence of oxygen and dithiothreitol (DTT). Using Maxam-Gilbert sequencing gel analyses, we find that ED· Fe(II) affords DNA cleavage patterns of unequal intensity covering two to four contiguous base pairs adjacent to a five base pair site consisting of adenines (A) and thymines (T). The multiple cleavages at each site might be evidence for a diffusible oxidizing species, perhaps hydroxyl radical. The unequal intensity of cleavage on each side of the A + T site permit assignment of major and minor orientations of the tripeptide binding unit. A comparison of the cleavage specificity of ED· Fe(II) with distamycin-EDTA· Fe(II), (DE· Fe(II)) which has EDTA · Fe(II) attached to the amino terminus of the N-methylpyrrole tripeptide, shows DNA cleavage patterns at the same sites but with intensities of opposite polarity. Maxam-Gilbert sequencing el analysis of the DNA cleavage patterns by ED Fe(II) and DE Fe(II) on both DNA strands of a 381 se pair restriction fragment reveals asymmetric DNA cleavage patterns. Cleavage is shifted to the 3' de of each DNA strand. A model consistent with this cleavage pattern indicates one preferred binding te for ED Fe(II) and DE Fe(II) is 3'-TTTAA-5' with the “amino end” of the tripeptide oriented to e 3' end of the thymine rich strand. p]This “DNA affinity cleavage” method which consists of attaching cleaving functions to DNA binding molecules followed by DNA cleavage pattern analyses using Maxam-Gilbert sequencing gels may be a useful direct method for determining the binding site and orientation of small molecules on native DNA.     

Ferrocene-conjugated copper(II) dipyridophenazine complex as a multifunctional model nuclease showing DNA cleavage in red light

The copper(II) complex [Cu(L)(dppz)](ClO₄)₂ (1) having a tripodal ligand ferrocenylmethylbis(2-pyridylmethylamine) (L) with a pendant ferrocenyl unit and a planar NN-donor dipyrido-[3,2-a:2′,3′-c]-phenazine (dppz) base is prepared and its DNA binding and cleavage properties studied. The complex is redox active showing cyclic voltammetric responses at 0.52 and –0.01 V vs. SCE due to Fe(III)/Fe(II) and Cu(II)/Cu(I) couples, respectively. The complex that binds to the major groove of DNA shows dual chemical nuclease activity involving both the metal centres. The complex displays efficient photo-induced DNA cleavage activity in visible laser light of 458 and 568 nm wavelengths forming cleavage active hydroxyl radicals. Significant DNA cleavage is also observed in red light of 647 nm within the photodynamic therapy (PDT) window.     

利用荧光标记引物和DNA自动测序仪确定DNA的断裂位点

建立了利用荧光标记引物和DNA自动测序仪进行DNA断裂位点分析的新方法, 该方法简便易行、灵敏度高、重复性好、数据分析客观性强、结果可靠, 适用于各种因素造成的DNA断裂位点的分析.     

Electrochemical DNA Hybridization Detection Using DNA Cleavage

We report the new method for detection of DNA hybridization using enzymatic cleavage. The strategy is based on that S1 nuclease is able to specifically cleave only single strand DNA, but not double strand DNA. The capture probe DNA, thiolated single strand DNA labeled with electroactive ferrocene group, was immobilized on a gold electrode. After hybridization of target DNA of complementary and noncomplementary sequences, nonhybridized single strand DNA was cleaved using S1 nuclease. The difference of enzymatic cleavage on the modified gold electrode was characterized by cyclic voltammetry and differential pulse voltammetry. We successfully applied this method to the sequence‐selective discrimination between perfectly matched and mismatched target DNA including a single‐base mismatched target DNA. Our method does not require either hybridization indicators or other exogenous signaling molecules which most of the electrochemical hybridization detection systems require.     

Synthesis,DNA-binding,and photocleavage studies of ruthenium(II) complexes with an asymmetric ligand

An asymmetric ligand (pdpiq?=?2-(pyridine-2-yl)-6,7-diphenyl-1-H-imidazo[4,5-g]quinoxaline) and its ruthenium complexes with [Ru(L)₂pdpiq]²⁺ (L?=?bpy (2,2′-bipyridine) or phen (1,10-phenanthroline)) have been synthesized and characterized by elemental analysis, ES-MS, and ¹H NMR. The DNA-binding behaviors of these complexes were studied by spectroscopic methods and viscosity measurements. The results indicate that the complexes can intercalate into DNA base pairs. When irradiated at 365?nm, the two complexes promote the cleavage of plasmid pBR322DNA. The mechanism of DNA cleavage is an oxidative process by generating singlet oxygen.     

A model of the structure of HOO-Co·bleomycin bound to d(CCAGTACTGG): recognition at the d(GpT) site and implications for double-stranded DNA cleavage

Background: The bleomycins (BLMs) are a family of natural products used clinically as antitumor agents. In the presence of their required cofactors, iron and oxygen, BLMs bind to and mediate single-stranded and double-stranded DNA cleavage. Recently, two dimensional nuclear magnetic resonance (2D NMR) spectroscopic studies and molecular modeling have provided a picture of how the hydroperoxide form of cobalt BLM A2 (HOO-CoBLM), an analog of ‘activated’ iron BLM (HOO-FeBLM), binds to a d(GpC) motif and of the basis for both sequence specificity and chemical specificity of DNA cleavage.Results: The solution structure of HOO-CoBLM bound to d(CCAGTACTGG) containing a'hot spot' for double-stranded DNA cleavage at T5 and T15 is reported using constraints from 2D NMR spectroscopy. The mode of binding and basis for sequence specificity and chemical specificity of cleavage is almost identical to that of a d(GpC) motif. This structure has allowed formulation of a structural model for how a single molecule of FeBLM can mediate a double-stranded DNA cleavage event without dissociation from the DNA.Conclusions: The structural similarity of HOO-CoBLM bound to d(GpT) in d(CCAGTACTGG) compared to a d(GpC) motif suggests a general paradigm for the binding of HOO-CoBLM to DNA and, by analogy, for the binding of the biological significant entity 100-FeBLM.     

A simple, high sensitivity mutation screening using Ampligase mediated T7 endonuclease I and Surveyor nuclease with microfluidic capillary electrophoresis

Mutation and polymorphism detection is of increasing importance for a variety of medical applications, including identification of cancer biomarkers and genotyping for inherited genetic disorders. Among various mutation-screening technologies, enzyme mismatch cleavage (EMC) represents a great potential as an ideal scanning method for its simplicity and high efficiency, where the heteroduplex DNAs are recognized and cleaved into DNA fragments by mismatch-recognizing nucleases. Thereby, the enzymatic cleavage activities of the resolving nucleases play a critical role for the EMC sensitivity. In this study, we utilized the unique features of microfluidic capillary electrophoresis and de novo gene synthesis to explore the enzymatic properties of T7 endonuclease I and Surveyor nuclease for EMC. Homoduplex and HE DNAs with specific mismatches at desired positions were synthesized using PCR (polymerase chain reaction) gene synthesis. The effects of nonspecific cleavage, preference of mismatches, exonuclease activity, incubation time, and DNA loading capability were systematically examined. In addition, the utilization of a thermostable DNA ligase for real-time ligase mediation was investigated. Analysis of the experimental results has led to new insights into the enzymatic cleavage activities of T7 endonuclease I and Surveyor nuclease, and aided in optimizing EMC conditions, which enhance the sensitivity and efficiency in screening of unknown DNA variations.     

Synthesis,characterization, DNA binding and cleavage properties of a ternary copper(II) Schiff base complex

A ternary coordination complex 2Cu(C₁₄H₈NO₃Cl)(C₁₂H₈N₂)·3CH₃OH of a Schiff base (C₁₄H₈NO₃Cl: 4-chloroanthranilic acid–salicylaldehyde) was synthesized from 4-chloroanthranilic acid, salicylaldehyde, copper acetate and 1,10-phenanthroline and characterized by physicochemical and spectroscopic methods. X-ray crystallography shows that the copper atom is five coordinated by the imine nitrogen, two nitrogen atoms from 1,10-phenanthroline, the hydroxyl oxygen and the carboxylate oxygen atom. The interaction of the complex with calf-thymus DNA was investigated by UV absorption spectroscopy, fluorescence emission spectroscopy and viscosity. In addition, the cleavage reaction with pBR322 supercoiled plasmid DNA was investigated. The complex binds to DNA and also exhibits significant DNA cleavage activity.     

Metallobleomycin-mediated cleavage of DNA not involving a threading-intercalation mechanism.

The DNA cleavage properties of metallobleomycins conjugated to three solid supports were investigated using plasmid DNA, relaxed covalently closed circular DNA, and linear duplex DNA as substrates. Cleavage of pBR322 and pSP64 plasmid DNAs by Fe(II).BLM A(5)-CPG-C(2) was observed with efficiencies not dissimilar to that obtained using free Fe(II).BLM A(5). Similar results were observed following Fe(II).BLM A(5)-CPG-C(2)-mediated cleavage of a relaxed plasmid, a substrate that lacks ends or negative supercoiling capable of facilitating strand separation. BLMs covalently tethered to solid supports, including Fe(II).BLM A(5)-Sepharose 4B, Fe(II).BLM A(5)-CPG-C(6), and Fe(II).BLM A(5)-CPG-C(2), cleaved a 5'-(32)P end labeled linear DNA duplex with a sequence selectivity identical to that of free Fe(II).BLM A(5); cleavage predominated at 5'-G(82)T(83)-3' and 5'-G(84)T(85)-3'. To verify that these results could also be obtained using other metallobleomycins, supercoiled plasmid DNA and a linear DNA duplex were employed as substrates for Co(III).BLM A(5)-CPG-C(2). Free green Co(III).BLM A(5) was only about 2-fold more efficient than green Co(III).BLM A(5)-CPG-C(2) in effecting DNA cleavage. A similar result was obtained using Cu(II).BLM A(5)-CPG-C(2) + dithiothreitol. In addition, the conjugated Co.BLM A(5) and Cu.BLM A(5) cleaved the linear duplex DNA with a sequence selectivity identical to that of the respective free metalloBLMs. Interestingly, when supercoiled plasmid DNA was used as a substrate, conjugated Fe.BLM A(5) and Co.BLM A(5) were both found to produce Form III DNA in addition to Form II DNA. The formation of Form III DNA by conjugated Fe.BLM A(5) was assessed quantitatively. When corrected for differences in the intrinsic efficiencies of DNA cleavage by conjugated vs free BLMs, conjugated Fe.BLM A(5) was found to produce Form III DNA to about the same extent as the respective free Fe.BLM A(5), arguing that this conjugated BLM can also effect double-strand cleavage of DNA. Although previous evidence supporting DNA intercalation by some metallobleomycins is convincing, the present evidence indicates that threading intercalation is not a requirement for DNA cleavage by Fe(II).BLM A(5), Co(III).BLM A(5), or Cu(I).BLM A(5).     

Investigation of DNA cleavage activities of new oxime-type ligand complexes and molecular modeling of complex-DNA interactions

Nucleolytic activities of some new oxime-type ligand complexes were investigated by neutral agarose gel electrophoresis. Analysis of the cleavage products in agarose gel indicated that all complexes used converted supercoiled pUC18 plasmid DNA to its nicked or linear form. It was found that nucleolytic activities of the complexes depend on the complex concentration, reaction time and the presence of a cooxidant (magnesium monoperoxyphthalate, MMPP) in the reaction mixture. However, the complexes cleaved pUC18 plasmid DNA at all investigated pH values. Nucleolytic activities of complexes were investigated for different complex concentrations (0.1–100 μmol L⁻¹), pH values (6.0–10.0) and reaction times (0–60 min). Molecular modeling studies performed by the Hyperchem Software together with DNA-binding studies showed that planar sites of the complexes intercalated into double stranded DNA. It can be concluded that all oxime-type ligand complexes used can be evaluated as nuclease mimics.     

Synthesis and DNA cleavage evaluation of epoxypiperidine derivatives bearing a dehydroamino acid unit

Epoxypiperidine derivatives bearing a dehydroamino acid unit were designed and synthesized as novel DNA alkylating agents based on the structure of azinomycins. A relaxation assay of plasmid DNA revealed that the epoxypiperidine derivative 3 has a DNA cleavage activity. Based on the studies, it would appear that the electron density of the amino group of epoxypiperidines plays a critically important role in the DNA cleavage.