多吡啶钴(Ⅲ)配合物与Zn2+形成的新型“关-开”荧光探针

近十几年来,对小分子过渡金属配合物与大分子DNA键合与识别机理的研究一直是国际上生物无机化学领域十分活跃的研究课题[1￣3],已发展了一系列具有特定功能的配合物,如DNA结构探针和DNA荧光探针等。与其他类型的金属配合物相比,八面体过渡金属多吡啶配合物具有丰富的光化学和光物理信息,当这些配合物与DNA相互作用时,由于结构匹配或微环境的差异,配合物的光谱特征会出现不同程度的改变,从而达到对DNA的检测。传统的DNA荧光探针有[Ru(bpy)2dppz]2 和[Ru(phen)2dppz]2 (bpy=2,2′-联吡啶,phen=1,10-菲咯啉,dppz=二吡啶[3,2-a∶2′,3′…     

DNA修饰电极的研究Ⅷ.1,10-菲咯啉存在时钴离子在ssDNA修饰金电极上的电化学行为及痕量钴的检测

发现在过量1,10-菲咯啉存在时,Co3+/2+在单链DNA(ssDNA)修饰金电极上的电化学响应显著增强.采用紫外光谱和循环伏安法考察了Co3+/2+/1,10-菲咯啉体系与ssDNA的相互作用,并利用Co3+/2+在1,10-菲咯啉存在时在ssDNA修饰金电极上的高灵敏电化学响应对痕量钴离子进行了测定.     

邻二氮菲-Cd2+与DNA的相互作用研究

本文以邻二氮菲作为分子探针,在磷酸盐-氯化钠中性介质中(pH=7.2),用荧光光谱和吸收光谱法研究了邻二氮菲-Cd²⁺与DNA之间的相互作用。结果表明,Cd²⁺离子与邻二氮菲形成1∶2型的配合物,该配合物与DNA有较强的相互作用,这是位于配合物中心的Cd²⁺离子与DNA发生键合。实验发现,在邻二氮菲-Cd²⁺-DNA体系中加入EDTA或柠檬酸,邻二氮菲-Cd²⁺与DNA的相互作用减弱,这表明EDTA或柠檬酸对Cd²⁺的毒性有一定的缓解作用。     

新型一维[Co(phen)(μ3-md)]n的水热合成与结构

采用有机分子建筑块与金属离子制备具有微孔结构材料在催化、化学吸附、磁性和导电性等方面具有潜在的应用前景, 因而成为研究的热点[1～4]. 近来的研究表明, 多齿的有机配体是很好的建筑块, 其中多羧酸化合物和含多氮化合物均是很好的多齿配体. 多羧酸化合物如均苯四甲酸、间苯三甲酸、对苯二甲酸等, 多氮化合物如1,10-邻菲咯啉、 4,4′-联吡啶、 2,2′-联吡啶等[5～11]. 但对同样具有多齿特征的间苯二甲酸作为配体的化合物研究得很少. 本文采用水热合成法合成了[Co(phen)(μ3-md)]n(phen=1,10-phenanthroline, md=Benzene-1,3-dicarboxylate). 该聚合物呈一维双链结构, 通过间苯二甲酸连接3个Co(Ⅱ)形成双分子链, 间苯二甲酸和它连接的3个Co(Ⅱ)离子在同一平面上, 通过垂直于该平面的phen之间的π-π共轭作用形成二维结构.     

单核Zn(Ⅱ)/Ni(Ⅱ)含氮配体配合物的合成、晶体结构及性质

合成了2个新的配合物[Zn(BPP)2(H2O)4](2,6-NDS)·0.5H2O(1)和[Ni(phen)2(H2O)2](A-2,5-DSA)·3H2O(2)(2,6-NDS=2,6-萘二磺酸根,A-2,5-DSA=苯氨-2,5-二磺酸根,BPP=1,3-二(4-吡啶基)丙烷,phen=1,10-邻菲咯啉),用X-射线单晶衍射结构分析方法测定了配合物的晶体结构。配合物1是单核分子,Zn2+离子与2个1,3-二(4-吡啶基)丙烷的2个N原子及4个水分子配位,形成单核配位阳离子。相邻配位阳离子通过配位水分子与氮原子的氢键作用联接成一维双螺旋阳离子链。双螺旋阳离子链与未配位的2,6-萘二磺酸根阴离子通过氢键作用形成二维超分子网。配合物2是单核分子,Ni2+离子与2个1,10-邻菲咯啉分子中的4个N原子及2个水分子配位,形成单核配位阳离子。配位阳离子与游离的水分子及苯氨-2,5-二磺酸根阴离子通过氢键作用构筑成二维超分子网。     

Co(phen)33+与6-巯基嘌呤及DNA间相互作用的研究

自1969年首次报道顺铂(cis-[Pt(NH 3 ) 2 Cl 2 ])对肿瘤有强烈抑制作用以来,金属配合物抗肿瘤药物的研究倍受重视 [1,2] ?很多抗肿瘤药物治疗恶性肿瘤疾病都是通过切割人体肿瘤细胞的DNA来实现的?DNA与外源性分子相互作用的研究构成肿瘤形成的机理和一些抗肿瘤药物作用机理的基     

过渡金属离子与3-氟邻苯二甲酸和1,10-邻菲啰啉配合物的合成、结构及性质

过渡金属离子与3-氟邻苯二甲酸(H2Fpht)、1,10-邻菲啰啉(phen)通过水热反应得到了5个配合物:[M(Fpht)(phen)(H2O)3]·H2O(M=Ni 1,Co 2),[Cu(Fpht)(phen)(H2O)]·H2O(3),[M(Fpht)(phen)(H2O)]·H2O(M=Zn 4,Cd 5)。通过X-射线单晶衍射分析、元素分析、红外分析、荧光分析以及差热-热重分析对配合物进行了表征。配合物1和2为单核分子,中心离子Ni(Ⅱ)和Co(Ⅱ)与3-氟邻苯二甲酸根的1个氧原子,1,10-邻菲啰啉的2个氮原子以及3个配位水分子的3个氧原子配位,形成六配位的扭曲八面体构型。配合物3为Z字形一维链状结构。中心Cu(Ⅱ)离子与2个3-氟邻苯二甲酸根的2个氧原子,1个1,10-邻菲啰啉的2个氮原子以及水分子的1个氧原子配位,形成四方锥构型。配合物4和5具有相似的一维螺旋结构,中心Zn(Ⅱ)和Cd(Ⅱ)离子与2个3-氟邻苯二甲酸根的3个氧原子、1,10-邻菲啰啉的2个氮原子以及水分子中的1个氧原子配位,形成扭曲的八面体构型。     

三维网状配位聚合物{[Cd2(phen)2(H2O)2(C6H5NO2)2]·(ClO4)}n的水热合成、晶体结构及荧光性质

以异烟酸和邻菲咯啉(phen)为原料,采用水热合成方法,合成了一个新的配位聚合物{[Cd2(phen)2(H2O)2(C6H5NO2)2]·(ClO4)}n,测定了其晶体结构.结果表明:该配合物晶体属单斜晶系,空间群P21/n.与中心镉(Ⅱ)离子配位的3个氧原子分别来自2个异烟酸根和1个水分子,3个氮原子分别来自1个异烟酸根和1个邻菲咯啉,形成六配位变形八面体结构.由于异烟酸的桥联作用及氢键作用,配合物堆积成三维网状结构;同时配合物通过异烟酸的羧基双齿桥联配位以及邻菲咯啉和水分子作为端基配位.形成了双核笼状结构,其Cd(Ⅱ)…Cd(Ⅱ)距离为0.8798 nm.此外,还研究了该聚合物的荧光性质.     

2,5-噻吩二甲酸与菲咯啉构筑的稀土配合物:晶体结构,荧光性质和对Cu2+离子的荧光传感

稀土硝酸盐和2,5-噻吩二甲酸与菲咯啉在水热反应条件下合成了3个新的配合物,[Ln(2,5-tdc)1.5(phen)(H2O)]n(Ln=Gd(1),Tb(2),Dy(3);2,5-tdc=2,5-噻吩二甲酸根,phen=菲咯啉)。通过X射线单晶衍射确定了它们的晶体结构。配合物1~3为同构的2D网络结构。配合物1在340 nm激发下出现最大发射中心位于366和387 nm的宽峰,可归属于配体的π*-π跃迁发射。配合物2在365 nm紫外灯照射下发绿光,其荧光发射光谱中出现了4个尖峰,位于491、545、588和620 nm处,对应于Tb3+的5D4→7FJ(J=6~3)跃迁。配合物2的荧光寿命显示为单指数衰减,其值为(0.123±0.005)ms。配合物3的发射光谱中出现了2个尖峰,位于482和575 nm处,分别对应于Dy3+的4F5/2→6H15/2和4F5/2→6H13/2跃迁。另外,研究了配合物2的荧光传感能力,该配合物可作为荧光探针检测水溶液中的Cu2+离子。     

乳酸钴配合物与牛血清蛋白相互作用的研究

合成和表征了系列乳酸钴配合物,测定二水二乳酸钴配合物的结构,配合物中乳酸的羟基和羧基配位键平均键长分别为0.206 0(2)nm和0.206 8(2)nm。当[Co(Hlact)2(H2O)2](2)或[Co(Hlact)2(phen)].2H2O(4)配合物与牛血清白蛋白(BSA=Bovine SerumAlbumin)相互作用后,红外光谱显示乳酸或邻菲咯啉的特征吸收消失,钴离子与BSA出现新的配位,初步推定乳酸或邻菲咯啉配体被BSA中的强配体所取代。     

Pb2+与Co(phen)33+及DNA间的相互作用及其分析测定的研究

DNA电化学传感器是近几年发展起来的一类新型的生物传感器[1]。它不仅可以用来识别和检测特定碱基序列的DNA[2],还可以用来研究DNA的损伤及与药物的作用机理[3]。与同位素标记等方法相比,该类传感器具有识别能力强、简单、快速和灵敏度高等特点[4]。随着人类基因组计划和流行性     

自组装DNA吸附取向的表面增强拉曼光谱法研究

对金基体上自组装寡聚核苷酸探针杂交前后进行电化学非现场及现场表面增强拉曼光谱(SERS)研究.非现场SERS研究表明,杂交形成的dsDNA在基体表面以A型和B型两种构象同时存在,杂交过程可能伴随DNA链在基体表面吸附取向的变化.根据现场SERS研究结果可知,ssDNA及dsDNA的大多数SERS谱带强度随电极电位正移而降低,尤其是归属于碱基A的两种面外振动模式,谱带变化更为明显.利用SERS表面选择定则判断出随着电极电位由负向正变化,ssDNA及dsDNA螺旋吸附取向由垂直吸附向平躺吸附于金基体表面变化.     

Synthesis,characterization, and DNA-binding of [Co(phen)2(CPIA)]3+, [Co(phen)2(BIP)]3+, and [Co(phen)2(CIP)]3+

Three ligands, 2-(3-(carboxymethyl)-1,10-phenanthroline-[5,6-d]imidazole-1-yl)acetate (CPIA), 2-(benzo[d][1,3]dioxol-4-yl)-1H-imidazo[4,5-f][1,10]phenanthroline (BIP), and 2-(9H-carbazol-3-yl)-1H-imidazo[4,5-f][1,10]phenanthroline (CIP), and their complexes, [Co(phen)₂(CPIA)]³⁺ (1) (phen = 1,10-phenanthroline), [Co(phen)₂(BIP)]³⁺ (2), and [Co(phen)₂(CIP)]³⁺ (3), have been synthesized and characterized. Binding of the three complexes with calf thymus DNA (CT-DNA) has been investigated by spectroscopic methods, cyclic voltammetry, and viscosity measurements. The three complexes bind to DNA through an intercalative mode, and the size and shape of the intercalative ligands have significant effects on the binding affinity of complexes to CT-DNA.     

Binding of Ru(bpy)3(2+) and Ru(phen)3(2+) to polynucleotides and DNA: effect to added salts on the absorption and luminescence properties

The interactions of tris(2,2'-bipyridyl)ruthenium(II) chloride and tris-(1,10-phenanthroline)ruthenium(II) chloride, Ru(bpy)3Cl2 and Ru(phen)3Cl2 respectively, with nucleic acids were studied by means of absorption spectroscopy and time-resolved and steady state luminescence techniques in unbuffered aqueous solution at room temperature as a function of added salt, oxygen and the [nucleotide]/[sensitizer] ratio (N/S). The hypochromicity of the visible absorption band of Ru(ligand)3(2+) and the changes in the luminescence intensity and luminescence decay kinetics are considerably larger in the presence of double-stranded calf thymus DNA (dsDNA) than in the presence of single-stranded DNA and polynucleotides. This is suggested to be the result of partial intercalation of the ruthenium complex into the dsDNA rather than just its higher charge density with respect to ssDNA. Spectral changes in the presence of dsDNA increase with increasing N/S ratio (maximum changes reached at N/S = 10-12, half-value 3-4). This is postulated to be due to a transition from mainly electrostatic binding to a binding in which partial intercalation plays an increased role. Addition of alkali or alkaline earth salts at very low concentrations stabilizes partial intercalation whereas higher salt concentrations lead to a release of the ruthenium complex from the strand. This effect of the salt cation increases in the order Cs less than Rb less than K less than Na less than Li less than Ba less than Sr less than Ca less than Mg less than Be. For Ru(bpy)3(2+) the presence of 0.5 mM Mg(ClO4)2 or 6 mM NaClO4 are sufficient to release 50% of the ruthenium complexes which are bound to the dsDNA (N/S = 10); the corresponding half-concentrations for Ru(phen)3(2+) are 0.8 mM and 40 mM respectively. The half-concentrations for release increase with increasing N/S ratio and decrease with the ionic radius of the added salt.     

Synthesis,characterization, photocleavage,antimicrobial activity and DNA binding of [Co(bpy)2MHPIP]3+, [Co(dmb)2MHPIP]3+, and [Co(phen)2MHPIP]3+ complexes

4-Methyl-2-(2-hydroxyphenyl)imidazo[4,5-f][1,10]phenanthroline) (MHPIP) and its complexes [Co(bpy)₂MHPIP]³⁺ (1) (bpy = 2,2′-bipyridine), [Co(dmb)₂MHPIP]³⁺ (2) (dmb = 4,4′-dimethyl-2,2′-bipyridine), and [Co(phen)₂MHPIP]³⁺ (3) (phen = 1,10-phenanthroline) have been synthesized and characterized by UV/VIS, IR, EA, ¹H, ¹³C-NMR, and mass spectra. The binding of the three complexes with calf-thymus-DNA (CT-DNA) has been investigated by absorption and emission spectroscopy, DNA-melting techniques, viscosity measurements, and DNA cleavage assay. The spectroscopic data and viscosity results indicate that these complexes bind to CT-DNA via an intercalative mode. The complexes also promote photocleavage of plasmid pBR322 DNA and were screened for antimicrobial activity.     

灿烂甲酚蓝在DNA修饰金电极上的电化学行为

利用自组装技术将巯基乙醇固定在金电极表面形成巯基乙醇自组装膜修饰金电极, 用乙基-(3-二甲基氨丙基)碳二亚胺盐酸盐(EDC)和N-羟基琥珀酰亚胺(NHS)为偶联试剂, 分别将鲱鱼精单链DNA(ssDNA)和双链DNA(dsDNA)固定于金电极表面形成ssDNA和dsDNA 修饰电极. 考察了灿烂甲酚蓝(BCB)在不同DNA 修饰电极上的电化学行为,结果表明, BCB 在ssDNA 和dsDNA 修饰电极上的吸附常数分别为1.67×10^4和3.22×10^4 L·mol-1, BCB 与ssDNA 主要以静电作用结合, 而与dsDNA作用存在静电和嵌插两种模式. dsDNA 对BCB 具有更高的亲和力, 使BCB 可以作为一种有效的电化学杂交指示剂.     

Spectroscopic Electrochemical Studies of Interaction Between Fuchsin Basic DNA

Visible spectroscopic and electrochemical methods were used to study the interactions between DNA and fuchsin basic(FB). FB has an irreversible electro-oxidation peak in 5 mmol/L Tris-HCl buffer solution at pH = 7.4 on a glassy carbon electrode(GCE). After adding certain concentration of dsDNA, the oxidation peak current of FB decreases, but the peak potential hardly changs. The visible absorption spectroscopic study shows that the binding mode of FB to dsDNA is intercalative binding and electrostatic binding when the ratio of the concentration of dsDNA to FB is smaller than 0. 2, and a new substance, which produces a new absorption peak, is obtained via a covalent binding between dsDNA and FB apart from intercalative binding and electrostatic binding when the ratio of the concentration of dsDNA to FB is larger than 0. 2. The visible absorption spectra varies no longer when the ratio of the concentration of dsDNA to FB is larger than 1.5. A mean binding ratio of dsDNA to FB was determined to be 1.4: 1,suggesting that two complexes FB-dsDNA and FB-2dsDNA be formed. The interaction between FB and ssDNA was only electrostatic binding. The more powerful interaction of FB with dsDNA than with ssDNA may be applied for the recognition of dsDNA and ssDNA, and in DNA biosensor as hybridization indicator.     

The thermal decomposition reactions of [Co(en)n(phen)m]Cl3 complexes

The thermal behaviour of [Co(en)_n(phen)_m]Cl₃ complexes has been studied using thermogravimetry (TG), differential thermogravimetry (DTG) and differential thermal analysis (DTA) in air, nitrogen and oxygen atmospheres. The effect of the stoichiometry of the complexes and that of the gas atmosphere in the furnace chamber on the thermal decomposition reaction is evidenced and discussed. The following thermal stability order has been found [Co(en)₃]Cl₃ [Co(en)₂(phen)]Cl₃ > [Co(en)(phen)₂]Cl₃ [Co(phen)₃]Cl₃     

Synthesis,Characterization, and Properties of Supported Tungstozincate Bridged by Co（Ⅱ） Complex Fragment

[Co^11（phen）3]2[{（ZnW12O40）Co^11（phen）2（H2O）}2Co^11（trien）2（NaH2O）2]·3H2O was synthesized via hydrothermal technique and characterized with elemental analyses, IR spectroscopy, TGA-DTA, and variable temperature magnetic susceptibility. The compound crystallized in the monoclinic system with the space group P21/n, a=1.8210 nm, b=2.3592 nm, c=2.2932 nm, β=110.31°, V=9.239 nm^3, Z=2, R1=0.0827. The compound consists of two coordination cations, three lattice water molecules, and a macroanion [{（ZnW12O40）Co（phen）2（H2O）}2Co（C6H18N4）2·（NaH2O）2]^4- in which each supported Keggin anion [（ZnW12O40Co^11（phen）2（H2O）]^4- acts as a ligand to coordinate to central bridging Co^2＋ ion via a terminal oxygen atom. Hydrogen bonds are responsible for the construction of 3D architecture of the compound. The compound is paramagnetic with a weak antiferromagnetic interaction（0=-46.796 K）.     

Interaction of rac-[Cu(diimine)3]2+ and rac-[Zn(diimine)3]2+ complexes with CT DNA: effect of fluxional Cu(II) geometry on DNA binding, ligand-promoted exciton coupling and prominent DNA cleavage

The complexes [Cu(phen)(3)](ClO(4))(2) 1, [Cu(5,6-dmp)(3)](ClO(4))(2) 2, [Cu(dpq)(3)](ClO(4))(2) 3, [Zn(phen)(3)](ClO(4))(2) 4, [Zn(5,6-dmp)(3)](ClO(4))(2) 5 and [Zn(dpq)(3)](ClO(4))(2) 6, where phen = 1,10-phenanthroline, 5,6-dmp = 5,6-dimethyl-1,10-phenanthroline and dpq = dipyrido[3,2-d:2',3'-f]quinoxaline, have been isolated, characterized and their interaction with calf thymus DNA studied by using a host of physical methods. The X-ray crystal structures of rac-[Cu(5,6-dmp)(3)](ClO(4))(2) and rac-[Zn(5,6-dmp)(3)](ClO(4))(2) have been determined. While 2 possesses a regular elongated octahedral coordination geometry (REO), 5 possesses a distorted octahedral geometry. Absorption spectral titrations of the Cu(II) complexes with CT DNA reveal that the red-shift (12 nm) and DNA binding affinity of 3 (K(b), 7.5 x 10(4) M(-1)) are higher than those of 1 (red-shift, 6 nm; K(b), 9.6 x 10(3) M(-1)) indicating that the partial insertion of the extended phen ring of dpq ligand in between the DNA base pairs is deeper than that of phen ring. Also, 2 with a fluxional Cu(II) geometry interacts with DNA (K(b), 3.8 x 10(4) M(-1)) more strongly than 1 suggesting that the hydrophobic forces of interaction of 5,6 methyl groups on the phen ring is more pronounced than the partial intercalation of phen ring in the latter with a static geometry. The DNA binding affinity of 1 is lower than that of its Zn(ii) analogue 4, and, interestingly, the DNA binding affinity 2 of with a fluxional geometry is higher than that of its Zn(II) analogue 5 with a spherical geometry. It is remarkable that upon binding to DNA 3 shows an increase in viscosity higher than that the intercalator EthBr does, which is consistent with the above DNA binding affinities. The CD spectra show only one induced CD band on the characteristic positive band of CT DNA upon interaction with the phen (1,4) and dpq (3,6) complexes. In contrast, the 5,6-dmp complexes 2 and 5 bound to CT DNA show exciton-coupled biphasic CD signals with 2 showing CD signals more intense than 5. The Delta-enantiomer of rac-[Cu(5,6-dmp)(3)](2+) 2 binds specifically to the right-handed B-form of CT DNA at lower ionic strength (0.05 M NaCl) while the Lambda-enantiomer binds specifically to the left-handed Z-form of CT DNA generated by treating the B-form with 5 M NaCl. The complex 2 is stabilized in the higher oxidation state of Cu(II) more than its phen analogue 1 upon binding to DNA suggesting the involvement of electrostatic forces in DNA interaction of the former. In contrast, 3 bound to DNA is stabilized as Cu(I) rather than the Cu(II) oxidation state due to partial intercalative interaction of the dpq ligand. The efficiencies of the complexes to oxidatively cleave pUC19 DNA vary in the order, 3> 1 > 2 with 3 effecting 100% cleavage even at 10 microM complex concentration. However, interestingly, this order is reversed when the DNA cleavage is performed using H(2)O(2) as an activator and the highest cleavage efficiency of 2 is ascribed to its electrostatic interaction with the exterior phosphates of DNA.