质粒DNA超螺旋构象的激光喇曼光谱研究

将pBR322重组质粒DNA纯化,经琼脂糖凝胶电泳鉴定其主要具共价闭合环状空间构象。对此制备物进行激光喇曼散射光谱分析,发现在表征其二级结构为B型的特征模之外,还有另外二个表征磷酸脱氧核糖主链骨架振动状态的特征模854和1083cm~(-1)。本文对此进行探讨,认为这二个特征模与闭合环状DNA分子的超螺旋状态有关,可作为质粒DNA三级结构的特征模。碱基堆积状态分析表明,超螺旋的存在使分子中脱氧胸苷的堆积反应活性增强,并使AT碱基间Hoogsteen型氢键有相当数量的破坏,导致反映脱氧胸苷参与氢键组成的二个基团振动状态的特征模1378cm~(-1)产生相对于线性DNA分子的明显减色及脱氧胸苷羰基双键振动模向高波数偏移。     

溶液中d(AT)_6的构象转化

 本文报道了溶液中d(AT)_6构象研究的结果。探讨了d(AT)_6的物化特征。d(AT)_6在0.05mol/L NaCl和4.5 mol/L NaCl中的UV和CD谱是典型的Z-和B-型DNA谱,UV熔化曲线形状依赖于盐的浓度。当盐浓度低于0.05 mol/L NaCl时,曲线有负斜率;而盐浓度大于0.05mol/L NaCl时,曲线的斜率变为正,即随盐浓度增加,T_m值增加。在链浓度的依赖性基础上,计算了两种构象的△H和△S。     

双股寡聚d(G-C)6 DNA Z-构象的形成及其构象转换的动态研究

研究揭示,生物信息的形成,传递与DNA构象的多样性,特别是其中的左手螺旋Z-构象DNA（Z-DNA）相关.在机体DNA链中,普遍存在的特异序列结构d（C-G）n和d（G-C）n片段易形成Z-构象.但对d（G-C）n序列结构的寡聚体Oligo-d（G-C）n,（n小于8）能转换形成Z-DNA片段少见报道.为促进对Z-DNA尤其是其中的短片段Z-DNA与生物功能的相关性研究,我们对合成并纯化后的寡聚体Oligo-d（G-C）n,n分别为4,6,8,10, 及Oligo-d（C-G）6和多聚体poly-d（G-C）500-900进行Z-构象的形成和其构象转换的比较研究.研究结果发现：①d（GpCpGpCpGpCpGpCpGpCpGpC）是d（G-C）n序列结构中能转换形成Z-构象的最短片段（n＝6）.其转换成Z-构象能力有链长依赖性（poly d（G-C）500-900易于Oligo-d（G-C）6）;②Oligo-d（G-C）6的Z-构象形成能力因溶液中的介质性质不同而异.Co（NH3）3＋〉Mg2＋〉Na＋;C1O-4〉Cl-,因此要求盐溶液的浓度差异很大.③PH7.2,室温条件下,在MgCl2, NaClO4, NaCl溶液浓度分别由0 mol/L增至6.0 mol/L,Oligo-d（G-C）6的B、Z构象转换都出现：B-构象相对稳定期,B-、Z-构象转换跃迁期和Z-构象相对稳定期.每个阶段要求跨越的盐浓度变迁范围也因所用介质而异.当溶液中Oligo-d（G-C）6 B-构象、Z-构象各占50%（θ1/2）时,其盐浓度分别为1.72 mol/L（MgCl2）,2.88 mol/L（NaClO4）,3.85 mol/L（NaCl）.④Oligo-d（G-C）6的B-,Z-构象转换程度受盐浓度影响：当Oligo-d（G-C）6处于最适条件和不同盐溶液其浓度为θ（12）浓度时,温度由8 ℃→22 ℃,在MgCl2,NaClO4溶液中的Oligo-d（G-C）6形成Z-构象能力增加,当由22 ℃→60 ℃,MgCl2溶液中的Z-构象Oligo-d（G-C）6加速增加,而在NaClO4溶液中则是急速向B-型Oligo-d（G-C）6方向转换;温度变化对处于NaCl溶液中的Oligo-d（G-C）6B-、Z-构象相对平衡影响较小.⑤甲基化胞嘧啶即Oligo-d（G-mC）6或d（mC-G）6均增大Z-构象形成能力.⑥在4 mol/L MgCl2溶液中的Oligo-d（G-C）6或Oligo-d（C-G）6或poly d（G-C）500-900的UVab谱、UVcd谱均显示出非B-型或Z-型DNA的新谱型.并且有链长依赖性和因溶液浓度改变出现构象可逆性转变.提示在Oligo-d（G-C）6的构象转换过程中可能存在新构象＂X＂型,即BZX构象转换模式.     

利用~1H-NMR模拟谱研究二核苷酸A2′P(CH_3)5′A的构象性质

根据Altona等人的方法,在利用~1H-NMR模拟谱确定18℃、40℃、70℃三种温度下有关质子化学位移及偶合常数基础上,分析了A2′P(CH_3)5′A的两种非对映异构体(a)和(b)的构象状态。它们与A2′P(OH)5′A相比发现:(1)在18℃时两个核糖环是S型构象占主要成分,但随温度升高有的核糖环趋向于转化成N型构象;(2)磷酸骨架的扭角ε′和β分别改变±2°及±12°;(3)A2′P(CH_3)5′A(a)和(b)的两个核糖环均属部分重叠,并且前者的重叠程度小于后者;(4)随着温度升高,A2′P(CH_3)5′A(a)比A2′P(CH_3)5′A(b)有着更强的去堆积效应。     

利用~1H-NMR模拟谱研究三核苷酸A3′P(CH_3)5′A3′P(CH_3)5′A的构象性质

根据Altona等人的方法.利用~1H—NMR模拟谱分析了A3′P(CH_3)5A3′P(CH_3)5′A的三种非对映异构体:a、b和C的构象状态.发现:在室温下三个核糖环都是S型构象占优势(X_N≤0.44),而且随温度升高S型构象成分增多;两个二核苷酸片段-PAPA和APAP-的磷酸骨架扭角分别与A3′P(CH_3)5′A两种异构体a或b数值接近.差值约5°左右;二核苷酸片段中核糖环的重叠程度与手性磷原子的构型有关、R构型比S构型的核糖环重叠程度小;从而推测,A3′P(CH_3)5′A3′P(CH_3)5′A各种非对映异构体的稳定性为RR>RS.SR>SS,与化学合成中所见相符合.     

1,25-(OH)_2D_3诱导HL-60细胞分化后胞液Ca~(2+)浓度、磷酸化酶a和微粒体Ca~(2+)-ATP酶活性的改变

1,25-(OH)_2D_3对HL-60细胞具有促分化作用。本文报道了1,25-(OH)_2D_3在促进HL-60细胞分化前后胞液Ca~(2+)浓度、磷酸化酶a和微粒体Ca~(2+)-ATP酶活性的改变。结果表明,1,25-(OH)_2D_3加入HL-60细胞培养液后72小时,细胞NBT染色阳性率高于70％,形态向正常分化的细胞转化。同对,胞液Ca~(2+)浓度和微粒体Ca~(2+)-ATP酶活性明显降低,而磷酸化酶a活性显著升高。结果提示,在1,25-(OH)2_D_3作用下,HL-60细胞不仅杀菌功能增强,细胞内胞液Ca~(2+)浓度趋向正常,与钙恒稳有关的酶活性也同样发生改变。即1,25-(OH)_2D_3对HL-60细胞的诱导作用伴有钙恒稳的改变。这些变化与DMSO的作用相同。     

激光拉曼光谱技术在生物分子DNA研究中的应用和进展

激光技术的兴起使拉曼光谱成为激光分析中最活跃的研究领域之一,已被广泛地用于物质成分的分析和分子结构的鉴定。本文综述了拉曼技术在DNA研究中近年来的最新进展,包括：DNA的常规拉曼光谱分析;DNA的激光共振拉曼光谱分析;DNA在金属表面或电极上吸附行为的表面增强拉曼光谱研究;DNA的傅立叶变换拉曼光谱研究等。并对拉曼光谱技术在DNA等生物大分子领域中的研究前景做了进一步的展望。     

Raman microspectroscopic study of effects of Na(I) and Mg(II) ions on low pH induced DNA structural changes

In this work a confocal Raman microspectrometer is used to investigate the influence of Na(+) and Mg(2+) ions on the DNA structural changes induced by low pH. Measurements are carried out on calf thymus DNA at neutral pH (7) and pH 3 in the presence of low and high concentrations of Na(+) and Mg(2+) ions, respectively. It is found that low concentrations of Na(+) ions do not protect DNA against binding of H(+). High concentrations of monovalent ions can prevent protonation of the DNA double helix. Our Raman spectra show that low concentrations of Mg(2+) ions partly protect DNA against protonation of cytosine (line at 1262 cm(-1)) but do not protect adenine and guanine N(7) against binding of H(+) (characteristic lines at 1304 and 1488 cm(-1), respectively). High concentrations of Mg(2+) can prevent protonation of cytosine and protonation of adenine (disruption of AT pairs). By analyzing the line at 1488 cm(-1), which obtains most of its intensity from a guanine vibration, high magnesium salt protect the N(7) of guanine against protonation. A high salt concentration can prevent protonation of guanine, cytosine, and adenine in DNA. Higher salt concentrations cause less DNA protonation than lower salt concentrations. Magnesium ions are found to be more effective in protecting DNA against binding of H(+) as compared with calcium ions presented in a previous study. Divalent metal cations (Mg(2+), Ca(2+)) are more effective in protecting DNA against protonation than monovalent ions (Na(+)).     

Synthesis,DNA Binding,and Oxidative Cleavage Studies of Fe(II) and Co(III) Complexes Containing Bioactive Ligands

The two complexes containing bioactive ligands of the type and [Fe(L)] (PF₆)₂ (1) (where L = [1-{[2-{[2-hydroxynaphthalen-1-yl)methylidine]amino}phenyl)imino] methyl}naphthalene-2-ol]) and [Co(L₁L₂)] (PF₆)₃ (2) (where L₁L₂ = mixed ligand of 2-seleno-4-methylquinoline and 1,10-phenanthroline in the ratio 1:2, respectively) were synthesized and structurally characterized. The DNA binding property of the complexes with calf thymus DNA has been investigated using absorption spectra, viscosity measurements, and thermal denaturation experiments. Intrinsic binding constant K_b has been estimated at room temperature. The absorption spectral studies indicate that the complexes intercalate between the base pairs of the CT-DNA tightly with intrinsic DNA binding constant of 2.8 × 10⁵ M^?1 for (1) and 4.8 × 10⁵ M^?1 for (2) in 5 mM Tris-HCl/50 mM NaCl buffer at pH 7.2, respectively. The oxidative cleavage activity of (1) and (2) were studied by using gel electrophoresis and the results show that complexes have potent nuclease activity.     

Circular dichroism spectra of DNA quadruplexes [d(G(5)T(5))](4) as formed with G(4) and T(4) tetrads and [d(G(5)T(5)). d(A(5)C(5))]2 as formed with Watson-Crick-like (G-C)(2) and (T-A)(2) tetrads

We utilize electrophoresis and find that a thermally treated equimolar mixture of the oligonucleotide d(G(5)T(5)) and its complementary oligonucleotide d(A(5)C(5)) exhibits either two bands or a single band in one lane, depending on the conditions of the incubation solutions. The thermally treated d(G(5)T(5)) solution loaded in a different lane exhibits a single band of the parallel quadruplex [d(G(5)T(5))](4), which is composed of homocyclic hydrogen-bonded G(4) and T(4) tetrads previously proposed. For the thermally treated equimolar mixture of d(G(5)T(5)) and d(A(5)C(5)), the fast band is assigned to a Watson-Crick d(G(5)T(5)). d(A(5)C(5)) duplex, so that the slow band with the same low mobility as that of [d(G(5)T(5))](4) may be assigned to either [d(G(5)T(5))](4) itself or a [d(G(5)T(5)). d(A(5)C(5))](2) quadruplex. If the latter compound is true, this may be the antiparallel quadruplex composed of the heterocyclic hydrogen-bonded G-C-G-C and T-A-T-A tetrads proposed previously. After removing these three bands for the duplex and two kinds of hypothetical quadruplexes, we electrophoretically elute the corresponding compounds in the same electrophoresis buffer using an electroeluter. The eluted compounds are ascertained to be stable by electrophoresis. The circular dichroism (CD) and UV absorption spectra measured for the three isolated compounds are found to be clearly different. For the electrophoretic elution of the hypothetical [d(G(5)T(5))](4) quadruplex, the result of the molecularity of n = 4 obtained from the CD melting curve analysis provides further support for the formation of the parallel [d(G(5)T(5))](4) quadruplex already proposed. For the thermally treated equimolar mixture of d(G(5)T(5)) and d(C(5)A(5)), the fast band with a molecularity of n = 2 corresponds to the Watson-Crick duplex, d(G(5)T(5)). d(A(5)C(5)). The slow band with a molecularity of n = 4 indicates the antiparallel quadruplex [d(G(5)T(5)). d(A(5)C(5))](2), whose observed CD and UV spectra are different from those of [d(G(5)T(5))](4). By electrophoresis, after reannealing the eluted compound [d(G(5)T(5)). d(A(5)C(5))](2), a distinct photograph showing the band splitting of this quadruplex band into the lower duplex and upper quadruplex bands is not possible; but by a transilluminator, we occasionally observe this band splitting with the naked eye. The linear response polarizability tensor calculations for the thus determined structures of the [d(G(5)T(5))](4) quadruplex, the McGavin-like [d(G(5)T(5)). d(A(5)C(5))](2) quadruplex, and the Watson-Crick d(G(5)T(5)). d(A(5)C(5)) duplex are found to qualitatively predict the observed CD and UV spectra.     

Polarized Raman spectrum of single crystal uridylyl (3′–5′) adenosine: Local Raman tensors of some functional groups

Polarized Raman scattering measurements have been made of a single crystal of uridylyl(3′–5′)adenosine (UpA) by the use of a Raman microscope with 488.0 nm excitation. The UpA crystal belongs to space group P2₁ (monoclinic), and Raman intensities I_aa, I_bb, and I_c′c′, have been determined for each Raman band. These intensities correspond to the aa, bb, and c′c′ components of the crystal Raman tensor, where c′ is defined as an axis perpendicular to the crystallographic a axis in the ac plane. From these experimental data, and by taking the known crystal structure into account, anisotropic and isotropic molecular Raman tensors have been calculated for the following 11 normal modes: ring stretching modes of the adenine residue (protonated) at 1560, 1516, 1330, and 715 cm⁻¹; ring stretching modes of the uracil residue at 1696, 1657, 1615, 1228, and 790 cm⁻¹; PO⁻₂ symmetric stretching mode at 1080 cm⁻¹; P(—)O single bond stretching mode at 801 cm₋₁. These pieces of information of the Raman tensors are considered to be useful for estimating the orientations of the DNA and RNA strands in a biological complex from a polarized Raman spectroscopic measurement of such a complex. © 1998 John Wiley & Sons, Inc. Biopoly 45: 135–147, 1998     

Mechanism of Inhibition of DNA Synthesis by 1-β-D-Arabinofuranosyl-E-5-(2-Bromovinyl)uracil

The mechanism of the inhibitory action of 1-β-D -arabinofuranosyl-E-5-(2-bromovinyl) uracil triphosphate (BV-araUTP) on DNA synthesis by Escherichia coli DNA polymerase I Klenow fragment was studied. Acting as a chain terminator, BV-araUTP inhibited DNA synthesis by Klenow fragment more effectively than 2′, 3′-dideoxythymidine triphosphate (ddTTP). However, the incorporation sites of BV-araU monophosphate were restricted at consecutive dTMP sequence whereas ddTMP was incorporated at every dTMP site.     

多位点DNA指纹技术在保加利亚普通田鼠中的应用探讨

DNA指纹是一种重要的现代分子遗传学标记技术（Jeffreys et al．,1985）,它所揭示的是生物体大量的、无遗传编码信息的、具有高度多态性的卫星DNA（Chen,1996）。这些DNA序列往往占据了生物体基因组总量的80％以上,由于它不编码蛋白基因,在系统发育过程中,通常不被自然选择和人工选择,使得生物变异积累形成个体基因组间的巨大差异。因此,DNA指纹受到生物学家的青睐,以用于生物个体和群体的基因组分析（Burke and Bruford,1987;Buitmap et al．,1991;Weising et al．,1995）。     

Effects of the comutagens, harman and norharman, on the interaction of a tryptophan pyrolysis product, 3-amino-1-methyl-5H-pyrido (4,3-b) indole with DNA.

Harman and norharman, known as comutagens of many chemicals, were tested for their effect on the binding to DNA of 3-amino-1-methyl-5H-pyrido(4,3-b)indole, (Trp-P-2), a potent mutagen found with harman and norharman in the pyrolysate of tryptophan (1). We demonstrated that the alteration of the DNA helix by intercalation of these comutagens to DNA does not affect the affinity of this potent mutagen for DNA. Covalent binding, however, was inhibited by the comutagens.     

Studies on the Circular Dichroism (CD) Spectra of Iron-Molyb-denum Protein from Azotobacter vinelandii Nitrogenase

Since the unsymmetry of metal cluster(P-cluster), which was under different redox states, in FeMo protein of A. vinelandii nitrogenase could be observed by circular dichroism, the numbers of the redox equivalent for the P-cluster was obtained by CD titration of DT-stripped FeMo protein with oxidant, i.e. plotting △δ450nm against the number of equivalent of oxidant added. After exposure to air, at the beginning P-cluster was reversibly oxidized, then followed by irreversible oxygen-damage. Dithiothreitol (DTT) was able to increase the C2H2-reduction activity of FeMo protein, which was not severely damaged by O2, or by other stronger oxidants, but could not change their CD spectra. It seems that the reactivation may be not due to the restoration of the P-cluster to its reducing state.