QUANTITATION OF DNA DAMAGE IN NON-RADIOACTIVE DNA

Three principal methods have been developed for measuring femtomoles of damage in nanogram quantities of non-radioactive DNA. Lesions which can be quantified include single and double strand breaks, alkali labile sites including apurinic and apyrimidinic sites, and pyrimidine dimers. The first in vitro method measures the conversion of supercoiled DNA to relaxed or linear molecules, and can detect up to four lesions per molecule. The second in vitro method (supercoil depletion) assesses the fraction of intact linear molecules of homogeneous length, and allows detection of 8 lesions/molecule. The third method, measurement of molecular length distributions of DNAs of heterogeneous length, reveals the extent of DNA damage and repair in vivo or in vitro.     

IRRADIATION OF CIRCULAR DNA WITH 254 nm RADIATION OR SENSITIZATION IN THE PRESENCE OF Ag+ EVIDENCE FOR UNWINDING BY PHOTOPRODUCTS OTHER THAN PYRIMIDINE DIMERS

Abstract— Structural alterations of DNA irradiated with UV light were analyzed by the agarose gel technique. Relaxed, circular pAT 153 DNA molecules were sensitized by broad band radiation with a maximum at 313 nm in the presence of silver ions or irradiated with 254 nm light in buffer only. In both cases the electrophoretic mobility of DNA topoisomers was altered as a linear function of UV exposure. For DNA irradiated in the sensitized reaction the unwinding angle per site sensitive to Micrococcus luteus pyrimidine dimer endonuclease was found tobe–11.4°. This value is significantly smaller thanthe–14.3° already known for DNA topoisomers irradiated with 254 nm light. The irradiated DNAs were a very good substrate for the Escherichia coli photoreactivating enzyme (PRE). However, the photoenzymic removal of all sites sensitive to the endonuclease specific for pyrimidine dimers was not coupled to a full restoration of the original electrophoretic mobility. Thirty and 23% of the unwinding were still present in the photoreactivated topoisomers and the unwinding angles per pyrimidine dimer were then recalculatedas–10.1°and–8.7° for DNAs irradiated with 254 nm and sensitized, respectively. The limited difference between these two values could result from the different base composition of the pyrimidine dimers generated in the conditions of irradiation used. These results show that the tertiary structure of DNA is measureably altered by UV photodamages other than pyrimidine dimers.     

β-K4H3[SiW9O37(CpTi)3]·11H2O环戊二烯钛多酸衍生物与DNA作用研究

某些过渡金属配合物具有特异性催化DNA和RNA断裂的功能, 因而研究过渡金属配合物对DNA和RNA的断链反应对新型抗肿瘤、抗艾滋病化学药物的定向设计及其基因治疗和分子生物学中DNA和RNA的高度专一性定点断裂、 DNA定位诱变和构象识别具有重要意义和应用前景[1,2]. 我们对二茂钛多酸有机金属衍生物合成及抗肿瘤活性研究表明, 环戊二烯钛多氧金属酸盐衍生物具有很高的抗肿瘤活性和较好的水溶性及稳定性, 有潜在的抗肿瘤药用价值[3].     

Single-molecule measurements of trapped and migrating circular DNA during electrophoresis in agarose gels

The effect of agarose gel concentration and field strength on the electrophoretic trapping of open (relaxed) circular DNA was investigated using microscopic measurements of individual molecules stained with a fluorescent dye. Three open circles with sizes of 52.5, 115, and 220 kbp were trapped by the electric field (6 V/cm) and found to be predominately fixed and stretched at a single point in the gel. The length of the stretched circles did not significantly change with agarose concentration of the gels (mass fractions of 0.0025, 0.01, and 0.02). The relaxation kinetics of the trapped circles was also measured in the gels. The relaxation of the large open circles was found to be a slow process, taking several seconds. The velocity and average length of the 52.5 kbp open circles and 48.5 kbp linear DNA were measured during electrophoresis in the agarose gels. The velocity increased when the agarose concentrations were lowered, but the average length of the open-circle DNA (during electrophoresis) did not significantly change with agarose gel concentrations. The circles move through the gels by cycles of stretching and relaxation during electrophoresis. Linear dichroism was also used to investigate the trapping and alignment of the 52.5 kbp open circles. The results in this study provide information that can be used to improve electrophoretic separations of circular DNA, an important form of genetic material and commonly used to clone DNA.     

FORMATION OF SINGLE AND DOUBLE STRAND BREAKS IN DNA ULTRAVIOLET IRRADIATED AT HIGH INTENSITY

The induction of single-strand breaks (SSB) by two quantum processes in DNA is well established. We now report that biphotonic processes result in double-strand breaks (DSB) as well. pUC19 and bacteriophage M13 RF DNA were irradiated using an excimer laser (248 nm) at intensities of 10(7), 10(9), 10(10) and 10(11) W/m2 and doses up to 30 kJ/m2. The proportion of DNA as supercoil, open circular, linear and short fragments was determined by gel electrophoresis. Linear molecules were noted at fluences where supercoiled DNA was still present. The random occurrence of independent SSB in proximity to each other on opposite strands (producing linear DNA) implies introduction of numerous SSB per molecule in the sample. If so, supercoiled DNA that has sustained no SSB should not be observed. A model accounting for the amounts of supercoiled, open circular, linear and shorter fragments of DNA due to SSB, DSB and Scissions (opposition of two independently occurring SSB producing an apparent DSB) was developed, our experimental data and those of others were fit to the model, and quantum yields determined for SSB and DSB formation at each intensity. Results showed that high intensity laser radiation caused an increase in the quantum yields for both SSB and DSB formation. The mechanism of DSB formation is unknown, and may be due to simultaneous cleavage of both strands in one biphotonic event or the biased introduction of an SSB opposite a preexisting SSB, requiring two biphotonic events.     

Migration properties of circular DNAs using orthogonal-field-alternation gel electrophoresis

The migration of a series of supercoiled plasmids ranging in size from 4 to 91 kilobases (kb) has been analyzed by orthogonal-field-alternation gel electrophoresis (OFAGE). These circular DNAs enter OFAGE gels and are resolved over the same region of the gel as linear DNAs from 260 to 2200 kb. Furthermore, a distinct triphasic migration pattern was observed for the supercoiled DNAs. The migration of plasmids between 6 and 20, and 60 and 91 kb is inversely proportional to size, whereas the mobilities of plasmids between 20 and 60 kb increase with size. Unlike linear DNA molecules, the relative mobilities of these plasmids are constant over a broad range of pulse times, from 10 to 120s. Electrophoresis of supercoiled, relaxed, and nicked open circular forms as well as topoisomers of small plasmids shows that the extent of supercoiling has a dramatic effect on plasmid migration on OFAGE. Several practical applications for exploiting the different migration properties of circular and linear DNA molecules on OFAGE are presented.     

Methods to electrophoretically stretch DNA: microcontractions, gels, and hybrid gel-microcontraction devices

The ability to controllably and continuously stretch large DNA molecules in a microfluidic format is important for gene mapping technologies such as Direct Linear Analysis (DLA). We have recently shown that electric field gradients can be readily generated in a microfluidic device and the resulting field is purely elongational. We present a single molecule fluorescence microscopy analysis of T4 DNA (169 kbp) stretching in the electric field gradients in a hyperbolic contraction microchannel. In addition, we are able to selectively pattern a crosslinked gel anywhere inside the microchannel. With an applied electric field, DNA molecules are forced to reptate through the gel and they moderately stretch as they exit the gel. By placing a gel immediately in front of the hyperbolic contraction, we bypass "molecular individualism" and achieve highly uniform and complete stretching of T4 DNA.     

Changes in the secondary structure of HMGB1 protein bonded to DNA

The stage of noncooperative interaction of the chromosomal nonhistone protein HMGB1 with DNA has been studied by spectroscopic methods and gel retardation. It was found that complexation was accompanied by compaction of the DNA molecule over a wide range of protein/DNA ratios in the complex. A circular dichroism study showed that the binding with DNA changed the secondary structure of the HMGB1 protein. Changes in the structure of the protein start under the conditions of an excess of binding sites on DNA and end at a ratio of ∼40–50 base pairs per protein molecule, the α-helicity of HMGB1 in the complex increasing by 20% compared with the free state. It is believed that the change in the secondary structure of HMGB1 during the binding with DNA underlies the mechanisms of the various functions of this protein in the cell.     

Nanoparticle-DNA conjugates bearing a specific number of short DNA strands by enzymatic manipulation of nanoparticle-bound DNA

Self-assembling of metallic nanoparticles to form well-defined nanostructured structures is a field that has been receiving considerable research interest in recent years. In this field, DNA is a commonly used linker molecule to direct the assembly of the nanoscale building blocks because of its unique recognition capabilities, mechanical rigidity, and physicochemical stability. This study reported our novel approach to generate gold nanoparticle-DNA conjugates bearing specially designed DNA linker molecules that can be used as building blocks to construct nanoassemblies with precisely controlled structure or as nanoprobes for quantitative DNA sequence detection analysis. In our approach, gold nanoparticle-DNA conjugates bearing a specific number of long double-stranded DNA strands were prepared by gel electrophoresis. A restriction endonuclease enzyme was then used to manipulate the length of the nanoparticle-bound DNA. This enzymatic cleavage was confirmed by gel electrophoresis, and digestion efficiency of 90% or more was achieved. With this approach, nanoparticle conjugates bearing a specific number of strands of short DNA with less than 20-base can be achieved.     

DNA conformation and base number simultaneously determined in a nanopore

When dsDNA polymers containing identical number of base pairs were electrophoresed through a nanopore in a voltage biased silicon nitride membrane, the measured time integral of blocked ionic current (the event-charge-deficit, ecd, Fologea, D., Gershow, M., Ledden, B., McNabb, D. S. et al.., Nano Lett. 2005, 5, 1905-1909) for each translocation event was the same regardless of whether the molecules were in a linear, circular relaxed, or supercoiled form. Conversely, when DNA polymers containing different numbers of base pairs were electrophoresed through a nanopore, the ecd depended strongly on, and predicted the value of, the molecule's number of base pairs. Measurements showed that the magnitude of the current blockages was strongly affected by a molecule's form. The current blockages exhibited characteristic differences that distinguished among single-stranded linear, double-stranded linear, circular relaxed, and supercoiled forms. Because the data that establish ecd are usually determined concomitantly with current blockade measurements, our results show that a single nanopore assay can simultaneously determine both DNA conformation and base number.     

SINGLET OXYGEN INDUCES FRANK STRAND BREAKS AS WELL AS ALKALI- AND PIPERIDINE-LABILE SITES IN SUPERCOILED PLASMID DNA

A covalently closed, circular, supercoiled plasmid was exposed to singlet oxygen by a separated-surface sensitizer. For each exposure, the quantity of single oxygen entering the DNA target solution was estimated by its oxidation of histidine. After singlet oxygen exposure, some DNA samples were treated to disclose occult lesions. Agarose gel electrophoresis was then used to resolve the unrelaxed supercoils from the relaxed circular and linear species, and all bands were quantitated fluorometrically. Exposure of supercoiled plasmid DNA to singlet oxygen induced frank DNA strand breaks, alkali-labile sites (pH 12.5, 90 degrees C, 30 min), and piperidine-labile sites (0.4 M, 60 degrees C, 30 min), all in a dose-dependent manner. Yields of alkali-labile and piperidine-labile sites ranged from one to four times the frank strand break yield. Replacement of buffered H2O by buffered D2O as the DNA solvent for singlet oxygen exposures increased DNA lesion yields by a factor of 2.6 (averaged over lesion classes). Our data for the detection of frank strand breaks is at variance with published results from studies in which singlet oxygen was derived from a thermolabile endoperoxide dissolved in the DNA solution.     

Effect of topological asymmetry on the electrophoretic mobility of branched DNA structures with and without single-base mismatches

The electrophoretic mobility of three-arm star DNA structures with varying degrees of branch length asymmetry has been investigated in polyacrylamide (PAA) hydrogels. We report the effect of single-base mismatches, adjacent to the branch point, on the mobility of branched DNA with three different arm lengths. Branched DNA structures were formed using wild-type and mutated fragments of the p53 tumor suppressor gene, which is believed to play an important role in cancer development. Branching was directed at the site of several previously characterized mutations in exon 7 of p53. At a given gel concentration, the mobility of branched DNA with fully complementary base pairing is found to increase as the degree of branch length asymmetry is increased. Ferguson analysis of the gel electrophoresis data leads to a retardation coefficient that is strongly dependent on topology. This finding can be explained in terms of a minimum molecular cross-section for each molecule. Specifically, we show that structures with the smallest molecular cross-section can access more pores in the gel, which leads to higher mobility. Our results can also be understood by considering the rotational diffusivity of branched DNA. Asymmetric DNA stars with higher calculated rotational diffusivities also have higher mobilities. When a mutated base is present in junctions with low degrees of branch length asymmetry, adjacent to the branch point, the mobility increases in comparison to the fully complementary molecules. The reason for this increased mobility is unclear, here, we propose that the mismatched base introduces additional flexibility to the arm containing the mutation leading to higher conformational freedom and enhanced mobility in gels. When a mismatched base is present in junctions with high degrees of branch length asymmetry, the opposite result is obtained. Here, the mutated species has a lower mobility. This result is argued to arise from incomplete hybridization and/or frayed ends. Finally, we have shown that by using two of the branch point oligonucleotides as probe molecules, mutations known to occur at specific sites can be detected through the mobility shift. If the sequences of the probe chains are changed in a controlled manner, the location and base of the mutant can also be determined.     

Orientation of DNA and the agarose gel matrix in pulsed electric fields

Transient electric birefringence has been used as an analytical tool to study the orientation of DNA in agarose gels, and to study the orientation of the matrix alone. The sign of the birefringence of DNA oriented in an agarose gel is negative, as observed in free solution, indicating that the DNA molecules orient parallel to the direction of the electric field. If the median pore diameter of the gel is larger than the contour length of the DNA molecule, the DNA effectively does not see the matrix and the birefringence relaxation time is the same as observed in free solution. However, if the median pore diameter of the gel is smaller than the contour length of the DNA, the DNA molecule becomes stretched as well as oriented. For DNA molecules of moderate size (less than or equal to 4 kb), stretching in the gel causes the birefringence relaxation times to increase to the values expected for fully stretched molecules. Complete stretching is not observed for larger DNA molecules. The orientation and stretching of DNA molecules in the gel matrix indicates that end-on migration, or reptation, is a likely mechanism for DNA electrophoresis in agarose gels. When the electric field is rapidly reversed in polarity, very little change in the orientation of the DNA is observed if the DNA molecules were completely stretched and had reached their equilibrium orientation before the field was reversed in direction. Hence completely stretched, oriented DNA molecules are able to reverse their direction of migration in the electric field with little or no loss of orientation. However, if the DNA molecules were not completely stretched or if the equilibrium orientation had not been reached, substantial disorientation of the DNA molecules is observed at field reversal. The forced rate of disorientation in the reversing field is faster than the field-free rate of disorientation. Complicated patterns of reorientation can be observed after field reversal, depending on the degree of orientation in the original field direction. The effect of pulsed electric fields on the orientation of the agarose gel matrix itself was also investigated.(ABSTRACT TRUNCATED AT 400 WORDS)     

溶胶-凝胶法制备的罗丹明B/二氧化钛分子印迹聚合物的结构与吸附性能

以罗丹明B为模板分子,以钛酸丁酯为交联剂,采用溶胶-凝胶法在酸性条件下制备了罗丹明B二氧化钛溶胶-凝胶分子印迹聚合物;利用傅立叶变换红外光谱和透射电镜分析了分子印迹聚合物的结构,使用热重分析测定了其热稳定性,采用静态吸附和动态吸附方法考察了其吸附性能,并与非印迹聚合物进行了对比.结果表明,与非印迹聚合物相比,印迹聚合物具有网络状多孔隙凝胶微结构及对模板分子的特异性识别结合位点,因而对模板分子具有更好的吸附性能和特异选择性.其原因可能在于,模板分子上的羰基与钛酸丁酯水解产生的羟基产生氢键作用,使钛酸围绕于模板分子周围,并通过缩聚形成凝胶;当模板分子洗脱后,孔隙得到保留并形成网络状凝胶,从而能够吸附更多的模板分子.     

Transverse alternating field electrophoresis and applications to mammalian genome mapping

The transverse alternating field electrophoresis system is a pulsed field gel apparatus that has been used to separate DNA molecules that range in size from a few thousand to approximately 7 million base pairs. This apparatus uses a vertical gel and a simple electrode arrangement to produce electric fields that are uniform across all lanes of the gel. The velocity of identical molecules does not vary from lane to lane, and hence there is no distortion in the paths of the DNA. The performance of this system is illustrated here using the chromosomes from S. pombe and S. cerevisiae, and restriction enzyme digested mammalian DNA. The mobility of molecules up to 1100 kilobase pairs is linear with size and can be accomplished in overnight runs. Resolution of very large molecules requires electrophoresis for several days, but molecules from 200 to 7000 kilobase pairs can be separated on a single gel. This electrophoresis system has been used extensively in the construction of a physical map of human chromosome 21, and examples of this application are discussed.     

DNA NICKING BY ULTRAVIOLET RADIATION IS ENHANCED IN THE PRESENCE OF IRON and OF OXYGEN

Double-stranded covalently closed circular supercoiled DNA (ccc DNA) from plasmid pUK 9 was irradiated in vitro at denned wavelengths in the UV region (290, 313 and 365 nm). The nicking was monitored by electrophoresis on agarose gels, ethidium staining and densitometric quantitation of supercoiled and relaxed moieties. At the explored wavelengths, the dose required for introducing one nick per million phosphodiester bonds diminishes with increased concentration of added ferric iron, whereas the effect of cupric iron is practically negligible. Adding metal chelators or bubbling argon prior to the irradiation results in a dramatic increase in the dose required for introducing one nick per million phosphodiester bonds. Taken together, these results seem to indicate that iron and oxygen play a role as cofactors in the UV-induced nicking of ccc DNA in vitro.     

Arrest of Rolling Circle Amplification by Protein‐Binding DNA Aptamers

Certain DNA polymerases, such as ?29 DNA polymerase, can isothermally copy the sequence of a circular template round by round in a process known as rolling circle amplification (RCA), which results in super‐long single‐stranded (ss) DNA molecules made of tandem repeats. The power of RCA reflects the high processivity and the strand‐displacement ability of these polymerases. In this work, the ability of ?29DNAP to carry out RCA over circular templates containing a protein‐binding DNA aptamer sequence was investigated. It was found that protein–aptamer interactions can prevent this DNA polymerase from reading through the aptameric domain. This finding indicates that protein‐binding DNA aptamers can form highly stable complexes with their targets in solution. This novel observation was exploited by translating RCA arrest into a simple and convenient colorimetric assay for the detection of specific protein targets, which continues to showcase the versatility of aptamers as molecular recognition elements for biosensing applications.     

Exploring the ability of frozen-density embedding to model induced circular dichroism

In this study, we present calculations of the circular dichroism (CD) spectra of complexes between achiral and chiral molecules. Nonzero rotational strengths for transitions of the nonchiral molecule are induced by interactions between the two molecules, which cause electronic and/or structural perturbations of the achiral molecule. We investigate if the chiral molecule (environment) can be represented only in terms of its frozen electron density, which is used to generate an effective embedding potential. The accuracy of these calculations is assessed in comparison to full supermolecular calculations. We can show that electronic effects arising from specific interactions between the two subsystems can reliably be modeled by the frozen-density representation of the chiral molecule. This is demonstrated for complexes of 2-benzoylbenzoic acid with (-)-(R)-amphetamine and for a nonchiral, artificial amino acid receptor system consisting of ferrocenecarboxylic acid bound to a crown ether, for which a complex with l-leucine is studied. Especially in the latter case, where multiple binding sites and interactions between receptor and target molecule exist, the frozen-density results compare very well with the full supermolecular calculation. We also study systems in which a cyclodextrin cavity serves as a chiral host system for a small, achiral molecule. Problems arise in that case because of the importance of excitonic couplings with excitations in the host system. The frozen-density embedding cannot describe such couplings but can only capture the direct effect of the host electron density on the electronic structure of the guest. If couplings play a role, frozen-density embedding can at best only partially describe the induced circular dichroism. To illustrate this problem, we finally construct a case in which excitonic coupling effects are much stronger than direct interactions of the subsystem densities. The frozen density embedding is then completely unsuitable.     

Looking at long molecules in solution: what happens when they are subjected to Couette flow?

Knowing the structure of a molecule is one of the keys to deducing its function in a biological system. However, many biomacromolecules are not amenable to structural characterisation by the powerful techniques often used namely NMR and X-ray diffraction because they are too large, or too flexible or simply refuse to crystallize. Long molecules such as DNA and fibrous proteins are two such classes of molecule. In this article the extent to which flow linear dichroism (LD) can be used to characterise the structure and function of such molecules is reviewed. Consideration is given to the issues of fluid dynamics and light scattering by such large molecules. A range of applications of LD are reviewed including (i) fibrous proteins with particular attention being given to actin; (ii) a far from comprehensive discussion of the use of LD for DNA and DNA-ligand systems; (iii) LD for the kinetics of restriction digestion of circular supercoiled DNA; and (iv) carbon nanotubes to illustrate that LD can be used on any long molecules with accessible absorption transitions.