Image analysis-based measurement of DNA supercoiling changes in transformed and nontransformed human cell lines

An image analysis system was used to visualize and measure the changes in nucleoid diameter (nuclear matrix core plus extruded DNA loops) which occur when increasing concentrations of propidium iodide are used to titrate the DNA supercoiling response. Parallel core size measurements allow estimates of the changes in apparent DNA loop size. Unlike sedimentation assays, DNA loop size estimates are not influenced by particle mass, require no prior cell labeling, and can be performed on a per cell basis. This technique was used to examine changes in DNA loop characteristics which may occur when cells are transformed or undergo changes in their proliferative state. SV40-transformation of human diploid fibroblast lines resulted in a significant increase in both the nucleoid core and average DNA loop size. Lymphoblast cell lines also had larger nucleoid dimensions than normal lymphocytes. The response of several established human tumor cell lines indicated slightly increased loop but not core sizes as compared to normal human diploid fibroblasts. Changes in proliferative state also resulted in changes in DNA loop characteristics as measured in this assay. Both quiescent fibroblasts and unstimulated lymphocytes appeared to have smaller or more condensed DNA loop structures than their proliferating counterparts. These results demonstrate the utility of this assay in detecting changes in DNA loop structure which occur in association with changes in the proliferative activity of cells in culture.     

Biological activity of thiophosphamide-alkylated DNA in the transformation system of Bacillus subtilis

DNA treated with thiophosphamide was studied for changes in its biological activity in transformation system of Bac. subtilis. DNA alkylation by this three-functional alkylating agent is shown to be followed by the reduction of transforming activity, changes in the competitive ability as well as by a decrease of the cotransfer coefficient for linked markers of transforming DNA. The observed changes in the transforming and cotransforming activities may be explained by variations in the DNA structure.     

Copy number and loss of heterozygosity detected by SNP array of formalin-fixed tissues using whole-genome amplification

The requirement for large amounts of good quality DNA for whole-genome applications prohibits their use for small, laser capture micro-dissected (LCM), and/or rare clinical samples, which are also often formalin-fixed and paraffin-embedded (FFPE). Whole-genome amplification of DNA from these samples could, potentially, overcome these limitations. However, little is known about the artefacts introduced by amplification of FFPE-derived DNA with regard to genotyping, and subsequent copy number and loss of heterozygosity (LOH) analyses. Using a ligation adaptor amplification method, we present data from a total of 22 Affymetrix SNP 6.0 experiments, using matched paired amplified and non-amplified DNA from 10 LCM FFPE normal and dysplastic oral epithelial tissues, and an internal method control. An average of 76.5% of SNPs were called in both matched amplified and non-amplified DNA samples, and concordance was a promising 82.4%. Paired analysis for copy number, LOH, and both combined, showed that copy number changes were reduced in amplified DNA, but were 99.5% concordant when detected, amplifications were the changes most likely to be 'missed', only 30% of non-amplified LOH changes were identified in amplified pairs, and when copy number and LOH are combined ～50% of gene changes detected in the unamplified DNA were also detected in the amplified DNA and within these changes, 86.5% were concordant for both copy number and LOH status. However, there are also changes introduced as ～20% of changes in the amplified DNA are not detected in the non-amplified DNA. An integrative network biology approach revealed that changes in amplified DNA of dysplastic oral epithelium localize to topologically critical regions of the human protein-protein interaction network, suggesting their functional implication in the pathobiology of this disease. Taken together, our results support the use of amplification of FFPE-derived DNA, provided sufficient samples are used to increase power and compensate for increased error rates.     

Relation between the supercoiling of DNA from loach sperm and the environmental temperature

The effect of environmental temperature changes in the physiological range on DNA supercoiling in the sperm of Misgurnus fossilis L. was studied. Living fishes from the Oka and the Danube and isolated gonads were exposed to temperature changes. In the living fishes, both temperature increase from 4 to 14 degrees C and decrease from 19-21 to 14 degrees resulted in a reversible relaxation of DNA superhelices. Upon decreasing the environmental temperature from 19-21 to 4 degrees C the reversibility of changes in DNA supercoiling was not observed during the next 15 days. In isolated gonads the temperature increase from 4 to 14 degrees C had no effect on the sperm DNA supercoiling. The temperature-dependent changes in the sperm DNA supercoiling were not dependent on the loach population. It is assumed that the effect of changes in environmental temperature on the supercoiling of sperm DNA in vivo plays an important role in the activation of the genome after fertilization.     

辐射后单个细胞DNA结构变化的定量检测

细胞照射后可产生DNA链断裂、DNA-DNA交联、DNA-蛋白质交联等重要的DNA结构损伤,最终可导致DNA高级结构-DNA超螺旋结构状态的改变,而引发DNA复制、表达等一系列改变.参考国外报导,建立了单细胞电泳法(single cell gel electrophoresis assay),并辅以图象分析技术,可快速检测低达0.1Gy剂量所致DNA结构损伤,并得到了较好的剂量-效应关系,可望成为生物剂量计,用于环境低剂量辐射的监测.     

ATPase activity of the UvrA and UvrAB protein complexes of the Escherichia coli UvrABC endonuclease.

We have analyzed the ATPase activity exhibited by the UvrABC DNA repair complex. The UvrA protein is an ATPase whose lack of DNA dependence may be related to the ATP induced monomer-dimer transitions. ATP induced dimerization may be responsible for the enhanced DNA binding activity observed in the presence of ATP. Although the UvrA ATPase is not stimulated by dsDNA, such DNA can modulate the UvrA ATPase activity by decreases in Km and Vm and alterations in the Ki for ADP and ATP-gamma-S. The induction of such changes upon binding to DNA may be necessary for cooperative interactions of UvrA with UvrB that result in a DNA stimulated ATPase for the UvrAB protein complex. The UvrAB ATPase displays unique kinetic profiles that are dependent on the structure of the DNA effector. These kinetic changes correlate with changes in footprinting patterns, the stabilization of protein complexes on DNA damage and with the expression of helicase activity.     

The structure of the complexes of DNA with non-histone chromosomal protein HMGB1 in the presence of manganese ions

The complexes of DNA - HMGB1 protein - manganese ions have been studied using circular dichroism (CD) technique. It was shown that in such three-component system the interactions of both the protein and metal ions with DNA differ from those in two-component complexes. The manganese ions do not affect the CD spectrum of free HMGB1 protein. However, Mn2+ ions induce considerable changes in the CD spectrum of free DNA in the spectral range of 260-290 nm. The presence of Mn2+ ions prevents formation of the ordered supramolecular structures specific for the HMGB1-DNA complexes. The interaction of manganese ions with DNA has a marked influence on the local DNA structure changing the properties of protein-binding sites. This results in the serious decrease in cooperativity of the DNA-protein binding. Such changes in the mode of the DNA-protein interactions occur at concentrations as small as 0.01 mM Mn2+. Moreover, the changes in local DNA structure induced by manganese ions promote the appearance of new HMGB1 binding sites on the DNA double helix. At the same time interactions with HMGB1 protein induce alterations in the structure of the DNA double helix which increase with a growth of the protein/DNA ratio. These alterations make the DNA/protein complex especially sensitive to manganese ions. Under these conditions the Mn2+ ions strongly affect the DNA structure that reflects in abrupt changes of the CD spectra of DNA in the complex in the range of 260-290 nm. Thus, structural changes of the DNA double helix in the three-component DNA-HMGB1-Mn2+ complexes come as a result of the combined and interdependent interactions of DNA with Mn2+ ions and the molecules of HMGB1.     

Design and implementation of computational systems based on programmed mutagenesis

In a new system for DNA computation called programmed mutagenesis, DNA strands are rewritten according to 'rules' that are sequence specific. In a programmed mutagenesis reaction DNA sequences undergo programmed changes, and these changes are implemented by an in-vitro mutagenesis system that is based on thermal cycling the rewriting reaction. We describe experimental results that demonstrate the key aspects of programmed mutagenesis. These results include the creation of full-length product DNA molecules that have embedded rewriting, the ability for later sequence changes to depend on earlier sequence changes, and the ability for multiple oligonucleotides to be active in close proximity on a template sequence. We also discuss the application of programmed mutagenesis to computational problems.     

Dose-dependence, sex- and tissue-specificity, and persistence of radiation-induced genomic DNA methylation changes

Radiation is a well-known genotoxic agent and human carcinogen that gives rise to a variety of long-term effects. Its detrimental influence on cellular function is actively studied nowadays. One of the most analyzed, yet least understood long-term effects of ionizing radiation is transgenerational genomic instability. The inheritance of genomic instability suggests the possible involvement of epigenetic mechanisms, such as changes of the methylation of cytosine residues located within CpG dinucleotides. In the current study we evaluated the dose-dependence of the radiation-induced global genome DNA methylation changes. We also analyzed the effects of acute and chronic high dose (5Gy) exposure on DNA methylation in liver, spleen, and lung tissues of male and female mice and evaluated the possible persistence of the radiation-induced DNA methylation changes. Here we report that radiation-induced DNA methylation changes were sex- and tissue-specific, dose-dependent, and persistent. In parallel we have studied the levels of DNA damage in the exposed tissues. Based on the correlation between the levels of DNA methylation and DNA damage we propose that radiation-induced global genome DNA hypomethylation is DNA repair-related.     

Circular dichroism of the complexes between poly-L-lysine and DNA with different GC contents

Studies were carried out of circular dichroism spectra of the complexes between poly-l-lysine (PL) and calf thymus DNA, E. coli DNA, T2--and T7--phage DNA, Modiolus sp. DNA. The results indicate that PL more strongly changes AT--DNA conformation as compared to GC DNA conformation. This change correlates with the size of minimal PL clusters on DNA investigated. Sequence of DNA bases produces almost no effect on conformational changes caused by the complex-formation with PL.     

Epigenetic regulation of genomic integrity

Inefficient and inaccurate repair of DNA damage is the principal cause of DNA mutations, chromosomal aberrations, and carcinogenesis. Numerous multiple-step DNA repair pathways exist whose deployment depends on the nature of the DNA lesion. Common to all eukaryotic DNA repair pathways is the need to unravel the compacted chromatin structure to facilitate access of the repair machinery to the DNA and restoration of the original chromatin state afterward. Accordingly, our cells utilize a plethora of coordinated mechanisms to locally open up the chromatin structure to reveal the underlying DNA sequence and to orchestrate the efficient and accurate repair of DNA lesions. Here we review changes to the chromatin structure that are intrinsic to the DNA damage response and the available mechanistic insight into how these chromatin changes facilitate distinct stages of the DNA damage repair pathways to maintain genomic stability.     

Evaluation of the random amplified polymorphic DNA (RAPD) assay for the detection of DNA damage and mutations

The random amplified polymorphic DNA (RAPD) assay and related techniques like the arbitrarily primed polymerase chain reaction (AP-PCR) have been shown to detect genotoxin-induced DNA damage and mutations. The changes occurring in RAPD profiles following genotoxic treatments include variation in band intensity as well as gain or loss of bands. However, the interpretation of the molecular events responsible for differences in the RAPD patterns is not an easy task since different DNA alterations can induce similar type of changes. In this study, we evaluated the effects of a number of DNA alterations on the RAPD profiles. Genomic DNA from different species was digested with restriction enzymes, ultrasonicated, treated with benzo[a]pyrene (B[a]P) diol epoxide (BPDE) and the resulting RAPD profiles were evaluated. In comparison to the enzymatic DNA digestions, sonication caused greater changes in the RAPD patterns and induced a dose-related disappearance of the high molecular weight amplicons. A DNA sample substantially modified with BPDE caused very similar changes but amplicons of low molecular weight were also affected. Appearance of new bands and increase in band intensity were also evident in the RAPD profiles generated by the BPDE-modified DNA. Random mutations occurring in mismatch repair-deficient strains did not cause any changes in the banding patterns whereas a single base change in 10-mer primers produced substantial differences. Finally, further research is required to better understand the potential and limitations of the RAPD assay for the detection of DNA damage and mutations.     

Evaluation of the random amplified polymorphic DNA (RAPD) assay for the detection of DNA damage and mutations

The random amplified polymorphic DNA (RAPD) assay and related techniques like the arbitrarily primed polymerase chain reaction (AP-PCR) have been shown to detect genotoxin-induced DNA damage and mutations. The changes occurring in RAPD profiles following genotoxic treatments include variation in band intensity as well as gain or loss of bands. However, the interpretation of the molecular events responsible for differences in the RAPD patterns is not an easy task since different DNA alterations can induce similar type of changes. In this study, we evaluated the effects of a number of DNA alterations on the RAPD profiles. Genomic DNA from different species was digested with restriction enzymes, ultrasonicated, treated with benzo[a]pyrene (B[a]P) diol epoxide (BPDE) and the resulting RAPD profiles were evaluated. In comparison to the enzymatic DNA digestions, sonication caused greater changes in the RAPD patterns and induced a dose-related disappearance of the high molecular weight amplicons. A DNA sample substantially modified with BPDE caused very similar changes but amplicons of low molecular weight were also affected. Appearance of new bands and increase in band intensity were also evident in the RAPD profiles generated by the BPDE-modified DNA. Random mutations occurring in mismatch repair-deficient strains did not cause any changes in the banding patterns whereas a single base change in 10-mer primers produced substantial differences. Finally, further research is required to better understand the potential and limitations of the RAPD assay for the detection of DNA damage and mutations.     

Changes in DNA conformation induced by gamma irradiation in the presence of copper

Gamma irradiation of DNA solutions containing copper causes changes in DNA conformation in oligonucleotides and in natural and synthetic DNAs. Diagnostic for these conformational changes is a ubiquitous 187-nm peak in the circular dichroism (CD) difference spectrum that has been predicted for a transformation from a right-handed to a left-handed helical DNA conformation. Changes in CD are correlated with changes in the UV spectrum. Reduction of DNA-bound Cu(II) to Cu(I) with ascorbic acid produces similar changes in CD spectra. These changes can be produced by the peroxy radical anion (O2*-) and the OH radical in the presence of copper. O2*- is approximately twice as efficient as *OH in initiating these changes in natural DNA. The changes in DNA conformation induced by ionizing radiation are remarkable in that they are dependent on the copper-ion concentration in a highly nonlinear manner at low copper concentrations and are not observed in the absence of copper ions. Possible implications of our results for radiobiological and oxidative damage in the cell nucleus are discussed.     

Direct electrical detection of hybridization at DNA-modified silicon surfaces

Electrochemical impedance spectroscopy was used to investigate the changes in interfacial electrical properties that arise when DNA-modified Si(111) surfaces are exposed to solution-phase DNA oligonucleotides with complementary and non-complementary sequences. The n- and p-type silicon(111) samples were covalently linked to DNA molecules via direct Si?C linkages without any intervening oxide layer. Exposure to solutions containing DNA oligonucleotides with the complementary sequence produced significant changes in both real and imaginary components of the electrical impedance, while exposure to DNA with non-complementary sequences generated negligible responses. These changes in electrical properties were corroborated with fluorescence measurements and were reproduced in multiple hybridization-denaturation cycles. The ability to detect DNA hybridization is strongly frequency-dependent. Modeling of the response and comparison of results on different silicon bulk doping shows that the sensitivity to DNA hybridization arises from DNA-induced changes in the resistance of the silicon substrate and the resistance of the molecular layers.     

In vitro analysis of integrated global high-resolution DNA methylation profiling with genomic imbalance and gene expression in osteosarcoma

Genetic and epigenetic changes contribute to deregulation of gene expression and development of human cancer. Changes in DNA methylation are key epigenetic factors regulating gene expression and genomic stability. Recent progress in microarray technologies resulted in developments of high resolution platforms for profiling of genetic, epigenetic and gene expression changes. OS is a pediatric bone tumor with characteristically high level of numerical and structural chromosomal changes. Furthermore, little is known about DNA methylation changes in OS. Our objective was to develop an integrative approach for analysis of high-resolution epigenomic, genomic, and gene expression profiles in order to identify functional epi/genomic differences between OS cell lines and normal human osteoblasts. A combination of Affymetrix Promoter Tilling Arrays for DNA methylation, Agilent array-CGH platform for genomic imbalance and Affymetrix Gene 1.0 platform for gene expression analysis was used. As a result, an integrative high-resolution approach for interrogation of genome-wide tumour-specific changes in DNA methylation was developed. This approach was used to provide the first genomic DNA methylation maps, and to identify and validate genes with aberrant DNA methylation in OS cell lines. This first integrative analysis of global cancer-related changes in DNA methylation, genomic imbalance, and gene expression has provided comprehensive evidence of the cumulative roles of epigenetic and genetic mechanisms in deregulation of gene expression networks.     

Effect of hydrocortisone on methylation and molecular population of DNA in rat liver]

The content of 5-methyl cytosine in rat liver DNA increases 1,7-fold 8 hours after intraperitoneal injection of hydrocortisone (5 mg per 100 g animal weight). The content of GC, physicochemical parameters (Tm, delta T, etc.) and DNA renaturation pattern did not show any changes. No changes were observed in the pattern of H3-thymidine incorporation into rat liver DNA: after hydrocortisone injection the radioactivity was found to be equally distributed in all isolated sequences of DNA, differing in the degree of reiteration (specific radioactivities of these DNA, fractions are very similar). Thus, the molecular population of DNA in liver cells remains unchanged, which suggests that the hormone-induced increase in the 5-methyl cytosine content is due to a change in the DNA methylation level. The methyation level of unique sequences (COt greater than 600), i. e. that of structural genes, does not undergo any essential changes. The reversible methylation of DNA regulated by hormones seems to be one of the mechanisms controlling gene activity.