Controlled Microwave Heating Accelerates Rolling Circle Amplification.

Rolling circle amplification (RCA) generates single-stranded DNAs or RNA, and the diverse applications of this isothermal technique range from the sensitive detection of nucleic acids to analysis of single nucleotide polymorphisms. Microwave chemistry is widely applied to increase reaction rate as well as product yield and purity. The objectives of the present research were to apply microwave heating to RCA and indicate factors that contribute to the microwave selective heating effect. The microwave reaction temperature was strictly controlled using a microwave applicator optimized for enzymatic-scale reactions. Here, we showed that microwave-assisted RCA reactions catalyzed by either of the four thermostable DNA polymerases were accelerated over 4-folds compared with conventional RCA. Furthermore, the temperatures of the individual buffer components were specifically influenced by microwave heating. We concluded that microwave heating accelerated isothermal RCA of DNA because of the differential heating mechanisms of microwaves on the temperatures of reaction components, although the overall reaction temperatures were the same.

PicoGreen assay of circular DNA for radiation biodosimetry.

We developed a simple, rapid and quantitative assay using the fluorescent probe PicoGreen to measure the concentration of ionizing radiation-induced double-stranded DNA (dsDNA) in mouse plasma, and we correlated this concentration with the radiation dose. With 70 µl of blood obtained by fingerstick, this 30 min assay reduces protein interference without extending sample processing time. Plasma from nonirradiated mice (BALB/c and NIH Swiss) was pooled, diluted and spiked with dsDNA to establish sensitivity and reproducibility of the assay to quantify plasma dsDNA. The assay was then used to directly quantify dsDNA in plasma at 0-48 h after mice received 0-10 Gy total-body irradiation (TBI). There are three optimal conditions for this assay: 1:10 dilution of plasma in water; 1:200 dilution of PicoGreen reagent in water; and calibration of radiation-induced dsDNA concentration through a standard addition method using serial spiking of samples with genomic dsDNA. Using the internal standard calibration curve of the spiked samples method, the signal developed within 5 min, exhibiting a linear signal (r(2) = 0.997). The radiation-induced elevation of plasma DNA in mice started at 1-3 h, peaked at 9 h and gradually returned to baseline at 24 h after TBI (6 Gy). DNA levels in plasma collected from mice 9 h after 0-10 Gy TBI correlated strongly with dose (r(2) = 0.991 and 0.947 for BALB/c and NIH Swiss, respectively). Using the PicoGreen assay, we observed a radiation dose-dependent response in extracellular plasma DNA 9 h after irradiation with an assay time ≤ 30 min.

Photosensitization by imatinib. A photochemical and photobiological study of the drug and its substructures.

Imatinib (IMT) is a promising tyrosine kinase inhibitor used in the treatment of some types of human cancer. It constitutes a successful example of rational drug design based on the optimization of the chemical structure to reach an improved pharmacological activity. Cutaneous reactions, such as increased photosensitivity or pseudoporphyria, are among the most common nonhematological IMT side effects; however, the molecular bases of these clinical observations have not been determined. Thus, to gain insight into the IMT photosensitizing properties, we addressed its photobehavior together with that of its potentially photoactive anilino-pyrimidine and pyridyl-pyrimidine fragments. In this context, steady-state and time-resolved fluorescence as well as laser flash photolysis experiments have been conducted, and the DNA photosensitization potential has been investigated by means of single-strand break detection using agarose gel electrophoresis. The obtained results reveal that the drug itself and its anilino-pyrimidine fragment are not DNA photosensitizers. By contrast, the pyridyl-pyrimidine substructure displays a marked phototoxic potential, which has been associated with the generation of a long-lived triplet excited state. Interestingly, this reactive species is efficiently quenched by benzanilide, another molecular fragment of IMT. Clearly, integration of the photoactive pyridyl-pyrimidine moiety in a more complex structure strongly modifies its photobehavior, which in this case is fortunate as it leads to an improved toxicological profile. Thus, on the bases of the experimental results, direct in vivo photosensitization by IMT seems unlikely. Instead, the reported photosensitivity disorders could be related to indirect processes, such as the previously suggested impairment of melanogenesis or the accumulation of endogenous porphyrins.

Novel method for quantifying radiation-induced single-strand-break yields in plasmid DNA highlights 10-fold discrepancy.

The widely used agarose gel electrophoresis method for assessing radiation-induced single-strand-break (SSB) yield in plasmid DNA involves measurement of the fraction of relaxed-circular (C) form that migrates independently from the intact supercoiled (SC) form. We rationalized that this method may underestimate the SSB yield since the position of the relaxed-circular form is not altered when the number of SSB per DNA molecule is >1. To overcome this limitation, we have developed a novel method that directly probes and quantifies SSBs. Supercoiled (3)H-pUC19 plasmid samples were irradiated with γ-rays, alkali-denatured, dephosphorylated, and kinated with γ-[(32)P]ATP, and the DNA-incorporated (32)P activities were used to quantify the SSB yields per DNA molecule, employing a standard curve generated using DNA molecules containing a known number of SSBs. The same irradiated samples were analyzed by agarose gel and SSB yields were determined by conventional methods. Comparison of the data demonstrated that the mean SSB yield per plasmid DNA molecule of [21.2±0.59]×10(-2)Gy(-1) as measured by direct probing is ~10-fold higher than that obtained from conventional gel-based methods. These findings imply that the SSB yields inferred from agarose gels need reevaluation, especially when they were utilized in the determination of radiation risk.

Promyelocytic leukemia nuclear bodies link the DNA damage repair pathway with hepatitis B virus replication: implications for hepatitis B virus exacerbation during chemotherapy and radiotherapy.

The mechanism responsible for hepatitis B virus (HBV) exacerbation during chemotherapy and radiotherapy remains unknown. We investigated whether the activation of DNA repair pathways influences HBV replication. The upregulation of the promyelocytic leukemia (PML) protein and its associated PML nuclear body (PML-NB) by chemotherapy and irradiation-induced DNA repair signaling correlated with the upregulation of HBV pregenomic transcription, HBV-core expression, and HBV DNA replication. The HBV-core protein and HBV DNA localized to PML-NBs, where they associated with PML and histone deacetylase 1 (HDAC1). Chemotherapy and radiotherapy affected the interactions between PML, HBV-core, and HDAC1. The enhanced protein-protein interaction between PML and HBV-core inhibited PML-mediated apoptosis and decreased PML-associated HDAC activity. The reversal of HDAC-mediated repression on the HBV covalently closed circular DNA basal core promoter resulted in the amplification of HBV-core and pregenomic expression. These results suggest that PML in PML-NBs links the DNA damage response with HBV replication and may cooperate with HBV-core and HDAC1 on the HBV covalently closed circular DNA basal core promoter to form a positive feedback loop for HBV exacerbation during chemotherapy and radiotherapy.

Gold nanoparticles enhance DNA damage induced by anti-cancer drugs and radiation.

The chemotherapeutic agent cisplatin was chemically linked to pGEM-3Zf(-) plasmid DNA to produce a cisplatin-DNA complex, Gold nanoparticles, which bind electrostatically to pure DNA, could also be added to this complex. Dry films of pure plasmid DNA and DNA-cisplatin, DNA-gold nanoparticles and DNA-cisplatin-gold nanoparticles complexes were bombarded by 60 keV electrons. The yields of single- and double-strand breaks were measured as a function of exposure by electrophoresis. From a comparison of such yields from the different type of films, we found that the binding of only one gold nanoparticle to a plasmid-cisplatin complex containing 3197 base pairs increases by a factor of 3 the efficiency of the chemotherapeutic agent cisplatin to produce double-strand breaks in irradiated DNA. Furthermore, adding two cisplatin molecules and one gold nanoparticle to DNA enhances radiation-induced DSBs by a factor of 7.5. A number of phenomena could contribute to this huge enhancement, including the higher density of low-energy electrons and reactive species around the gold nanoparticles and the weakening of bonds adjacent to cisplatin in the DNA backbone. The addition of gold nanoparticles to cisplatin and other platinum agents may therefore provide interesting avenues of research to improve the treatment of cancer by concomitant chemoradiation.

Reversible photopadlocking on double-stranded DNA.

We describe a highly efficient method for reversible photocircularization of oligonucleotide (ODN) on a double-stranded DNA template: 5-carboxyvinyl-2'-deoxyuridine-containing ODN was reversibly circularized around the target sequence of the double-stranded plasmid DNA resulting in formation of a catenated plasmid.

Characterization of a complex 125I-induced DNA double-strand break: implications for repair.

PURPOSE: To examine the role of radiation-induced DNA double-strand break (DSB) structural organization in DSB repair, and characterize the structural features of 125I-induced DSBs that may impact the repair process. METHODS: Plasmid DNA was linearized by sequence-specific targeting using an 125I-labeled triplex-forming oligonucleotide (TFO). Following isolation from agarose gels, base damage structures associated with the DSB ends in plasmids linearized by the 125I-TFO were characterized by probing with the E. coli DNA damage-specific endonuclease and DNA-glycosylases, endonuclease IV (endo IV), endonuclease III (endo III), and formamidopyrimidine-glycosylase (Fpg). RESULTS: Plasmid DNA containing DSBs produced by the high-LET-like effects of 125I-TFO has been shown to support at least 2-fold lower end joining than gamma-ray linearized plasmid, and this may be a consequence of the highly complex structure expected near an 125I-induced DSB end. Therefore, to determine if a high density of base damage exists proximal to the DSBs produced by 125I-TFOs, short fragments of DNA recovered from the DSB end of 125I-TFO-linearized plasmid were enzymatically probed. Base damage and AP site clustering was demonstrated within 3 bases downstream and 7 bases upstream of the targeted base. Furthermore, the pattern and extent of base damage varied depending upon the presence or absence of 2 M DMSO during irradiation. CONCLUSIONS: 125I-TFO-induced DSBs exhibit a high degree of base damage clustering proximal to the DSB end. At least 60% of the nucleotides within 10 bp of the 125I decay site are sensitive to cleavage by endo IV, endo III, or Fpg following damage accumulation in the presence of DMSO, whereas > or = 80% are sensitive in the absence of DMSO. The high degree of base damage clustering associated with the 125I-TFO-induced DSB end may be a major factor leading to its negligible in vitro repair by the non-homologous end-joining pathway (NHEJ).

New preparation of PM2 phage DNA and an endonuclease assay for a single-strand break.

PM2 is a bacteriophage which has closed circular double-stranded DNA as a genome, which is the sole source for endonuclease assay for a single strand break in the fmol range. Therefore, it is important to isolate PM2 DNA with low control nicks for the endonuclease assay. Usually, the isolation method of phage DNA is to use ultracentrifugation which takes at least 4 days. In this report, a fast and effective method which takes only 2 days was developed to purify DNA using polyethylene glycol (PEG) 8000 and the yields of phage DNA isolated by these two methods were compared. The method using PEG 8000 increased the yield of PM2 DNA from 31.2% to 45.2%, and decreased the nick from 17.1% to 13.1%. Recently, the complete PM2 DNA genome sequence of 10,079 bp was published. The exact number of nucleotides of PM2 DNA is important for the correct enzyme assay which measures nicks generated by an endonuclease. The correct calculation of endonuclease activity of rpS3 for nick-circle assay was performed to measure single-strand breaks in this report.

Factors influencing the removal of thymine glycol from DNA in gamma-irradiated human cells.

The toxic and mutagenic effects of ionizing radiation are believed to be caused by damage to cellular DNA. We have made use of a novel immunoassay for thymine glycol to examine the removal of this lesion from the DNA of irradiated human cells. Because of the sensitivity of the assay, we have been able to keep the radiation doses at or below the standard clinical dose of 2 Gy. Our initial observations indicated that although removal of thymine glycol is > 80% complete by 4 h post-irradiation with 2 Gy, there is a lag of 30-60 min before repair commences. However, if cells are irradiated with 0.25 Gy 4 h prior to the 2-Gy dose, removal of the thymine glycols commences immediately after the second irradiation, suggesting that repair of thymine glycol is inducible. Our current studies are directed at two aspects of the repair process, (1) factors involved in the repair process leading up to and including glycosylase-mediated removal of thymine glycol and (2) the control of the inducible response. We have observed that mutation of the XPG gene drastically reduced the level and rate of global removal of thymine glycol (induced by 2-Gy irradiation), and there was no evidence for an inducible response. Similar results were seen with a Cockayne syndrome B (CSB) cell line. We have also examined repair in quiescent and phytohemagglutinin-stimulated human lymphocytes. Both show similar kinetics for the rate of removal of thymine glycol under induced and noninduced conditions.

Mechanism of protection against radiation-induced DNA damage in plasmid pBR322 by caffeine.

PURPOSE: Caffeine (1,3,7-trimethyl xanthine), a dietary component, has been shown to have widely varying effects on DNA damage induced by UV and ionizing radiation, depending upon pre- or post-irradiation administration and its concentration. Caffeine administered post-UV irradiation is known to inhibit enzymatic repair of DNA lesions, leading to potentiation of damage, whereas its presence before or during irradiation elicits protection in a wide range of test systems: bacteria, cultured human cells, plant seeds and mouse. The purpose of this study is to test whether caffeine present during gamma-irradiation of plasmid DNA, a system devoid of replication and repair, could elicit protection by scavenging free radicals. MATERIALS AND METHODS: Plasmid pBR322 DNA was exposed to gamma-radiation in the presence or absence of caffeine at a dose-rate of 1.20 Gy min(-1) and damage measured as single-strand breaks. To understand the mechanisms of the observed protection, especially under oxic conditions, reaction of caffeine with superoxide radical (O(2)(-)), hydrogen peroxide (H(2)O(2)) and the deoxyribose peroxyl radical (ROO(*)) were studied. RESULTS: Irradiation of pBR322 was observed to induce a dose-dependent increase in single-strand breaks. Caffeine itself did not induce strand breaks but reduced radiation-induced strand breaks at micromolar to millimolar concentrations. Caffeine has been shown to react with the radiation-derived oxidants. The reaction rate constants observed were 7.5x10(1) M(-1) s(-1) with O(2)(-) 1.05x10(8) M(-1) s(-1) with ROO(*) and 8.8x10(1) M(-1) s(-1) with H(2)O(2). CONCLUSIONS: Caffeine effectively protects DNA against ionizing radiation in a system devoid of repair and replication machinery. Thus, DNA protection shown by caffeine is possibly due to the scavenging of radiation-derived primary as well as secondary reactive oxygen species, and this physicochemical protective pathway possibly pre-empts any subsequent inhibitory effect of caffeine on the enzymatic repair of DNA.

Stimulation of DNA repair by the spermatidal TP1 protein.

The chromatin remodeling process that takes place during spermiogenesis in mammals is characterized by a transient increase in DNA single-strand breaks (SSB). The mammalian transition proteins (TPs) are expressed at a high level at mid-spermiogenesis steps coincident with chromatin remodeling and could be involved in the repair of these lesions since SSB are no longer detected in terminally differentiated spermatids. We report that TP1 can stimulate the repair of SSB in vitro and demonstrate that in vivo repair of UV-induced DNA lesions is enhanced in mammalian cells stably expressing TP1. These results suggest that, aside from its role in DNA compaction, this major transition protein may contribute to the yet unidentified enzymatic activity responsible for the repair of SSB at mid-spermiogenesis steps. These results also suggest that the TP1 proteins have the potential to participate in the repair process following genotoxic insults and therefore may play an active role in the maintenance of the integrity of the male haploid genome during spermiogenesis.

Analysis of radiation damage of DNA by atomic force microscopy in comparison with agarose gel electrophoresis studies.

DNA damage induced with ionizing radiation is considered one of the main causes of cell inactivation. Several methods including gel electrophoresis, pulsed-field gel electrophoresis, neutral filter elution method, neutral sedimentation and electron microscopy have been applied to analyze this type of DNA damage. A new method employing an atomic force microscope (AFM) for nanometer-level-structure analysis of DNA damage induced with gamma-irradiation is introduced in this report. Structural changes of plasmid DNA on a molecular size scale of about 3 kbp were visually analyzed by AFM after irradiation with 60Co gamma-rays at doses of 1.9, 5.6, and 8.3 kGy. Three forms of plasmid DNA, closed circular (intact DNA), open circular (DNA with a single strand break) and linear form (DNA with a double strand break) were visualized by dynamic force mode AFM after gamma-irradiation. The torsional feature of the plasmid DNA was visualized better with AFM than with a transmission electron microscope (TEM). All three forms of plasmid DNA were observed in the sample irradiated with gamma-rays at the dose of 1.9 kGy. Open circular and linear forms were observed in the samples irradiated with gamma-rays at doses of 5.6 and 8.3 kGy, though no closed circular form was observed. A shortening of the length of a linear form of DNA irradiated with 5.6 and 8.3 kGy gamma-rays was observed by AFM. Structural changes of DNA after gamma-irradiation were visualized by AFM at nanometer level resolution. In addition, shortening of the length of the linear form of DNA after radiation exposure was observed by AFM.

Gamma-irradiation stimulates homology-directed DNA double-strand break repair in Drosophila embryo.

To test the DNA double-strand break (DSB) repair activities present in Drosophila early embryos, we have analyzed the circularization of a microinjected linear plasmid. In order to study repair by homologous recombination, the linear plasmid was injected with an homologous fragment encompassing the break. After extraction from embryos, repair products were analyzed directly by PCR and after their cloning into bacteria. We demonstrate, in addition to the repair by homologous recombination, the presence of an efficient end-joining activity in embryos. Plasmid circularization by end-joining was accompanied by short deletions frequently associated with non-random insertions. Most importantly, pre-irradiation of embryos specifically enhanced the accurate repair by homologous recombination. Such a stimulation is described for the first time in the context of a whole higher organism.

Effects of AQ4N and its reduction product on radiation-mediated DNA strand breakage.

Supercoiled plasmid pBR322 DNA was irradiated in phosphate buffer by 60Co gamma-rays at a dose rate 19.26 Gy/min and total dose of 10 Gy in the presence of a bioreductive antitumour prodrug namely 1,4-bis [¿2-(dimethylamino-N-oxide)ethyl¿ amino] 5, 8-dihydroxyanthracene-9,10-dione (AQ4N) and its DNA affinic reduction product 1,4-bis[¿2(dimethylamino)ethyl¿ amino] 5,8-dihydroxyanthracene-9,10-dione (AQ4) under air and nitrogen. AQ4N and AQ4 were found to protect against radiation-induced plasmid single and double strand breakage as assessed by agarose gel electrophoresis. The differences between the two agents, and between atmospheres of air or nitrogen were negligible. It was also found that the protection efficiencies of the compounds were pH dependent and showed maximum protection at pH 6. These results indicate that protection of DNA by AQ4 and AQ4N against radiation damage is an indirect effect since both agents are equally effective despite major differences in their DNA affinity. It is likely that radiation-induced phosphate buffer radicals are intercepted by AQ4 and AQ4N in a pH-dependent process.

Two independent molecular pathways for recombinant adeno-associated virus genome conversion occur after UV-C and E4orf6 augmentation of transduction.

Numerous environmental influences have been demonstrated to enhance recombinant adeno-associated virus (rAAV) transduction. Such findings are the foundation of developing new and innovative strategies to improve the efficiency of rAAV as a gene therapy vector. Several of these environmental factors included genotoxic stresses such as UV and y irradiation as well as certain adenoviral gene products such as E4orf6. The mechanisms by which these environmental stimuli increase rAAV transduction are only partially understood but have been suggested to involve both endocytosis and uptake of virus to the nucleus, as well as conversion of single-stranded DNA viral genomes to double-stranded expressible forms. Two molecular intermediates of rAAV genomes, which have been demonstrated to correlate with transgene expression and/or the persistence of rAAV, include both replication form (Rf) monomers and dimers as well as circular intermediates. In the present study, we demonstrate that augmentation of rAAV transduction by UV irradiation and the adenoviral protein E4orf6 correlates with distinct increases in either circular or replication form intermediates, respectively. UV irradiation of primary fibroblasts at 15 J/m2 resulted in a 15-fold induction of head-to-tail circular intermediates, with minimal induction of replication form rAAV genomes. In contrast, E4orf6-augmented rAAV transduction was correlated with the formation of replication form intermediates, with no alteration in the abundance of circular intermediates. These findings demonstrate that rAAV transduction can occur through two independent molecular pathways that convert single-stranded AAV genomes to expressible forms of DNA.

Characterization by pulse-field electrophoresis of a new region of DNA amplification containing the M2 subunit of ribonucleotide reductase in hydroxyurea-resistant Leishmania.

An extrachromosomal circular DNA of of approximately 50-kb size was amplified in the hydroxyurea-resistant variant of Leishmania mexicana amazonensis. The amplicon carried the M2 gene of ribonuleotide reductase as part of the gene encoding resistance to hydroxyurea. The amplicon was unstable. It disappeared rapidly as shown in pulse-field gradient electrophoresis gels after reversion of the cells for 20-80 days. This loss of amplified DNA was accompanied by a rapid loss of resistance to hydroxyurea during the same period. The amplicon was not hybridized to specific probes from any of the four regions of DNA amplification previously reported for Leishmania. This region of amplification thus appears to be a new region of DNA amplification in Leishmania.

Fractionated ionizing radiation accelerates loss of amplified MDR1 genes harbored by extrachromosomal DNA in tumor cells.

In tumor specimens such as those from neuroblastoma, ovarian, and lung carcinoma patients, the prevalence of extrachromosomal circular DNA molecules harboring amplified genes has been well established. In some cases, the amplified genes have been identified as oncogenes, and their increased expression appears to contribute to the maintenance and progression of the malignancy. The aim of this study was to investigate the effect of fractionated radiation treatment, given in daily doses similar to those administered clinically, on the stability of extrachromosomal circular DNA molecules in cancer cells. Our studies were conducted with multidrug-resistant KB cells, which harbor extrachromosomal copies of the multidrug resistance gene (MDR1) almost exclusively on circular DNA molecules of approximately 750 and 1500 kb pairs. This size range is representative of extrachromosomal circular DNA molecules that have been shown to harbor amplified oncogenes in vivo. Exponentially growing MDR KB cells were exposed to 1400 and 2800 cGy ionizing radiation administered in 7 and 14 fractions, respectively, at 200 cGy per fraction/day. A statistically significant decrease in MDR1 extrachromosomal gene copy number was reproducibly detected in the irradiated cells compared with unirradiated cells passaged for the duration of the experiment in the absence of radiation treatment. This decrease was accompanied by a reduction in multidrug resistance and in P-glycoprotein levels, as determined by clonogenic dose-response assays and Western analyses, respectively. P-glycoprotein is a multidrug transporter encoded by the MDR1 gene. Fluorescence in situ hybridization studies further determined that extrachromosomal circular DNA loss correlated to the entrapment of these DNA molecules in radiation-induced micronuclei. These results indicate that radiation-induced loss of extrachromosomally amplified genes from tumor cells via their entrapment in micronuclei contributes to the improved therapeutic response observed for some cancers.

Protection by trehalose of DNA from radiation damage.

The most serious damage to cells exposed to radiation is attributed mostly to effects on the structure of cellular DNA. We found that trehalose protects DNA from irradiation. In the presence of 10 mM trehalose, DNA can be protected from about 4 times higher doses of beta- and gamma-ray irradiation. The protective effect increases with the amount of the sugar. Other disaccharides, sucrose, and maltose had similar effects.

Migration of the yeast linear DNA plasmid from the cytoplasm into the nucleus in Saccharomyces cerevisiae.

The Kluyveromyces linear plasmids, pGKL1 and pGKL2, carrying terminal protein (TP), are located in the cytoplasm and have a unique gene expression system with the plasmid-specific promoter element termed UCS, which functions only in the cytoplasm. In this study we have developed an in vivo assay system in Saccharomyces cerevisiae which enables the detection of a rare migration of the yeast cytoplasmic plasmid to the nucleus, using a pGKL1-derived cytoplasmic linear plasmid pCLU1. pCLU1 had both the UCS-fused LEU2 gene (a cytoplasmic marker) and the native URA3 gene (a nuclear marker) and therefore its cytoplasmic-nucleo localized could be determined by the phenotypic analysis of the marker. The nuclearly migrated plasmids were often detected as linear plasmids having the telomere sequence of the host yeast at both ends, although circular plasmids were also found. The circular form was produced by the the terminal fusion of pCLU1. Insertion of a Ty element into a nuclearly migrated plasmid was observed, allowing the ROAM-regulated expression of the adjacent nuclearly silent UCS-fused LEU2 gene. The nuclearly located plasmids, whether linear or circular, were less sensitive to UV-mediated curing than pGKL and pCLU1.