Nonpolar isosteres of damaged DNA bases: effective mimicry of mutagenic properties of 8-oxopurines

A substantial fraction of mutations that arise in the cell comes from oxidative damage to DNA bases. Oxidation of purine bases at the 8-position, yielding 8-oxo-G and 8-oxo-A, results in conformational changes (from anti to syn) that cause miscoding during DNA replication. Here we describe the synthesis and biophysical and biochemical properties of low-polarity shape mimics of 8-oxopurines, and we report that these new analogues exhibit remarkable mimicry of the mutagenic properties of the natural damaged bases. A 2-chloro-4-fluoroindole nucleoside (1) was designed as an isosteric analogue of 8-oxo-dG, and a 2-chloro-4-methylbenzimidazole nucleoside (2) as a mimic of 8-oxo-dA. The nucleosides were prepared by reaction of the parent heterocycles with Hoffer's chlorodeoxyribose derivative. Structural studies of the free nucleosides 1 and 2 revealed that both bases are oriented syn, thus mimicking the conformation of the oxopurine nucleosides. Suitably protected phosphoramidite derivatives were prepared for incorporation into synthetic DNAs, to be used as probes of DNA damage responses, and 5'-triphosphate derivatives (3 and 4) were synthesized as analogues of damaged nucleotides in the cellular nucleotide pool. Base pairing studies in 12-mer duplexes showed that 1 and 2 have low affinity for polar pairing partners, consistent with previous nonpolar DNA base analogues. However, both compounds pair with small but significant selectivity for purine partners, consistent with the idea that the syn purine geometry leads to pyrimidine-like shapes. Steady-state kinetics studies of 1 and 2 were carried out with the Klenow fragment of Escherichia coli DNA Pol I (exo-) in single-nucleotide insertions. In the DNA template, the analogues successfully mimicked the mutagenic behavior of oxopurines, with 1 being paired selectively with adenine and 2 pairing selectively with guanine. The compounds showed similar mutagenic behavior as nucleoside triphosphate analogues, being preferentially inserted opposite mutagenic purine partners. The results suggest that much of the mutagenicity of oxopurines arises from their shapes in the syn conformation rather than from electrostatic and hydrogen-bonding effects. The new analogues are expected to be generally useful as mechanistic probes of cellular responses to DNA damage.     

High-throughput gender determination using automated denaturant gel capillary electrophoresis

Sex determination of anonymous samples is a requirement before analysis of DNA variation on X or Y chromosomes. Based on this, we designed a method for screening samples on different DNA capillary sequencing instruments with a sensitivity that is able to quantify sex chromosome abnormalities. The two different amelogenin alleles sited on the X and Y chromosomes were polymerase chain reaction amplified with the same set of primers and separated by denaturant capillary electrophoresis (DCE). Sex chromosome ratios could be reproducibly determined with a relative standard deviation of 8.7%, which is sufficient to distinguish a normal XY karyotype from an XYY karyotype associated with Klinefelter syndrome. Reconstruction experiments demonstrated sensitivity down to a simulated Y:X allelic ratio of 1:127 in all three instruments, enabling the prediction of sex chromosomal aneuploidies. When tested on anonymous pooled and single samples, DCE gave a good prediction of the male to female ratio in pools of 1000 blood donors. In conclusion, DCE is a simple and robust method for sex determination that can be readily performed on commercially available CE systems.     

PSORALENS CLEAVE pBR322 DNA UNDER ULTRAVIOLET RADIATION

Supercoiled (SC) pBR322 was used to probe the recent claim that 5-geranoxylpsoralen (5-GOP) did not photoreact with DNA. Contrary to expectations, 5-GOP was found to damage DNA in the presence of UV-A through two competing pathways: (a) single strand breaks, identified by the conversion of supercoiled into open circular and linear DNA, and (b) cross-linking, revealed by the fluence-dependent decrease in the extent of denaturation of the double stranded supercoiled DNA to single stranded circular DNA. In addition, a fluence-dependent modification reduced the ability of the restriction enzyme EcoR I to linearize the photosensitized DNA, and alkali-labile lesions were generated. Psoralen, 5-methoxypsoralen, and 8-methoxypsoralen, which are well-known to undergo cycloaddition to DNA, had a more pronounced effect on supercoiled DNA. Single strand breaks occurred more readily than with 5-GOP, and the surviving SC form remaining had reduced electrophoretic mobility in agarose gels. In all cases, the DNA damage was more prominent when oxygen was absent.     

Chromosomal organization of simple repeated DNA sequences used for DNA fingerprinting

Stretches of short, simple DNA sequences are widespread in all eukaryote genomes studied so far. Simple sequences are thought to undergo frequent expansion and deletion due to intrinsic genomic mechanisms. Some of the simple sequences were used successfully to detect hypervariable loci in various genomes. Hybridization experiments using synthetic probes not only revealed the informative simple repeats suitable for DNA fingerprinting in a particular species, but also reflected the wide range of distribution of the simple sequences among eukaryotes. The organization of these simple repetitive sequences at the chromosomal loci was investigated using in situ hybridization with chemically synthesized, pure oligonucleotide probes. Both biotin- and digoxigenin-attached probes detected specific chromosomal sites that are enriched in the respective simple-repeat blocks. Depending on the organism and probe used, accumulation of simple DNA sequences at individual or multiple sites on the chromosomes of different vertebrates could be demonstrated. The simple repetitive DNA sequences are located in different chromosomal regions (e.g., heterochromatin on the sex chromosomes, nucleolus organizer regions, and R-band sites), which are constrained considerably during evolution.     

A novel technique for observing the internal ultrastructure of human chromosomes with known karyotype

Observation of the internal ultrastructure of human chromosomes by transmission electron microscopy (TEM) has frequently been attempted in spite of the difficulties in detaching metaphase chromosome spreads from the glass slide for further processing. In this study we have used a method in which metaphase chromosome spreads were prepared on a flexible thermoplastic membrane (ACLAR) film. To assess chromosome identity, a diamidino-phenylindole staining and karyotying was first done using a conventional cytogenetic system. The chromosome spreads were then fixed with 1% osmium tetroxide, stained with freshly prepared 2% tannic acid, dehydrated, and flat-embedded in epoxy resin. The resin sheet was easily detachable and carried whole chromosome spreads. By this method, TEM observation of chromosomes from normal human lymphocytes allowed a thorough examination of the ultrastructure of centromeres, telomeres, fragile sites, and other chromosomal regions. Various ultrastructural patterns including thick electron dense boundaries, less dense internal regions, and extended chromatin loops at the periphery of the chromosomes were discernible. Application of the present method to chromosome research is expected to provide comprehensive information on the internal ultrastructure of different chromosomal regions in relation to function.     

Retroactive DNA analysis for sex determination and dystrophin gene by polymerase chain reaction with archived cytogenetic slides

We describe a rapid and efficient diagnostic method for sex determination and the dystrophin gene by the polymerase chain reaction (PCR) using archived cytogenetic slides. Archived cytogenetic slides stored for about 4 years at room temperature were used. To confirm whether DNA analysis is possible using the archived cytogenetic slides, we extracted the DNA from the slides and amplified the Y centromeric region (DYZ3), the X centromeric region (DXZ1) and the exon 46 of the dystrophin gene. Of the 50 cases, 24 were peripheral bloods, 13 were amniotic fluid cells, 5 were chorionic villus samplings and 8 were cord bloods. The PCR related sex determination in 22 females and 28 males, showed 100% concordance with the results of chromosome analysis, and all cases showed positive band for the exon 46 of the dystrophin gene. Of the 50 cases of the archived cytogenetic slides, we were fortunate enough to obtain the fresh blood sample from one fetus whose karyotype showed 45,X[34]/46,X,+mar[145] to compare the results of the gDNA with that from archived cytogenetic slide. To confirm whether the marker chromosome was derived from Y chromosome, we studied the six loci (PABY, SRY, RPS4Y (SY16, 17), ZFY, DYS14) on the short arm, one locus (DYZ3) on the centromere and one locus (DYZ1) on the long arm. Of the 8 loci studies, all PCR related Y chromosome showed positive band from both gDNA obtained from cord blood and archived cytogenetic slides. We could conclude from the above results that the marker chromosome was derived from the Y chromosome. We believe our experiment is rapid and efficient for studies of over 10 independent loci from a single slide which has been kept in storage for up to 4 years and that archival Giemsa-stained cytogenetic slide repositories represent valuable DNA resources for clinical and forensic studies.     

Experimental and theoretical investigation effect of flavonols antioxidants on DNA damage

A new electrochemical biosensor was developed to demonstrate the effect of Acridine Orange (AO) on DNA damage. Then, the biosensor was used to check the inhibitors effect of three flavonols antioxidants (myricetin, fisetin and kaempferol) on DNA damage. Acridine Orange (AO) was used as a damaging agent because it shows a high affinity to nucleic acid and stretch of the double helical structure of DNA. Decreasing on the oxidation signals of adenine and guanine (in the DNA) in the presence of AO were used as probes to study the antioxidants power, using DNA-modified screen printed graphene electrode (DNA/SPGE). The results of our study showed that the DNA-biosensor could be suitable biosensor to investigate the inhibitors ability of the flavonols antioxidants on the DNA damage. The linear dependency was detected in the two regions in the ranges of 1.0–15.0 and 15.0–500.0 pmol L⁻¹. The detection limit was found 0.5 pmol L⁻¹ and 0.6 pmol L⁻¹ for guanine and adenine, respectively. To confirm the electrochemical results, Uv–Vis and fluorescence spectroscopic methods were used too. Finally molecular dynamic (MD) simulation was performed on the structure of DNA in a water box to study any interaction between the antioxidant, AO and DNA.     

RNP STRUCTURE IN METAPHASE CHROMOSOMES OF Vicia faba

The results of studies on ultrastructural and cytochemical features of metaphase chromosomes of Vicia faba are reported. In conventionally stained specimens are observed many electron-lucent compartments, in which exists an internal fibrillar-granular structure. When stained with the Bernhard's technique, the internal structure is found to consist of ribonucleoprotein (RNP) fibrilsand granules that measure about 15 to 20 nmin diameter. In the transverse section of metaphase chromosomes, the RNP structures are distributed in both the central and the peripheral regions of chromatids. It is conceivable that this RNP structure constitutes a special component of chromosomes. The distribution of the RNP structure in a chromosome and some questions related to the chromosomal scaffold are discussed on the basis of these data.     

Impact of pyrophosphate and O-ethyl-substituted pyrophosphate groups on DNA structure

Design of novel DNA probes to inhibit specific repair pathways is important for basic science applications and for use as therapeutic agents. As shown previously, single pyrophosphate (PP) and O-ethyl-substituted pyrophosphate (SPP) modifications can inhibit the DNA glycosylase activities on damaged DNA. To understand the structural basis of this inhibition, the influence of the PP and SPP internucleotide groups on the helical parameters and geometry of a double-stranded DNA was studied by using molecular modeling tools including molecular dynamics and quantum mechanical-molecular mechanical (QM/MM) approaches. Native and locally modified PP- and SPP-containing DNA duplexes of dodecanucleotide d(C1G2C3G4A5A6T7T8C9G10C11G12) were simulated in aqueous solution. The energies and forces were computed by using the PBE0/6-31+G** approach in the QM part and the AMBER force-field parameters in the MM part. Analysis of the local base-pair helical parameters, internucleotide distances, and overall global structure at the located stationary points revealed a close similarity of the initial and modified duplexes, with only torsion angles of the main chain being altered in the vicinity of introduced chemical modification. Results show that the PP and SPP groups are built into a helix structure without elongation of the internucleotide distance due to flipping-out of phosphate group from the sugar-phosphate backbone. The mechanism of such embedding has only a minor impact on the base pairs stacking and Watson-Crick interactions. Biochemical studies revealed that the PP and SPP groups immediately 5', but not 3', to the 8-oxoguanosine (8oxodG) inhibit translesion synthesis by a DNA polymerase in vitro. These results suggest that subtle perturbations of the DNA backbone conformation influence processing of base lesions.     

Comparative study of synonymous codon usage variations between the nucleocapsid and spike genes of coronavirus, and C-type lectin domain genes of human and mouse

Coronaviruses (CoVs) are single-stranded RNA viruses which contain the largest RNA genomes, and severe acute respiratory syndrome coronavirus (SARS-CoV), a newly found group 2 CoV, emerged as infectious disease with high mortality rate. In this study, we compared the synonymous codon usage patterns between the nucleocapsid and spike genes of CoVs, and C-type lectin domain (CTLD) genes of human and mouse on the codon basis. Findings indicate that the nucleocapsid genes of CoVs were affected from the synonymous codon usage bias than spike genes, and the CTLDs of human and mouse partially overlapped with the nucleocapsid genes of CoVs. In addition, we observed that CTLDs which showed the similar relative synonymous codon usage (RSCU) patterns with CoVs were commonly derived from the human chromosome 12, and mouse chromosome 6 and 12, suggesting that there might be a specific genomic region or chromosomes which show a more similar synonymous codon usage pattern with viral genes. Our findings contribute to developing the codon-optimization method in DNA vaccines, and further study is needed to determine a specific correlation between the codon usage patterns and the chromosomal locations in higher organisms.     

Sulfur speciation defined subcellular localization of coumarin derivatives: Correlation of structural relationship to biological behaviors

Modulating the speciation of sulfur containing functional group could alter the subcellular localization of a series thiomorpholine incorporated coumarins.     

Electric potential induced dissociation of hybridized DNA with hairpin motif immobilized on silicon surface

DNA probes were immobilized on silicon surfaces through ester condensation between the -COOH group on the surface and the terminal -OH group in the oligonucleotide, and the surface density of DNA probes against the concentration of immobilization solution was measured by radioactive labeling. The dissociation of DNA duplex on the surface by an electric potential was studied with the scanning potential hairpin denaturation/dissociation (SPHD). The influence of the stem length in the hairpin probe on the SPHD curve was systematically investigated. It was found that the capability of discrimination on single nucleotide polymorphism (SNP) by a hairpin probe was related to the free energy of formation of the secondary structure in the probe (DeltaG(ss)). In our system, when DeltaG(ss) was around -3 kcal/mol, an optimal recognition of SNP was reached and the SPHD curve was sigmoid. In contrast, the equivalent SPHD curve from a linear probe was exponential-decay alike with a poor discrimination of SNP. The concentration dependent experiments showed good linearity between the melting potential and logarithm of target concentration in the range of 1 x 10(-9) to 5 x 10(-7) M.     

Increased levels of 8-hydroxy-2'-deoxyguanosine in Drosophila larval DNA after irradiation with 364-nm laser light but not with X-rays

Exposure to UVA light causes damage to cellular components such as DNA and membrane lipids. We showed previously that UVA irradiation can induce mutations in Drosophila larvae and that the major lesions responsible for mutations were not thymidine dimers when wavelengths tested became longer. The use of a longer wavelength with UVA laser apparatus (364 nm) has made it possible to test the effects of this powerful light in biological organisms. In the present study, we irradiated third instar larvae of the urate-null Drosophila mutant strain y v ma-l, which is sensitive to oxidative stress, and compared the effects of 364 nm light irradiation with the effects of X-rays. To assay viability, some of the larvae were kept at 25 degrees C until they eclosed in order to obtain a measure of viability. The remaining larvae were used to measure the amount of 8-hydroxydeoxyguanosine (8-OHdG), an indicator of oxidative DNA damage. The amount of 8-OHdG increased and viability decreased in response to increased UV dose in both the y v ma-l and wild-type strains. With irradiation of 600 kJ m(-2), 8-OHdG/10(6)dG was 7.2 +/- 3.2 and 6.2 +/- 2.0 in y v ma-l and wild-type strains, respectively, whereas the respective levels were 2.2 +/- 0.6 and 2.3 +/- 0.8 without irradiation. Our results indicated that irradiation with a 364-nm laser light caused significant oxidative damage in Drosophila larval DNA; however, induction of the damage was not prohibited by urate. To the best of our knowledge, this is the first report of a study in whole animals that shows increased levels of 8-OHdG in response to 364-nm UVA. X-ray ionizing radiation is also thought to generate reactive oxygen species in irradiated cells. We found that the amount of 8-OHdG in DNA following X-ray radiation remained unchanged in both strains, though survival rates were affected. X-ray-generated oxidative damage in Drosophila cells was followed by cell death but not DNA base oxidation, and the damage was suppressed by urate. The overall results suggest significant differences in the major in vivo oxidative damage caused by 364-nm light and X-rays.     

Self-quenching smart probes as a platform for the detection of sequence-specific UV-induced DNA photodamage

Molecular beacons (MBs) are sensitive probes for many DNA sequence-specific applications, such as DNA damage detection, but suffer from technical and cost limitations. We have designed smart probes with self-quenching properties as an alternative to molecular beacons to monitor sequence-specific UV-induced photodamage of oligonucleotides. These probes have similar stem-loop structural characteristics as molecular beacons, but quenching is achieved instead via photoinduced intramolecular electron transfer by neighboring guanosine residues. Our results indicate that the probes are sensitive enough to detect nanomolar target concentrations and are specific enough to discriminate single-base damage. When the probes were used to monitor UV-induced photodamage in oligonucleotide sequences that differ by a single-base mismatch, the photodamage time constant was higher for the perfectly complementary target sequences than for the mismatch sequences, indicating that these probes are specific for each target sequence. In addition, time constants obtained for oligonucleotide target sequences with both stem and loop base mismatches are lower than those with only loop mismatches, suggesting that these sequences are also specifically distinguished by the smart probes. These probes thus constitute robust, sensitive, specific, and cheaper alternatives to MBs for sequence-specific DNA damage detection.     

Detection of DNA hybridization by ABEI electrochemiluminescence in DNA-chip compatible assembly

The electrochemiluminescence (ECL) of a luminol derivate (ABEI) generated both by a carbon electrode and a polypyrrole-coated carbon electrode was examined. It was found that the polypyrrole film (ppy) did not inhibit the ECL. After that, ABEI anchored on a single stranded DNA target (ODNt) has been used for the ECL detection of the hybridization between a complementary single stranded DNA probe (ODNp) covalently linked to a polypyrrole support and the ODNt. The ECL detection has been performed using a DNA sensor having a low surface concentration of ODNp probes, constituted of a polypyrrole copolymer electrosynthesized from a pyrrole-ODNp/pyrrole monomer ratio of 1/20,000.     

Monitoring molecular beacon DNA probe hybridization at the single-molecule level

We have monitored the reaction dynamics of the DNA hybridization process on a liquid/solid interface at the single-molecule level by using a hairpin-type molecular beacon DNA probe. Fluorescence images of single DNA probes were recorded by using total internal reflection fluorescence microscopy. The fluorescence signal of single DNA probes during the hybridization to individual complementary DNA probes was monitored over time. Among 400 molecular beacon DNA probes that we tracked, 349 molecular beacons (87.5 %) were hybridized quickly and showed an abrupt fluorescence increase, while 51 probes (12.5 %) reacted slowly, resulting in a gradual fluorescence increase. This ratio stayed about the same when varying the concentrations of cDNA in MB hybridization on the liquid/surface interface. Statistical data of the 51 single-molecule hybridization images showed that there was a multistep hybridization process. Our results also showed that photostability for the dye molecules associated with the double-stranded hybrids was better than that for those with the single-stranded molecular beacon DNA probes. Our results demonstrate the ability to obtain a better understanding of DNA hybridization processes using single-molecule techniques, which will improve biosensor and biochip development where surface-immobilized molecular beacon DNA probes provide unique advantages in signal transduction.     

Microarray of DNA probes on carboxylate functional beads surface

The microarray of DNA probes with 5' -NH2 and 5' -Tex/3' -NH2 modified terminus on 10 um carboxylate functional beads surface in the presence of 1-ethyl-3-(3-dimethylaminopropyl)-carbodiimide (EDC) is characterized in the preseni paper. it was found that the microarray capacity of DNA probes on the beads surface depends on the pH of the aqueous solution, the concentra-tion of DNA probe and the total surface area of the beads. On optimal conditions, the minimum distance of 20 mer single-stranded DNA probe microarrayed on beads surface is about 14 nm, while that of 20 mer double-stranded DNA probes is about 27 nm. If the probe length increases from 20 mer to 35 mer, its microarray density decreases correspondingly. Mechanism study shows that the binding mode of DNA probes on the beads surface is nearly parallel to the beads surface.     

Noncovalent attachment of psoralen derivatives with DNA: Hartree-Fock and density functional studies on the probes

Two psoralen derivatives (probes) were prepared. Their geometries were optimized at the Hartree-Fock (HF) and Density Functional (B3LYP) levels employing 6-31G** and cc-pVDZ basis sets. Their interaction with DNA was investigated using spectrophotometric and computational techniques. Both of them have shown strong binding to calf thymus DNA. The red-shift and hypochromism that detected in the spectrum were taken as an evidence for the strong interaction between these probes and DNA. The spectrophotometric DNA titration data were treated by two different methodologies to calculate the intercalation affinity. Half-reciprocal plots gave binding constants of 5.5065 x 10(4) and 6.4727 x 10(4) for 8-butoxypsoralen (8-BOP) and 8-hexoxypsoralen (8-HOP), respectively. Schatchard plots gave a comparable intercalation binding constants and also the surface binding constants along with the number of intercalated probe molecules per base pair. The interaction between these probes and DNA were studied theoretically. The energy of interaction was computed using molecular mechanics method. Strength of interaction of these probes with different types of DNA was computed and compared. Calculated energies of interaction were compared with the observed intercalation affinities. HOMO and LUMO energies were computed and used to account for the strength of interaction.     

Selective immobilization of DNA and antibody probes on electrode arrays: simultaneous electrochemical detection of DNA and protein on a single platform

A proof of concept procedure for the electroaddressable covalent immobilization of DNA and protein on arrayed electrodes along with simultaneous detection of multiple bioagents in the same sample solution is described. Carboxyphenyldiazonium was selectively deposited onto five of nine individually addressable electrodes in an array via bias assisted assembly. Amine functionalized DNA probes were covalently coupled to the carboxyl surface via carbodiimide chemistry. This was followed by the covalent immobilization of diazonium-antibody conjugates into the remaining four electrodes via cyclic voltammetry. Simultaneous electrochemical detection of a DNA sequence related to the breast cancer BRCA1 gene and the human cytokine protein interleukin-12, which is a substantial component in the immune system response and attack of tumor cells, is reported. These results demonstrate the possibility of selective patterning of diverse biomolecules on a single device and may have significant implications for future development of microarrays and biosensors.