Modulation of ochratoxin A induced DNA-damage in urothelial cell cultures

Despite good evidence for a genotoxic potential of ochratoxin A (OTA), the mechanism of OTA-induced genotoxicity (direct or indirect?) is still unclear. This calls for a further characterization of OTA-related DNA damage, and investigations of factors that may modulate dose-effect relationships in cells. Since bladder epithelium is a target tissue for the toxicity of OTA, its effects were studied in cultures of human bladder carcinoma (H5637) cells. Cytotoxicity of OTA, assessed by Neutral red (NR) uptake or Alamar-Blue assay, is concentration- and time-dependent: Upon 24 h treatment of 5637 cells, NR uptake is reduced by 50% with OTA concentrations of ≥0.2 microM, but not with 3 h treatment of the cells. Since cytotoxicity of OTA was not affected by addition of xenobiotic metabolizing enzymes (S-9 mix), it appears to be unrelated to biotransformation of the mycotoxin. Also, addition of S-9 mix did not significantly affect the genotoxicity of OTA as studied by alkaline single cell gel electrophoresis (Comet assay). DNA damage was detectable after 3 h treatment of cells at OTA concentrations between 0.1 and 1 microM, and increased further at higher concentrations. The magnitude of OTA-induced DNA damage did not increase with longer treatment times (18, 24 h), probably due to repair processes in the cells. Repair of OTA-induced lesions is quite efficient in kidney (Arch Toxicol 2002, 75, 734–741) and in porcine bladder cells (Föllmann and Lebrun, 2005, Mycotoxin Research, this volume). Interestingly, the genotoxicity of OTA is modulated by the pH of the culture medium, with higher damage at pH 5 compared to pH 7.5. In line with this, uptake studies with tritiated OTA show a higher cellular accumulation of the mycotoxin at pH 5 than in buffer of pH 7.5. Thus, bladder cells exposed to OTA in slightly acidic urine (which facilitates reabsorption) may be at higher risk.     

DNA-DNA dot hybridization technique used as DNA determination method in the alkaline elution analysis of DNA damage

A DNA-DNA (‘Southern’) dot hybridization technique was adapted for use as a quantitative DNA detection method during alkaline elution analysis of irradiated rat cell material. In comparison to standard microfluorometric methods, similar γ-ray-dose-response relationships were obtained with less than 1% of the cell material when the dot hybridization assay was used. When a highly repetitive, long interspersed DNA element of the rat genome is used as a hybridization probe, as few as 10⁴ cells of rat tissue or rat cell culture cells per sample with approx. 50 ng of DNA were sufficient to detect single-strand breaks and protein cross-links in the DNA of rat hepatocytes and cells of the nasal epithelium after in vitro γ-irradiation. Since highly repetative DNA elements are available from nearly all higher eukaryotes, this alternative approach of detecting DNA in alkaline elution analysis is generally proposed for tissues which yield only low amounts of cell material and/or which are difficult to label by radioactive DNA precursors.     

Depletion of the DarG antitoxin in Mycobacterium tuberculosis triggers the DNA-damage response and leads to cell death

Of the ~80 putative toxin-antitoxin (TA) modules encoded by the bacterial pathogen Mycobacterium tuberculosis (Mtb), three contain antitoxins essential for bacterial viability. One of these, Rv0060 (DNA ADP-ribosyl glycohydrolase, DarG_Mtb), functions along with its cognate toxin Rv0059 (DNA ADP-ribosyl transferase, DarT_Mtb), to mediate reversible DNA ADP-ribosylation (Jankevicius et al., 2016). We demonstrate that DarT_Mtb-DarG_Mtb form a functional TA pair and essentiality of darG_Mtb is dependent on the presence of darT_Mtb, but simultaneous deletion of both darT_Mtb-darG_Mtb does not alter viability of Mtb in vitro or in mice. The antitoxin, DarG_Mtb, forms a cytosolic complex with DNA-repair proteins that assembles independently of either DarT_Mtb or interaction with DNA. Depletion of DarG_Mtb alone is bactericidal, a phenotype that is rescued by expression of an orthologous antitoxin, DarG_Taq, from Thermus aquaticus. Partial depletion of DarG_Mtb triggers a DNA-damage response and sensitizes Mtb to drugs targeting DNA metabolism and respiration. Induction of the DNA-damage response is essential for Mtb to survive partial DarG_Mtb-depletion and leads to a hypermutable phenotype.     

A modified fluorimetric neutral filter elution method for analyzing radiation-induced double strand break and repair

Neutral filter elution assay is one of the methods used for detection of DNA double strand breaks (DSBs). However, it is laborious, expensive, and hazardous (radiolabeled precursors for DSB detection and scintillation counter for quantification), making it a less preferred method for DSB detection. In the present study, an attempt was made to improve the existing neutral filter elution assay by making use of fluorescent dye (PicoGreen) and microfiltration assembly for eluting the fragmented DNA, thereby reducing the cost and time required for the assay. We studied the effect of dye dilution, pH conditions, and cell number as a part of method standardization. X-ray dose–response and repair kinetics in lymphocytes as well as cell lines were studied for validating the sensitivity of the assay. A linear dose–response relationship for DSBs was observed at a cell number of 4 × 10⁵ cells, a dye dilution of 500-fold, and at pH 10. Repair kinetics revealed a time-dependent repair of DSBs up to 360 min of posttreatment, indicating its usefulness in DSB repair studies. In conclusion, the present modified method is more efficient (in terms of cell number), cost effective, less time-consuming, and less hazardous compared to the existing method.     

A non-viral gene delivery system designed for clinical use

Gene delivery can be accomplished using non-viral systems, and these have received increased attention These include ex vivo transfection of cells using an electric field to induce transient cell-membrane permeability (electroporation). This approach has the distinct advantage of not requiring the inclusion of a secondary agent (e.g. a lipid, viral package or carrier protein) any of which can be immunogenic or toxic. Available electroporation systems utilize a low volume (<1 mL) processing chamber and are open systems. The MaxCyte system employs a continuous flow design and can very rapidly process volumes ranging from 0.02 mL to >1 L. Transgenes for markers (eGFP) and functional proteins (e.g., cytokines, angiogenic factors) have been loaded in plasmids up to 14 kB in size. With appropriate application of pre- and post-processing cell manipulations, very satisfactory loading efficiencies and cell viability have been obtained. Cells can be processed with multiple plasmids, resulting in expression of the corresponding number of gene products. This capability has been considered for therapeutic and bioprocessing applications. The MaxCyte system was designed specifically for ex vivo clinical applications. The electrodes are manufactured of special materials and under precise conditions, in order to eliminate potential risks from electrolytic effects. The processing chamber and associated containers can be provided as disposable, sterile, closed (or functionally closed) systems-quite similar to the disposable harnesses used with cell separators. This system is thus suitable for integration into a current good manufacturing practice environment.     

A new synthesis method for complex electric field patterning using a multichannel dense array system with applications in low-intensity noninvasive neuromodulation

Multichannel coil array systems offer precise spatiotemporal electronic steering and patterning of electric and magnetic fields without the physical movement of coils or magnets. This capability could potentially benefit a wide range of biomagnetic applications such as low-intensity noninvasive neuromodulation or magnetic drug delivery. In this regard, the objective of this work is to develop a unique synthesis method, that enabled by a multichannel dense array system, generates complex current pattern distributions not previously reported in the literature. Simulations and experimental results verify that highly curved or irregular (e.g., zig–zag) patterns at singular and multiple sites can be efficiently formed using this method. The synthesis method is composed of three primary components; a pixel cell (basic unit of pattern formation), a template array (“virtual array”: code that disseminates the coil current weights to the “physical” dense array), and a hexagonal coordinate system. Low-intensity or low-field magnetic stimulation is identified as a potential application that could benefit from this work in the future and as such is used as an example to frame the research.     

A nuclear magnetic resonance imaging technique designed for studies of water in plant leaves.

A new imaging technique is described which uses nuclear magnetic resonance (NMR) to create a water profile of plant leaves. The water profile shows the average distribution of water as a function of depth into a leaf along a line perpendicular to the leaf surface; it can be used to measure the thickness of cell layers and the quantity of water in each layer. Two-dimensional NMR methods were used to avoid chemical shift distortion which degrades the resolution in leaf images made by conventional NMR techniques; image resolution was improved further by deconvolution analysis. To illustrate its application, the technique was used to follow changes in the internal structure of developing leaves.     

An ultrasoft X-ray multi-microbeam irradiation system for studies of DNA damage responses by fixed- and live-cell fluorescence microscopy

Localized induction of DNA damage is a valuable tool for studying cellular DNA damage responses. In recent decades, methods have been developed to generate DNA damage using radiation of various types, including photons and charged particles. Here we describe a simple ultrasoft X-ray multi-microbeam system for high dose-rate, localized induction of DNA strand breaks in cells at spatially and geometrically adjustable sites. Our system can be combined with fixed- and live-cell microscopy to study responses of cells to DNA damage. This article has been submitted as a contribution to the Festschrift entitled “Uncovering cellular sub-structures by light microscopy” in honour of Professor Cremer’s 65th birthday. C. van Oven and P. M. Krawczyk contributed equally to this work.     

A new DNA profiling system for cell line identification for use in cell banks in Japan

Summary Using the polymorphic DNA probes, ChdTC-15, ChdTC-114, pYNH24, and λTM-18, a DNA profiling system was developed that verified identities of individual cultured cell lines collected in the Japanese cell banks, JCRB, RCB, and IFO. These highly polymorphic DNA probes include both VNTR (Variable Number of Tandem Repeats) sequences and substantial lengths of unique regions. In the mixed probe system, several distinct bands from four to eight can be used for cell line identification. These bands were widely spread in a range of molecular sizes, and were stable and reproducible under stringent conditions of Southern blot hybridization. Because the DNA profile was specific for each individual human cell line, it is useful not only to authenticate many existing cultured cell lines but also to monitor their identity during propagation in a laboratory, and to confirm newly established lines as unique.     

A recurrent chromosomal inversion suffices for driving escape from oncogene-induced senescence via subTAD reorganization

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Evaluation of saliva as a source of human DNA for population and association studies

A simple noninvasive procedure for saliva sample collection and DNA extraction was developed. On average, the amount of human DNA (as measured by a TaqMan-based assay) was about 11.4 microg/mL saliva, which is more than can be obtained from other noninvasive samples such as cheek swabs. However, the presence of large amounts of nonhuman DNA (up to 90% of the total extracted DNA) in saliva samples does necessitate DNA quantitation methods that are specific for human DNA. We were able to reliably and accurately type different genetic markers (mDNA sequences, Y-chromosomal single-nucleotide polymorphisms, and autosomal microsatellite loci) from saliva samples stored for up to 30 days at 37 degrees C, making this method well-suited for field conditions and convenient transportation of samples back to the laboratory. Thus, saliva can be considered a reliable source of DNA for a wide variety of genetic studies.     

A family of versatile centromeric vectors designed for use in the sectoring-shuffle mutagenesis assay in Saccharomyces cerevisiae

A simple assay called the sectoring shuffle was developed to monitor the mutational state of essential genes cloned into yeast centromeric plasmids. The essence of this assay is the creation of a conditional phenotype, colony color sectoring, for an essential gene in the absence of conditional thermosensitive or cold-sensitive alleles of that gene. This allows the quick determination of the mutational state of a cloned essential gene by observing its effect on the sectoring phenotype of the tester strain. During the course of this work we developed a family of 20 Escherichia coli-yeast shuttle vectors, pUN plasmids, containing ARS1 CEN4 and a variety of selectable markers as well as the SUP11 gene which can act as a color marker in the proper background. These vectors are compact and have been very useful for the sectoring-shuffle assay and for gene analysis in general. This paper decribes these vectors, the sectoring shuffle and several applications of sectoring phenotypes.     

A combinatorial problem in pharmacology

A novel coding scheme is used to enumerate configurations in a combinatorial problem arising in research on effects of drugs or radiation on DNA.     

A neuroprotective role for the DNA damage checkpoint in tauopathy

ATM and p53, effectors of the DNA damage checkpoint, are generally considered pro-apoptotic in neurons. We show that DNA damage and checkpoint activation occurs in postmitotic neurons in animal models of tauopathy, neurodegenerative disorders that include Alzheimer's disease. Surprisingly, checkpoint attenuation potently increases neurodegeneration through aberrant cell cycle re-entry of postmitotic neurons. These data suggest an unexpected neuroprotective role for the DNA damage checkpoint in tauopathies.     

A multichannel telemetry system for long-term in vivo evaluation of implantable materials

Long-term in vivo measurements of the corrosion potentials of various implantable metal materials are performed using an implantable multichannel telemetry system. The data acquisition system has been designed to achieve maximum ease of operation for routine tests in animal applications. A novel signal encoding technique offers advantageous properties in connection with a commercial audio cassette tape recorder for signal storage. The flexibility of the design extends the scope of application to include not only biomaterial testing but all low frequency data transmissions in biological research.     

A rapid screening technique for the detection of repeated DNA sequences in plant tissues

Summary DNA sequences cloned from nuclear and mitochondrial chromosomes have been used as hybridisation probes to distinguish different plant genotypes. The probes are hybridised to squashed segments of tissue e.g. root tips. The squash-dot method is rapid and suitable for screening large numbers of individual plants. One probe, specific for a rye repeated sequence family, enables rye chromosomes to be detected in wheat plants. A probe for ribosomal DNA enables plants with high or low numbers of ribosomal RNA genes to be distinguished. A maize mitochondrial DNA probe is used to distinguish plants with N, T or S cytoplasms.     

A new technique for simultaneous collection of macroalgal propagules in the water column

A Simultaneous Collection Module (SCM) was designed to concurrently collect multiple samples of macroalgal propagules, and to evaluate their abundance and spatial distribution in the water column. The basic sampling units are water collectors (tubes), held together to form an evenly spaced grid forming a spatial array with three dimensions. Each collector in the module possesses a simultaneous closing mechanism. The water collected in each tube is then filtered and the propagules retained on each filter cultivated under controlled conditions. The sampling system was deployed in the field in central Chile. Results suggest the system is an efficient collector, able to provide data on time-space changes of macroalgal propagules in the water column.     

ATM dependent apoptosis in the nervous system

Ataxia-telangiectasia is a human syndrome resulting from mutations of the ATM protein kinase that is characterized by radiation sensitivity and neurodegeneration. Although neuroprotective, the molecular details of ATM function in the nervous system are uncertain. However, in the mouse, Atm is essential for ionizing radiation-induced apoptosis in select postmitotic populations of the developing nervous system. Atm-dependent apoptosis in the nervous system also requires p53, consistent with the well-established link of p53 as a major substrate of ATM. Furthermore, the proapoptotic effector Bax is also required for most, but not all, Atm-dependent apoptosis. Therefore, after DNA damage in the developing nervous system, Atm initiates a p53-dependent apoptotic cascade in differentiating neural cells. Together, these data suggest ATM-dependent apoptosis may be important for elimination of neural cells that have accumulated genomic damage during development, thus preventing dysfunction of these cells later in life.     

Impact of single nucleotide polymorphisms in the OGG1 and XRCC1 genes on modulation of DNA damage in pesticide-exposed agricultural workers in Punjab,North-West India

Abstract

Pesticide-induced DNA damage is primarily repaired by base excision repair (BER) pathway. However, polymorphism in DNA repair genes may modulate individual’s DNA repair capacity (DRC) leading to increased genotoxicity and adverse health effects. Our first study in North-West Indian population aimed to evaluate the impact of OGG1 rs1052133 (Ser326Cys; C1245G), XRCC1 rs1799782 (Arg194Trp; C26304T) and XRCC1 rs25487 (Arg399Gln; G28152A) polymorphisms on the modulation of pesticide-induced DNA damage in a total of 450 subjects (225 pesticide-exposed agricultural workers and 225 age- and sex-matched controls). DNA damage was estimated by alkaline comet assay using silver-staining method. Genotyping was carried out by PCR-RFLP using site-specific restriction enzymes. Mann-Whitney U-test revealed elevation in DNA damage parameters (p?<?0.01) in pesticide-exposed agricultural workers than controls. Chi-square test showed significant (p?<?0.05) differences in the XRCC1 Arg194Trp (C26304T) and Arg399Gln (G28152A) genotypes among two groups. Multivariate logistic-regression analysis revealed that heterozygous genotypes of OGG1 rs1052133 (326Ser/Cys; 1245CA), XRCC1 rs1799782 (194Arg/Trp; 26304CT) and XRCC1 rs25487 (399Arg/Gln; 2815GA) were positively associated (p?<?0.05) with elevated DNA damage parameters in pesticide-exposed agricultural workers. Our results strongly indicate significant positive association of variant OGG1 and XRCC1 genotypes with reduced DRC and higher pesticide-induced DNA damage in North-West Indian agricultural workers.