ABSTRACT
DNA repair pathways, cell cycle checkpoints, and redox protection systems are essential factors for securing genomic stability. The aim of the present study was to analyze the effect of Ilex paraguariensis (Ip) infusion and one of its polyphenolic components rutin on cellular and molecular damage induced by ionizing radiation. Ip is a beverage drank by most inhabitants of Argentina, Paraguay, Southern Brazil, and Uruguay. The yeast Saccharomyces cerevisiae (SC7Klys 2-3) was used as the eukaryotic model. Exponentially growing cells were exposed to gamma rays (γ) in the presence or absence of Ip or rutin. The concentrations used simulated those found in the habitual infusion. Surviving fractions, mutation frequency, and DNA double-strand breaks (DSB) were determined after treatments. A significant increase in surviving fractions after gamma irradiation was observed following combined exposure to γ+R, or γ+Ip. Upon these concomitant treatments, mutation and DSB frequency decreased significantly. In the mutant strain deficient in MEC1, a significant increase in γ sensitivity and a low effect of rutin on γ-induced chromosomal fragmentation was observed. Results were interpreted in the framework of a model of interaction between radiation-induced free radicals, DNA repair pathways, and checkpoint controls, where the DNA damage that induced activation of MEC1 nodal point of the network could be modulated by Ip components including rutin. Furthermore, ionizing radiation-induced redox cascades can be interrupted by rutin potential and other protectors contained in Ip.
Subject(s)
Rutin/pharmacology , Saccharomyces cerevisiae/drug effects , Saccharomyces cerevisiae/radiation effects , Plant Extracts/pharmacology , Antimutagenic Agents/pharmacology , Ilex paraguariensis/chemistry , Radiation Protection/methods , Mass Spectrometry , DNA, Fungal/radiation effects , Cell Survival/drug effects , Cell Survival/radiation effects , Cells, Cultured , Reproducibility of Results , Chromatography, Liquid , Mutagenesis , DNA Repair , Dose-Response Relationship, Radiation , DNA Breaks, Double-Stranded , Mutation Rate , Gamma RaysABSTRACT
Se exploró un posible efecto protector del genoma por parte de un derivado de la uva (vino Tannat). Se utilizaron poblaciones celulares haploides y diploides de Saccharomyces cerevisiae como modelo eucariota. Muestras celulares se expusieron a H2O2 en medio nutriente. El ADN se analizó por densitometría láser, luego de su aislamiento y separación por electroforesis con campos pulsados. Se aplicó la distribución de Poisson para la determinación de roturas dobles. El número de roturas dobles del ADN y la frecuencia mutagénica aumentaron en función de la dosis de H2O2, disminuyendo la probabilidad de sobrevida. La combinación de H2O2 con vino Tannat aumentó significa-tivamente la probabilidad de sobrevida y disminuyó el número de roturas dobles. No se observó efecto mutagénico por el vino Tannat. Estos efectos pudieron simularse utilizando altas concentraciones de α-tocoferol. Los resultados indican que un derivado de Vitis vinifera puede, en ciertas condiciones, disminuir las dobles roturas de ADN producidas por el H2O2 e incrementar las probabilidades de sobrevida celular. Los blancos involucrados podrían ser, entre otros, componentes intracelulares de las cascadas redox y/o enzimas de reparación del ADN.
The aim of this work was to analyse a possible genome protection provided by a grape derivative (Tannat wine) in yeast cell populations exposed to H2O2. Haploid and diploid strains of Saccharomyces cerevisiae were used as eukaryotic model. Cell samples were exposed to H2O2 in a nutrient medium. Chromosomal DNA was analysed after isolation and separation by pulsed field electrophoresis. Double strand breaks were determined by laser densitometry and application of Poisson distribution. Both haploid and diploid cells showed H2O2 dose dependent DNA fractionation, as well as an increase of lethal -and mutation- events. Upon combination of the Tannat wine and H2O2 a significant decrease of double strand breaks was observed, in association with an increase in surviving fractions. No mutagenic effect was observed after wine exposure. Part of the observations regarding protective wine effect were simulated by exposure to high concentrations of α-tocopherol. Present results indicate that a grape derivative could act as a genome protector increasing cell survival probabilities. Among others, the involved molecular targets could be components of transduction redox cascades as well as DNA repair enzymes.