Abstract
Genotoxicity is the ability of specific substances to cause DNA damage, affecting development, physiology, and reproduction. This is often mediated by induction of oxidative stress. This in vitro study aims to test the ability of two antioxidants, ellagic acid (EA, 100 µM) and curcumin (Cur, 40 µM) to protect zebrafish blood cells from the genotoxic action of benzene (10 µL/mL). Cells were treated for 30, 60, and 90 min with EA or Cur alone and in combination with benzene. The antigenotoxic role of antioxidants was evaluated in terms of cytotoxicity by trypan blue dye, genome stability by RAPD-PCR technique, DNA fragmentation and percentage of apoptotic cells using Comet and Diffusion assay, respectively. The results did not show statistical differences in terms of cell viability, genome stability, DNA damage and apoptosis between cells treated with antioxidants. When zebrafish blood cells were co-incubated with individual antioxidants and benzene, a significant improvement of these parameters was observed in comparison with cells incubated in benzene. Our results suggested that EA and Cur are able to protect zebrafish blood cells against DNA damage and apoptosis caused by mutagenic substance, and laid the foundation for future studies investigating their antigenotoxic potential in DNA oxidative damage therapy.
Highlights
Published: 2 September 2021Genotoxicity is the capacity of a substance to damage the DNA by chemically modifying the nucleotide sequence or the DNA structure [1]
Benzene exposure resulted in reduced zebrafish blood cells
We observed that DNA damage and apoptotic rate were increased when zebrafish blood cells were incubated with benzene
Summary
Genotoxicity is the capacity of a substance to damage the DNA by chemically modifying the nucleotide sequence or the DNA structure [1]. This can have severe repercussions on cellular functions and survival, and can be transmitted to the offspring when germ cells are damaged [1]. A heavy metal present in pigments used for plastic products [4], significantly increases the rate of DNA damage in zebrafish [5], mainly through the generation of OS [6]. In vitro exposure of human sperm cells to nano-contaminant resulted in an increased rate of DNA damage and reduced DNA integrity, along with increased ROS generation [7]
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