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Toxic vents and DNA damage: first evidence from a naturally contaminated deep-sea environment
Pruski, A.M.; Dixon, D.R. (2003). Toxic vents and DNA damage: first evidence from a naturally contaminated deep-sea environment. Aquat. Toxicol. 64(1): 1-13
In: Aquatic Toxicology. Elsevier Science: Tokyo; New York; London; Amsterdam. ISSN 0166-445X; e-ISSN 1879-1514, more
Peer reviewed article  

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Keywords
    Acids > Organic compounds > Organic acids > Nucleic acids > DNA
    Chemical reactions > Oxidation
    Dna repair
    Eukaryotes > Animals > Invertebrates > Mollusca > Bivalvia > Shellfish > Mussels
    Mussels
    Water springs > Geothermal springs > Hydrothermal springs
    Bathymodiolus azoricus Cosel & Comtet, 1999 [WoRMS]
    ANE, Azores [Marine Regions]
    Marine/Coastal

Authors  Top 
  • Pruski, A.M., more
  • Dixon, D.R., correspondent

Abstract
    Levels of DNA strand breakage were measured, using the comet assay, in cells from vent mussels, Bathymodiolus azoricus, from three contrasting vent fields on the mid Atlantic Ridge. Different levels of DNA damage were recorded in untreated mussels, shortly after collection, and it was animals from the shallowest, and less active, Menez Gwen vent field (840-m depth), which showed the greatest amount of damage. In contrast to animals from two deeper and putatively more toxic sites, Menez Gwen animals went on to repair this damage and were able to survive under laboratory conditions at 1 bar pressure for several months. Animals from the two deeper sites showed both higher levels of initial mortality and a much reduced capacity for survival at 1 bar. The differences in DNA damage levels at the time of collection were interpreted as an expression of differences in cell viability/enzyme activity rather than a reflection of any differences in their natural environmental conditions. Small B. azoricus showed a capacity to repair DNA damage, whereas this ability appeared to be lacking in large individuals. By reproducing at a relatively early age, the deep-sea vent fauna may be able to resist the toxic effects of its environment by exploiting this natural, stage specific capacity to repair damaged DNA.

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