AOBPreview originally published online on November 2, 2007
Annals of Botany 2008 101(2):267-276; doi:10.1093/aob/mcm276
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Adaptation and Impairment of DNA Repair Function in Pollen of Betula verrucosa and Seeds of Oenothera biennis from Differently Radionuclide-contaminated Sites of Chernobyl
1 Department of Biochemistry, University of Oxford, South Parks Road, Oxford OX1 3QU, UK
2 Institute of Cell Biology and Genetic Engineering, UAS, 148 Zabolotnogo street, Kiev, 03143, Ukraine
3 Department of Virology, Kiev National University, 64, Volodymyrska Street, Kiev, 01033, Ukraine
4 School of Life Sciences, Oxford Brookes University, Gipsy Lane, Oxford OX3 0BP, UK
5 Oxford Research Unit, The Open University, Boars Hill, Oxford OX1 5HR, UK
* For correspondence. E-mail ivan.boubriak{at}bioch.ox.ac.uk
Received: 24 June 2007 Returned for revision: 2 August 2007 Accepted: 26 September 2007 Published electronically: 2 November 2007
Background and Aims: The plants that have remained in the contaminated areas around Chernobyl since 1986 encapsulate the effects of radiation. Such plants are chronically exposed to radionuclides that they have accumulated internally as well as to 
-, β- and 
-emitting radionuclides from external sources and from the soil. This radiation leads to genetic damage that can be countered by DNA repair systems. The objective of this study is to follow DNA repair and adaptation in haploid cells (birch pollen) and diploid cells (seed embryos of the evening primrose) from plants that have been growing in situ in different radionuclide fall-out sites in monitored regions surrounding the Chernobyl explosion of 1986.
Methods: Radionuclide levels in soil were detected using gamma-spectroscopy and radiochemistry. DNA repair assays included measurement of unscheduled DNA synthesis, electrophoretic determination of single-strand DNA breaks and image analysis of rDNA repeats after repair intervals. Nucleosome levels were established using an ELISA kit.
Key Results: Birch pollen collected in 1987 failed to perform unscheduled DNA synthesis, but pollen at /β-emitter sites has now recovered this ability. At a site with high levels of combined - and /β-emitters, pollen still exhibits hidden damage, as shown by reduced unscheduled DNA synthesis and failure to repair lesions in rDNA repeats properly. Evening primrose seed embryos generated on plants at the same /β-emitter sites now show an improved DNA repair capacity and ability to germinate under abiotic stresses (salinity and accelerated ageing). Again those from combined - and /β-contaminated site do not show this improvement.
Conclusions: Chronic irradiation at /β-emitter sites has provided opportunities for plant cells (both pollen and embryo cells) to adapt to ionizing irradiation and other environmental stresses. This may be explained by facilitation of DNA repair function.
Key words: DNA repair, adaptation, pollen, seed, Chernobyl, radionuclides, Betula verrucosa, Oenothera biennis
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