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Microbiology 146 (2000), 283-288
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Microbiology (2000), 146, 283-288.
© 2000 Society for General Microbiology

Physiology and Growth

Vibrio harveyi bioluminescence plays a role in stimulation of DNA repair

Agata Czyz1, Borys Wróbel2 and Grzegorz Wegrzyn1

Department of Molecular Biology, University of Gdask, Kladki 24, 80-822 Gdask, Poland1
Marine Biology Center, Polish Academy of Sciences, w. Wojciecha 5, 81-347 Gdynia, Poland2

Author for correspondence: Grzegorz Wegrzyn. Tel: +48 58 346 3014. Fax: +48 58 301 0072. e-mail: wegrzyn{at}biotech.univ.gda.pl

Although the genetics and biochemistry of bacterial luminescence have been investigated extensively, the biological role of this phenomenon remains unclear. Here it is shown that luxA, luxB and luxD mutants (unable to emit light) of the marine bacterium Vibrio harveyi are significantly more sensitive to UV irradiation when cultivated in the dark after irradiation than when cultivated under a white fluorescent lamp. This difference was much less pronounced in the wild-type (luminescent) V. harveyi strain. Survival of UV-irradiated Escherichia coli wild-type cells depended on subsequent cultivation conditions (in the dark or in the presence of external light). However, after UV irradiation, the percentage of surviving E. coli cells that bear V. harveyi genes responsible for luminescence was significantly higher than that of non-luminescent E. coli, irrespective of the subsequent cultivation conditions. Moreover, it is demonstrated that luminescence of V. harveyi can be stimulated by UV irradiation even in diluted cultures, under conditions when light emission by these bacteria is normally impaired due to quorum sensing regulation. It is proposed that luminescent bacteria have an internal source of light which could be used in DNA repair by a photoreactivation process. Therefore, production of internal light ensuring effective DNA repair seems to be at least one of the biological functions of bacterial luminescence.

Keywords: bioluminescence, Vibrio harveyi lux genes, DNA repair, photoreactivation, OS response

We would like to dedicate this paper to the memory of Karol Taylor, who introduced V. harveyi projects to our laboratories.




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