We studied the effects of natural sunlight on heterotrophic marine bacterioplankton in short-term experiments. We used a single-cell level approach involving flow cytometry combined with physiological probes and microautoradiography to determine sunlight effects on the activity and integrity of the cells. After 4 h of sunlight exposure, most bacterial cells maintained membrane integrity and viability as assessed by the simultaneous staining with propidium iodide and SYBR green I. In contrast, a significant inhibition of heterotrophic bacterial activity was detected, measured by 5-cyano-2,3 ditolyl tetrazolium chloride reduction and leucine incorporation. We applied microautoradiography combined with catalyzed reporter deposition-fluorescence in situ hybridization to test the sensitivity of the different bacterial groups naturally occurring in the Northwestern Mediterranean to sunlight. Members of the Gammaproteobacteria and Bacteroidetes groups appeared to be highly resistant to solar radiation, with small changes in activity after exposure. On the contrary, Alphaproteobacteria bacteria were more sensitive to radiation as measured by the cell-specific incorporation of labeled amino acids, leucine, and ATP. Within Alphaproteobacteria, bacteria belonging to the Roseobacter group showed higher resistance than members of the SAR11 cluster. The activity of Roseobacter was stimulated by exposure to photosynthetic available radiation compared to the dark treatment. Our results suggest that UV radiation can significantly affect the in situ single-cell activity of bacterioplankton and that naturally dominating phylogenetic bacterial groups have different sensitivity to natural levels of incident solar radiation.Aquatic bacterioplankton has been shown to be sensitive to sunlight radiation, especially to the shortest-wavelength fraction of UV radiation (for examples, see references 22, 27, 52, and 53). Solar UV radiation (UVR, 290 to 400 nm) causes cellular damage on different cell targets, including nucleic acids, proteins, and lipids, which may end up in mutations, cell inactivation, and death. Because bacteria are considered to be too small to develop efficient photoprotection against UVR (16) and their genetic material comprises a significant portion of their cellular volume (25), bacteria are probably among the most susceptible group to photodamage within the plankton.A relatively large number of studies have assessed the effect of UVR on bulk metabolic activities of natural bacterioplankton assemblages (see compilation in reference 24). Results from field studies on marine bacteria indicate that exposure to natural solar UVR results in a decrease in total bacterial abundance (38, 41), amino acid uptake (7), exoenzymatic activities (38), and oxygen consumption (41) and a significant inhibition of protein and DNA synthesis (22, 52). However, the effects of UVR on bacterioplankton have seldom been studied at the single-cell level (but see reference 33). Thus, we do not know whether the negative effects of UVR on cellula...
