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Photosynthesis and respiration were measured in 1 to 6 mm large aggregates (marine snow) collected in the Southern Californian Bight. USA. The aggregates were freely slnking in a vertical flow system with an upward flow velocity whlch opposed the sinking velocity of individual aggregates during the measurements. The aggregates were net heterotrophic communities at llght intensities S00 pE m-2 SS'. Bacterial densities on aggregates were >2000-fold higher than in the surrounding water. Cytophaga was highly abundant in the aggregate-associated bacterial community as identified by in situ hybridization techniques. Both the respiration rate per aggregate volume and the bacterial densities decreased with increasi.ng aggregate size. The respiration rates normalized to the number of bacteria in single aggregates were 7 4 to 70 fmol C cell-' d.' The aggregate community respired 433 to 984 ng C d-l per aggregate in darkness, which yielded a turnover time of 8 to 9 d for the total organic carbon in aggregates. Thus, marine snow is not only a vehicle for vertical flux of organic matter; the aggregates are also hotspots of microbial respiration which cause a fast and efficient respiratory turnover of particulate organic carbon in the sea.
Ploug et al. (Fri,) studied this question.
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