Abstract
Incorporation of [14C]leucine into proteins of bacteria was studied in a temperate mesohumic lake. The maximum incorporation of [14C] leucine was reached at a concentration of 30 nm determined in dilution cultures. Growth experiments were used to estimate factors for converting leucine incorporation to bacterial cell numbers or biomass. The initially high conversion factors calculated by the derivative method decreased to lower values after the bacteria started to grow. Average conversion factors were 7.09 × 1016 cells mol−1 and 7.71 × 1015 μm3 mol−1, if the high initial values were excluded. Using the cumulative method, the average conversion factor was 5.38 × 1015 μm−3 mol−1 I . The empirically measured factor converting bacterial biomass to carbon was 0.36 pg C μm−3 or 33.1 fg C cell−1. Bacterial production was highest during the growing season, ranging between 1.8 and 13.2 μg C liter−1 day−1, and lowest in winter, at 0.2–2.9 μg C liter−1 day−1. Bacterial production showed clear response to changes in the phytoplankton production, which indicates that photosynthetically produced dissolved compounds were used by bacteria. In the epilimnion bacterial production was, on average, 19–33% of primary production. Assuming 50% growth efficiency for bacteria, the allochthonous organic carbon could have also been an additional energy and carbon source for bacteria, especially in autumn and winter. In winter, a strong relationship was found between temperature and bacterial production. The measuring of [14C]leucine incorporation proved to be a simple and useful method for estimating bacterial production in humic water. However, an appropriate amount of [14C]leucine has to be used to ensure the maximum uptake of label and to minimize isotope dilution.
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Tulonen, T. Bacterial production in a mesohumic lake estimated from [14C]leucine incorporation rate. Microb Ecol 26, 201–217 (1993). https://doi.org/10.1007/BF00176953
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DOI: https://doi.org/10.1007/BF00176953