Estimating Bacterial Production in Marine Waters from the Simultaneous Incorporation of Thymidine and Leucine

2001

167

126

The major pathways of transformation of particulate organic matter by heterotrophic bacteria are respiration and production of new biomass. Until today only a limited number of studies have measured simultaneously respiration and production by aggregate-associated bacteria. To study their role in the carbon cycle of aquatic systems we have formed model particles from diatoms (Skeletonema costatum, Thalasiosira weissflogii, Chaetoceros debilis) in roller tanks filled with natural seawater from Øresund, Denmark. Changes in bacterial community structure were analyzed by in situ hybridization and revealed members of the Cytophaga/Flavobacterium cluster and of the ␥ subclass of Proteobacteria to be the main actors. The combination of radiotracer and microsensor techniques allowed determination of bacterial protein production and community respiration on the same aggregate and hence the apparent growth efficiency. Apparent growth efficiency (bacterial production/[bacterial production ϩ community respiration]) was 0.50 Ϯ 0.03 (se) on 1.5-2.5 d old aggregates and independent of bacterial growth rate. The initial carbonspecific bacterial production and community respiration was 0.082 d Ϫ1 and 0.084 d Ϫ1 , respectively. Thereafter, the carbon-specific bacterial production decreased to 0.020 d Ϫ1, whereas specific community respiration decreased to 0.057 d Ϫ1. Hence, the apparent net growth efficiency decreased, partly as a result of grazing by protozoa, and it was much lower (0.23 Ϯ 0.04) at the end of incubation. Bacterial production was best correlated to particulate amino acids, whereas community respiration was best correlated to particulate organic carbon (POC). Protease activity was correlated to bacterial production and particulate combined amino acid content, whereas ␤-glucosidase activity was better correlated to POC and community respiration than to particulate combined amino acid content. Turnover times of radiolabeled amino acids increased from 17.8 to 1,190 h during incubation and were tightly coupled to particulate combined amino acids and POC. Eighty-seven percent of the decrease in particulate organic nitrogen (PON) over time could be explained by turnover of particulate combined amino acids by aggregateassociated food web. Thus, transformation and remineralization of freshly produced particulate organic matter by aggregate-attached food web is significant and the vertical flux of particulate organic matter in the ocean is highly reduced during sedimentation.Marine and lake snow (larger than 0.5 and 0.3 mm in diameter, respectively) are characterized as microzones highly enriched with nutrients (Shanks and Trent 1980; Grossart and Simon 1993). High concentrations of nutrients and heterotrophic flagellates and ciliates on these aggregates (Silver and Alldredge 1981;Caron et al. 1982) suggest high activities of aggregate-associated microbes. Whereas measured enzymatic hydrolysis rates are high, those of bacterial production are relatively low (Simon et al. 1990;Smith et al. 1992). This notion implie...

Section: Methodsmentioning

confidence: 99%

Microbial degradation of organic carbon and nitrogen on diatom aggregates

2001

167

126

“…Bacterial production rates-Bacterial production rates were measured using the microcentrifugation method (Smith and Azam 1992). Incorporation of [ 3 H]-thymidine ( 3 H-TdR; Fuhrman and Azam 1980) and [ 14 C]-leucine ( 14 C-Leu; Kirchman et al 1985, Simon andAzam 1989) into the ice-cold trichloroacetic acid precipitate was measured with a dual label approach (Chin-Leo and Kirchman 1988). 3 H-TdR (75 Ci mmol Ϫ1 ) and 14 C-Leu (312 mCi mmol Ϫ1 , both from Amersham) were added to samples and a formalin-killed control and were incubated at in situ temperature for 1 h in the dark.…”

Section: Methodsmentioning

confidence: 99%

Bacterial growth and grazing on diatom aggregates: Respiratory carbon turnover as a function of aggregate size and sinking velocity

2000

145

113

Bacterial growth, respiration, particulate organic carbon (POC), and particulate organic nitrogen (PON) were measured directly on differentially sized diatom aggregates incubated individually in suspension in order to study the coupling between these parameters under controlled conditions. After 3 d of incubation, bacteria, flagellates, and ciliates were present on aggregates in the ratio of 1,100 : 30 : 1. Bacterial generation times ranged from 0.4 to 2 d, but these short generation times did not result in an increase of bacterial abundance because bacteria were grazed approximately at similar rates. The entire microbial community respired 2.90 carbon units for each carbon unit incorporated by the bacteria. Bacterial production, community respiration, POC, and PON increased with increasing aggregate size, and respiration was proportional to POC and PON content. The POC specific respiration rate on aggregates was 0.083 d Ϫ1 , and 40% of the initial POC content was respired after 6 d. From simple calculations combining carbon-specific respiration rates and aggregate sinking velocities, it is concluded that a tight coupling between POC and microbial respiration may control the carbon fluxes of sinking diatom aggregates in the ocean.

“…Bacterial production rates-Bacterial production rates were measured directly after respiration had been determined on the same aggregate using the microcentrifugation method (Smith and Azam 1992 Kirchman 1988). 3 H-TdR (75 Ci mmol Ϫ1 ) and 14 C-Leu (312 mCi mmol Ϫ1 , both from Amersham) were added to samples and to a formalinkilled control and incubated at in situ temperature for 1 h in the dark.…”

Section: Methodsmentioning

confidence: 99%

Bacterial production and growth efficiencies: Direct measurements on riverine aggregates

2000

Heterotrophic bacteria transform organic matter by respiration and production of new biomass. Because there are only a limited number of studies on the respiration of bacteria attached to particulate organic matter, their role in the carbon cycle of aquatic systems is not well known. In this study, we combine radiotracer with microsensor techniques to measure bacterial production and respiration rates on the same aggregate and to directly determine the growth efficiency of the microbial community attached to aggregates. Aggregates of defined age were formed after incubation of water samples of the river Weser, Northern Germany, in roller tanks and their bacterial community was analyzed by in situ hybridization. The growth efficiency was 0.45± 0.04 (SE) on 1–3‐d‐old aggregates, and it was independent of the growth rate (µ). There was no correlation between respiration and the particulate organic carbon (POC) or particulate organic nitrogen (PON) content of the same aggregate. Bacterial growth efficiencies on aggregates decreased after 5 d of incubation, as bacterial production decreased and respiration increased. On 7‐ and 14‐d‐old aggregates, the growth efficiency was 0.23 ± 0.06 and 0.04 ± 0.01, respectively, and proportional to µ. The bacterial production was thus apparently substrate limited. Respiration was then correlated with both POC and PON content of the same aggregates. The changes in bacterial production and respiration occurred with con‐current changes in the bacterial community. The percentage of members of the a‐ and b‐subclass of Proteobacteria decreased from 13% and 33.7% to 2.6% and 9.0%, respectively, whereas those of the g‐subclass of filamentous Proteobacteria and Cytophaga increased from 31.9% to 50.4% and from 8.5% to 24.9%, respectively, during the 14 d of incubation. These results demonstrate that bacterial production and respiration on aggregates are dependent on the bacterial community and the substrate composition of aggregate. High growth efficiencies of aggregate‐associated bacteria, especially during the first days of colonization, suggest that aggregates are spots of high bacterial growth where a rapid and efficient transfer of organic matter into bacterial biomass takes place.