Bacterioplankton dynamics in Antarctic lakes
Entry ID:
ASAC_2154
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Summary
---- Public Summary from Project ---- Bacteria are an important part of the planktonic community of lakes and other aquatic environments. They use dissolved organic carbon in the water as a source of energy. This project aims to characterise the chemical nature of the pool of dissolved organic carbon, and manner in which bacteria use different fractions of it during the ... course of the year. Such information is crucial to constructing models of carbon cycling in lake communities. Models which characterise energy flow are important in understanding how these extreme, fragile lake ecosystems function. Methods used in the research (from the paper available in the download): (i) Sampling and sites - Crooked Lake and Lake Druzhby in the Vestfold Hills, Eastern Antarctica (68 degrees S, 78 degrees E) were studied between January 1999 and February 2000 (Figure 1 - see download). Crooked Lake has an area of 9 km2 and a maximum depth of 160m and was sampled at one site at 60m. Lake Druzhby has an area of 7 km2. It is a complex of three basins, two of which are shallow (sites 1 and 3) with maximum depths of 7m and 5m respectively, and one deep basin (site 2) with a maximum depth of 40m. Each of the basins was sampled at one site indicated on Figure 1. Sampling and production measurements were conducted monthly when logistics allowed access to the lakes. Access in summer was by helicopter and in winter, when the sea ice was sufficiently thick, by caterpillar track vehicle (Hagglunds). Vehicle access over land is not permitted for environmental reasons. The lakes were sampled by drilling a hole in the ice with a Jiffy drill and depth samples taken with a Kemmerer sampler from 0m (immediately under the ice), 2, 5, 8,10, 15 and 20m in Crooked Lake and site 2 of Lake Drzuhby, and 0m and 5m in the shallow basins. During a short phase of open water in Lake Druzhby during summer the lake was sampled from a boat. Water temperatures were measured with a digital thermometer. Aliquots of water from each depth were collected as follows: 1L in acid washed, deionsed water rinsed bottles for inorganic nutrients, dissolved organic carbon (DOC), dissolved amino acids (DAA) and dissolved carbohydrates (DCHO) analyses; 50 mL was fixed in buffered glutaradehyde (final concentration 2%) for counts of bacterial abundances. ii) Analysis of samples - Samples for inorganic nutrient analysis (soluble reactive phosphorus PO4-P, ammonium NH4-N, nitrate NO3-N) were filtered through GF/F glass fibre filters and concentrations assayed colorimetrically according to the methods of Mackereth et al. (1989) and Eisenreich et al. (1975). DOC concentrations were determined on GF/F filtered samples in a Shimadzo TOC 5000 carbon analyser. Concentrations of bulk DCHO were determined using MBTH according to Pakulski and Benner (1992) and bulk DAA using the o-phlaldialdehide/b-mercaptoethanol fluorescence procedure of Jones et al. (2002) with a LS-5B Fluorimeter (Perkin Elmer Corp, Boston,MA) with the emission wavelength set to 340 nm (slit width = 15 nm) and the emission wavelength set to 450 nm (slit width 20 nm). Total organic nitrogen (TON) was determined using a Shimadzu TC/TN analyser equipped with chemo-luminescence detection. Dissolved organic nitrogen was calculated by subtracting the inorganic N present in samples from the TON vlaues. Bacteria concentrations were determined on 10 mL glutaradehyde fixed aliquots. Each was sonicated for 2 minutes to disperse bacteria attached to particles of organic carbon that were noted in previous studies (Laybourn-Parry et al., 1994). Aliquots were stained with DAPI ( 4',6-diamidino-2-phenylindole, Sigma) then filtered through a black 0.2 micro m polycarbonate filter and viewed under epifluorescence micrcoscopy with UV excitation at x 1600. Bacterial biomass was calculated by measuring 50 cells on each preparation with a Patterson graticule, calculating cell volume using a sphere or ellipsoid as appropriate and converting volumes to carbon equivalents using a conversion factor of 0.20 pg C micro m3 (Bratbak and Dundas, 1984). (iii) Determination of bacterial production - Experiments were conducted in situ on water collected from 0, 5 and 10 m in Crooked Lake and site 2 of Lake Druzhby. In the shallow basins of Lake Druzhby (sites 1 and 3) experiments were conducted at 0m and 5m. The experiments were suspended from a frame through a hole in the ice, at the depths from which the water was collected. During the summer phase of open water in Lake Druzhby, incubations were undertaken in the laboratory at Davis under field light and temperature conditions. Bacterial production was determined using the dual labelling procedure for assessing the incorporation of thymidine into DNA and leucine into protein (Chin-Leo and Kirchman, 1988) with some modification (Zohary and Robarts, 1993). Saturation experiments on Crooked Lake and Lake Druzhby indicated that a minimum of 40 nM of [3H] thymidine and 20 nM of [14C] leucine was appropriate. To each incubation [3H] thymidine (specific activity 49 Ci mmol-1; Amerhsam) was added to a final concentration of 40nM and 14C-labelled leucine (specific activity 315 mCi mmol-1) was added to a final concentration of 20nM. At each depth four 20mL experimental and two control incubations were run in Whirlpaks. After incubation for 90 minutes the reaction was terminated by the addition of 0.6ml of formalin to give a final concentration of 4% and ice-cold trichloroacetic acid (TCA) to give a final concentration of 10%. Samples were filtered through 0.22 micro m cellulose acetate filters and washed with two volumes (5ml) of 5% ice cold TCA. The filters were dissolved with 1mL ethyl acetate, 10mL of scintillation fluid added and counts conducted in Beckman LS6500 scintillation counter. A conversion factor of 2x1018 cell mol-1 was applied to the incorporation rates of thymidine into DNA. Freshwater studies have demonstrated that where generation time exceeds 20 h a conversion factor in the region of 2.5 x 1018 cells mol-1 is appropriate, whereas where generation times are less than 20 h a conversion factor of 11.8 x 1018 cell mol-1 occurs (Smits and Riemann, 1988). We assumed similar low generation times in the cold waters of the saline lakes in this study. A conversion factor of 1.42 x 1017 cells mol-1 for the incorporation of leucine was applied (Chin-Leo and Kirchman, 1988). The determination of bacterial cell sizes and conversion to carbon is described under (ii) above. (iv) Nutrient addition effects on bacterial production - In these experiments the DOC from 10-12 litres of water were separated into 2 molecular weight fractions: less than 1000 Da and greater than 1000 Da, using a Pellicon-2 tangential ultra-filtration system (Millipore, USA). The water samples used were integrated from 2 m, 5 m, 10 m and 20 m. To prepare the water samples for enrichment incubations, a 0.2 micro M membrane filter plate was installed in the Pellicon-2 system. This membrane provided a sterilized DOC sample (less than 1000 Da fraction). The 0.2 micro M membrane plate was then replaced with 2 x 1000 Da membrane plates thereby providing efficient sample throughput. The samples were run until 2 litres of greater than 1000 Da fraction remained. Five hundred mL of raw lake water was then added to each of the water fractions (less than 1000 Da and greater than 1000 Da) in a ratio of 1:1 (v/v). A series of flasks each containing 1 L of water were set up, of which three acted as controls: lake water, less than 1000 Da 1:1 with lake water and greater than 1000 Da 1:1 with lake water. To a further three identical flasks 1 mL of a composite standard of inorganic nutrients were added made up of 100 micro g mL-1 PO4-P, NO3-N and NH4-N using KH2PO4, KN03 and NH4Cl respectively. The experiment was incubated (shaken) for three days in the dark at 4oC. Each flask was sub-sampled at 0, 24, 48 and 72 hours. Thirty-two mL aliquots were taken for DOC and inorganic nutrient analysis bacterial enumeration as outlined above. Fifty mL was removed for bacterial production determinations as described above. (v) Aggregate versus 'free' bacterial production - small particles of particulate organic matter have been shown to have high concentrations of bacteria and different rates of production relative to free floating bacteria (refs). To test any differences integrated water samples were collected from Crooked Lake and site 2 of Lake Druzhby. Two hundred mL samples where reverse gravity filtered through 18 micro m bolting silk sieves to produce 180 mL of filtrate and a residue of 20 mL concentrated particles, which was then made up to 200 mL with 0.2 micro m filtered lake water. Aliquots (20 mL) were fixed in buffered glutaradehyde, as in (ii) above, for determinations of bacterial abundance and biomass. Bacterial production determinations were conducted on each fraction and whole water controls as outlined in (iii) above. For further information, see the attached paper. The fields in this dataset are: Date Lake Depth Dissolved Organic Carbon Dissolved carbohydrates and amino acids Inorganic Nutrient Concentrations Primary Production Chlorophyll a
Geographic Coverage
Spatial coordinates
N: -68.0 |
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S: -68.0 |
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E: 78.0 |
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W: 78.0 |
Min Depth: 0 M
Max Depth: 20 M
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Temporal Coverage
Start Date:
1999-01-01
Stop Date:
2000-02-29
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Location Keywords
Science Keywords
ISO Topic Category
Platform
Access Constraints
The dataset is currently not publicly available.
Ancillary Keywords
Data Set Progress
Data Center
Distribution
Distribution Media:
HTTP
Distribution Size:
764 kb
Distribution Format:
.xls
Fees:
free
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Personnel
JOHANNA
LAYBOURN-PARRY
Role:
TECHNICAL CONTACT
Role:
DIF AUTHOR
Role:
INVESTIGATOR
Phone:
+44 115 951 6262
Fax:
+44 115 951 6261
Email:
J.Laybourn-Parry at nottingham.ac.uk
Contact Address:
University of Nottingham
DIVISION OF ENVIRONMENTAL SCIENCE
School Of Biological Sciences
City:
SUTTON BONINGTON
Province or State:
LEICS
Postal Code:
LE12 5RD
Country:
UNITED KINGDOM
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Related URL
Link:
GET DATA
Description:
Download point for the data - excel spreadsheet
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Publications/References
Alldredge, A.L. and Silver, M.W. (1988) Characteristics, dynamics and significance of marine snow. Prog. Oceanogr., 20, 41-82. Alldredge, A.L. and Youngbluth, M.J. (1985) The significance of macroscopic aggregates (marine snow) as sites for heterotrophic bacterial production in the mesopelagic zone of the subtropical Atlantic. Deep Sea Res. 32, 1445-1456. ... Amon, R.M.W. and Benner, R. (1996) Bacterial utilisation of different size classes of dissolved organic carbon, Limnol. Oceangr., 41, 41-51. Bayliss, P., Ellis-Evans, J.C. and Laybourn-Parry, J. (1997) Temporal patterns of primary production in a large ultra-oligotrophic Antarctic freshwater lake. Polar Biol. 18, 363-370. Bratbak, G. and Dundas, I. (1984) Bacterial dry matter content and biomass estimations. Appl. Environ. Microbiol., 48, 755-757. Bunte, C. and Simon, M. (1999) Bacterioplankton turnover of dissolved free monosaccharides in a mesotrophic lake. Limnol. Oceanogr., 44, 1862-1870. Campbell, J.W. and Arap, T. (1989) Photosynthetically available radiation at high latitudes. Limnol. Oceanogr., 34, 1490-1499. Carlsson, P. and Caron, D.A. (2001) Seasonal variation of phosphorus limitation of acterial growth in a small lake. Limnol. Oceanogr., 46, 108-120. Chin-Leo, G. and Kirchman, D.L. (1988) Estimating bacterial production in marine waters from the simultaneous incorporation of thymidine and leucine. Appl. Environ. Microbiol., 54, 1934-1939. Chróst, T.J., Münster, U., Rai, H, Albrecht, D., Witzel, K.P. and Overbeck, J. (1989) Photosynthetic production and exoenzymatic degradation of organic matter in the euphotic zone of a eutophic lake. J. Plankton Res., 11, 223-242. Coffin, R. B. (1989) Bacterial uptake of dissolved free and combined amino acids in estuarine waters.Limnol. Oceanogr., 34, 531-542. Eisenriech, S.J., Bannerman,R.T. and Armstrong, D.E. (1975) A simplified phosphorus analysis technique. Environ. Lett., 9, 43-53. Evans, H.E., Evans, R.D. and Lingard, S.M. (1989) Factors affecting the variation in the average molecular weight of dissolved organic carbon in freshwaters. Sci. Tot. Environ. 81/82, 297-306. Felip, M., Pace, M.L. and Cole, J.J. (1996) Regulation of planktonic bacterial growth rates: the effects of temperature and resources. Microb. Ecol., 31, 15028. Fuhrman, J. (1987) Close coupling between release and uptake of dissolved free amino acids in seawater studied by isotope dilution approach. Mar. Ecol. Prog. Ser. 37, 45-52. Grossart, H-P and Simon, M. (1993) Limnetic macroscopic organic aggregates) lake snow): occurrence, characteristics, and microbial dynamics in Lake Constance. Limnol. Oceanogr., 38, 532-546. Henshaw, T. and Laybourn-Parry, J. (2002) The annual patterns of photosynthesis in two large, freshwater, ultra-oligotrophic Antarctic lakes. Polar Biol., 25, 744-752. Jeffery,W.H., Von Haven, R., Hoch, M.P. and Coffin, R.B. (1996) Bacterioplankton RNA, DNA, protein content and relationships to rates of thymidine and leucine incorporation. Aquat. Microb. Ecol., 10, 87-95. Jones, D.L., Owen and A.G., Farrar, J.F. (2002) Simple method to enable the high resolution determination of total free amino acids in soil solutions and soil extracts. Soil Biol. Biochem. In Press Jones, R.I., Laybourn-Parry, J., Walton, M.C. and Young, J.M. (1997) The forms and distribution of carbon in a deep, oligotrophic lake (Loch Ness, Scotland). Vereh. Internat. Verein. Limnol., 26, 330-334. Jørgensen, N.O.G. (1987) Free amino acids in lakes: concentrations and assimilation rates in realtion to phytoplankton and bacterial production. Limnol. Oceanogr. 32, 97-111. Jørgensen, N.O.G. and Søndergaard, M. (1984) Are dissolved free amino acids free? Microb. Ecol., 10, 301-316. Kemp, P.F., Lee, S. and LeRoche, J. (1993) Estimating the growth rate of slowly growing marine bacteria from RNA content. Appl., Environ, Microbiol., 59, 2594-2601. Kerkhof, L. and Ward, B.B. (1993) Comparison of nucleic acid hybridization and fluorometry for measurement of the relationship between RNA/DNA ratio and growth rate in a marine bacterium. Appl. Environ. Micrcobiol., 59, 1303-1309. Kirchman, D. L.(1983) The production of bacteria attached to particles suspended in a freshwater pond. Limnol. Oceanogr. 28, 856-872. Kirchman, D.L.(2000) Uptake and regeneration of organic nutrients by marine heterotrophic bacteria. In D.L. Kirchman (Ed) Microbial Ecology of the Oceans. Wiley, pp 261-288. Kirchman, D.L. and Mitchell, R. (1982) Contribution of particle-bound bacteria to total microhterotrophic activity in five ponds and two marshes. Appl. Environ. Microbiol. 43, 200-209. Kirchman, D.L., K'nees, E. and Hodson, R.E. (1985) Leucine incorporation and its potential as a measure of protein synthesis by bacteria in natural aquatic systems. Appl. Environ. Microbiol., 49, 599-607. Laybourn-Parry, J., Walton, M., Young, J., Shrine, A. and Jones, R.I. (1994) The protozooplankton and bacterioplankton of a large oligotrophic lake. - Loch Ness, Scotland. J. Plankton Res., 16, 1655-1670 Laybourn-Parry, J., Bayliss, P and Ellis-Evans, J.C. (1995) The dynamics of heterotrophic nanoflagellates and bacterioplankton in a large ultra-oligotrophic Antarctic lake. J. Plankton Res., 17, 1835-1850. Laybourn-Parry, J., Quayle, W. and Henshaw, T. (2002) The biology and evolution of Antarctic saline lakes in relation to salinity and trophy. Polar Biol., 25, 542-552. Laybourn-Parry, J., Hofer, J. and Sommaruga, R. (2001c) Viruses in Antarctic freshwater and saline lakes. Freshwater Biol,. 46, 1279-1287. Mackereth, F.J.H., Heron, J. and Talling, J.F. (1989) Water Analysis: Some Revised Methods for Limnologists. Freshwater Biological Association, Ambleside, United Kingdom. Meyer, J.L., Edwards, R.T. and Risley, R.(1987) Bacterial growth on dissolved organic carbon from a blackwater river. Microb.Ecol., 13, 13-29. Obernosterer, I., Reitner, B. abd Herndl, G.J. (1999) Contrasting effects of solar radiation on dissolved organic matter and its bioavailability to marine bacterioplankton. Limnol. Oceanogr. 44, 1645-1654. Paluski, J.D. and Benner, R. (1992) an improved method for the hydrolysis and MBTH analysis of dissolved and particulate carbohydrates in seawater. Mar. Chem., 40, 143-160. Pedrós-Alió, C. and Brock, T.D. (1983) The importance of attachment to particles for planktonic bacteria. Arch. Hydrobiol., 96, 354-379. Rich, J.H., Gosselin, M., Sherr, E, Sherr, B. and Kirchman, D.L. (1997) High bacterial production, uptake and concentration of dissolved organic matter in the central Arctic Ocean. Deep Sea Res., 44, 1645-1663. Riemann, B., Bell, R.T. and Jørgensen, N.O.G. (1990) Incorporation of thymidine, adenine and leucine into natural bacterial assemblages. Mar. Ecol. Prog. Ser., 65, 87-94. Robarts, R.D. and Zohary, T. (1993) Fact or fiction - bacterial growth rates and production as determined by [methyl-3H]thymidine? Adv. Microbial. Ecol. 13, 371-425. Rodrigues, R.M.N.V. and Williams, P. le B. (2001) Heterotrophic bacterial utilisation of nitrogenous substances, determined from ammonia and oxygen fluxes. Limnol. Oceanogr., 46, 1675-1683. Rogerson, A and Laybourn-Parry, J., (1992) Bacterioplankton abundance and production in the Clyde, Scotland, Arch. Hydrobiol. 126, 1-14. Rosenstock, B. and Simon, M. (1993) Use of dissolved combined and free amino acids by planktonic bacteria in Lake Constance. Limnol. Oceanogr. 38, 1521-1531. Rosset, R., Julien, J. and Monier, R. (1966) Ribonucleic acid composition of bacteria as a function of growth rate. J. Molec. Biol., 18, 308-320. Silver, M.W., Shanks, A.L. and Trent, J.D. (1978) Marine snow: microplankton habitat and source of small-scale patchiness in pelagic populations. Science 201, 371-373. Simon, M. and Azam, F. (1989) Protein content and protein synthesis rates of planktonic marine bacteria. Mar. Ecol. Prog. Ser. 51, 201-213. Takacs, C.D. and Priscu, J.C. (1998) Bacterioplankton dynamics in the McMurdo Dry Valley lakes, Antarctica: production and biomass loss over four seasons. Microbial. Ecol., 78, 473-476. Tranvik, L.J. (1988) Availability of dissolved organic carbon for planktonic bacteria in oligotrophic lakes of differing humic content. Microbial Ecol., 16, 311-322. Tranvik, L.J. (1990) Bacterioplankton growth on fractions of dissolved organic carbon of different molecular weights from humic and clear waters. Appl. Environ. Microbiol., 56, 1672-1677. Vrede, K, Vrede, T., Isaksson, A. and Karlson, A. (1999) Effects of nutrients (phosphorus, nitrogen and carbon) and zooplanktonon bacterioplankton and phytoplankton - a seasonal study. Limnol. Oceanogr., 44. 1616-1624. Weinbaurer, M.G. and Peduzzi, P. (1995) effects of virus-rich molecular weight concentrations of seawater on the dynamics of dissolved amino acids and carbohydrates. Mar. Ecol. Prog. Ser. 127, 245-253.
Creation and Review Dates
DIF Creation Date:
2000-08-11
Last DIF Revision Date:
2009-01-21
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