Abstract
We used the stable isotopes of carbon and nitrogen to examine the food webs of three small flood-plain lakes (billabongs) in south-eastern Australia. With few exceptions, stable carbon isotope analysis could not be used to discriminate among the conspicuous potential sources of fringing, emergent or floating vegetation or benthic detritus. These primary sources showed little spatial or temporal variation in δ13C values, with means ranging from-28.5 to-26.8‰ in spring and-29.1 to-25.4‰ in late summer. Submerged vegetation had similar δ13C values to the above sources in spring but showed greater spatial variation and were less 13C-depleted, considerably so in some species, in late summer. Epiphytes and algae were 13C-depleted in spring compared with the other primary sources but became more 13C-enriched in late summer. Mean δ13C values for primary and secondary consumers were not only far more variable (-37.4 to-22.7‰) but in general were more negative than the potential food sources, particularly in spring. Using the combined information from stable carbon and nitrogen isotope analysis, we could narrow down the list of potential primary sources driving food webs in these billabongs. The freshwater crayfish (Cherax) was one of the few taxa that appeared to obtain its biomass carbon from detrital material. Gastropods and leptocerid caddis larvae on emergent or submerged vegetation obtained a mixture of carbon from epiphytes and macrophytes; in both taxa, epiphytes contributed more to biomass carbon than did the macrophytes. However, other common grazers and collector/gatherers sampled from macrophytes, e.g. baetid mayflies, chironomid larvae and atyid shrimps, were often too 13C-depleted even to have derived their biomass carbon solely from epiphytes. Many other primary consumers, including zooplankton, and mussels (Velesunio), and most of the secondary consumers, including water mites (Hydracarina), phantom midge larvae (Chaoborus) and fish, were also 13C-depleted. The enormous biomass of littoral and fringing vegetation could contribute to metazoan food webs in these billabongs only if an additional highly 13C-depleted source was consumed simultaneously. Methane released from billabong sediments could provide such a 13C-depleted carbon source that is re-introduced into metazoan food webs via the consumption of methanotrophic bacteria. Alternatively, food webs in these water bodies are largely driven by an unknown and inconspicuous 13C-depleted primary producer, such as planktonic Chlorophyta.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Boon PI (1990) Organic matter degradation and nutrient regeneration in Australian freshwaters: II. Spatial and temporal variation, and relation with environmental conditions. Arch Hydrobiol 117: 405–436
Boon PI (1991) Bacterial assemblages in rivers and billabongs of southeastern Australia. Microb Ecol 22: 27–52
Boon PI, Sorrell BK (1991) Biogeochemistry of billabong sediments. I. The effect of macrophytes. Freshwat Biol 26: 209–226
Boon PI, Shiel RJ (1990) Grazing on bacteria by zooplankton in Australian billabongs. Aust J Mar Freshwat Res 41: 247–257
Boon PI, Frankenberg J, Hillman TJ, Oliver RL, Shiel R (1990) Billabongs. In: Mackay N, Eastburn D (eds) The Murray. Murray-Darling Basin Commission, Canberra, pp 182–198
Brinson MM, Lugo AE, Broun S (1981) Primary productivity, decomposition and consumer activity in freshwater wetlands. Annu Rev Ecol Syst 12: 123–161
Carlough LA, Meyer JL (1991) Bacterivory by sestonic protists in a southeastern blackwater river. Limnol Oceanogr 36: 873–883
Carpenter SR, Lodge DM (1986) Effects of submersed macrophytes on ecosystem processes. Aquat Bot 26: 341–370
Chanton JP, Martens CS (1988) Seasonal variations in ebullitive flux and carbon isotopic composition of methane in a tidal freshwater estuary. Global Biogeochem Cycles 2: 289–298
Chanton JP, Pauly GG, Martens CS, Blair NE, Dacey JWH (1988) Carbon isotopic composition of methane in Florida everglade soils and fractionation during its transport to the trophosphere. Global Biogeochem Cycles 2: 245–252
Conrad R, Rothfuss F (1991) Methane oxidation in the soil surface layer of a flooded rice field and the effect of ammonium. Biol Fertil Soils 12: 12–32
Corpe WA, Jensen TE (1992) An electron microscopic study of picoplanktonic organisms from a small lake. Microb Ecol 24: 181–197
Ehhalt DH (1976) The atmospheric cycle of methane. In: Schlegel HG, Gottschalk G, Pfennig N (eds) Symposium on microbial production and utilisation of gases (H2, CH4, CO). Akademie der Wissenschaften, Gottingen, pp 13–22
Ehhalt DH, Volz A (1976) Coupling of the CH4 with the H2 and CO cycle: isotopic evidence. In: Schlegel HG, Gottschalk G, Pfennig N (eds) Symposium on microbial production and utilisation of gases (H2, CH4, CO). Akademie der Wissenschaften, Gottingen, pp 23–33
Estep MLF, Vigg S (1985) Stable carbon and nitrogen isotope tracers of trophic dynamics in natural populations and fisheries of the Lahontan lake system, Nevada. Can J Fish Aquat Sci 42: 1712–1719
Fenchel TM, Jørgensen BB (1977) Detritus food chains of aquatic ecosystems: the role of bacteria. In: Alexander M (ed) Advances in microbial ecology. Plenum, New York, pp 1–58
Fry B (1984) 13C/12C ratios and the trophic importance of algae in Florida Syringodium filiforme seagrass meadows. Mar Biol 79: 11–19
Haines EB (1977) The origins of detritus in Georgia salt marsh estuaries. Oikos 29: 254–260
Haines EB (1979) Interaction between Georgia salt marshes and coastal waters: a changing paradigm. In: Livingston RJ (ed) Ecological processes in coastal and marine systems. Plenum, New York, London, pp 35–46
Haines EB, Montague CL (1979) Food sources of estuarine invertebrates analysed using 13C/12C ratios. Ecology 60: 48–56
Hamilton SK, Lewis WM, Sippel SJ (1992) Energy sources for aquatic animals in the Orinoco River floodplain: evidence from stable isotopes. Oecologia 89: 324–330
Hillman TJ (1986) Billabongs. In: De Deckker P, Williams WD (eds) Limnology in Australia. Junk, Dordrecht, pp 457–470
Hillman TJ, Shiel RJ (1991) Macro- and microinvertebrates in Australian billabongs. Verh Int Verein Limnol 24: 1581–1587
Kitting CL, Fry B, Morgan MD (1984) Detection of inconspicuous epiphytic algae supporting food webs in seagrass meadows. Oecologia 62: 145–149
Kraffzik B, Conrad R (1991) Thymidine incorporation into lake water bacterioplankton and pure cultures of chemolithotrophic (CO, H2) and methanotrophic bacteria. Microb Ecol 23: 7–14
Large PJ (1983) Methylotrophy and methanogenesis. American Society for Microbiology, Washington
LaZerte BD, Szalados JE (1982) Stable carbon isotope ratio of submerged freshwater macrophytes. Limnol Oceanogr 27: 413–418
Lodge DM (1991) Herbivory on freshwater macrophytes. Aquat Bot 41: 195–224
Mann KH (1988) Production and the use of detritus in various freshwater, estuarine, and coastal marine ecosystems. Limnol Oceanogr 33: 910–930
Neill C, Cornwell JC (1992) Stable carbon, nitrogen, and sulfur isotopes in a prairie marsh food web. Wetlands 12: 217–224
Newman RM (1991) Herbivory and detritivory on freshwater macrophytes by invertebrates: a review. J North Am Benthol Soc 10: 89–114
Peterson BJ, Fry B (1987) Stable isotopes in ecosystem studies. Annu Rev Ecol Syst 18: 293–320
Peterson BJ, Howarth RW (1987) Sulfur, carbon, and nitrogen isotopes used to trace organic matter flow in the salt-marsh estuaries of Sapelo Island, Georgia. Limnol Oceanogr 32: 1195–1213
Peterson BJ, Howarth RW, Lipschultz F, Ashendorf D (1980) Salt marsh detritus: an alternative interpretation of stable carbon isotope ratios and the fate of Spartina alterniflora. Oikos 34: 173–177
Polunin NVC (1984) The decomposition of emergent macrophytes in fresh water. In: Macfayden A, Ford ED (eds) Advances in ecological research vol 14. Academic, London, pp 115–166
Rau GH (1980) Carbon-13/carbon-12 variation in subalpine lake aquatic insects: food source implications. Can J Fish Aquat Sci 37: 742–746
Shelford VE (1918) Conditions of existence. In: Ward HB, Whipple GC (eds) Freshwater biology. John Wiley, New York, pp 21–60
Shiel RJ (1980) Billabongs of the Murray-Darling System. In: Williams WD (ed) An ecological basis for water resource management. ANU Press, Canberra, pp 376–390
Sorrell BK, Boon PI (1992) Biogeochemistry of billabong sediments. II. Seasonal variations in methane production. Freshwat Biol 27: 435–445
Sweerts JRA, Bär-Gilissen M, Cornelese AA, Cappenburg TE (1991) Oxygen-consuming process at the profundal and littoral sediment-water interface of a small meso-trophic lake (Lake Vechten, The Netherlands). Limnol Oceanogr 36: 1124–1133
Uzaki M, Mizutani H, Wada E (1991) Carbon isotope composition of CH4 from rice paddies in Japan. Biogeochemistry 13: 159–175
Wahlen M, Tanaka N, Henry R, Deck R, Zeglen J, Vogel JS, Southon J, Shemesh A, Fairbanks R, Broecker W (1989) Carbon-14 in methane sources and in atmospheric methane: the contribution from fossil carbon. Science 245: 286–290
Webster JR, Benfield EF (1986) Vascular plant breakdown in freshwater ecosystems. Annu Rev Ecol Syst 17: 567–594
Wetzel RG (1990) Land-water interfaces: metabolic and limnological regulators. Verh Int Verein Limnol 24: 6–24
Whiticar MJ, Faber E, Schoell M (1986) Biogenic methane formation in marine and freshwater environments: CO2 reduction vs. acetate formation-isotopic evidence. Geochim Cosmochim Acta 50: 693–709
Author information
Authors and Affiliations
Rights and permissions
About this article
Cite this article
Bunn, S.E., Boon, P.I. What sources of organic carbon drive food webs in billabongs? A study based on stable isotope analysis. Oecologia 96, 85–94 (1993). https://doi.org/10.1007/BF00318034
Received:
Accepted:
Issue Date:
DOI: https://doi.org/10.1007/BF00318034