Abstract
Freshwater wetlands constitute important ecosystems, and their benthic, attached microbial communities, including biofilms, represent key habitats that contribute to primary productivity, nutrient cycling, and substrate stabilization. In many wetland biofilms, algae constitute significant parts of the microbial population, yet little is known about their activities in these communities. An analysis of wetland biofilms from the Adirondack region of New York (USA) was performed with special emphasis on desmids, a group of evolutionarily advanced green algae commonly found in these habitats. Desmids constituted as much as 23.7% of the total algal and cyanobacterial flora of the biofilms during the July and August study periods. These algae represented some of the first eukaryotes to colonize new substrates, and during July their numbers correlated with fluctuations in general biofilm parameters such as biofilm thickness and dry weight as well as total carbohydrate. Significant numbers of bacteria were associated with both the EPS sheaths and cell wall surfaces of the desmids. Colonization of new substrates and development of biofilms were rapid and were followed by various fluctuations in microbial community structure over the short- and long-term observations. In addition to desmids, diatoms, filamentous green algae and transient non-motile phases of flagellates represented the photosynthetic eukaryotes of these biofilms.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Aubert, H, Brook, AJ, Shephard, KL (1989) Measurement of the adhesion of a desmid to a substrate. Br Phycol J 24: 293–295
Baranguet, C, van Beusekom, SAM, Veuger, B, Neu, TR, Manders, EMM, Sinke, JJ, Admiraal, W (2004) Studying undisturbed autorophic biofilms: still a technical challenge. Aquat Microb Ecol 34: 1–9
Baylson, FA, Stevens, BW, Domozych, DS (2001) Composition and synthesis of the pectin and protein components of the cell wall of Closterium acerosum (Chlorophyta). J Phycol 37: 796–809
Ben-Ari, E (1999) Not just slime. BioScience 49: 689–695
Bott, TL (1996) Algae in microscopic food webs. In: Stevenson, RJ, Bothwell, ML, Lowe, RL (Eds.) Algal Ecology: Freshwater Benthic Ecosystems. Academic Press, New York, pp 574–608
Brook, AJ (1981) The Biology of Desmids. Botanicals Monographs, vol 16. Blackwell Scientific Publications, Oxford, pp 276
Brook, AJ, Ellis, W (1987) The feeding of amoebae on desmids. Microscopy 35: 537–540
Browder, JA, Gleason, PJ, Swift, DR (1994) Periphyton in the Everglades: spatial variation, environmental correlates, and ecological implications. In: David, SM, Ogden, JC (Eds.) Everglades. The Ecosystem And Restoration. St. Lucie Press, Delray Beach, FL, pp 379–416
Burkholder, JM, Sheath, RG (1984) The seasonal distribution, abundance and diversity of desmids (Chlorophyta) in a softwater, north temperate stream. J Phycol 20: 159–172
Coesel, PFM (1997) The edibility of Staurastrum chaetoceros and Cosmarium abbreviatum (Desmidiaceae) for Daphnia galeata/hyaline and the role of desmids in aquatic food chains. Aquat Ecol 31: 73–78
Coesel, PFM (1994) On the ecological significance of a cellular mucilaginous envelope in planktic desmids. Algological Studies 73: 65–74
Costerton, JW (2000) Biofilms in the millennium: musings from a peak at Xanadu. In: Allison, DA, Gilbert, P, Lippin-Scott, HM, Wilson, M (Eds.) Community Structure and Cooperation in Biofilms. Cambridge University Press, New York, pp 329–344
Davey, ME, O’Toole, GA (2000) Microbial biofilm from ecology to molecular genetics. Microbiol Mol Biol Rev 64: 847–867
Devito, KJ, Dillon, P (1993) Importance of runoff and winter anoxia to the P and N dynamics of a beaver pond. Can J Fish Aquat Sci 50: 2222–2234
Devito, KJ, Hill, AR (1997) Sulphate dynamics in relation to groundwater-surface water interactions in headwater wetlands of the southern Canadian Shield. Hydrol Process 11: 485–500
Dodds, WK (2002) Freshwater ecology: concepts and environmental applications. Academic Press, San Diego, pp 569
Domozych, DS, Kort, S, Benton, S, Yu, T (2005) The extracellular polymeric substance of the green alga Penium margaritaceum and its role in biofilm formation. Biofilms 2: 1–16
Domozych, CR, Plante K, Blais, P, Paliulis, L, Domozych, DS (1993) Mucilage processing and secretion in the green alga Closterium. I. Cytology and biochemistry. J Phycol 29: 650–659
Domozych, DS, Domozych, CR (1993) Mucilage processing and secretion in the green alga Closterium. II. Ultrastructure and immunochemistry. J Phycol 29: 659–667
Dubois, M, Gilles, KA, Hamilton, JK, Rebers, PA, Smith, F (1956) Colorimetric method for determination of sugars and related substances. Anal Chem 28: 350–356
Edgar, LA, Pickett-Heaps, JD (1984) Diatom locomotion. In: Round, FE, Chapman, DJ (Eds.) Progress in Phycological Research. Vol. 3. Biopress Ltd. Bristol, UK, pp 47–88
Fisher, MM, Wilcox, LW (1996) Desmid–bacterial associations in Sphagnum-dominated Wisconsin peatlands. J Phycol 32: 543–549
Fisher, MM, Wilcox, LW, Graham, LE (1998a) Molecular characterization of epiphyte bacterial communities on charophycean green algae. Appl Environ Microbiol 64: 4384–4389
Fisher, MM, Wilcox, LW, Graham, LE (1998b) Bacterial numbers and activities in two northern Wisconsin Sphagnum bogs. Microb Ecol 36: 259–269
Gaur, JP, Rai, LC (2001) Heavy metal tolerance in algae. In: Rai, LC, Gaur, JP (Eds.) Algal Adaptation to Environmental Stresses. Springer, New York, pp 363–388
Gerrath, JF (2003) Conjugating green algae and desmids. In: Wehr, JD, Sheath, RG (Eds.) Freshwater Algae of North America. Ecology and Classification Academic Press, New York, pp 353–381
Gerrath, JF (1993) The biology of desmids: a decade of progress. In: Round, FE, Chapman, DJ (Eds.) Progress in Phycological Research, Vol. 9, Biopress, Bristol, pp 79–192
Goldsborough, LG, Robinson, GGC (1996) Pattern in wetlands. In: Stevenson, RJ, Bothwell, ML, Lowe, RL (Eds.) Algal Ecology: Freshwater Benthic Ecosystems. Academic Press, New York, pp 353–381
Graham, LE, Graham, JM, Wilcox, LW (2006) Plant Biology. Pearson/Prentice-Hall, Upper Saddle River, New Jersey, pp 670
Graham, LE, Wilcox, LW (2000) Algae. Prentice Hall, New Jersery, pp 640
Hader, DP (1982) Effects of inhibitors on photomovement in desmids. Arch Microbiol 129: 168–172
Hader, DP (1981) Coupling of photomovement and photosynthesis in desmids. Cell Motil 2: 73–82
Hader, DP, Wenderoth, K (1986) Light induced electrical potential changes and motility in desmids. Gen Phys Biophys 5: 173–178
Hoagland, KD, Rosowski, JR, Gretz, MR, Roemer, SC (1993) Diatom extracellular polymeric substrates: function, fine structure, chemistry, and physiology. J Phycol 29: 537–566
Jensen, A (1978) Chlorophyll and carotenoids. In: Hellebust, JA, Craigie, JS (Eds.) Handbook of Phycological Methods. Physiological and Biochemical Methods. Cambridge University Press, Cambridge, UK
Kalff, J (2002) Limnology. Inland water ecosystems. Prentice-Hall, Upper Saddle River, New Jersey, pp 592
Keevil, CW, Godfree, A, Holt, D, Dow, C (1999) Biofilms in the aquatic environment. Royal Society of Chemistry, Cambridge, UK, pp 242
Klarer, DM, Millie, DF (1992) Aquatic macrophytes and algae at Old Woman Creek estuary and other great lakes coastal wetlands. J Great Lakes Res 18: 6322–633
Komarek, J (2003) Coccoid and colonial cyanobacteria. In: Wehr, JD, Sheath, RE (Eds.) Freshwater Algae of North America. Elsevier Science, New York, pp 59–116
Lamberti, GA (1996) The role of periphyton in benthic food webs. In: Stevenson, RJ, Bothwell, ML, Lowe, RL (Eds.) Algal Ecology: Freshwater Benthic Ecosystems. Academic Press, New York, pp 533–573
Ledger, ME, Hildrew, AG (1998) Temporal and spatial variation in the epilithic biofilm of an acid stream. Freshw Biol 40: 655–670
Leppard, GG (1995) The characterization of algal and microbial mucilages and their aggregates in aquatic ecosystems. Sci Total Environ 165: 103–121
Linde, J, Morse, L, Domozych, DS (2001) Calmodulin and its role in the secretory apparatus of the desmid Closterium. Int J Plant Sci 162: 15–27
Lorch, D (1986) Desmids and heavy metals. I. Uptake of lead by cultures and isolated cell walls of selected species. Beiheft zur Nova Hedwigia 56: 105–118
Lorch, D (1978) Manganese: uptake and influence on growth and morphogenesis of selected species. Arch Hydrobiol 84: 166–179
McCormick, PV, O’Dell, MB, Shuford III, RBE, Backus, JG, Kennedy, WC (2001) Periphyton responses to experimental phosphorus enrichment in a subtropical wetland. Aquat Bot 71: 119–139
McCormick, PV, Shuford, RBE, Backus, JG, Kennedy, WC (1998) Spatial and seasonal patterns of periphyton biomass and productivity in the northern Everglades, Florida, USA. Hydrobiologia 362: 185–208
McCormick, PV, Rawlik, PS, Lurding, K, Smith, EP, Sklar, FH (1996) Periphyton–water quality relationships along a nutrient gradient in the northern Florida Everglades. J North Am Benthol Soc 15: 433–449
Mitsch, WJ, Gosselink, JG (1993) Wetlands. Van Norstrand-Reinhold, New York
Muller-Schwarze, D, Sun, L (2003) The Beaver: Natural History of a Wetlands Engineer. Cornell University Press, Ithaca, New York
Naiman, RJ, Johnston, CA, Kelly, JC (1988) Alteration of North American streams by beaver. BioScience 38: 753–762
Neu, TR, Woefl, S, Lawrence, JR (2004) Three-dimensional differentiation of photo-autotrophic biofilm constituents by multi-channel laser scanning microscopy (single-photon and two-photon excitation). J Microbiol Methods 56: 161–172
Neu, TR, Lawrence, JR (1997) Development and structure of microbial biofilms in river water studied by confocal laser scanning microscopy. FEMS Microb Ecol 24: 11–25
Oertel, A, Aichinger, N, Hochreiter, R, Thalhamer, J, Lutz-Meindl, U (2004) Analysis of mucilage secretion and excretion in Micrasterias (Chlorophyta) by means of immunoelectron microscopy and digital time lapse photography. J Phycol 40: 711–720
Parsek, MR, Fuqua, C (2003) Biofilms 2003: emerging themes and challenges in studies of surface-associated microbial life. J Bacteriol 186: 4427–4440
Paulsen, BS, Vieira, AAH (1994) Structure of the capsular and extracellular polysaccharides produced by the desmid Spondylosium panduriforme (Chlorophyta). J Phycol 30: 638–641
Prescott, GW, Bicudo, C, Vinyard, WC (1982) A synopsis of North American desmids. Part II. Desmidicaceae: Placodermae. Section 4. University of Nebraska Press, Lincoln, pp 700
Prescott, GW, Croasdale, HT, Vinyard, WC, Bicudo, C (1981) A synopsis of North American desmids. Part II. Desmidicaceae: Placodermae. Section 3. University of Nebraska Press, Lincoln, pp 720
Prescott, GW, Croasdale, HT, Vinyard, WC (1977) A synopsis of North American desmids. Part II. Desmidicaceae: Placodermae. Section 2. University of Nebraska Press, Lincoln, pp 413
Prescott, GW, Croasdale, HT, Vinyard, WC (1975) A synopsis of North American desmids. Part II. Desmidicaceae: Placodermae. Section 1. University of Nebraska Press, Lincoln, pp 275
Prescott, GW, Croasdale, HT, Vinyard, WC (1972) Desmidiales, Part 1. Saccodermae, Mesotaeniaceae. North American flora, Vol. II, Chap. 6, of Nebraska Press, Lincoln, p 84
Rolaufs, P, Hering, D, Lohse, S (2001) Composition, invertebrate community and productivity of a beaver dam in comparison to other stream habitat types. Hydrobiologia 459: 201–212
Shannon, CE, Weaver, W (1963) The Mathematical Theory of Communication 2University of Illinois Press, Urbana, pp 226
Spijkerman, E, Coesel, PFM (1998) Alkaline phosphatase activity in two planktonic desmid species and the possible role of an extracellular envelope. Freshw Biol 39: 503–513
Spijkerman, E, Coesel, PFM (1997) Growth kinetic parameters of two planktonic desmid species under fluctuating phosphorus conditions in continuous flow culture. J Plank Res 19: 1899–1912
Sutherland, IW (2001a) The biofilm matrix—an immobilized but dynamic microbial environment. Trends Microbiol 9: 222–227
Sutherland, IW (2001b) Biofilm exopolysaccahrides: a strong and sticky framework. Microbiology 147: 3–9
Updegraff, K, Pastor, J, Bridgham, SD, Johnston, CA (1995) Environmental and substrate controls over carbon and nitrogen wetlands. Ecol Appl 5: 151–163
Vicre, M, Santaella, C, Blanchet, S, Gateau, A, Driouich, A (2005) Root border-like cells of Arabidopsis. Microscopical characterization and role in the interaction with Rhizobacteria. Plant Physiol 138: 998–1008
Watanabe, MM, Mayama, S, Hiroki, M, Nozaki, H (2000) Biomass, species composition and diversity of epipelic algae in mire pools. Hydrobiologia 421: 91–102
Watnick, P, Kilter, R (2000) Biofilm, city of microbes. J Bacteriol 182: 2675–2679
Wehr, JD (2003) Freshwater habitats of algae. In: Wehr, JD, Sheath, RG (Eds.) Freshwater Algae of North America. Ecology and Classification. Academic Press, New York, pp 11–57
Wimpenny, JWT (2000) An overview of biofilms as function communities. In: Allison, DG (Ed.) SGM Symposium 59: Community Structure and Cooperation in Biofilms. Cambridge University Press, Cambridge, UK, pp 1–24
Woelkerling, WJ, Gough, SB (1976) Wisconsin desmids. I. Aufwuchs and plankton communities of selected acid bogs, alkaline bogs, and closed bogs. Hydrobiologia 48: 209–232
Woelkerling, WJ, Gough, SB (1976) Wisconsin desmids. III. Desmid community composition and distribution in relation to lake type and water chemistry. Hydrobiologia 51: 3–11
Wright, JP, Jones, CG, Flecker, AS (2002) An ecosystem engineer, the beaver, increase in species richness at the landscape level. Oecologia 132: 96–101
Acknowledgements
Special thanks to Kelly Dempsey-Little for her help in this project. Part of this study was supported by NSF grant 0419131 and Faculty Development Grants from Skidmore College.
Author information
Authors and Affiliations
Corresponding author
Rights and permissions
About this article
Cite this article
Domozych, D.S., Domozych, C.R. Desmids and Biofilms of Freshwater Wetlands: Development and Microarchitecture. Microb Ecol 55, 81–93 (2008). https://doi.org/10.1007/s00248-007-9253-y
Received:
Revised:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s00248-007-9253-y