Ciliates versus other components of the microbial loop in the psammolittoral zone: horizontal distribution

The objective of this study was to determine the abundance and biomass of microbial loop components in 2 lakes of different trophic status. The lakes (mesotrophic and eutrophic ones) were located in the Leczna-Wlodawa Lakeland. The effect of selected physical and chemical water parameters on this group of organisms was also analyzed. Psammon samples were collected during 3 seasons: spring, summer, and autumn 2011. In each of the lakes, samples were collected in the euarenal, higroarenal, and hydroarenal zones. The highest abundance and biomass of the microbial loop components were recorded in spring in the eutrophic lake. The mesotrophic lake showed an increase in flagellates in autumn with a decline in the abundance of ciliates. In the mesotrophic lake, the density of individual elements of the microbial loop was correlated with temperature and total organic carbon, and in the eutrophic lake with pH, chlorophyll a, and ammonium nitrogen. In both lakes, a significant correlation occurred between bacteria and ciliate abundances. In both trophic types of lakes, the highest correlations between bacteria and heterotrophic protists were noted in hydroarenal zone. In the euarenal and higroarenal zones, the correlations were weaker.

Anahtar Kelimeler:

Key words: lake, microbial loop, psammon

Ciliates versus other components of the microbial loop in the psammolittoral zone: horizontal distribution

Keywords:

Key words: lake, microbial loop, psammon,

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Alongi DM (1986). Quantitative estimates of benthic protozoa in tropical marine systems using silica gel: a comparison of methods. Estuar Coast Shelf Sci 23: 443–450.
Amblard C, Carrias JF, Bourdier G, Maurin N (1995). The microbial loop in a humic lake: seasonal and vertical variations in the structure of different communities. Hydrobiologia 300/301: 71–
Arvola L, Kankaala P, Tulonen T, Ojala A (1996). Effects of phosphorus and allochthonous humic matter enrichment on the metabolic processes and community structure of plankton in a boreal lake (Lake Pääjärvi). Can J Fish Aquat Sci 53: 1646–1662.
Auer B, Arndt H (2001). Taxonomic composition and biomass of heterotrophic flagellates in relation to lake trophy and season. Freshwat Biol 46: 959–972.
Azam F, Fenchel T, Field JG, Gray JS, Meyer-Reil LA, Thingstad F (1983). The ecological role of water column microbes in the sea. Mar Ecol Prog Ser 10: 257–263.
Chróst RJ, Adamczewski T, Kalinowska K, Skowrońska A (2009). Abundance and structure of microbial loop components (bacteria and protist) in lakes of different trophic status. J Microbiol Biotechnol 19: 858–868.
Czernaś K, Krupa D, Wojciechowski I, Galek J (1991). Differentiation and activity changes of algal communities in the shore zone of mesotrophic Piaseczno Lake in years 1983–1985. Ekol Pol 39: 323–341.
Ejsmont-Karabin J (2008). Vertical microzonation of psammon rotifers (Rotifera) in the psammolittoral habitat of an eutrophic lake. Pol J Ecol 56: 351–357.
Ejsmont-Karabin J, Gorelysheva Z, Kalinowska K, Węgleńska T (2004). Role of zooplankton (Ciliata, Rotifera and Crustacea) in phosphorus removal from cycling: lakes of the river Jorka watershed (Masurian Lakeland, Poland). Pol J Ecol 52: 275–284.
Epstein SS (1997). Microbial food webs in marine sediments. I. Trophic interactions and grazing rates in two tidal flat communities. Microb Ecol 34: 188–198.
Fenchel T (1987). The Ecology of Protozoa: The Biology of FreeLiving Phagotrophic Protists. Madison, WI, USA: Science Tech Publishers.
Foissner W, Berger H (1996). A user-friendly guide to the ciliates (Protozoa, Ciliophora) commonly used by hydrobiologist as bioindicators in rivers, lakes and waste waters, with notes on their ecology. Freshwater Biol 35: 375–470.
Gücker B, Fischer H (2003). Flagellate and ciliate distribution in sediments of a lowland river: relationships with environmental gradients and bacteria. Aquat Microb Ecol 31: 67–76.
Gudasz C, Bastviken D, Premke K, Steger K, Tranvik JL (2012). Constrained microbial processing of allochthonous organic carbon in boreal lake sediments. Limnol Oceanogr 57: 163–175.
Hagström A, Azam F, Andersson A, Wikner J, Rassoulzadegan F (1988). Microbial loop in an oligotrophic pelagic marine ecosystem: possible roles of cyanobacteria and nanoflagellates in the organic fluxes. Mar Ecol Prog Ser 49: 171–178.
Hermanowicz W, Dożańska W, Doilido J, Koziorowski B (1976). Physical and Chemical Investigation Methods of Water and Sewage. Warsaw, Poland: Arkady (in Polish).
Jędrzejczak MF (1999). The degradation of stranded carrion on a Baltic Sea sandy beach. Oceanol Stud 3/4: 109–141.
Jerome CA, Montagnes DJS, Taylor FJR (1993). The effect of the quantitative protargol stain and Lugol’s and Bouin’s fixatives on cell size: a more accurate estimate of ciliate species biomass. J Euk Microbiol 40: 254–259.
Kalinowska K (2004). Bacteria, nanoflagellates and ciliates as components of the microbial loop in three lakes of different trophic status. Pol J Ecol 52: 19–34.
Kalinowska K (2008). Psammon ciliates: diversity and abundance in hygroarenal of eutrophic lake. Pol J Ecol 56: 259–271.
Kalinowska K, Ejsmont-Karabin J, Gorelysheva Z, Rybak IJ (2012). Biomass distribution and dynamics and food web relations in psammon community of a eutrophic lake. Pol J Ecol 60: 443– 4
Kalinowska K, Ejsmont-Karabin J, Rybak JI (2010). The role of lake shore sand deposits as bank of ciliate, rotifer and crustacean resting forms: experimental approach. Pol J Ecol 58: 323–332.
Kalinowska K, Gorelysheva Z, Ejsmont-Karabin J (2011). Psammon algae: composition and spatial distribution in hygroarenal of eutrophic lake- Pol J Ecol 59: 193-200.
Kemp PF (1988). Bacterivory by benthic ciliates: significance as a carbon source and impact on sediment bacteria. Mar Ecol Prog Ser 49: 163–169.
Koop RG, Griffiths CL (1982). The relative significance of bacteria, meio- and macrofauna on an exposed sandy beaches. Mar Biol 66: 295–300.
Koop K, Newell R C, Lucas M I (1982). Microbial regeneration of nutrients from the decomposition of macrophyte debris on the shore. Mar Ecol Prog Ser 9: 91–96.
Koton-Czarnecka M, Chróst RJ (2003). Protozoans prefer large and metabolically active bacteria. Pol J Environ Stud 12: 325–334.
Lokko K, Virro T, Kotta J (2013). Testing effects of shore height level, sediment characteristics and vegetation cover on the seasonality of zoopsammon communities in the two boreal lakes differing in their trophic state. Hydrobiologia 700: 1–8.
Mayer J, Dokulil MT, Salbrechter M, Berger M, Posch T, Pfister G, Kirschner AKT, Velimirov B, Steitz A, Ulbricht T (1997). Seasonal successions and trophic relations between phytoplankton, zooplankton, ciliate and bacteria in a hypertrophic shallow lake in Vienna, Austria. Hydrobiologia 342/343: 165–174.
Mieczan T (2008). Diversity and vertical distribution of planktonic ciliates in a stratified mesotrophic lake: relationship to environmental conditions. Oceanol Hydrobiol Stud 37: 83–95.
Mieczan T, Nawrot D (2012a). Horizontal distribution of psammonic ciliates in two lakes of different trophic status: relationship to physical and chemical parameters. Arch Env Protect 38: 55–70.
Mieczan T, Nawrot D (2012b). Vertical micro-distribution of psammonic ciliates and their relationship to physical and chemical parameters in two lakes of different trophic status. Oceanol Hydrobiol Stud 2: 48–56.
Mudryk Z, Podgórska B, Ameryk A (2001). Bacteriological characterization of a Baltic sandy beach in summer. Ecohydrol Ecohyrobiol 1: 503–509.
Nawrot D, Mieczan T (2012). Co-occurrence of psammonic ciliates and rotifers in poor eutrophic lake (Łęczna-Włodawa Lakeland). TEKA Komisji Ochrony i Kształtowania Środowiska Przyrodniczego 9: 125–133.
Novitsky JA, MacSween MC (1989). Microbiology of a high energy beach sediment: evidence for an active and growing community. Mar Ecol Prog Ser 52: 71–75.
Ochieng CA, Erftemejer PLA (1999). Accumulation of seagrass beach cast along the Kenyan coast: a quantitative assessment. Aqua Bot 65: 221–238.
Podgórska B, Mudryk Z, Skórczewski P (2008). Abundance and production of bacteria in a marine beach (Southern Baltic Sea). Pol J Ecol 56: 405–414.
Pomeroy LR (1974). The ocean’s food web, a changing paradigm. BioScience 24: 499–504.
Porter KG, Feig YS (1980). The use of DAPI for identifying and counting aquatic microflora. Limnol Oceanogr 25: 943–948.
Porter KG, Pearl H, Hodson R, Pace ML, Priscu J, Riemann B, Scavia D, Stockner J G (1988). Microbial interactions in lake food webs. In: Carpenter SR, editor. Complex Interactions in Lake Communities. Berlin, Germany: Springer, pp 209–227.
Radwan S, Kornijów R (1998). Hydrobiological characteristics of lakes. In: Harasimiuk M, Michalczyk Z, Turczyński M, editors. Lakes in Łęczna-Włodawa Lakeland. Lublin, Poland: Wydawnictwo UMCS, pp. 129–144.
Sanders RW, Caron DA, Berninger UG (1992). Relationship between bacteria and heterotrophic nanoplankton in marine and fresh waters: an inter-ecosystem comparison. Mar Ecol Prog Ser 86: 1–
Sanders RW, Porter KG, Bennett SJ, DeBiase AE (1989). Seasonal patterns of bacterivory by flagellates, ciliates, rotifers, and cladocerans in a freshwater planktonic community. Limnol Oceanogr 34: 673–687.
Schmid-Araya JM (1998). Small-sized invertebrates in a gravel stream: community structure and variability of benthic rotifers. Freshwat Biol 39: 25–39.
Šimek K, Bobková J, Macek M, Nedoma J (1995). Ciliate grazing on picoplankton in a eutrophic reservoir during the summer phytoplankton maximum: a study at the species and community level. Limnol Oceanogr 40: 1077–1090.
Starink M, Bär-Gilissen MJ, Bak RPM, Cappenberg TE (1996). Seasonal and spatial variations in heterotrophic nanoflagellate and bacteria abundances in sediments of a freshwater littoral zone. Limnol Oceanogr 41: 234–242.
Stockner JG, Shortreed KS (1989). Algal picoplankton and contribution to food webs in oligotrophic British Columbia Lakes. Hydrobiologia 173: 151–166.
Szeląg-Wasielewska E, Fyda J (1999). Phytoplankton and ciliate communities of ten lobelian Pomeranian lakes (NW Poland). Acta Hydrobiol 41: 153–164.
Weisse T, Müller H, Pinto-Coelho RM, Schweizer A, Sprigmann D, Baldringer G (1990). Response of the microbial loop to the phytoplankton spring bloom in a large prealpine lake. Limnol Oceanogr 35: 781–794.
Wiszniewski J (1934). Researches ecologiques sur le psammon et specialement sur les Rotiferes psammiques. Arch Hydrobiol I Ryb 6: 149–165 (in French).
Wiszniewski J (1937). Differenciation ecologique des Rotiferes dans le Psammon. d’eaux douces. Ann Mus Zool Pol 13: 1–13 (in French).