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The dependence between bacterial production and environmental conditions in the Gulf of Gdańsk

Identyfikatory
Warianty tytułu
Języki publikacji
EN
Abstrakty
EN
Bacterial production, primary production and a number of other environmental factors were measured during six cruises in the Gulf of Gdańsk conducted in various seasons from 1995 to 2001. Bacterial production (BP) in the epipelagic layer ranged from 1.5% (April) to 80% (July) of the gross primary production (PP). Significant differences were observed between the BP/PP ratios in estuarine and open-water areas. The highest values were recorded in the coastal area and near the mouth of the river Vistula. It suggests that allochthonous organic matter has a great influence on BP. The correlations between particular parameters and regression analyses indicated that BP in the Gulf of Gdańsk depended on temperature, organic nitrogen concentration, PP, chlorophyll a concentration, organic phosphorus concentration, salinity and biochemical oxygen demand. Of all the independent variables, the temperature had the greatest impact on BP (R2 = 0.62). There was an inverse parabolic relationship between bacterial production and temperature. It appears that above a temperature of 12°C bacterial production depended on substrates to a higher degree than on temperature. The negative correlation between BP and concentrations of mineral nitrogen and phosphorus in the annual cycle were probably due to an indirect dependence. A multiple regression equation, which included temperature and organic phosphorus concentrations, explained 78% of the variation in BP.
Czasopismo
Rocznik
Strony
27--45
Opis fizyczny
bibliogr. 58 poz., tab., wykr.
Twórcy
autor
  • Sea Fisheries Institute, Department of Fisheries, Oceanography and Marine Ecology, Kołłątaja 1, PL–81–332 Gdynia, Poland
  • Institute of Oceanology, Polish Academy of Sciences, Genetics and Marine Biotechnology Department, św. Wojciecha 5, PL–81–347 Gdynia, Poland
autor
  • Sea Fisheries Institute, Department of Fisheries, Oceanography and Marine Ecology, Kołłątaja 1, PL–81–332 Gdynia, Poland
Bibliografia
  • [1] Albright L. J., Sherr E. B., Sherr B. F., Fallon R. D., 1987, Grazing of ciliated protozoa on free and particle-attached bacteria, Mar. Ecol. Prog. Ser., 38, 125–129.
  • [2] Autio M. R., 1992, Temperature regulation of brackish water bacterioplankton, Arch. Hydrobiol. Beih. Ergebn. Limnol., 37, 253–263.
  • [3] Bergström I., Heinänen A., Salonen K., 1986, Comparison of Acridine Orange, Acriflavin and Bisbentzimin stains for enumeration of bacteria in clear and humic waters, Appl. Environ. Microbiol., 51 (3), 664–667.
  • [4] Bjørnsen P. K., 1986, Automatic determination of bacterioplankton biomass by image analysis, Appl. Environ. Microbiol., 51 (6), 1199–1204.
  • [5] Carman R., Rahm L., 1997, Early diagenesis and chemical characteristics of interstitial water and sediments in the deep deposition bottoms of the Baltic Proper, J. Sea Res., 37 (1)–(2), 25–47.
  • [6] Caron D. A., 1983, Technique for enumeration of heterotrophic and phototrophic nanoplankton, using epifluorescence microscopy, and comparison with other procedures, Appl. Environ. Microbiol., 46, 491–498.
  • [7] Cole J. J., Findlay S., Pace M. L., 1988, Bacterial production in fresh and saltwater ecosystems: a cross-system overview, Mar. Ecol. Prog. Ser., 43, 1–10.
  • [8] Cyberska B., Lauer Z., 1990, Oxygen and thermohaline conditions in the Polish fishing zone in 1979–1983, Oceanologia, 29, 3–25.
  • [9] Dojlido J. R., Niemirycz E., Morawiec P., 1994, Nutrient loads in the Vistula River–outflowintotheBalticSea, [in:] Hydrochemical, chemical and biological processes of transformation and transport of contaminants in aquatic environments, N. E. Peters, R. J. Allan & V. V. Tsirkunov (eds.), IAHS Publ. No 219, 205–215.
  • [10] Evans C. A., O’Reilly J. E., Thomas J. P., 1987, A handbook for measurement of chlorophyll a and primary productivity, BIOMASS Sci. Ser., 8, 114 pp.
  • [11] Farmer J. N., 1980, The Protozoa. Introduction to protozoology, C. V. MosbyCo., St. Louis (Mo), 732 pp.
  • [12] Fenchel T., 1968, The ecology of marine microbenthos. III. The reproductive potential of ciliates, Ophelia, 5 (1), 123–136.
  • [13] Fenchel T., 1969, The ecology of marine microbenthos. IV. Structure and function of the benthic ecosystem, its chemical and physical factors and the microfauna communities with special reference to the ciliated Protozoa, Ophelia, 6, 1–182.
  • [14] Fuhrman J. A., Azam F., 1982, Thymidine incorporation as a measure of heterotrophic bacterioplankton production in marine surface waters: evaluation and field results, Mar. Biol., 66, 109–120.
  • [15] Gast V., 1985, Bacteria as a food source for microzooplankton in the Schlei Fjord and Baltic Sea, with special references to ciliates, Mar. Ecol. Prog. Ser., 22 (2), 107–120.
  • [16] Grasshoff K., Ehrhardt M., Kremling K. (eds.), 1983, Methods of sea water analysis, Verl. Chem., Weinheim, 63–97 and 127–187.
  • [17] Heinänen A., Kononen K., Kuosa H., Kuparinen J., Mäkelä K., 1995, Bacterioplankton growth associated with physical fronts during a cyanobacterial bloom, Mar. Ecol. Prog. Ser., 116, 233–245.
  • [18] HELCOM, 1988, Guidelines for the Baltic monitoring programme for the third stage, Baltic Sea Environ. Proc. No 27 (D), 161 pp.
  • [19] HELCOM, 1990, Second periodic assessment of the state of the marine environment of the Baltic Sea, 1984–1989, Baltic Sea Environ. Proc. No 35 (B), 432 pp.
  • [20] HELCOM, 2002, Fourth periodic assessment of the state of the marine environment of the Baltic Sea, 1994–1998, Baltic Sea Environ. Proc. No 82 (B), 215 pp.
  • [21] Hobbie J. E., Daley R. J., Jasper S., 1977, Use of Nuclepore filters for counting bacteria by fluorescence microscopy, Appl. Environ. Microbiol., 33 (5), 1225–1228.
  • [22] Joint I. R., Pomroy A. J., 1987, Activity of heterotrophic bacteria in the euphotic zone of the Celtic Sea, Mar. Ecol. Prog. Ser., 41, 155–165.
  • [23] Kruk-Dowgiałło L., 1998, Phytobenthos as indicator of the state of environment of the Gulf of Gdańsk, Oceanol. Stud., 27 (4) 105–123.
  • [24] Kuosa H., Kivi K., 1989, Bacteria and heterotrophic flagellates in the pelagic carbon cycle in the northern Baltic Sea, Mar. Ecol. Prog. Ser., 53, 93–100.
  • [25] Kuparinen J., 1988, Development of bacterioplankton during winter and early spring at the entrance to the Gulf of Finland, Baltic Sea,Verh.Int.Verein. Limnol., 23, 1869–1878.
  • [26] Kuparinen J., Heinänen A., 1993, Inorganic nutrient and carbon controlled bacterioplankton growth in the Baltic Sea, Estuar. Coast. Shelf Sci., 37, 271–285.
  • [27] Larsson U., Hagström A., 1979, Phytoplankton exudate release as an energy source for the growth of pelagic bacteria, Mar. Biol., 52, 199–206.
  • [28] Larsson U., Hagström A., 1982, Fractionated phytoplankton primary, exudate release and bacterial production in a Baltic eutrophication gradient, Mar. Biol., 67, 57–70.
  • [29] Li W. K. W., Harrison W. G., 2001, Chlorophyll, bacteria and picophytoplankton in ecological provinces of the North Atlantic, Deep-Sea Res. Pt. II, 48, 2271–2293.
  • [30] Lignell R., 1990, Excretion of organic carbon by phytoplankton: its relation to algal biomass, primary productivity and bacterial secondary productivity in the Baltic Sea, Mar. Ecol. Prog. Ser., 68, 85–99.
  • [31] Lignell R., Kaitala S., Kuosa H., 1992, Factors controlling phyto- and bacterioplankton in late spring on a salinity gradient in the northern Baltic, Mar. Ecol. Prog. Ser., 84, 121–131.
  • [32] Maciejowska M., Boćwińska G., 1996, Bacterioplankton in the coastal zone of the Gulf of Gdańsk, Oceanol. Stud., 25 (1)–(2), 115–125.
  • [33] Mudryk Z., 2003, Characteristic of heterotrophic bacteria inhabiting the Gulf of Gdańsk, Baltic Coast. Zone, 6, 65–77.
  • [34] Mudryk Z., Korzeniewski K., Falkowska L., 1991, Bacteriological investigation of the surface microlayer of the Gulf of Gdańsk, Oceanologia, 30, 93–103.
  • [35] Niemirycz E., Rybiński J., Korzec E., Makowski Z., Ceglarski R., Heybowicz E., 1989, Pollution flow from the Vistula and Oder rivers, [in:] Environmental conditions in the Polish zone of the southern Baltic Sea during 1988, B. Cyberska, Z. Lauer & A.Trzosińska (eds.), Mater. Oddz. Mor. Inst. Meteor. i Gosp. Wod., Gdynia, 215–224, (in Polish).
  • [36] Norrman B., Zweifel U. L., Hopkinson C. S., Fry B., 1995, Production and utilization of dissolved organic carbon during an experimental diatom bloom, Limnol. Oceanogr., 40, 898–907.
  • [37] Pempkowiak J., Kupryszewski G., 1980, The input of organic matter to the Baltic from the Vistula river, Oceanologia, 12, 79–98.
  • [38] Pratt I. R., Cairns J. Jr, 1985, Functional groups in the Protozoa: roles in differing ecosystems, J. Protozool., 32 (3), 415–423.
  • [39] Renk H., Ochocki S., Kurzyk S., 2000, In situ and simulated in situ primary production in the Gulf of Gdańsk, Oceanologia, 42 (2), 263–282.
  • [40] Riemann B., Bjørnsen P. K., Newell S., Fallon R., 1987, Calculation of cel production of coastal marine bacteria based on measured incorporation of [3H]-thymidine, Limnol. Ocenogr., 32, 471–476.
  • [41] Sanders R. W., 1988, Feeding by Cyclidium sp. (Ciliophora, Scuticociliatida) on particles of different sizes and surface properties, Bull. Mar. Sci., 43 (3), 446–457.
  • [42] Shiah F-K., Gong G-C., Chen C-C., 2003, Seasonal and spatial variation of bacterial production in the continental shelf of the East China Sea: possible controlling mechanisms and potential roles in carbon cycling, Deep-Sea Res. Pt. II, 50 (6)–(7), 1295–1309.
  • [43] Shiah F-K., Gong G-C., Chen T-Y., Chen C-C., 2000, Temperature dependence of bacterial specific growth rates on the continental shelf of the East China Sea and its potential application in estimating bacterial production Aquat.Microb. Ecol., 22, 155–162.
  • [44] Shiah F-K., Liu K-K., Gong G-C., 1999, Temperature versus substrate limitation of heterotrophic bacterioplankton production across trophic and temperaturę gradients in the East China Sea, Aquat. Microb. Ecol., 17, 247–254.
  • [45] Stanisz A., 2000, Przystępny kurs statystyki z wykorzystaniem programu STATISTICA PL na przykładach z medycyny, Tom II, StatSoft Polska, Kraków, 408 pp.
  • [46] Steemann-Nielsen E., 1952, The use of radio-active carbon C-14 for measuring organic production in the sea, J. Cons. Int. Explor. Mer., 18 (3), 117–140.
  • [47] Trzosińska A., Łysiak-Pastuszak E., 1996, Oxygen and nutrients in the southern Baltic Sea, [in:] Assessment of the effects of pollution in the Polish marine area of the Baltic Sea, 1989–1993, Oceanol. Stud., 25 (1)–(2), 41–76.
  • [48] Turley C. M., Newell R. C., Robins D. B., 1988, Survival strategies of two small marine ciliates and their role in regulating bacterial community structure under experimental conditions, Mar. Ecol. Prog. Ser., 33 (1), 59–70.
  • [49] UNESCO, 1983, Chemical methods for use in marine environmental monitoring, IOC Man. Guides, 12, 1–53.
  • [50] Utermöhl H., 1958, Zur Vervollkommnung der qualitativen Phytoplankton-Methodik, Mitt. Int. Verein. Theor. Angew. Limnol., 9, 1–38.
  • [51] Wikner J., Hagström A., 1999, Bacterioplankton intra-annual variability: importance of hydrography and competition, Aquat. Microb. Ecol., 20 (3), 245–260.
  • [52] Williams P. J. le B., 1981, Incorporation of microheterotrophic processes into the classical paradigm of the planktonic food web, Kieler Meeresforsch. Sonderh., 5, 1–28.
  • [53] Witek M., 1998, Annual changes of abundance and biomass of planktonic ciliates in the Gdańsk Basin, southern Baltic, Int. Rev. Hydrobiol., 83 (2), 163–182.
  • [54] Witek Z., Humborg C., Savchuk O., Grelowski A., Łysiak-Pastuszak E., 2003, Nitrogen and phosphorus budgets of the Gulf of Gdańsk (Baltic Sea), Estuar. Coast. Shelf Sci., 57, 239–248.
  • [55] Witek Z., Ochocki S., Maciejowska M., Pastuszak M., Nakonieczny J., Podgórska B., Kownacka J. M., Mackiewicz T., Wrzesińska-Kwiecień M., 1997a, Phytoplankton primary production and its utilization by the pelagic community in the coastal zone of the Gulf of Gdańsk (southern Baltic), Mar. Ecol. Prog. Ser., 148, 169–186.
  • [56] Witek Z., Ochocki S., Nakonieczny J., Podgórska B., Drgas A., 1999, Primary production and decomposition of organic matter in the epipelagic zone of the Gulf of Gdańsk, an estuary of the Vistula, ICES J. Mar. Sci., 56 (Suppl.), 3–14.
  • [57] Witek Z., Pastuszak M., Nakonieczny J., Ochocki S., Zalewski M., Maciejowska M., Gromisz S., Mackiewicz T., Wrzesińska-Kwiecień M., 1997b, Experimental studies on processes taking place in enclosures with mixed sea and Vistula water, Oceanol. Stud., 26 (1), 36–57.
  • [58] Zweifel U. L., Norrman B., Hagström A., 1993, Consumption of dissolved organic carbon by marine bacte carbon by marine bacteria and demand for inorganic nutrients, Mar.Ecol. Prog. Ser., 101, 23–32.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-article-BUS5-0007-0033
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