Studies concerning heterotrophic bacteria decomposing macromolecular compounds at two marine beaches

• Autorzy: Mudryk Z. , Skórczewski P. , Perliński P. , Wielgat M.
• Języki publikacji: EN

Abstrakty

EN

The potential capability to decompose macromolecular compounds was confirmed in heterotrophic bacteria isolated from two sandy beaches located on the southern Baltic coast. Proteolytic bacteria were the most numerous group, whereas lipolytic organisms were rare among bacteria inhabiting the studied beaches. All studied physiological groups of bacteria were considerably more numerous in the sand of the beach subject to stronger anthropopressure. The differences in bacteriological parameters across the horizontal profile of the beaches were noted. In both studied beaches a higher number of bacteria able to decompose macromolecular compounds were recorded in the surface as compared to the subsurface sand layer.

Słowa kluczowe

EN

beach; bacteria; decompose; organic matter

• Wydawca: Institute of Oceanography University of Gdańsk
• Czasopismo: Oceanological and Hydrobiological Studies
• Rocznik: 2011
• Tom: Vol. 40, No.3
• Strony: 74--83
• Opis fizyczny: Bibliogr. 54 poz., tab., wykr.

Twórcy

autor

Mudryk Z.

autor

Skórczewski P.

autor

Perliński P.

autor

Wielgat M.

• Department of Experimental Biology, Pomeranian Academy ul. Arciszewskiego 22 B, 76-200 Słupsk, Poland,

Bibliografia

• 1.Arnosti C., Jorgensen B., Sagemann J., Tramdrup T., 1998, Temperature dependence of microbial degradation of organic matter in marine sediment: polysaccharide hydrolysis, oxygen consumption, and sulphate reduction, Mar. Ecol. Prog. Ser., 165: 59-70
• 2.Billen G., Fontigny A., 1987, Dynamics of a phaeocystis - dominated spring bloom in Belgian coastal waters, II. Bacterioplankton dynamics, Mar. Ecol. Prog. Ser., 37: 249-257
• 3.Boetius A., 1995, Microbial hydrolytic enzyme activities in deep-sea sediments Helgoland, Mar. Res., 49: 177-187
• 4.Boucher G., Chamroux S., 1976, Bacteria and meiofauna in an experimental sand ecosystems. I. Material and preliminary results, J. Exp. Mar. Biol. Ecol., 24: 237-249
• 5.Brown A.C., Mclachlan A., 1990, Ecology of Sandy Shores, Elsevier, Amsterdam, pp. 328
• 6.Gomes D.N., Cavalacanti M.A., Fernandes M.J., Lima D.M., Passavante L.Z., 2008, Filamentus fungi isolated from sand and water of "Bairro Novo" and "Casa Caida" beaches, Olinda, Pernambuco, Brazil, Brazil. J. Biol., 68: 577-582
• 7.Haque A.M., Szymelfenig M., Węcławski M., 1996, The sandy littoral zoobentos of the Polish Baltic coast, Oceanologia, 38: 361-378
• 8.Helmke E., Weyland H., 1986, Effect of hydrostatic pressure and temperature on the activity and synthessis of chitinases of Antarctic Ocean bacteria, Mar. Biol., 91: 1-7
• 9.Halliwell G., 1962, Methods of enzymatic analysis [in:] Cellulose, Ed. Bergmayer, H.V., Academic Press, New York- London, 64-71
• 10.Heymans J.J., McLachlan A., 1996, Carbon budget and network analysis of a high energy beach/surf-zone ecosystems, Estuar. Coast. Shelf Sci., 43: 485-505
• 11.Incera M., Cividanes S.P., López J., Costas R., 2003, Role of hydrodynamic conditions on quantity and biochemical composition of sediment organic matter in sandy intertidal sediments ( NW Atlantic coast, Iberian Peninsula), Hydrobiologia, 497: 39-51
• 12.Jackson C.R., Foreman C.M., Sinsabaugh R.L., 1995, Microbial enzyme activities as indicator of organic matter processing rates in a lake Erie coastal wetland, Fresh. Biol., 34: 329-342
• 13.Jacobsen T.R., Azam F., 1984, Role of bacteria in copoepoded fecal pellet decomposition. Colonization, growth rates and mineralization, Bull. Mar. Sci., 35: 495-502
• 14.Jędrzejczak M.F., 1999, The degradation of stranded carrion on a Baltic Sea sandy beach, Oceanol. Stud., 3/4: 109-141
• 15.Jocz J., 2010, Dynamic concentration of protein and chlorophyll in sand beach of diffrent anthropopressure, Master's thesis, AP Słupsk pp. 74
• 16.Jones J.G., 1971, Studies on freswater bacteria factors which influence the population and its activity, J. Ecol., 59: 593-613
• 17.Khiyama H.M., Makemson J.C., 1973, Sand beach bacteria: enumeration and characterization, Appl. Microbiol., 26: 293-297
• 18.Kiersztyn B., Siuda W., Chróst R., 2002, Microbial ectoenzyme activity: useful parameters for characterizing the trophic conditions of lakes, Pol. J. Environ Stud., 1: 367-373
• 19.Kolm H.E., Correa M.F.M., 1994, Spatial distribution and temporal variability of saprophytic bacteria on the sandy beach of Pontal, du Sul, Parna State, Brazil, Arq. Biol. Tecnol., 37: 391-402
• 20.Koop K., Griffiths C.L., 1982, The relative significance of bacteria meio and macrofauna on exposed sand beach, Mar. Biol., 66: 295-300
• 21.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
• 22.Kramarska, R., Uscinowicz, Sz., Zachowicz, J., Przezdziecki, P., Warzocha, J., Netzel J., Janusz J., 2003, Identification of submarine deposit drifts to artificial swelling, Department of Marine in Słupsk (in Polish)
• 23.Krstulović N., Solić M., 1988, Distribution of proteolytic, amylolytic and lipolytic bacteria in the Kastela Bay, Acta Adria., 29: 75-82
• 24.Lingappa Y., Lockwood J.L., 1962, Chitin media for selective isolation and culture of actinomycetes, Phytopathology, 52: 317-323
• 25.McLachlan A., Jarmillo E., 1995, Zonation on sandy beaches, Oceanogr. Mar. Ecol. Ann. Rev., 33: 305-335
• 26.Malam T., Raberg S., Fell T., Carlson P., 2004, Effects by beaches cleaning on litoral water quality microbial food web and macro faunal biodiversity, Est. Coast. Shelf Sci., 60: 339-347
• 27.Mallet C., Debroas D., 1999, Relations between organic matter and bacterial proteolytic activity in sediment surface layers of a eutrophic lake (Lake Aydat, Puy de Dôme, France), Arch. Hydrobiol., 39: 145- 156
• 28.Martinez, J., Azam F., 1993, Periplasmic aminopeptidase and alkaline phosphatase activities in a marine bacterium: implications for substrate processing in the sea, Mar. Ecol. Prog. Ser., 92: 89-97
• 29.Martinez J., Smith D.C., Steward D.F., Azam F., 1996, Variability in ectohydrolytic enzyme actives of pelagic marine bacteria and its significance for substrate processing in the sea, Aqua. Microbial Ecol., 10: 223- 229
• 30.Misic C., Harriague A.C., 2007, Enzymatic activity and organic substrates on sandy beach of the Ligurian Sea (NW Mediterranean) influenced by anthropogenic pressure, Aqua. Microbial. Ecol., 47: 239-251
• 31.Montagna P.A., 1982, Sampling design and enumeration statistics for bacteria extracted from marine sediments, Appl. Environ. Microbiol., 4: 1366-1372
• 32.Mudryk Z., Donderski W., 1997, The occurrence of heterotrophic bacteria decomposing some macromolecular compounds in shallow estuarine lakes, Hydrobiologia, 342/343: 71-78
• 33.Mudryk Z., Donderski W., Skórczewski P., Walczak M., 1999, Neustonic and planktonic bacteria isolated from a brackish lake Gardno, Pol. Arch. Hydrobiol., 46: 121-129
• 34.Mudryk Z., Podgórska B., Ameryk A., 2001, Bacteriological characterisation of a Baltic sandy beach in summer, Ecohydrol. & Hydrobiol., 4: 503-509
• 35.Mudryk. Z., Podgórska B., 2006, Enzymatic activity bacterial strains isolated from marine beach, Pol. J. Ecol., 15: 441 - 448
• 36.Mudryk Z., Podgórska B., 2007, Culturable microorganisms in sandy beaches in south Baltic Sea, Pol. J. Ecol., 55: 221-231
• 37.Nair S., Bharathi L., 1980, Heterotrophic bacterial population in tropical sandy beaches, Mahas. Bull. Nat. Inst. of Oceanogr., 13: 261-267
• 38.Newell S.Y., Fallon R.D., 1982, Bacterial productivity in the water column and sediments of the Georgia (USA) coastal zone estimates via Mar. Ecol., 8: 33-46
• 39.Novitsky J.A., MacSween M.C., 1989, Microbiology of a high energy beach sediment: evidence for an active and growing community, Mar. Ecol. Prog. Ser., 52: 71-75
• 40.Olańczuk - Neyman K., Jankowska K., 1998, Bacteriological investigations of the sandy beach ecosystem in Sopot, Oceanologia, 40: 137-151
• 41.Patel A.B., Fukami K., Nishijama T., 2000, Regulation of seasonal variability of aminopeptidase activities in surface and bottom waters of Uranouchi Inlet, Japan, Aqua. Microbiol. Ecol., 21: 139- 147
• 42.Piechocka A., 2010, Dynamic concentration of carbohydrates and lipids in sand beach of diffrent anthropopressure, Master's thesis, AP Słupsk pp. 60
• 43.Podgórska B., Mudryk Z., 2003, Distribution and enzymatic activity of heterotrophic bacteria decomposing selected macromolecular compounds in a Baltic Sea beach, Estuar. Coast. Shelf Sci., 56: 539-546
• 44.Podgórska B., Mudryk Z., 2007, Physiological properties of bacteria inhabiting polluted and unpolluted marine sandy beaches (Southern Baltic Sea), Pol. J. Ecol., 55: 15-26
• 45.Podgórska B., Mudryk Z., Skórczewski P., 2008, Abundance and production of bacteria in a marine beach (southern Baltic Sea) in summer, Pol. J. Ecol., 56: 405-414
• 46.Pugh K.B., Andrews A.R., Gibbs C.F., Davis S.J., Floodgate G.D., 1974, Some physical, chemical and microbiological characteristics of two beaches of Anglesey, J. Exp. Mar. Biol. Ecol., 15: 305-333
• 47.Rodil I.F., Lastra M., 2004, Environmental factors affecting benthic macrofauna along a gradient of intermediate sandy beches in northern Spain, Estuar. Coast. Shelf Sci., 61: 37-44.
• 48.Rodriguez J.G., Lastra M., Lopez J., 2003, Meiofauna distribution along a gradient of sandy beaches, Estuar. Coast. Shelf Sci., 58: 63-69
• 49.Uraban - Malinga B., Opaliński K.W., 1999, Vertical zonation of the total, biotic and abiotic oxygen consumption in a Baltic sandy beach, Oceanol. Stud., 28: 85-96
• 50.Uraban - Malinga B., Opaliński K.W., 2001, Interstitial community oxygen consumption in a Baltic sandy beaches: horizontal zonation, Oceanologia, 43: 455-468
• 51.Wehr J.D., Petersen J., Findlay S., 1999, Influence of three contrasting detritial carbon sources on planktonic bacterial metabolism in a mesotrophic lake, Microbiol. Ecol., 37: 23-35
• 52.Worm J., Jensen L.E., Hansen T.S., Sondergaard M., Nybroe O., 2000, Interactions between proteolytic and non-proteolytic Pseudomonas fluorescens affect protein degradation in a model community, FEMS Microbiol. Ecol., 32: 103-109
• 53.Yamamoto N., Lopez G., 1985, Bacterial abundance in relation to surface area and organic content of marine sediments, J. Exp. Mar. Biol. Ecol., 90: 209-220
• 54.Zawadzka, E., 1996, Litho - morphodynamics in the vicinity of small ports of the Polish Central Coast, [in:] Partnership of the Coastal Management, Eds. Taussik J., Mitchel J., Samara, Publ. Limited, Cardigan GB. pp. 353-360