Acta Biologica

Wcześniej: Zeszyty Naukowe Uniwersytetu Szczecińskiego. Acta Biologica


ISSN: 2450-8330     eISSN: 2353-3013    OAI    DOI: 10.18276/ab.2019.26-05
CC BY-SA   Open Access   DOAJ

Lista wydań / No. 26
Somatic and F-specific bacteriophages in waters of the small, municipal Rusałka Lake in Szczecin
(Somatyczne i F-specyficzne bakteriofagi małego miejskiego jeziora Rusałka w Szczecinie)

Autorzy: Małgorzata Pawlikowska-Warych
Department of Microbiology, Faculty of Biology, University of Szczecin, Felczaka 3c, 71-412 Szczecin, Poland

Paulina Czupryńska
Department of Microbiology, Faculty of Biology, University of Szczecin, Felczaka 3c, 71-412 Szczecin, Poland

Beata Tokarz-Deptuła
Department of Immunology, Faculty of Biology, University of Szczecin, Felczaka 3c, 71-412 Szczecin, Poland

Wiesław Deptuła
Nicolaus Copernicus University in Toruń, Faculty of Biological and Veterinary Sciences, Institute of Veterinary Medicine, Gagarina 7, 87-100 Toruń, Poland
Słowa kluczowe: bakteriofagi środowisko wodne ochrona środowiska
Data publikacji całości:2019
Liczba stron:11 (45-55)
Cited-by (Crossref) ?:

Abstrakt

Badania bakteriofagów wykazały, że w środowisku naturalnym znajdują się one głównie w wodzie, ale w małych jeziorach miejskich badano je sporadycznie. Poprzednie badania bakteriofagów w środowisku wodnym dotyczyły określania ilości i różnorodności oraz wyko-rzystywania ich jako wskaźników zanieczyszczenia wody. Wcześniejsze badania wykazały, że prawdopodobnie najważniejszymi są F-specyficzne i somatyczne bakteriofagi E. coli. W obecnym badaniu oznaczaliśmy je w małym jeziorze miejskim w Szczecinie (Polska), za pomocą metody SAL. Udowodniliśmy, że liczba bakteriofagów w tym zbiorniku jest mniejsza w porównaniu do innych wód, ale związek między liczbą tych wirusów a warunkami środowiska (temperatura powietrza i wody) był podobny do wyników obserwowanych w wodach mórz, rzek i jezior.
Pobierz plik

Plik artykułu

Bibliografia

1.Breitbart, M., Rohwer, F. (2005). Here a virus, there a virus, everywhere the same virus? Trends Microbiol., 13, 278–284.
2.Brezina, S.S., Baldini, M.D. (2008). Detection of somatic coliphages as indicators of fecal contamination in estuarine waters. Rev. Argent.
3.Microbiol., 40, 72–74.
4.Burbano-Rosero, E.M., Ueda-Ito, M., Kisielius, J.J., Nagasse-Sugahara, T.K., Almeida, B.C., Souza, C.P., Markman, C., Martins, G.G.,
5.Albertini, L., Rivera, I.N.G. (2011). Diversity of somatic coliphages in coastal regions with different levels of anthropogenic activity in Sao
6.Paulo State, Brazil. Appl. Envi-ronm. Microbiol., 77, 4208–4216.
7.Cole, D., Long, S.C., Sobsey, M.D. (2003). Evaluation of F+ RNA and DNA coliphages as source-specific indicators of fecal contamination in
8.surface water. Appl. Environm. Microbiol., 69, 6507–6514.
9.Demuth, J., Neve, H., Witzel, K. (1993). Direct electron microscopy study on morphological diversity of bacteriophage populations in lake
10.Pluβsee. Appl. Environm. Microbiol., 59, 3378–3384.
11.Dore, W., Henshillwood, K., Lees, D. (2000). Evaluation of F- specific RNA bacteriophages as a candidate human enteric virus indicator for
12.bivalve Molluscan Shellfish. Appl. Environm. Microbiol., 66, 1280–1285.
13.Drucker, V.V., Dutova, N.V. (2006). Study of the morphological diversity of bacteriophages in Lake Bajkal. Russ. Dok. Akad. Nauk, 410,
14.421–423.
15.Dryden, S.K., Ramaswami, B., Yuan, Z., Giammar, D.E., Angenet, L.T. (2006). A rapid reverse transcription-PCR assay for F+RNA coliphges
16.to trace fecal pollution in Table Rock Lake on the ArkansasMissouri border. Water Res., 40, 3719–3724.
17.Duran, A.E., Muniesa, M., Mendez, X., Valero, F., Lucena, F., Jofre, J. (2002). Removal and inactivation of indicator bacteriophages in fresh
18.waters. J. Appl. Microbiol., 92, 338–347.
19.Fauvel, B., Gantzer, Ch., Cauchie, H.-M., Ogorzaly, L. (2016). In situ dynamics of F-specific RNA bacterio-phages in small river: new way to
20.assess viral propagation in water quality studies. Food Environm. Virol. DOI: 10.1007/s12560-016-9266-0.
21.Havelaar, A.H., van Olphen, M., Drost, Y.C. (1993). F-specific RNA bacteriophages are adequate model organisms for enteric viruses in
22.fresh water. Appl. Evironm. Microbiol., 59, 2956–2962.
23.Hennes, K., Simon, M. (1995). Significance of bacteriophages for controlling bacterioplancton growth in a mesotrophic lake. Appl. Environm.
24.Microbiol., 61, 333–340.
25.Hernroth, B.E., Conden-Hansson, A., Rehnstam-Holm, A., Girones, R., Allard, A.K. (2002). Environmental factors influencing human viral
26.pathogens and their potential indicator organisms in the blue mussel, Mytilus edulis: the first Scandinavian report. Appl. Environm. Microbiol.,
27.68, 4523–4530.
28.Hłyńczak, A., Deptuła, W,. Możdżer, A., Poleszczuk, G., Słupińska, A. (1995). Ecological importance of water reservoirs in the urban areas
29.on the examples of Rusałka in Szczecin. Aura, 2, 9–11 (in Polish).
30.Hot, D., Legeay, O., Jacques, J., Gantzer, C., Caudrelier, Y., Guyard, K. (2003). Detection of somatic phag-es, infectious enteroviruses and
31.enterovirus genomes as indicators of human enteric viral pollution in surface water. Water Res., 37, 4703–4710.
32.Jiang, S.C., Paul, J.H. (1994). Seasonal and diel abundance of viruses and occurrence of lysogeny/bacteriocinogeny in the marine
33.environment. Marine Ecology Progres Series, 104, 163–172.
34.Jiang, S., Noble, R., Chu, W. (2001). Human adenoviruses and coliphages in urban runoff-impacted coastal waters of Southern California.
35.Appl. Environm. Microbiol., 67, 179–184.
36.Jiang, S.C., Chu, W., He, J.-W. (2007). Seasonal detection of human viruses and coliphages in Newport Bay, California. Appl. Environm.
37.Microbiol., 73, 6468–6474.
38.Kończak, G., Trzpiot, G. (2002). Statistical analysis of the spreadsheet Microsoft Exel. Economic Academy Press of. Karol Adamiecki.
39.Katowice (in Polish).
40.Long, S.C., Sobsey, M.D. (2004). A comparison of the survival of F+RNA and F+DNA coliphages in lake water microcosms. J. Water Health,
41.2, 15–22.
42.Moce-Llivina, L., Lucena, F., Jofre, J. (2005). Enteroviruses and bacteriophages in bathing waters. Appl. Environm. Microbiol., 71,
43.6838–6844.
44.Ogorzaly, L., Tissier, A., Bertrand, I., Maul, A., Ganzer, C. (2009). Relationship between F-specific RNA phage genogroups, faecal pollution
45.indicators and human adenoviruses in river water. Water Res., 43, 1257–1264.
46.Olson, M.R., Axler, R.P., Hicks, R.E., Henneck, J.R., McCarthy, B.J. (2005). Seasonal virus removal by alternative onsite wastewater
47.treatment systems. J. Water Health, 3, 139–155.
48.Ostasiewicz, S., Rusnak, Z., Siedlecka, U. (2003). Statystyka elementy teorii i zadania. Wrocław: Economic Academy of Oskar Lange Press.
49.Paez-Espino, D., Eloe-Fadrosh, E.A., Pavlopoulos, G.A., Thomas, A.N.D., Huntemann, M., Mikhailova, N., Rubin, E., Ivanova, N.N.,
50.Kyrpides, N.C. (2016). Uncovering Earth’s virome. Nature, 536, 425–430.
51.Pelleieux, S., Mathieu, L., Block, J.-C., Gantzer, C., Bertramd, I. (2016). The effect of chlorinationand hydrodynamic shear stress on the
52.persistence of bacteriophages associated with drinking water bio-films. J. Appl. Microbiol., 121, 1189–1197.
53.Pusch, D., Oh, D.-Y., Wolf, S., Dumke, R., Schroter-Bobsin, U., Hohne, M., Roske, I., Schreier, E. (2005). Detection of enteric viruses and
54.bacterial indicators in German environmental waters. Arch. Virol., 150, 929–947.
55.Ravva, S.V., Sarreal, Ch.Z. (2016). Persistence of F-specific RNA coliphages in surface waters from a produce production region along the
56.central coast of California. PLOS ONE, 11, e0146623.
57.Shirasaki, N., Matsushita, T., Matsui, Y., Urasaki, T., Ohno, K. (2009). Comparison of behaviors of two surrogates for pathogenic waterborne
58.viruses, bacteriophages QB and MS2, during the aluminum coagulation process. Water Res., 43, 665–615.
59.Simkova, A., Cervenka, J. (1981). Coliphages as ecological indicators of enteroviruses in various water systems. Bull. WHO, 59, 611–618.
60.Sinton, L.W., Finlay, R.K., Lynch, P.A. (1999). Sunlight inactivation of fecal bacteriophages and bacteria in sewage-polluted seawater. Appl.
61.Environm. Microbiol., 65, 3605–3613.
62.Skraber, S., Gassilloud, B., Gantzer, C. (2004). Comparison of coliforms and coliphages as tools for assessment of viral contamination in
63.river water. Appl. Environm. Microbiol., 70, 3644–3649.
64.Stewart, J.R., Vinje, J., Oudejans, S.J.G., Scott, G.I., Sobsey, M.D. (2006). Sequence variation among group III F-specific RNA coliphages
65.from water samples and swine lagoon. Appl. Environm. Microbiol., 72, 1226–1230.
66.Stewart-Pullaro, J., Daugomah, J.W., Chestnut, D.E., Grave, D.A., Sobsey, M.D., Scott, G.I. (2006). F+RNA coliphage typing for microbial
67.source tracking in surface waters. J. Appl. Microbiol., 101, 1015–1026. Suttle, C.A. (2007). Marine viruses – major players in the global
68.ecosystem. Nature Microbiol., 5, 801–812.
69.Śliwa-Dominiak, J., Tokarz-Deptuła, B., Deptuła, W. (2010). F-specific RNA bacteriophages and bacteria of the coli group in water samples
70.from a small urban lake in Szczecin. Woda – Środowisko – Obszary Wiejskie, 10, 189–199 (in Polish).
71.Śliwa-Dominiak, J., Tokarz-Deptuła, B., Deptuła, W. (2015). Mammalian and bacterial viruses in aquatic enviromentals. Pol. J. Enivronm.
72.Stud., 24, 951–960.
73.Śliwa-Dominiak, J., Tokarz-Deptuła, B., Deptuła, W. (2014). Occurrence of F-specific RNA coliphages and microbial indicator in municipal
74.lake water. Pol. J. Environm. Stud., 23, 467–473.
75.Vergara, G.G.R.V., Goh, S.G., Rezaeinejad, Y., Sobsey, M.D., Gin, K.Y.H. (2015). Evolution of FRNA co-liphages as indicators of human
76.enteric viruses in a tropical urban freshwater catchment. Water Res., 79, 39–47.
77.Zupok, A., Sokołowska, E., Śliwa-Dominiak, J., Tokarz-Deptuła, B. (2010). F-specific bacteriophages RNA in water samples originating from
78.Syrenie Stawy (municipal lake in Szczecin). Mikrobiot 2010 the 2nd workshop on microbiology in health and environmental protection. Łódź,
79.Poland.