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Record number 406776
Title Free-living protozoa in drinking water supplies: community composition and role as hosts for Legionella pneumophila
Author(s) Valster, R.M.
Source University. Promotor(en): D. van der Kooij, co-promotor(en): Hauke Smidt. - [S.l.] : S.n. - ISBN 9789085858843 - 178
Department(s) Microbiological Laboratory
Publication type Dissertation, internally prepared
Publication year 2011
Keyword(s) watermicrobiologie - drinkwater - legionella pneumophila - waterkwaliteit - water microbiology - drinking water - water quality
Categories Water Microbiology

Free-living protozoa in drinking water supplies: community composition and role as hosts for Legionella pneumophila

Free-living protozoa, which feed on bacteria, play an important role in the communities of microorganisms and invertebrates in drinking water supplies and in (warm) tap water installations. Several bacteria, including opportunistic human pathogens such as Legionella pneumophila, are able to survive and replicate within protozoan hosts, and certain free-living protozoa are opportunistic human pathogens as well. However, not much is known about the occurrence of these organisms in drinking water supplies in relation to water quality and other environmental conditions. This lack of knowledge may in part be attributed to the limitations of microscopic techniques and cultivation methods for detection and identification of protozoa. In the investigations described in this thesis, molecular methods were applied to identify communities of free-living protozoa in drinking water supplies and to elucidate the effects of environmental conditions on the growth of these organisms. Molecular methods were also used to detect and identify protozoan hosts, both known and yet-undescribed, for L. pneumophila. The eukaryotic communities were studied using terminal restriction fragment length polymorphism (T-RFLP), clone library analyses of partial 18S rRNA gene fragments, and qPCR assays for Acanthamoeba spp. and Hartmannella vermiformis.

In two groundwater supplies in the Netherlands (T < 18°C) and three supplies in the Caribbean (T ~ 30°C) using seawater as source, highly diverse eukaryotic communities were observed, including free-living protozoa, fungi, and metazoa. A total of 127 operational taxonomic units (OTUs, each OTU contains sequences with ≥ 99\\\\% similarity) related to free-living protozoa were obtained from the supplies in the Netherlands and 59 OTUs were identified from the supplies in the Caribbean. Free-living protozoa related to the phyla Amoebozoa, Cercozoa, Choanozoa, Ciliophora and Stramenopiles were observed in both regions, whereas the phyla Euglenozoa and Myzozoa were only found in the supplies in the Netherlands. H. vermiformis, a described host for L. pneumophila was observed in all five supplies, and was a predominant protozoan in the treated water and in the distribution system in one of the examined supplies. Acanthamoeba spp. were detected at low concentrations in only a few samples.

In one drinking water supply in the Caribbean, the concentration of H. vermiformis correlated with the concentration of Legionella spp., and clones related to Amoebozoa predominated the protozoan community. These observations, in combination with the low turbidity and the varying ATP concentrations, indicated that biofilms in this system promoted growth of amoebae and also Legionella spp. Ciliophora represented 25\\\\% of the protozoan OTUs in another Caribbean supply with elevated ATP concentrations and turbidity, related to corroding cast-iron pipes. Thus, sediments seem to favor growth of ciliates. Cercozoan types predominated in one of the Caribbean supplies with low ATP concentrations (< 1 ng liter-1) and turbidity (< 1 NTU) in most samples of distributed water. Growth of H. vermiformis was also observed in a drinking water supply in the Netherlands with a high concentration of natural organic matter (NOM) combined with an elevated concentration of active biomass (ATP), whereas no growth of this amoeba was observed in the groundwater supply with a low concentration of ATP (< 1 ng liter-1) and NOM (< 0.5 mg C liter-1).

A biofilm batch test (BBT) was applied to amplify and subsequently identify protozoan hosts for L. pneumophila. In this test 21 freshwater samples, with added polyethylene cylinders to promote biofilm formation, were inoculated with L. pneumophila and subsequently incubated in duplicate at 37°C. Growth of L. pneumophila was observed in 16 of 18 water types when the host protozoan H. vermiformis had been added. Indigenous H. vermiformis was indicated as host in 12 of the 19 BBT flasks with growth of L. pneumophila. In none of the water samples incubated at 37°C in the BBT system, growth of Acanthamoeba spp. was observed. In several flasks with growth of L. pneumophila, the protozoa Diphylleia rotans, Echinamoeba thermarum and Neoparamoeba sp. were identified as candidate hosts. In vitro studies are needed to confirm their role as hosts for L. pneumophila.

To assess the effects of water temperature on indigenous free-living protozoan communities, four water types were incubated in a BBT system at 20, 30, 37 and 42°C. Only two of the 53 OTUs related to free-living protozoa obtained from these freshwater types at day 0 were also detected after incubation. Multiplication of indigenous Acanthamoeba spp. was observed at 20 and 30°C, with only limited growth in one flask at 37°C. Indigenous H. vermiformis multiplied at 20, 30 and 37°C, but at 42°C proliferation was only observed in water collected from the river Rhine. Growth of organisms related to Amoebozoa and Stramenopiles was observed at all four temperatures, whereas Cercozoan and Euglenozoan types predominated in the BBT system incubated at 37 and 30°C, respectively. The Amoebozoan Arachnula sp. was identified as candidate host for L. pneumophila at 42°C, but in vitro studies with this organism are needed for confirmation.

These observations indicate that H. vermiformis, the predominating protozoan host for Legionella spp., is ubiquitous in water supplies and other engineered water installations. This organism can grow at temperatures ranging from less than 20 to 42°C. Proliferation is limited at active biomass concentrations < 1 ng ATP liter-1 in combination with NOM concentrations < 0.5 mg C liter-1. However, production of drinking water with such low concentrations of NOM and ATP is not achievable in most cases. Therefore, a combination of measures in water treatment (reducing the NOM concentration) and distribution (prevention of sediment accumulation, disinfection) is needed to reduce the potential for growth of free-living protozoa in water supplies and in water installations.

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