Successional trophic complexity and biogeographical structure of eukaryotic communities in waterworks' rapid sand filters
(2019) In FEMS Microbiology Ecology 95(11).- Abstract
As groundwater-fed waterworks clean their raw inlet water with sand filters, a variety of pro-and eukaryotic microbial communities develop on these filters. While several studies have targeted the prokaryotic sand filter communities, little is known about the eukaryotic communities, despite the obvious need for knowledge of microorganisms that get in contact with human drinking water. With a new general eukaryotic primer set (18S, V1-V3 region), we performed FLX-454 sequencing of material from 21 waterworks' sand filters varying in age (3-40 years) and geographical location on a 250 km east-west axis in Denmark, and put the data in context of their previously published prokaryotic communities. We find that filters vary highly in trophic... (More)
As groundwater-fed waterworks clean their raw inlet water with sand filters, a variety of pro-and eukaryotic microbial communities develop on these filters. While several studies have targeted the prokaryotic sand filter communities, little is known about the eukaryotic communities, despite the obvious need for knowledge of microorganisms that get in contact with human drinking water. With a new general eukaryotic primer set (18S, V1-V3 region), we performed FLX-454 sequencing of material from 21 waterworks' sand filters varying in age (3-40 years) and geographical location on a 250 km east-west axis in Denmark, and put the data in context of their previously published prokaryotic communities. We find that filters vary highly in trophic complexity depending on age, from simple systems with bacteria and protozoa (3-6 years) to complex, mature systems with nematodes, rotifers and turbellarians as apex predators (40 years). Unlike the bacterial communities, the eukaryotic communities display a clear distance-decay relationship that predominates over environmental variations, indicating that the underlying aquifers feeding the filters harbor distinct eukaryotic communities with limited dispersal in between. Our findings have implications for waterworks' filter management, and offer a window down to the largely unexplored eukaryotic microbiology of groundwater aquifers.
(Less)
- author
- Bugge Harder, Christoffer LU ; Nyrop Albers, Christian ; Rosendahl, Søren ; Aamand, Jens ; Ellegaard-Jensen, Lea and Ekelund, Flemming
- organization
- publishing date
- 2019-10-17
- type
- Contribution to journal
- publication status
- published
- subject
- keywords
- aquatic microbiology, artificial environments, distance decay, groundwater ecology, protozoa, trophic complexity
- in
- FEMS Microbiology Ecology
- volume
- 95
- issue
- 11
- article number
- fiz148
- pages
- 13 pages
- publisher
- Oxford University Press
- external identifiers
-
- pmid:31518408
- scopus:85073643675
- ISSN
- 0168-6496
- DOI
- 10.1093/femsec/fiz148
- language
- English
- LU publication?
- yes
- id
- 3bddf400-f448-414f-8f40-aca8692368cd
- date added to LUP
- 2020-09-09 11:21:09
- date last changed
- 2024-10-03 09:29:33
@article{3bddf400-f448-414f-8f40-aca8692368cd, abstract = {{<p>As groundwater-fed waterworks clean their raw inlet water with sand filters, a variety of pro-and eukaryotic microbial communities develop on these filters. While several studies have targeted the prokaryotic sand filter communities, little is known about the eukaryotic communities, despite the obvious need for knowledge of microorganisms that get in contact with human drinking water. With a new general eukaryotic primer set (18S, V1-V3 region), we performed FLX-454 sequencing of material from 21 waterworks' sand filters varying in age (3-40 years) and geographical location on a 250 km east-west axis in Denmark, and put the data in context of their previously published prokaryotic communities. We find that filters vary highly in trophic complexity depending on age, from simple systems with bacteria and protozoa (3-6 years) to complex, mature systems with nematodes, rotifers and turbellarians as apex predators (40 years). Unlike the bacterial communities, the eukaryotic communities display a clear distance-decay relationship that predominates over environmental variations, indicating that the underlying aquifers feeding the filters harbor distinct eukaryotic communities with limited dispersal in between. Our findings have implications for waterworks' filter management, and offer a window down to the largely unexplored eukaryotic microbiology of groundwater aquifers.</p>}}, author = {{Bugge Harder, Christoffer and Nyrop Albers, Christian and Rosendahl, Søren and Aamand, Jens and Ellegaard-Jensen, Lea and Ekelund, Flemming}}, issn = {{0168-6496}}, keywords = {{aquatic microbiology; artificial environments; distance decay; groundwater ecology; protozoa; trophic complexity}}, language = {{eng}}, month = {{10}}, number = {{11}}, publisher = {{Oxford University Press}}, series = {{FEMS Microbiology Ecology}}, title = {{Successional trophic complexity and biogeographical structure of eukaryotic communities in waterworks' rapid sand filters}}, url = {{http://dx.doi.org/10.1093/femsec/fiz148}}, doi = {{10.1093/femsec/fiz148}}, volume = {{95}}, year = {{2019}}, }