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Title:NanoSIMS and tissue autoradiography reveal symbiont carbon fixation and organic carbon transfer to giant ciliate host
Authors:ID Volland, Jean-Marie (Author)
ID Schintlmeister, Arno (Author)
ID Zambalos, Helena (Author)
ID Reipert, Siegfried (Author)
ID Mozetič, Patricija (Author)
ID Espada-Hinojosa, Salvador (Author)
ID Turk, Valentina (Author)
ID Wagner, Michael (Author)
ID Bright, Monika (Author)
Files:URL URL - Source URL, visit http://dx.doi.org/10.1038/s41396-018-0069-1
 
.pdf PDF - Presentation file, download (6,49 MB)
MD5: 9965697C0AA9DF515540C424E3D3AB16
 
Language:English
Typology:1.01 - Original Scientific Article
Organization:Logo NIB - National Institute of Biology
Abstract:The giant colonial ciliate Zoothamnium niveum harbors a monolayer of the gammaproteobacteria Cand. Thiobios zoothamnicoli on its outer surface. Cultivation experiments revealed maximal growth and survival under steady flow of high oxygen and low sulfide concentrations. We aimed at directly demonstrating the sulfur-oxidizing, chemoautotrophic nature of the symbionts and at investigating putative carbon transfer from the symbiont to the ciliate host. We performed pulse-chase incubations with 14C- and 13C-labeled bicarbonate under varying environmental conditions. A combination of tissue autoradiography and nanoscale secondary ion mass spectrometry coupled with transmission electron microscopy was used to follow the fate of the radioactive and stable isotopes of carbon, respectively. We show that symbiont cells fix substantial amounts of inorganic carbon in the presence of sulfide, but also (to a lesser degree) in the absence of sulfide by utilizing internally stored sulfur. Isotope labeling patterns point to translocation of organic carbon to the host through both release of these compounds and digestion of symbiont cells. The latter mechanism is also supported by ultracytochemical detection of acid phosphatase in lysosomes and in food vacuoles of ciliate cells. Fluorescence in situ hybridization of freshly collected ciliates revealed that the vast majority of ingested microbial cells were ectosymbionts.
Keywords:microbial ecology, symbiosis
Publication status:Published
Publication version:Version of Record
Publication date:01.03.2018
Year of publishing:2018
Number of pages:str. 714-727
Numbering:Vol. 12
PID:20.500.12556/DiRROS-19636 New window
UDC:577
ISSN on article:1751-7362
DOI:10.1038/s41396-018-0069-1 New window
COBISS.SI-ID:4610639 New window
Publication date in DiRROS:24.07.2024
Views:279
Downloads:224
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Record is a part of a journal

Title:The ISME journal
Shortened title:ISME j.
Publisher:Nature Publishing Group
ISSN:1751-7362
COBISS.SI-ID:513948953 New window

Document is financed by a project

Funder:EC - European Commission
Project number:294343
Name:Nitrification Reloaded - a Single Cell Approach
Acronym:NITRICARE

Funder:FWF - Austrian Science Fund
Project number:P24565-B22

Funder:Other - Other funder or multiple funders
Funding programme:Austrian Wirtschaftsservice
Project number:P1404894
Name:Grant

Licences

License:CC BY 4.0, Creative Commons Attribution 4.0 International
Link:http://creativecommons.org/licenses/by/4.0/
Description:This is the standard Creative Commons license that gives others maximum freedom to do what they want with the work as long as they credit the author.

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