{"response":{"status":"ok","message_type":"publication"},"id":2585,"citation":"Viver et al., 2017, Environmental Microbiology","doi":"10.1111/1462-2920.13763","url":"https://api.seqco.de/v1/publications/2585.json","link_ext":"https://doi.org/10.1111/1462-2920.13763","title":"The low diverse gastric microbiome of the jellyfish\n                    \u003ci\u003eCotylorhiza tuberculata\u003c/i\u003e\n                    is dominated by four novel taxa","journal":"Environmental Microbiology","journal_loc":"19 (8)","journal_date":"2017-08-01","pub_type":"journal-article","abstract":"\u003cjats:title\u003eSummary\u003c/jats:title\u003e\n                  \u003cjats:p\u003e\n                    \u003cjats:italic\u003eCotylorhiza tuberculata\u003c/jats:italic\u003e\n                    is an important scyphozoan jellyfish producing population blooms in the Mediterranean probably due to pelagic ecosystem's decay. Its gastric cavity can serve as a simple model of microbial–animal digestive associations, yet poorly characterized. Using state‐of‐the‐art metagenomic population binning and catalyzed reporter deposition fluorescence\n                    \u003cjats:italic\u003ein situ\u003c/jats:italic\u003e\n                    hybridization (CARD‐FISH), we show that only four novel clonal phylotypes were consistently associated with multiple jellyfish adults. Two affiliated close to\n                    \u003cjats:italic\u003eSpiroplasma\u003c/jats:italic\u003e\n                    and\n                    \u003cjats:italic\u003eMycoplasma\u003c/jats:italic\u003e\n                    genera, one to chlamydial ‘\n                    \u003cjats:italic\u003eCandidatus\u003c/jats:italic\u003e\n                    Syngnamydia’, and one to bacteroidetal\n                    \u003cjats:italic\u003eTenacibaculum\u003c/jats:italic\u003e\n                    , and were at least one order of magnitude more abundant than any other bacteria detected. Metabolic modelling predicted an aerobic heterotrophic lifestyle for the chlamydia, which were found intracellularly in\n                    \u003cjats:italic\u003eOnychodromopsis\u003c/jats:italic\u003e\n                    ‐like ciliates. The\n                    \u003cjats:italic\u003eSpiroplasma\u003c/jats:italic\u003e\n                    ‐like organism was predicted to be an anaerobic fermenter associated to some jellyfish cells, whereas the\n                    \u003cjats:italic\u003eTenacibaculum\u003c/jats:italic\u003e\n                    ‐like as free‐living aerobic heterotroph, densely colonizing the mesogleal axis inside the gastric filaments. The association between the jellyfish and its reduced microbiome was close and temporally stable, and possibly related to food digestion and protection from pathogens. Based on the genomic and microscopic data, we propose three candidate taxa: ‘\n                    \u003cjats:italic\u003eCandidatus\u003c/jats:italic\u003e\n                    Syngnamydia medusae’, ‘\n                    \u003cjats:italic\u003eCandidatus\u003c/jats:italic\u003e\n                    Medusoplasma mediterranei’ and ‘\n                    \u003cjats:italic\u003eCandidatus\u003c/jats:italic\u003e\n                    Tenacibaculum medusae’.\n                  \u003c/jats:p\u003e","long_citation_html":"Viver et al. (2017). The low diverse gastric microbiome of the jellyfish\n                    \u003ci\u003eCotylorhiza tuberculata\u003c/i\u003e\n                    is dominated by four novel taxa. \n\u003ci\u003eEnvironmental Microbiology\u003c/i\u003e. \u003ca href=\"https://doi.org/10.1111/1462-2920.13763\" target=\"_blank\"\u003eDOI:10.1111/1462-2920.13763\u003c/a\u003e\n","created_at":"2022-04-29T11:33:36.187Z","updated_at":"2025-11-06T13:54:11.711Z","authors":[{"id":7634,"given":"Tomeu","family":"Viver","created_at":"2020-09-04T00:54:47.859Z","updated_at":"2020-09-04T00:54:47.859Z","url":"https://api.seqco.de/v1/authors/7634.json"},{"id":7466,"given":"Luis H.","family":"Orellana","created_at":"2020-05-31T06:31:23.249Z","updated_at":"2020-05-31T06:31:23.249Z","url":"https://api.seqco.de/v1/authors/7466.json"},{"id":6387,"given":"Janet K.","family":"Hatt","created_at":"2019-04-15T19:30:26.931Z","updated_at":"2019-04-15T19:30:26.931Z","url":"https://api.seqco.de/v1/authors/6387.json"},{"id":7635,"given":"Mercedes","family":"Urdiain","created_at":"2020-09-04T00:54:48.175Z","updated_at":"2020-09-04T00:54:48.175Z","url":"https://api.seqco.de/v1/authors/7635.json"},{"id":10339,"given":"Sara","family":"Díaz","created_at":"2022-04-29T11:33:36.260Z","updated_at":"2022-04-29T11:33:36.260Z","url":"https://api.seqco.de/v1/authors/10339.json"},{"id":3790,"given":"Michael","family":"Richter","created_at":"2019-04-15T19:19:33.505Z","updated_at":"2019-04-15T19:19:33.505Z","url":"https://api.seqco.de/v1/authors/3790.json"},{"id":10340,"given":"Josefa","family":"Antón","created_at":"2022-04-29T11:33:36.282Z","updated_at":"2022-04-29T11:33:36.282Z","url":"https://api.seqco.de/v1/authors/10340.json"},{"id":10341,"given":"Massimo","family":"Avian","created_at":"2022-04-29T11:33:36.294Z","updated_at":"2022-04-29T11:33:36.294Z","url":"https://api.seqco.de/v1/authors/10341.json"},{"id":2194,"given":"Rudolf","family":"Amann","created_at":"2019-04-15T18:47:13.704Z","updated_at":"2019-04-15T18:47:13.704Z","url":"https://api.seqco.de/v1/authors/2194.json"},{"id":3601,"given":"Konstantinos T.","family":"Konstantinidis","created_at":"2019-04-15T18:48:03.743Z","updated_at":"2019-04-15T18:48:03.743Z","url":"https://api.seqco.de/v1/authors/3601.json"},{"id":10342,"given":"Ramon","family":"Rosselló‐Móra","created_at":"2022-04-29T11:33:36.322Z","updated_at":"2022-04-29T11:33:36.322Z","url":"https://api.seqco.de/v1/authors/10342.json"}],"names":[{"id":23502,"name":"Sygnamydia medusae","url":"https://api.seqco.de/v1/names/23502.json","uri":"https://seqco.de/i:23502"}],"subjects":[{"id":2,"name":"Ecology, Evolution, Behavior and Systematics","url":"https://api.seqco.de/v1/subjects/2.json"},{"id":9,"name":"Microbiology","url":"https://api.seqco.de/v1/subjects/9.json"}]}