{"id":4983,"date":"2021-01-20T11:45:32","date_gmt":"2021-01-20T10:45:32","guid":{"rendered":"https:\/\/ukazky.euweb.cz\/?page_id=4983"},"modified":"2026-02-04T12:02:41","modified_gmt":"2026-02-04T11:02:41","slug":"publications","status":"publish","type":"page","link":"https:\/\/web.natur.cuni.cz\/ecology\/DiCE\/publications\/","title":{"rendered":"List of publications"},"content":{"rendered":"\n<div class=\"wp-block-columns are-vertically-aligned-center researcher-ID is-layout-flex wp-container-core-columns-is-layout-1 wp-block-columns-is-layout-flex\">\n<div class=\"wp-block-column is-vertically-aligned-center is-layout-flow wp-block-column-is-layout-flow\">\n\n\n<p><\/p>\n<\/div>\n<\/div>\n\n\n\n<div class=\"wp-block-uagb-faq uagb-faq__outer-wrap uagb-block-02396e4a uagb-faq-icon-row uagb-faq-layout-accordion uagb-faq-expand-first-true uagb-faq-inactive-other-true uagb-faq__wrap uagb-buttons-layout-wrap uagb-faq-equal-height\" data-faqtoggle=\"true\" role=\"tablist\"><script type=\"application\/ld+json\">{\"@context\":\"https:\/\/schema.org\",\"@type\":\"FAQPage\",\"@id\":\"https:\/\/web.natur.cuni.cz\/ecology\/DiCE\/publications\/\",\"mainEntity\":[{\"@type\":\"Question\",\"name\":\"2026\",\"acceptedAnswer\":{\"@type\":\"Answer\",\"text\":\"&lt;strong>Koll\u00e1r J.&lt;\/strong>, Van de Vijver B., Kulichov\u00e1 J., &lt;strong>Hejdukov\u00e1 E.&lt;\/strong>, &lt;strong>Viso R.&lt;\/strong>, &lt;strong>Kohler T.J.&lt;\/strong>, Kahlert M., Pinseel E., Poul\u00ed\u010dkov\u00e1 A., Zimmermann J., Neustupa J., Vyverman W. &amp; &lt;strong>Kopalov\u00e1 K.&lt;\/strong> (2026): A polyphasic taxonomy of the pseudocryptic diatom species complex\u00a0&lt;em>Pinnularia acidicola&lt;\/em>, including description of new species.\u00a0&lt;em>Eur. J. Phycol.\u00a0&lt;\/em>(&lt;em>in press&lt;\/em>).\u00a0&lt;a href=\\\"https:\/\/doi.org\/10.1080\/09670262.2026.2626682\\\">DOI: 10.1080\/09670262.2026.2626682&lt;\/a>\"}},{\"@type\":\"Question\",\"name\":\"2025\",\"acceptedAnswer\":{\"@type\":\"Answer\",\"text\":\"Coria S.H., Colman D.I., &lt;strong>Kohler T.J.&lt;\/strong>, &lt;strong>Koll\u00e1r J.&lt;\/strong>, Vieira R., P\u00e9rez Cat\u00e1n S., Rosa L.H., V\u00e1zquez S.C., Mac Cormack W.P., Lirio J.M. &amp; &lt;strong>Kopalov\u00e1 K.&lt;\/strong> (2025): Comparison of bacterial and diatom diversity patterns from waterbodies across two Antarctic Peninsula island groups. &lt;em>Arctic, Antarctic, and Alpine Research&lt;\/em> 57(1): 2584836. &lt;a href=\\\"https:\/\/doi.org\/10.1080\/15230430.2025.2584836\\\">DOI: 10.1080\/15230430.2025.2584836&lt;\/a>&lt;br>&lt;br>&lt;strong>Hejdukov\u00e1 E.&lt;\/strong>, Pushkareva E., Kv\u00edderov\u00e1 J., Becker B. &amp; Elster J. (2025): Summer and autumn photosynthetic activity in High Arctic biological soil crusts and their winter recovery.\u00a0&lt;em>Frontiers in Microbiology&lt;\/em>\u00a016: 1684649.&lt;br>&lt;a href=\\\"https:\/\/doi.org\/10.3389\/fmicb.2025.1684649\\\">DOI: 10.3389\/fmicb.2025.1684649&lt;\/a>&lt;br>&lt;br>&lt;strong>Kochoska H.&lt;\/strong>, &lt;strong>Koll\u00e1r J.&lt;\/strong>, &lt;strong>Kopalov\u00e1 K.&lt;\/strong>, Styllas M., Ezzat L., Michoud G., Peter H., Bourquin M., Busi S., &lt;br>Hamilton P.B., Battin T.J. &amp; &lt;strong>Kohler T.J.&lt;\/strong> (2025): Glacier-fed stream diatoms (Bacillariophyta) from the Rwenzori Mountains, Uganda, with description of one new species from the genus &lt;em>Neidium&lt;\/em>. &lt;em>Diatom Research&lt;\/em> 40(3): 237-258. &lt;a href=\\\"https:\/\/doi.org\/10.1080\/0269249X.2025.2474765\\\" data-type=\\\"link\\\" data-id=\\\"https:\/\/doi.org\/10.1080\/0269249X.2025.2474765\\\">DOI: 10.1080\/0269249X.2025.2474765&lt;\/a>&lt;br>&lt;br>Bourquin M., Peter H., Michoud G., Busi S.B, &lt;strong>Kohler T.J.&lt;\/strong>, Robison A.L., Styllas M., Ezzat L., Geers A.U., Huss M., Fodelianakis S., The Vanishing Glaciers Field Team &amp; Battin T.J. (2025). Predicting climate-change impacts on the global glacier-fed stream microbiome. &lt;em>Nature Communications&lt;\/em> 16(1): 1264. &lt;a href=\\\"https:\/\/www.nature.com\/articles\/s41467-025-56426-4#article-info\\\" data-type=\\\"link\\\" data-id=\\\"https:\/\/www.nature.com\/articles\/s41467-025-56426-4#article-info\\\">DOI: 10.1038\/s41467-025-56426-4&lt;\/a>&lt;br>&lt;br>Kl\u00edmov\u00e1 P., &lt;strong>Kohler T.J.&lt;\/strong>, Van de Vijver B. &amp; &lt;strong>Kopalov\u00e1 K&lt;\/strong>. (2025). Moss-inhabiting diatom (Bacillariophyta) communities from Gough Island, Southern Atlantic Ocean. &lt;em>Nova Hedwigia&lt;\/em> 120(1-4): 473\u2013511. &lt;a href=\\\"https:\/\/www.schweizerbart.de\/papers\/nova_hedwigia\/detail\/prepub\/106348\/Moss_inhabiting_diatom_Bacillariophyta_communities?af=crossref\\\" data-type=\\\"link\\\" data-id=\\\"https:\/\/www.schweizerbart.de\/papers\/nova_hedwigia\/detail\/prepub\/106348\/Moss_inhabiting_diatom_Bacillariophyta_communities?af=crossref\\\">DOI: 10.1127\/nova_hedwigia\/2025\/0989&lt;br>&lt;\/a>&lt;br>&lt;strong>Koll\u00e1r J.&lt;\/strong>, &lt;strong>Kopalov\u00e1 K.&lt;\/strong> &amp; &lt;strong>Kohler T. J.&lt;\/strong> (2025) Diatom studies three decades into the molecular age: a bibliometric analysis reveals genetic underexploration of diatoms compared to other taxa. &lt;em>Fottea&lt;\/em> 25(1): 1-11.&lt;em> &lt;\/em>&lt;a href=\\\"https:\/\/fottea.czechphycology.cz\/corproof.php?tartkey=fot-000000-0584\\\" data-type=\\\"link\\\" data-id=\\\"https:\/\/fottea.czechphycology.cz\/corproof.php?tartkey=fot-000000-0584\\\">DOI: 10.5507\/fot.2024.009&lt;\/a>&lt;br>&lt;br>Geers A.U., Michoud G., Busi S.B., Peter H., &lt;strong>Kohler T.J.&lt;\/strong>, Ezzat L., The Vanishing Glaciers Field Team &amp; T.J. Battin. (2025) Deciphering the biosynthetic landscape of biofilms in glacier-fed streams. &lt;em>mSystems&lt;\/em> 10(2): e01137-\u200c24. &lt;a href=\\\"https:\/\/journals.asm.org\/doi\/10.1128\/msystems.01137-24\\\" data-type=\\\"link\\\" data-id=\\\"https:\/\/journals.asm.org\/doi\/10.1128\/msystems.01137-24\\\">DOI: 10.1128\/msystems.01137-24&lt;\/a>&lt;br>&lt;br>Michoud G., Busi S.B., Bourquin M., Peter H., &lt;strong>Kohler &lt;strong>T.J.&lt;\/strong>&lt;\/strong>, Geers A., Ezzat L., The Vanishing Glaciers Field Team &amp; Battin T.J. (2025) Mapping the metagenomic diversity of the multi-kingdom glacier-fed stream microbiome. &lt;em>Nature Microbiology&lt;\/em> 10(1): 217\u2013230. &lt;a href=\\\"https:\/\/www.nature.com\/articles\/s41564-024-01874-9\\\" data-type=\\\"link\\\" data-id=\\\"https:\/\/www.nature.com\/articles\/s41564-024-01874-9\\\">DOI: 10.1038\/s41564-024-01874-9&lt;\/a>&lt;br>&lt;br>Ezzat L., Peter H., Bourquin M., Busi S.B., Michoud G., Fodelianakis S., &lt;strong>Kohler T.J.&lt;\/strong>, Lamy T., Geers A., Pramateftaki P., Baier F., Marasco R., Daffonchio D., Deluigi N., Wilmes P., Styllas M., Sch\u00f6n M., Tolosano M., De Staercke V. &amp; Battin T.J. (2025) Diversity and biogeography of the bacterial microbiome in glacier-fed streams. &lt;em>Nature&lt;\/em> 637(8046): 622\u2013630. &lt;a href=\\\"https:\/\/www.nature.com\/articles\/s41586-024-08313-z\\\" data-type=\\\"link\\\" data-id=\\\"https:\/\/www.nature.com\/articles\/s41586-024-08313-z\\\">DOI: 0.1038\/s41586-024-08313-z&lt;\/a>&lt;br>&lt;br>Goeyers C., Van de Vijver B., &lt;strong>Kohler T.J.&lt;\/strong>, Verleyen E., Tytgat B., Gradstein R.S. &amp; K. Sabbe. (2025) Local and regional, not latitudinal, variation in microclimate and bedrock shapes moss-associated diatom communities in Greenland. &lt;em>Journal of Biogeography&lt;\/em> 52(2): 479\u2013494. &lt;a href=\\\"https:\/\/onlinelibrary.wiley.com\/doi\/10.1111\/jbi.15050\\\" data-type=\\\"link\\\" data-id=\\\"https:\/\/onlinelibrary.wiley.com\/doi\/10.1111\/jbi.15050\\\">DOI: 10.1111\/jbi.15050&lt;\/a>\"}},{\"@type\":\"Question\",\"name\":\"2024\",\"acceptedAnswer\":{\"@type\":\"Answer\",\"text\":\"Pushkareva E., &lt;strong>Hejdukov\u00e1 E.&lt;\/strong>, Elster J. &amp; Becker B. (2024) Microbial response to seasonal variation in Arctic biocrusts with a focus on fungi and cyanobacteria. &lt;em>Environmental Research&lt;\/em> 263(2): 1\u20139. &lt;a href=\\\"https:\/\/doi.org\/10.1016\/j.envres.2024.120110\\\">DOI: 10.1016\/j.envres.2024.120110&lt;\/a>&lt;br>&lt;br>Goeyers, C., K. Sabbe, E. Verleyen, P.B. Hamilton, &lt;strong>T.J. Kohler&lt;\/strong> &amp; B. Van de Vijver. (2024) The genus &lt;em>Humidophila &lt;\/em>(Bacillariophyta) in Greenland with the description of 2 new species. &lt;em>Fottea &lt;\/em>24(2): 198\u2013221. &lt;a href=\\\"https:\/\/fottea.czechphycology.cz\/artkey\/fot-202402-0003_the_genus_humidophila_bacillariophyta_in_greenland_with_the_description_of_2_new_species.php\\\" data-type=\\\"link\\\" data-id=\\\"https:\/\/fottea.czechphycology.cz\/artkey\/fot-202402-0003_the_genus_humidophila_bacillariophyta_in_greenland_with_the_description_of_2_new_species.php\\\">DOI: 10.5507\/fot.2024.004&lt;\/a>&lt;br>&lt;br>&lt;strong>Hejdukov\u00e1 E.&lt;\/strong>, &lt;strong>Koll\u00e1r J&lt;\/strong>. &amp; Nedbalov\u00e1 L. (2024) Freezing stress tolerance of benthic freshwater diatoms from the genus &lt;em>Pinnularia&lt;\/em>: comparison of strains from polar, alpine and temperate habitats. &lt;em>Journal of Phycology&lt;\/em> 60: 1105-1120. &lt;a href=\\\"https:\/\/doi.org\/10.1111\/jpy.13486\\\" data-type=\\\"link\\\" data-id=\\\"https:\/\/doi.org\/10.1111\/jpy.13486\\\">DOI: 10.1111\/jpy.13486&lt;\/a>&lt;br>&lt;br>Roman M., P\u00ed\u0161kov\u00e1 A., Sanderson D.C., Cresswell A.J., Bul\u00ednov\u00e1 M., Pokorn\u00fd M., Kavan J., Jennings S.J., Lirio J.M., Nedbalov\u00e1 L., Sacherov\u00e1 V., &lt;strong>Kopalov\u00e1 K.&lt;\/strong>, Glasser N.F. &amp; N\u00fdvlt D. (2024). The Late-Holocene deglaciation of James Ross Island, Antarctic Peninsula: OSL and 14C-dated multi-proxy sedimentary record from Monolith Lake. &lt;em>Quaternary Science Reviews&lt;\/em> 333: 108693. &lt;a href=\\\"https:\/\/www.sciencedirect.com\/science\/article\/pii\/S027737912400194X\\\" data-type=\\\"link\\\" data-id=\\\"https:\/\/www.sciencedirect.com\/science\/article\/pii\/S027737912400194X\\\">DOI: 10.1016\/j.quascirev.2024.108693&lt;\/a>&lt;br>&lt;br>Stanish L.F., &lt;strong>Kohler &lt;strong>T.J.&lt;\/strong>&lt;\/strong>, Darling J., &amp; McKnight D.M. (2024). Drifting along: Using diatoms to track the contribution of microbial mats to particulate organic matter transport in a glacial meltwater stream in the McMurdo Dry Valleys, Antarctica. &lt;em>Frontiers in Microbiology&lt;\/em> 15: 1352666. &lt;a href=\\\"https:\/\/www.frontiersin.org\/journals\/microbiology\/articles\/10.3389\/fmicb.2024.1352666\/abstract\\\" data-type=\\\"link\\\" data-id=\\\"https:\/\/www.frontiersin.org\/journals\/microbiology\/articles\/10.3389\/fmicb.2024.1352666\/abstract\\\">DOI: 10.3389\/fmicb.2024.1352666&lt;\/a>&lt;br>&lt;br>&lt;strong>Kohler T.J.&lt;\/strong>, Bourquin M., Peter H., Yvon-Durocher G., Sinsabaugh R.L., Deluigi N., Styllas M., Vanishing Glaciers Field Team &amp; Battin T.J. (2024). Global emergent responses of stream microbial metabolism to glacier shrinkage. &lt;em>Nature Geoscience&lt;\/em> 17: 309\u2013315. &lt;a href=\\\"https:\/\/www.nature.com\/articles\/s41561-024-01393-6\\\" data-type=\\\"link\\\" data-id=\\\"https:\/\/www.nature.com\/articles\/s41561-024-01393-6\\\">DOI: 10.1038\/s41561-024-01393-6&lt;\/a>&lt;br>&lt;br>Busi S.B., Peter H., Brandani J., &lt;strong>Kohler T.J.&lt;\/strong>, Fodelianakis S., Pramateftaki P., Bourquin M., Michoud G., Ezzat L., Lane S., Wilmes P. &amp; Battin T.J. (2024) Cross-domain interactions confer stability to benthic biofilms in proglacial streams. &lt;em>Frontiers in Microbiomes&lt;\/em> 2: 1280809. &lt;a href=\\\"https:\/\/www.frontiersin.org\/articles\/10.3389\/frmbi.2023.1280809\/full\\\" data-type=\\\"link\\\" data-id=\\\"https:\/\/www.frontiersin.org\/articles\/10.3389\/frmbi.2023.1280809\/full\\\">DOI: 10.3389\/frmbi.2023.1280809&lt;\/a>\"}},{\"@type\":\"Question\",\"name\":\"2023\",\"acceptedAnswer\":{\"@type\":\"Answer\",\"text\":\"Brandani J., Peter H., Fodelianakis S., &lt;strong>Kohler T.J.&lt;\/strong>, Bourquin M., Michoud G., Busi S.B., Ezzat L., Lane S. &amp; Battin T.J. (2023) Homogeneous environmental selection structures the bacterial communities of benthic biofilms in proglacial floodplain streams. &lt;em>Applied and Environmental Microbiology &lt;\/em>89(3): e02010-22. &lt;a href=\\\"https:\/\/journals.asm.org\/doi\/full\/10.1128\/aem.02010-22\\\" data-type=\\\"link\\\" data-id=\\\"https:\/\/journals.asm.org\/doi\/full\/10.1128\/aem.02010-22\\\">DOI: 10.1128\/aem.02010-22&lt;\/a>&lt;br>&lt;br>Busi S.B., de Nies L., Pramateftaki P., Bourquin M., &lt;strong>Kohler T.J&lt;\/strong>., Ezzat L., Fodelianakis S., Michoud G., Peter H., Styllas M., Tolosano M., De Staercke V., Sch\u00f6n M., Galata V., Wilmes P. &amp; Battin T.J. (2023) Glacier-fed stream biofilms harbour diverse resistomes and biosynthetic gene clusters. &lt;em>Microbiology Spectrum&lt;\/em> 11(1): e04069-22. &lt;a href=\\\"https:\/\/journals.asm.org\/doi\/full\/10.1128\/spectrum.04069-22\\\" data-type=\\\"link\\\" data-id=\\\"https:\/\/journals.asm.org\/doi\/full\/10.1128\/spectrum.04069-22\\\">DOI: 10.1128\/spectrum.04069-22&lt;\/a>&lt;br>&lt;br>&lt;strong>Kohler T.J.&lt;\/strong>, Singley J.G., Wlostowski A.N. &amp; McKnight D.M. (2023) Nitrogen fixation facilitates stream microbial mat biomass across the McMurdo Dry Valleys, Antarctica. &lt;em>Biogeochemistry&lt;\/em> 166: 247\u2013268. &lt;a href=\\\"https:\/\/link.springer.com\/article\/10.1007\/s10533-023-01069-0#article-info\\\" data-type=\\\"link\\\" data-id=\\\"https:\/\/link.springer.com\/article\/10.1007\/s10533-023-01069-0#article-info\\\">DOI: 10.1007\/s10533-023-01069-0&lt;br>&lt;\/a>&lt;br>&lt;strong>Koll\u00e1r J.&lt;\/strong>, &lt;strong>Kopalov\u00e1 K.&lt;\/strong>, Kavan J., Vrbick\u00e1 K., N\u00fdvlt D., Nedbalov\u00e1 L., Stibal M. &amp; &lt;strong>Kohler T.J.&lt;\/strong> (2023) Recently-formed Antarctic lakes host less diverse bacterial and diatom communities than their older counterparts. &lt;em>FEMS Microbiology Ecology&lt;\/em>&lt;a> &lt;\/a>99(9): fiad087. &lt;a href=\\\"https:\/\/academic.oup.com\/femsec\/article\/99\/9\/fiad087\/7233717\\\" data-type=\\\"link\\\" data-id=\\\"https:\/\/academic.oup.com\/femsec\/article\/99\/9\/fiad087\/7233717\\\">DOI: 10.1093\/femsec\/fiad087&lt;\/a>&lt;br>&lt;br>Michoud G, &lt;strong>Kohler T.J.&lt;\/strong>, Ezzat L., Peter H., Kigongo Nattabi J., Nalwanga R., Pramateftaki P., Styllas M., Tolosano M., De Staercke V., Sch\u00f6n M., Marasco R., Daffonchio D., Bourquin M., Busi S.B. &amp; Battin T.J. (2023) The dark side of the moon: first insights into the microbiome structure and function of one of the last glacier-fed streams in Africa. &lt;em>Royal Society Open Science &lt;\/em>10(8): 230329. &lt;a href=\\\"https:\/\/royalsocietypublishing.org\/doi\/full\/10.1098\/rsos.230329\\\" data-type=\\\"link\\\" data-id=\\\"https:\/\/royalsocietypublishing.org\/doi\/full\/10.1098\/rsos.230329\\\">DOI: 10.1098\/rsos.230329&lt;\/a>&lt;br>&lt;br>Michoud G., &lt;strong>Kohler T.J.&lt;\/strong>, Peter H., Brandani J., Busi S.B. &amp; Battin T.J. (2023) Unexpected functional diversity of stream biofilms within and across proglacial floodplains despite close spatial proximity. &lt;em>Limnology and Oceanography &lt;\/em>68(9): 2183-2194. &lt;a href=\\\"https:\/\/aslopubs.onlinelibrary.wiley.com\/doi\/full\/10.1002\/lno.12415\\\" data-type=\\\"link\\\" data-id=\\\"https:\/\/aslopubs.onlinelibrary.wiley.com\/doi\/full\/10.1002\/lno.12415\\\">DOI: 10.1002\/lno.12415&lt;\/a>&lt;br>&lt;br>Tytgat B., Verleyen E., Sweetlove M., Van den Berge K.,\u00a0Pinseel E., Hodgson D.A., Chown S.L., Sabbe K., Wilmotte A., Willems A., &lt;strong>Polar lake Sampling Consortium&lt;\/strong>, Vyverman W.\u00a0(2023)\u00a0Polar lake microbiomes have distinct evolutionary histories. &lt;em>Science Advances&lt;\/em> 9(46): eade7130. &lt;a href=\\\"https:\/\/www.science.org\/doi\/full\/10.1126\/sciadv.ade7130#abstract\\\" data-type=\\\"link\\\" data-id=\\\"https:\/\/www.science.org\/doi\/full\/10.1126\/sciadv.ade7130#abstract\\\">DOI: 10.1126\/sciadv.ade7130&lt;\/a>\"}},{\"@type\":\"Question\",\"name\":\"2022\",\"acceptedAnswer\":{\"@type\":\"Answer\",\"text\":\"Bourquin M., Busi S.B., Fodelianakis S., Peter H., Washburne A., &lt;strong>Kohler T.J.&lt;\/strong>, Ezzat L., Wilmes P. &amp; Battin T.J. (2022) The microbiome of cryospheric ecosystems. &lt;em>Nature Communications &lt;\/em>13: 3087. &lt;a href=\\\"https:\/\/www.nature.com\/articles\/s41467-022-30816-4\\\" data-type=\\\"link\\\" data-id=\\\"https:\/\/www.nature.com\/articles\/s41467-022-30816-4\\\">DOI: 10.1038\/s41467-022-30816-4&lt;\/a>&lt;br>&lt;br>Brandani J., Peter H., Busi S.B, &lt;strong>Kohler T.J.&lt;\/strong>, Fodelianakis S., Ezzat L., Michoud G., Bourquin M., Pramateftaki P., Roncoroni M., Lane S.N. &amp; Battin T.J. (2022) Spatial patterns of benthic biofilm diversity among streams draining proglacial floodplains. &lt;em>Frontiers in Microbiology&lt;\/em> 13: 948165. &lt;a href=\\\"https:\/\/www.frontiersin.org\/articles\/10.3389\/fmicb.2022.948165\/full\\\" data-type=\\\"link\\\" data-id=\\\"https:\/\/www.frontiersin.org\/articles\/10.3389\/fmicb.2022.948165\/full\\\">DOI: 10.3389\/fmicb.2022.948165&lt;\/a>&lt;br>&lt;br>Busi S.B., Bourquin M., Fodelianakis S., Michoud G., &lt;strong>Kohler&lt;\/strong> &lt;strong>T.J.&lt;\/strong>, Peter H., Pramateftaki P., Styllas M., Tolosano M., de Staercke V., Sch\u00f6n M., de Nies L., Marasco R., Daffonchio D., Ezzat L., Wilmes P. &amp; Battin T.J. (2022) Genomic and metabolic adaptations of biofilms to ecological windows of opportunities in glacier-fed streams. &lt;em>Nature Communications&lt;\/em> 13: 2168. &lt;a href=\\\"https:\/\/www.nature.com\/articles\/s41467-022-29914-0\\\" data-type=\\\"link\\\" data-id=\\\"https:\/\/www.nature.com\/articles\/s41467-022-29914-0\\\">DOI: 10.1038\/s41467-022-29914-0&lt;\/a>&lt;br>&lt;br>Chattov\u00e1 B., Cahov\u00e1 T., Pinseel E., &lt;strong>Kopalov\u00e1 K.&lt;\/strong>, &lt;strong>Kohler T.J.&lt;\/strong>, Hrb\u00e1\u010dek F., Van de Vijver B. &amp; N\u00fdvlt D. (2022) Diversity, ecology, and community structure of the terrestrial diatom flora from Ulu Peninsula (James Ross Island, NE Antarctic Peninsula). &lt;em>Polar Biology &lt;\/em>45(5): 873\u2013894. &lt;a href=\\\"https:\/\/link.springer.com\/article\/10.1007\/s00300-022-03038-z\\\" data-type=\\\"link\\\" data-id=\\\"https:\/\/link.springer.com\/article\/10.1007\/s00300-022-03038-z\\\">DOI: 10.1007\/s00300-022-03038-z&lt;\/a>&lt;br>&lt;br>Ezzat L., Fodelianakis S., &lt;strong>Kohler T.J.&lt;\/strong>, Bourquin M., Brandani J., Busi S.B., Daffonchio D., de Staercke V., Marasco R., Michoud G., Oppliger E., Peter H., Pramateftaki P., Sch\u00f6n M., Styllas M., Tadei V., Tolosano M. &amp; Battin T.J. (2022) Benthic biofilms in glacier-fed streams from Scandinavia to the Himalayas host distinct bacterial communities compared to the streamwater. &lt;em>Applied and Environmental Microbiology &lt;\/em>88(12): e00421-22.\u00a0&lt;a href=\\\"https:\/\/journals.asm.org\/doi\/full\/10.1128\/aem.00421-22\\\" data-type=\\\"link\\\" data-id=\\\"https:\/\/journals.asm.org\/doi\/full\/10.1128\/aem.00421-22\\\">DOI: 10.1128\/aem.00421-22&lt;\/a>&lt;br>&lt;br>Fodelianakis S., Washburne A.D., Bourquin M., Pramateftaki P., &lt;strong>Kohler T.J.&lt;\/strong>, Styllas M., Tolosano M., de Staercke V., Sch\u00f6n M., Busi S.B., Brandani J., Wilmes P., Peter H. &amp; Battin T.J. 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(2016) &lt;em>Humidophila komarekiana&lt;\/em> sp. nov. (Bacillariophyta), a new limnoterrestrial diatom species from King George Island (Maritime Antarctica). &lt;em>Phytotaxa&lt;\/em> 272(3): 184\u2013190. &lt;a href=\\\"https:\/\/www.biotaxa.org\/Phytotaxa\/article\/view\/phytotaxa.272.3.2\\\">DOI: 10.11646\/phytotaxa.272.3.2&lt;\/a>&lt;br>&lt;br>&lt;strong>Kohler T.J.&lt;\/strong>, Van Horn D.J., Darling J.P., Takacs-Vesbach C.D. &amp; McKnight D.M. (2016) Nutrient treatments alter microbial mat colonization in two glacial meltwater streams from the McMurdo Dry Valleys, Antarctica. &lt;em>FEMS Microbiology Ecology &lt;\/em>92(4): fiw049. &lt;a href=\\\"https:\/\/academic.oup.com\/femsec\/article\/92\/4\/fiw049\/2197973\\\" data-type=\\\"link\\\" data-id=\\\"https:\/\/academic.oup.com\/femsec\/article\/92\/4\/fiw049\/2197973\\\">DOI: 10.1093\/femsec\/fiw049&lt;\/a>&lt;br>&lt;br>&lt;strong>Kopalov\u00e1 K.&lt;\/strong>, Zidarova R. &amp; Van de Vijver B. (2016) Four new monoraphid diatom species (Bacillariophyta, Achnanthaceae) from the Maritime Antarctic Region. &lt;em>European Journal of Taxonomy&lt;\/em> 217: 1\u201319. &lt;a href=\\\"https:\/\/europeanjournaloftaxonomy.eu\/index.php\/ejt\/article\/view\/341\/0\\\">DOI: 10.5852\/ejt.2016.217&lt;\/a>&lt;br>&lt;br>Lecomte K.L., Vignoni P., C\u00f3rdoba F.E., Chaparro Marcos A.E., Chaparro Mauro A.E., &lt;strong>Kopalov\u00e1 K.&lt;\/strong>, Gargiulo J.D., Lirio J.M., Irurzun M.A. &amp; B\u00f6hnel H.N. (2016) Hydrological systems from the Antarctic Peninsula under climate change: James Ross Archipelago as study case. &lt;em>Environmental Earth Sciences &lt;\/em>75(7): 623. &lt;a href=\\\"https:\/\/link.springer.com\/article\/10.1007\/s12665-016-5406-y\\\">DOI: 10.1007\/s12665-016-5406-y&lt;br>&lt;\/a>&lt;br>Sakaeva A., Sokol E.R., &lt;strong>Kohler T.J.&lt;\/strong>, Stanish L.F., Spaulding S.A., Howkins A., Welch K.A., Lyons W.B., Barrett J.E. &amp; McKnight D.M. 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(2016) Two new &lt;em>Gomphonema&lt;\/em> species (Bacillariophyta) from the Maritime Antarctic Region. &lt;em>Phytotaxa&lt;\/em> 269(3): 209\u2013220. &lt;a href=\\\"https:\/\/www.biotaxa.org\/Phytotaxa\/article\/view\/phytotaxa.269.3.4\\\">DOI: 10.11646\/phytotaxa.269.3.4&lt;\/a>&lt;br>&lt;br>Van Horn D.J., Wolf C.R., Colman D.R., Jiang X., &lt;strong>Kohler T.J.&lt;\/strong>, McKnight D.M., Stanish L.F., Yazzie T. &amp; Takacs-Vesbach C.D. (2016) Patterns of bacterial biodiversity in the glacial meltwater streams of the McMurdo Dry Valleys, Antarctica. &lt;em>FEMS Microbiology Ecology&lt;\/em> 92(10): fiw148. &lt;a href=\\\"https:\/\/academic.oup.com\/femsec\/article\/92\/10\/fiw148\/2197762\\\" data-type=\\\"link\\\" data-id=\\\"https:\/\/academic.oup.com\/femsec\/article\/92\/10\/fiw148\/2197762\\\">DOI:\u00a010.1093\/femsec\/fiw148&lt;\/a>&lt;br>&lt;br>Vin\u0161ov\u00e1 P., &lt;strong>Kopalov\u00e1 K.&lt;\/strong> &amp; Van de Vijver B. (2016) Morphological observations on &lt;em>Pseudeunotia linearis&lt;\/em> Carter (Bacillariophyta) and its transfer to the genus &lt;em>Eunotia&lt;\/em>. &lt;em>Botany Letters &lt;\/em>163(2): 117-123.&lt;br>&lt;br>Zidarova R., &lt;strong>Kopalova&lt;\/strong> &lt;strong>K.&lt;\/strong> &amp; Van de Vijver B. (2016) Diatoms from the Antarctic Region. I: Maritime Antarctica.\u00a0Annotated Diatom Micrograph. Ed. by Horst Lange \u2013 Bertalot. Volume 24: 216 photographic plates. 509 p. Hardcover. (&lt;a href=\\\"https:\/\/www.koeltz.com\/en\/iconographia-diatomologica24-zidarovaret-aldiatoms-from-the-ant-arctic-regionimaritime-antarctica2016\\\">ISBN 978-3-946583-05-9&lt;\/a>)&lt;br>&lt;br>Zidarova R., &lt;strong>Kopalov\u00e1 K. &lt;\/strong>&amp; Van de Vijver B. (2016) Ten new Bacillariophyta species from James Ross Island and the South Shetland Islands (Maritime Antarctic Region). &lt;em>Phytotaxa&lt;\/em> 272(1): 037\u2013062. &lt;a href=\\\"https:\/\/www.biotaxa.org\/Phytotaxa\/article\/view\/phytotaxa.272.1.2\\\">DOI: 10.11646\/phytotaxa.272.1.2&lt;\/a>\"}},{\"@type\":\"Question\",\"name\":\"2015\",\"acceptedAnswer\":{\"@type\":\"Answer\",\"text\":\"&lt;strong>Kohler T.J.&lt;\/strong>, Chatfield E., Gooseff M.N., Barrett J.E. &amp; McKnight D.M. (2015) Recovery of Antarctic stream epilithon from simulated scouring events. &lt;em>Antarctic Science&lt;\/em> 27(4): 341\u2013354. &lt;a href=\\\"https:\/\/www.cambridge.org\/core\/journals\/antarctic-science\/article\/abs\/recovery-of-antarctic-stream-epilithon-from-simulated-scouring-events\/9263E172156ADB7EDDCA5302EBF8D78A\\\" data-type=\\\"link\\\" data-id=\\\"https:\/\/www.cambridge.org\/core\/journals\/antarctic-science\/article\/abs\/recovery-of-antarctic-stream-epilithon-from-simulated-scouring-events\/9263E172156ADB7EDDCA5302EBF8D78A\\\">DOI: 10.1017\/S0954102015000024&lt;\/a>&lt;br>&lt;br>&lt;strong>Kohler T.J.&lt;\/strong>, &lt;strong>Kopalov\u00e1 K&lt;\/strong>., Van de Vijver B. &amp; Kociolek J.P. (2015) The genus &lt;em>Luticola&lt;\/em> D.G.Mann (Bacillariophyta) from the McMurdo Sound Region, Antarctica, with the description of 4 new species. &lt;em>Phytotaxa&lt;\/em> 208(2): 103\u2013134. &lt;a href=\\\"https:\/\/www.biotaxa.org\/Phytotaxa\/article\/view\/phytotaxa.208.2.1\\\">DOI: 10.11646\/phytotaxa.208.2.1&lt;\/a>&lt;br>&lt;br>&lt;strong>Kohler T.J.&lt;\/strong>, Stanish L.F., Crisp S.W., Koch J.C., Liptzin D., Baeseman J.L. &amp; McKnight D.M. (2015) Life in the main channel: long-term hydrologic control of microbial mat abundance in McMurdo Dry Valley streams, Antarctica. &lt;em>Ecosystems &lt;\/em>18(2): 310\u2013327. &lt;a href=\\\"https:\/\/link.springer.com\/article\/10.1007\/s10021-014-9829-6\\\" data-type=\\\"link\\\" data-id=\\\"https:\/\/link.springer.com\/article\/10.1007\/s10021-014-9829-6\\\">DOI: 10.1007\/s10021-014-9829-6&lt;\/a>&lt;br>&lt;br>&lt;strong>Koll\u00e1r J.&lt;\/strong>, Fr\u00e1nkov\u00e1 M., Ha\u0161ler P., Let\u00e1kov\u00e1 M. &amp; Poul\u00ed\u010dkov\u00e1 A. (2015) Epiphytic diatoms in lotic and lentic waters \u2013 diversity and representation of species complexes. &lt;em>Fottea &lt;\/em>15(2): 259-271. &lt;a href=\\\"https:\/\/fottea.czechphycology.cz\/artkey\/fot-201502-0011_Epiphytic_diatoms_in_lotic_and_lentic_waters_-_diversity_and_representation_of_species_complexes.php\\\">DOI:\u00a010.5507\/fot.2015.022&lt;\/a>&lt;br>&lt;br>&lt;strong>Kopalov\u00e1 K.&lt;\/strong>, Kociolek P.J., Lowe R.L., Zidarova R. &amp; Van De Vijver B. (2015) Five new species of the genus &lt;em>Humidophila&lt;\/em> (Bacillariophyta) from the Maritime Antarctic Region. &lt;em>Diatom Research&lt;\/em> 30(2): 117\u2013131. &lt;a href=\\\"https:\/\/www.tandfonline.com\/doi\/full\/10.1080\/0269249X.2014.998714\\\">DOI: 10.1080\/0269249X.2014.998714&lt;\/a>&lt;br>&lt;br>Pinseel E., Van de Vijver B. &amp; &lt;strong>Kopalov\u00e1 K.&lt;\/strong> (2015) &lt;em>Achnanthidium petuniabuktianum&lt;\/em> sp. nov. Achnanthidiaceae, Bacillariophyta), a new representative of the &lt;em>A. pyrenaicum&lt;\/em> group from Spitsbergen (Svalbard Archipelago, High Arctic). &lt;em>Phytotaxa&lt;\/em> 226 (1): 063\u2013074. &lt;a href=\\\"https:\/\/www.biotaxa.org\/Phytotaxa\/article\/view\/phytotaxa.226.1.6\\\">DOI: 10.11646\/phytotaxa.226.1.6&lt;\/a>&lt;br>&lt;br>Van de Vijver B., &lt;strong>Kopalov\u00e1 K.,&lt;\/strong> Kociolek J.P. &amp; Ector L. (2015) &lt;em>Denticula jamesrossensis&lt;\/em>, a new freshwater diatom (Bacillariophyta) species from the Maritime Antarctic Region. &lt;em>Fottea&lt;\/em> 15(1): 105\u2013111. &lt;a href=\\\"https:\/\/fottea.czechphycology.cz\/artkey\/fot-201501-0009_Denticula_jamesrossensis_a_new_freshwater_diatom_Bacillariophyta_species_from_the_Maritime_Antarctic_Region.php\\\">DOI:\u00a010.5507\/fot.2015.009&lt;\/a>&lt;br>&lt;br>Van de Vijver B., &lt;strong>Kopalov\u00e1 K. &lt;\/strong>&amp; Zidarova R. (2015) Three new &lt;em>Craticula&lt;\/em> species (Bacillariophyta) from the Maritime Antarctic Region. &lt;em>Phytotaxa&lt;\/em> 213(1): 035\u2013045. &lt;a href=\\\"https:\/\/www.biotaxa.org\/Phytotaxa\/article\/view\/phytotaxa.213.1.3\\\">DOI: 10.11646\/phytotaxa.213.1.3&lt;\/a>&lt;br>&lt;br>Vin\u0161ov\u00e1 P., Pinseel E., &lt;strong>Kohler T.J.&lt;\/strong>, Van de Vijver B., \u017d\u00e1rsk\u00fd J.D., Kavan J. &amp; &lt;strong>Kopalov\u00e1 K.&lt;\/strong> (2015) Diatoms in cryoconite holes and adjacent proglacial freshwater sediments, Nordenski\u00f6ld glacier (Spitsbergen, High Arctic). &lt;em>Czech Polar Reports &lt;\/em>5(2): 112\u2013133. &lt;a href=\\\"https:\/\/journals.muni.cz\/CPR\/article\/view\/12871\\\">DOI: 10.5817\/CPR2015-2-11&lt;\/a>\"}},{\"@type\":\"Question\",\"name\":\"2014\",\"acceptedAnswer\":{\"@type\":\"Answer\",\"text\":\"Hamilton P., De Haan M., &lt;strong>Kopalov\u00e1 K.&lt;\/strong>, Zidarova R. &amp; Van de Vijver B. (2014) An evaluation of selected &lt;em>Neidium&lt;\/em> species from the Antarctic Region. &lt;em>Diatom Research&lt;\/em> 29(1): 27\u201340. &lt;a href=\\\"https:\/\/www.tandfonline.com\/doi\/abs\/10.1080\/0269249X.2013.822020\\\">DOI: 10.1080\/0269249X.2013.822020&lt;\/a>&lt;br>&lt;br>&lt;strong>Kopalov\u00e1 K.,&lt;\/strong> Ochyra R., Nedbalov\u00e1 L. &amp; Van de Vijver B. (2014) Moss-inhabiting diatoms from two contrasting Maritime Antarctic islands. &lt;em>Plant Ecology and Evolution&lt;\/em> 147(1): 67\u201384. DOI: 10.5091\/plecevo.2014.896&lt;br>&lt;br>&lt;strong>Kopalov\u00e1 K.&lt;\/strong> &amp; Van de Vijver B. (2013) Structure and ecology of freshwater benthic diatom communities from Byers Peninsula (Livingston Island, South Shetland Island). &lt;em>Antarctic Science&lt;\/em> 25(2): 239\u2013253. &lt;a href=\\\"https:\/\/www.cambridge.org\/core\/journals\/antarctic-science\/article\/abs\/structure-and-ecology-of-freshwater-benthic-diatom-communities-from-byers-peninsula-livingston-island-south-shetland-islands\/2FB16DCEC4E735AAB23C225A3B3363D3\\\">DOI: 10.1017\/S0954102012000764&lt;\/a>&lt;br>&lt;br>Lowe R.L., Kociolek P., Johansen J.R., Van de Vijver B., Lange-Bertalot H. &amp; &lt;strong>Kopalov\u00e1 K.&lt;\/strong> (2014) &lt;em>Humidophila&lt;\/em> gen. nov., a new genus for a clade of diatoms (Bacillariophyta) formerly within the genus &lt;em>Diadesmis&lt;\/em>: species from Hawai\u2019i, including one new species. &lt;em>Diatom Research&lt;\/em> 29(4): 351\u2013360. &lt;a href=\\\"https:\/\/www.tandfonline.com\/doi\/abs\/10.1080\/0269249X.2014.889039\\\">DOI: 10.1080\/0269249X.2014.889039&lt;\/a>&lt;br>&lt;br>Pinseel E.,&lt;strong> Kopalov\u00e1 K.&lt;\/strong>\u00a0 &amp; Van de Vijver B. (2014) &lt;em>Gomphonema svalbardense&lt;\/em> sp. nov., a new freshwater diatom species (Bacillariophyta) from the Arctic Region. &lt;em>Phytotaxa&lt;\/em> 170(4): 250\u2013258. &lt;a href=\\\"https:\/\/www.biotaxa.org\/Phytotaxa\/article\/view\/phytotaxa.170.4.2\\\">DOI: 10.11646\/phytotaxa.170.4.2&lt;\/a>&lt;br>&lt;br>Van de Vijver B. &amp; &lt;strong>Kopalov\u00e1, K.&lt;\/strong> (2014) Four &lt;em>Achnanthidium&lt;\/em> species (Bacillariophyta) formerly identified as &lt;em>Achnanthes minutissima&lt;\/em> from the Antarctic Region. &lt;em>European Journal of Taxonomy&lt;\/em> 79: 1\u201319. &lt;a href=\\\"https:\/\/europeanjournaloftaxonomy.eu\/index.php\/ejt\/article\/view\/201\\\">DOI: 10.5852\/ejt.2014.79&lt;\/a>&lt;br>&lt;br>Van de Vijver B., &lt;strong>Kopalov\u00e1 K.&lt;\/strong>, Zidarova R. &amp; Levkov Z. (2014) Revision of the genus\u00a0&lt;em>Halamphora&lt;\/em>\u00a0(Bacillariophyta) in the Antarctic Region.\u00a0&lt;em>Plant Ecology and Evolution&lt;\/em>\u00a0147: 374\u2013391.\u00a0&lt;a href=\\\"https:\/\/plecevo.eu\/article\/32111\/\\\">DOI: 10.5091\/plecevo.2014.979&lt;\/a>&lt;br>&lt;br>Van de Vijver B., Morales E.A. &amp; &lt;strong>Kopalov\u00e1 K.&lt;\/strong> (2014) Three new araphid diatoms (Bacillariophyta) from the Maritime Antarctic Region. &lt;em>Phytotaxa&lt;\/em> 167(30): 256\u2013266. &lt;a href=\\\"https:\/\/www.biotaxa.org\/Phytotaxa\/article\/view\/phytotaxa.167.3.4\\\">DOI: 10.11646\/phytotaxa.167.3.4&lt;\/a>&lt;br>&lt;br>Van de Vijver B., Zidarova R. &amp; &lt;strong>Kopalov\u00e1 K.&lt;\/strong> (2014) New species in the genus &lt;em>Muelleria&lt;\/em> (Bacillariophyta) from the Maritime Antarctic Region. &lt;em>Fottea&lt;\/em> 14(1): 77\u201390. &lt;a href=\\\"https:\/\/fottea.czechphycology.cz\/artkey\/fot-201401-0006_New_species_in_the_genus_Muelleria_Bacillariophyta_from_the_Maritime_Antarctic_Region.php\\\">DOI:\u00a010.5507\/fot.2014.006&lt;\/a>&lt;br>&lt;br>Wetzel C.E., Van de Vijver B., &lt;strong>Kopalov\u00e1 K.&lt;\/strong>, Hoffmann L., Pfister L. &amp; Ector L. (2014) Type analysis of the South American diatom\u00a0&lt;em>Achnanthes haynaldii&lt;\/em>\u00a0(Bacillariophyta) and description of\u00a0&lt;em>Planothidium amphibium\u00a0&lt;\/em>sp. nov., from aerial and aquatic environments of Oregon (USA).\u00a0&lt;em>Plant Ecology and Evolution&lt;\/em>\u00a014: 439\u2013454. &lt;a href=\\\"https:\/\/plecevo.eu\/article\/32125\/\\\">DOI: 10.5091\/plecevo.2014.1058&lt;\/a>&lt;br>&lt;br>Zidarova R., &lt;strong>Kopalov\u00e1 K. &lt;\/strong>&amp; Van de Vijver B. (2014) The genus &lt;em>Stauroneis &lt;\/em>(Bacillariophyta) from the South Shetland Islands and James Ross Island (Antarctica). &lt;em>Fottea&lt;\/em> 14(2): 201\u2013207. &lt;a href=\\\"https:\/\/fottea.czechphycology.cz\/artkey\/fot-201402-0007_The_genus_Stauroneis_Bacillariophyta_from_the_South_Shetland_Islands_and_James_Ross_Island_Antarctica.php\\\">DOI:\u00a010.5507\/fot.2014.015&lt;\/a>\"}},{\"@type\":\"Question\",\"name\":\"2013\",\"acceptedAnswer\":{\"@type\":\"Answer\",\"text\":\"&lt;strong>Kopalov\u00e1 K&lt;\/strong>., Nedbalov\u00e1 L., N\u00fdvlt D., Elster J. &amp; Van de Vijver B. (2013) Diversity, ecology and biogeography of the freshwater diatom communities from Ulu Peninsula (James Ross Island, NE Antarctic Peninsula). &lt;em>Polar Biology&lt;\/em> 36(7): 933\u2013948. \u00a0&lt;a href=\\\"https:\/\/link.springer.com\/article\/10.1007\/s00300-013-1317-5\\\">DOI: 10.1007\/s00300-013-1317-5&lt;br>&lt;\/a>&lt;br>Van de Vijver B., Cocquyt C., De Haan M., &lt;strong>Kopalov\u00e1 K&lt;\/strong>. &amp; Zidarova R. (2013) The genus &lt;em>Surirella&lt;\/em> (Bacillariophyta) in the sub Antarctic and Maritime Antarctic region. &lt;em>Diatom Research&lt;\/em> 28(1): 92-108. &lt;a href=\\\"https:\/\/www.tandfonline.com\/doi\/abs\/10.1080\/0269249X.2012.739975\\\">DOI: 10.1080\/0269249X.2012.739975&lt;\/a>&lt;br>&lt;br>Van de Vijver B., &lt;strong>Kopalov\u00e1 K&lt;\/strong>., Zidarova R. &amp; Cox E. J. (2013) New and interesting small-celled naviculoid taxa from the Maritime Antarctic Region. &lt;em>Nova Hedwigia &lt;\/em>97(1-2): 189-208. &lt;a href=\\\"https:\/\/www.schweizerbart.de\/papers\/nova_hedwigia\/detail\/97\/80529\/New_and_interesting_small_celled_naviculoid_diatoms_Bacillariophyta_from_the_Maritime_Antarctic_Region\\\">DOI: 10.1127\/0029-5035\/2013\/0101&lt;\/a>&lt;br>&lt;br>Van de Vijver B., Wetzel C., &lt;strong>Kopalov\u00e1 K&lt;\/strong>., Zidarova R. &amp; Ector L. (2013) Analysis of the type material of &lt;em>Achnanthidium lanceolatum&lt;\/em> Br\u00e9bisson ex K\u00fctzing (Bacillariophyta) with the description of two new &lt;em>Planothidium&lt;\/em> species from the Antarctic Region. &lt;em>Fottea&lt;\/em> 13(2): 105-117. &lt;a href=\\\"https:\/\/fottea.czechphycology.cz\/artkey\/fot-201302-0002_Analysis_of_the_type_material_of_Achnanthidium_lanceolatum_Brebisson_ex_K_tzing_Bacillariophyta_with_the_desc.php\\\">DOI:\u00a010.5507\/fot.2013.010&lt;\/a>\"}},{\"@type\":\"Question\",\"name\":\"2012\",\"acceptedAnswer\":{\"@type\":\"Answer\",\"text\":\"Auer S.K., Lopez-Sepulcre A., Heatherly II T.N., &lt;strong>Kohler T.J.&lt;\/strong>, Bassar R.D., Thomas S.A. &amp; Reznick D.N. (2012) Life histories have a history: Effects of past and present conditions on somatic growth in wild Trinidadian guppies. &lt;em>Journal of Animal Ecology &lt;\/em>81(4): 818\u2013826. &lt;a href=\\\"https:\/\/besjournals.onlinelibrary.wiley.com\/doi\/10.1111\/j.1365-2656.2012.01964.x\\\">DOI: 10.1111\/j.1365-2656.2012.01964.x&lt;\/a>&lt;br>&lt;br>El-Sabaawi R.W., &lt;strong>Kohler T.J.&lt;\/strong>, Zandon\u00e0 E., Travis J., Marshall M.C., Thomas S.A., Reznick D.N., Walsh M., Gilliam J.F., Pringle C.M. &amp; Flecker A.S. (2012) Environmental and organismal predictors of intraspecific variation in the stoichiometry of a neotropical freshwater fish. &lt;em>PLoS ONE&lt;\/em> 7(3): e32713. &lt;a href=\\\"https:\/\/journals.plos.org\/plosone\/article?id=10.1371\/journal.pone.0032713\\\">DOI: 10.1371\/journal.pone.0032713&lt;\/a>&lt;br>&lt;br>El-Sabaawi R.W., Zandon\u00e0 E., &lt;strong>Kohler T.J.&lt;\/strong>, Marshall M.C., Moslemi J.M., Travis J., L\u00f3pez-Sepulcre A., Ferri\u00e9re R., Pringle C.M., Thomas S.A., Reznick D.N. &amp; Flecker A.S. (2012) Widespread intraspecific organismal stoichiometry among populations of the Trinidadian guppy (&lt;em>Poecilia reticulata&lt;\/em>). &lt;em>Functional Ecology &lt;\/em>26(3): 666\u2013676. &lt;a href=\\\"https:\/\/besjournals.onlinelibrary.wiley.com\/doi\/10.1111\/j.1365-2435.2012.01974.x\\\">DOI:\u00a010.1111\/j.1365-2435.2012.01974.x&lt;\/a>&lt;br>&lt;br>&lt;strong>Kohler T.J.&lt;\/strong>, Heatherly II T.N., El-Sabaawi R.W., Zandon\u00e0 E., Marshall M.C., Flecker A.S., Pringle C.M., Reznick D.N. &amp; Thomas S.A. (2012) Flow, nutrients and light availability influence Neotropical epilithon biomass and stoichiometry. &lt;em>Freshwater Science &lt;\/em>31(4): 1019\u20131034. &lt;a href=\\\"https:\/\/www.journals.uchicago.edu\/doi\/abs\/10.1899\/11-141.1?journalCode=fws\\\">DOI: 10.1899\/11-141.1&lt;\/a>&lt;br>&lt;br>&lt;strong>Kopalov\u00e1 K.&lt;\/strong>, Elster J., Kom\u00e1rek J., Vesel\u00e1 J., Nedbalov\u00e1 L. &amp; Van de Vijver B. (2012) Benthic diatoms (Bacillariophyta) from seepages and streams on James Ross Island (NW Weddell Sea, Antarctica). &lt;em>Plant Ecology and Evolution&lt;\/em> 145(2): 190\u2013208.&lt;br>&lt;br>Stanish L.F., &lt;strong>Kohler T.J.&lt;\/strong>, Esposito R.M.M., Simmons B.L., Nielsen U.N., Wall D.H., Nemergut D.R. &amp; McKnight D.M. (2012) Extreme streams: flow intermittency as a control on diatom communities in meltwater streams in the McMurdo Dry Valleys, Antarctica. &lt;em>Canadian Journal of Fisheries and Aquatic Sciences&lt;\/em> 69(8): 1405\u20131419. &lt;a href=\\\"https:\/\/cdnsciencepub.com\/doi\/abs\/10.1139\/f2012-022?mobileUi=0\\\">DOI: 10.1139\/f2012-022&lt;\/a>&lt;br>&lt;br>Zidarova R., &lt;strong>Kopalov\u00e1 K&lt;\/strong>. &amp; Van de Vijver B. (2012) The genus &lt;em>Pinnularia&lt;\/em> (Bacillariophyta) excluding the sectio Distantes on Livingston Island (South Shetland Islands) with the description of the new taxa. &lt;em>Phytotaxa&lt;\/em> 44: 11\u201337. &lt;a href=\\\"https:\/\/www.biotaxa.org\/Phytotaxa\/article\/view\/phytotaxa.44.1.2\\\">DOI: 10.11646\/phytotaxa.44.1.2&lt;\/a>\"}},{\"@type\":\"Question\",\"name\":\"2011\",\"acceptedAnswer\":{\"@type\":\"Answer\",\"text\":\"&lt;strong>Kohler T.J&lt;\/strong>., Murdock J.N, Gido K.B. &amp; Dodds W.K. (2011) Nutrient loading and grazing by the minnow &lt;em>Phoxinus erythrogaster&lt;\/em> shift periphyton abundance and stoichiometry in mesocosms. &lt;em>Freshwater Biology&lt;\/em> 56(6): 1133\u20131146. &lt;a href=\\\"https:\/\/onlinelibrary.wiley.com\/doi\/abs\/10.1111\/j.1365-2427.2010.02557.x\\\">DOI:\u00a010.1111\/j.1365-2427.2010.02557.x&lt;\/a>&lt;br>&lt;br>&lt;strong>Kopalov\u00e1 K.,&lt;\/strong> Nedbalov\u00e1 L., de Haan M. &amp; Van de Vijver B. (2011) Description of five new species of the diatom genus &lt;em>Luticola&lt;\/em> (Bacillariophyta, Diadesmidaceae) found in lakes of James Ross Island (Maritime Antarctic Region). &lt;em>Phytotaxa&lt;\/em> 27: 44\u201360. &lt;a href=\\\"https:\/\/www.biotaxa.org\/Phytotaxa\/article\/view\/phytotaxa.27.1.5\\\">DOI: 10.11646\/phytotaxa.27.1.5&lt;\/a>\"}},{\"@type\":\"Question\",\"name\":\"2010\",\"acceptedAnswer\":{\"@type\":\"Answer\",\"text\":\"Van de Vijver B., Sterken M., Vyverman W., Mataloni G., Nedbalov\u00e1 L., &lt;strong>Kopalov\u00e1 K&lt;\/strong>., Elster J., Verleyen E. &amp; Sabbe K. (2010)\u00a0Four new non-marine diatom taxa from the Subantarctic and Antarctic Regions. &lt;em>Diatom Research&lt;\/em> 25(2): 431\u2013443. &lt;a href=\\\"https:\/\/www.tandfonline.com\/doi\/abs\/10.1080\/0269249X.2010.9705861\\\">DOI: 10.1080\/0269249X.2010.9705861&lt;\/a>\"}},{\"@type\":\"Question\",\"name\":\"2009\",\"acceptedAnswer\":{\"@type\":\"Answer\",\"text\":\"&lt;strong>Kopalov\u00e1 K.&lt;\/strong>, Elster J., Nedbalov\u00e1 L. &amp; Van de Vijver B. (2009) Three new terrestrial diatom species from seepage areas on James Ross Island (Maritime Antarctic Region). &lt;em>Diatom Research&lt;\/em> 24(1): 113\u2013122. &lt;a href=\\\"https:\/\/www.tandfonline.com\/doi\/abs\/10.1080\/0269249X.2009.9705786\\\">DOI: 10.1080\/0269249X.2009.9705786&lt;\/a>&lt;br>&lt;br>Zidarova R., Van de Vijver B., Mataloni G., &lt;strong>Kopalov\u00e1 K&lt;\/strong>. &amp; Nedbalov\u00e1 L. (2009) Four new freshwater diatom species (Bacillariophyceae) from Antarctica. &lt;em>Cryptogamie Algologie&lt;\/em> 30(4): 295\u2013310.\"}},{\"@type\":\"Question\",\"name\":\"2008\",\"acceptedAnswer\":{\"@type\":\"Answer\",\"text\":\"Esposito R.M.M., Spaulding S.A., McKnight D.M., Van de Vijver B., &lt;strong>Kopalov\u00e1 K.&lt;\/strong>, Lubinski D., Hall B. &amp; Whittaker T. (2008) Inland diatoms from the McMurdo Dry Valleys and James Ross Island, Antarctica. &lt;em>Botany&lt;\/em> 86(12): 1378\u20131392. &lt;a href=\\\"https:\/\/cdnsciencepub.com\/doi\/10.1139\/B08-100\\\">DOI: 10.1139\/B08-100&lt;\/a>&lt;br>&lt;br>Van de Vijver B. &amp; &lt;strong>Kopalov\u00e1 K&lt;\/strong>. (2008) &lt;em>Orthoseira gremmenii&lt;\/em> sp. nov., a new aerophilic diatom from Gough Island (Southern Atlantic Ocean). &lt;em>Cryptogamie Algologie&lt;\/em> 29(2): 105\u2013118.\"}}]}<\/script>\n<div class=\"wp-block-uagb-faq-child uagb-faq-child__outer-wrap uagb-faq-item uagb-block-8d80fec4\" role=\"tab\" tabindex=\"0\"><div class=\"uagb-faq-questions-button uagb-faq-questions\"><span class=\"uagb-icon uagb-faq-icon-wrap\"><svg xmlns=\"https:\/\/www.w3.org\/2000\/svg\" viewBox=\"0 0 384 512\"><path d=\"M192 384c-8.188 0-16.38-3.125-22.62-9.375l-160-160c-12.5-12.5-12.5-32.75 0-45.25s32.75-12.5 45.25 0L192 306.8l137.4-137.4c12.5-12.5 32.75-12.5 45.25 0s12.5 32.75 0 45.25l-160 160C208.4 380.9 200.2 384 192 384z\"><\/path><\/svg><\/span><span class=\"uagb-icon-active uagb-faq-icon-wrap\"><svg xmlns=\"https:\/\/www.w3.org\/2000\/svg\" viewBox=\"0 0 384 512\"><path d=\"M352 352c-8.188 0-16.38-3.125-22.62-9.375L192 205.3l-137.4 137.4c-12.5 12.5-32.75 12.5-45.25 0s-12.5-32.75 0-45.25l160-160c12.5-12.5 32.75-12.5 45.25 0l160 160c12.5 12.5 12.5 32.75 0 45.25C368.4 348.9 360.2 352 352 352z\"><\/path><\/svg><\/span><h4 class=\"uagb-question\">2026<\/h4><\/div><div class=\"uagb-faq-content\"><p><strong>Koll\u00e1r J.<\/strong>, Van de Vijver B., Kulichov\u00e1 J., <strong>Hejdukov\u00e1 E.<\/strong>, <strong>Viso R.<\/strong>, <strong>Kohler T.J.<\/strong>, Kahlert M., Pinseel E., Poul\u00ed\u010dkov\u00e1 A., Zimmermann J., Neustupa J., Vyverman W. &amp; <strong>Kopalov\u00e1 K.<\/strong> (2026): A polyphasic taxonomy of the pseudocryptic diatom species complex\u00a0<em>Pinnularia acidicola<\/em>, including description of new species.\u00a0<em>Eur. J. Phycol.\u00a0<\/em>(<em>in press<\/em>).\u00a0<a href=\"https:\/\/doi.org\/10.1080\/09670262.2026.2626682\">DOI: 10.1080\/09670262.2026.2626682<\/a><\/p><\/div><\/div>\n\n\n\n<div class=\"wp-block-uagb-faq-child uagb-faq-child__outer-wrap uagb-faq-item uagb-block-9dfc7d1a\" role=\"tab\" tabindex=\"0\"><div class=\"uagb-faq-questions-button uagb-faq-questions\"><span class=\"uagb-icon uagb-faq-icon-wrap\"><svg xmlns=\"https:\/\/www.w3.org\/2000\/svg\" viewBox=\"0 0 384 512\"><path d=\"M192 384c-8.188 0-16.38-3.125-22.62-9.375l-160-160c-12.5-12.5-12.5-32.75 0-45.25s32.75-12.5 45.25 0L192 306.8l137.4-137.4c12.5-12.5 32.75-12.5 45.25 0s12.5 32.75 0 45.25l-160 160C208.4 380.9 200.2 384 192 384z\"><\/path><\/svg><\/span><span class=\"uagb-icon-active uagb-faq-icon-wrap\"><svg xmlns=\"https:\/\/www.w3.org\/2000\/svg\" viewBox=\"0 0 384 512\"><path d=\"M352 352c-8.188 0-16.38-3.125-22.62-9.375L192 205.3l-137.4 137.4c-12.5 12.5-32.75 12.5-45.25 0s-12.5-32.75 0-45.25l160-160c12.5-12.5 32.75-12.5 45.25 0l160 160c12.5 12.5 12.5 32.75 0 45.25C368.4 348.9 360.2 352 352 352z\"><\/path><\/svg><\/span><h4 class=\"uagb-question\">2025<\/h4><\/div><div class=\"uagb-faq-content\"><p>Coria S.H., Colman D.I., <strong>Kohler T.J.<\/strong>, <strong>Koll\u00e1r J.<\/strong>, Vieira R., P\u00e9rez Cat\u00e1n S., Rosa L.H., V\u00e1zquez S.C., Mac Cormack W.P., Lirio J.M. &amp; <strong>Kopalov\u00e1 K.<\/strong> (2025): Comparison of bacterial and diatom diversity patterns from waterbodies across two Antarctic Peninsula island groups. <em>Arctic, Antarctic, and Alpine Research<\/em> 57(1): 2584836. <a href=\"https:\/\/doi.org\/10.1080\/15230430.2025.2584836\">DOI: 10.1080\/15230430.2025.2584836<\/a><br><br><strong>Hejdukov\u00e1 E.<\/strong>, Pushkareva E., Kv\u00edderov\u00e1 J., Becker B. &amp; Elster J. (2025): Summer and autumn photosynthetic activity in High Arctic biological soil crusts and their winter recovery.\u00a0<em>Frontiers in Microbiology<\/em>\u00a016: 1684649.<br><a href=\"https:\/\/doi.org\/10.3389\/fmicb.2025.1684649\">DOI: 10.3389\/fmicb.2025.1684649<\/a><br><br><strong>Kochoska H.<\/strong>, <strong>Koll\u00e1r J.<\/strong>, <strong>Kopalov\u00e1 K.<\/strong>, Styllas M., Ezzat L., Michoud G., Peter H., Bourquin M., Busi S., <br>Hamilton P.B., Battin T.J. &amp; <strong>Kohler T.J.<\/strong> (2025): Glacier-fed stream diatoms (Bacillariophyta) from the Rwenzori Mountains, Uganda, with description of one new species from the genus <em>Neidium<\/em>. <em>Diatom Research<\/em> 40(3): 237-258. <a href=\"https:\/\/doi.org\/10.1080\/0269249X.2025.2474765\" data-type=\"link\" data-id=\"https:\/\/doi.org\/10.1080\/0269249X.2025.2474765\">DOI: 10.1080\/0269249X.2025.2474765<\/a><br><br>Bourquin M., Peter H., Michoud G., Busi S.B, <strong>Kohler T.J.<\/strong>, Robison A.L., Styllas M., Ezzat L., Geers A.U., Huss M., Fodelianakis S., The Vanishing Glaciers Field Team &amp; Battin T.J. (2025). Predicting climate-change impacts on the global glacier-fed stream microbiome. <em>Nature Communications<\/em> 16(1): 1264. <a href=\"https:\/\/www.nature.com\/articles\/s41467-025-56426-4#article-info\" data-type=\"link\" data-id=\"https:\/\/www.nature.com\/articles\/s41467-025-56426-4#article-info\">DOI: 10.1038\/s41467-025-56426-4<\/a><br><br>Kl\u00edmov\u00e1 P., <strong>Kohler T.J.<\/strong>, Van de Vijver B. &amp; <strong>Kopalov\u00e1 K<\/strong>. (2025). Moss-inhabiting diatom (Bacillariophyta) communities from Gough Island, Southern Atlantic Ocean. <em>Nova Hedwigia<\/em> 120(1-4): 473\u2013511. <a href=\"https:\/\/www.schweizerbart.de\/papers\/nova_hedwigia\/detail\/prepub\/106348\/Moss_inhabiting_diatom_Bacillariophyta_communities?af=crossref\" data-type=\"link\" data-id=\"https:\/\/www.schweizerbart.de\/papers\/nova_hedwigia\/detail\/prepub\/106348\/Moss_inhabiting_diatom_Bacillariophyta_communities?af=crossref\">DOI: 10.1127\/nova_hedwigia\/2025\/0989<br><\/a><br><strong>Koll\u00e1r J.<\/strong>, <strong>Kopalov\u00e1 K.<\/strong> &amp; <strong>Kohler T. J.<\/strong> (2025) Diatom studies three decades into the molecular age: a bibliometric analysis reveals genetic underexploration of diatoms compared to other taxa. <em>Fottea<\/em> 25(1): 1-11.<em> <\/em><a href=\"https:\/\/fottea.czechphycology.cz\/corproof.php?tartkey=fot-000000-0584\" data-type=\"link\" data-id=\"https:\/\/fottea.czechphycology.cz\/corproof.php?tartkey=fot-000000-0584\">DOI: 10.5507\/fot.2024.009<\/a><br><br>Geers A.U., Michoud G., Busi S.B., Peter H., <strong>Kohler T.J.<\/strong>, Ezzat L., The Vanishing Glaciers Field Team &amp; T.J. Battin. (2025) Deciphering the biosynthetic landscape of biofilms in glacier-fed streams. <em>mSystems<\/em> 10(2): e01137-\u200c24. <a href=\"https:\/\/journals.asm.org\/doi\/10.1128\/msystems.01137-24\" data-type=\"link\" data-id=\"https:\/\/journals.asm.org\/doi\/10.1128\/msystems.01137-24\">DOI: 10.1128\/msystems.01137-24<\/a><br><br>Michoud G., Busi S.B., Bourquin M., Peter H., <strong>Kohler <strong>T.J.<\/strong><\/strong>, Geers A., Ezzat L., The Vanishing Glaciers Field Team &amp; Battin T.J. (2025) Mapping the metagenomic diversity of the multi-kingdom glacier-fed stream microbiome. <em>Nature Microbiology<\/em> 10(1): 217\u2013230. <a href=\"https:\/\/www.nature.com\/articles\/s41564-024-01874-9\" data-type=\"link\" data-id=\"https:\/\/www.nature.com\/articles\/s41564-024-01874-9\">DOI: 10.1038\/s41564-024-01874-9<\/a><br><br>Ezzat L., Peter H., Bourquin M., Busi S.B., Michoud G., Fodelianakis S., <strong>Kohler T.J.<\/strong>, Lamy T., Geers A., Pramateftaki P., Baier F., Marasco R., Daffonchio D., Deluigi N., Wilmes P., Styllas M., Sch\u00f6n M., Tolosano M., De Staercke V. &amp; Battin T.J. (2025) Diversity and biogeography of the bacterial microbiome in glacier-fed streams. <em>Nature<\/em> 637(8046): 622\u2013630. <a href=\"https:\/\/www.nature.com\/articles\/s41586-024-08313-z\" data-type=\"link\" data-id=\"https:\/\/www.nature.com\/articles\/s41586-024-08313-z\">DOI: 0.1038\/s41586-024-08313-z<\/a><br><br>Goeyers C., Van de Vijver B., <strong>Kohler T.J.<\/strong>, Verleyen E., Tytgat B., Gradstein R.S. &amp; K. Sabbe. (2025) Local and regional, not latitudinal, variation in microclimate and bedrock shapes moss-associated diatom communities in Greenland. <em>Journal of Biogeography<\/em> 52(2): 479\u2013494. <a href=\"https:\/\/onlinelibrary.wiley.com\/doi\/10.1111\/jbi.15050\" data-type=\"link\" data-id=\"https:\/\/onlinelibrary.wiley.com\/doi\/10.1111\/jbi.15050\">DOI: 10.1111\/jbi.15050<\/a><\/p><\/div><\/div>\n\n\n\n<div class=\"wp-block-uagb-faq-child uagb-faq-child__outer-wrap uagb-faq-item uagb-block-b3a556ca\" role=\"tab\" tabindex=\"0\"><div class=\"uagb-faq-questions-button uagb-faq-questions\"><span class=\"uagb-icon uagb-faq-icon-wrap\"><svg xmlns=\"https:\/\/www.w3.org\/2000\/svg\" viewBox=\"0 0 384 512\"><path d=\"M192 384c-8.188 0-16.38-3.125-22.62-9.375l-160-160c-12.5-12.5-12.5-32.75 0-45.25s32.75-12.5 45.25 0L192 306.8l137.4-137.4c12.5-12.5 32.75-12.5 45.25 0s12.5 32.75 0 45.25l-160 160C208.4 380.9 200.2 384 192 384z\"><\/path><\/svg><\/span><span class=\"uagb-icon-active uagb-faq-icon-wrap\"><svg xmlns=\"https:\/\/www.w3.org\/2000\/svg\" viewBox=\"0 0 384 512\"><path d=\"M352 352c-8.188 0-16.38-3.125-22.62-9.375L192 205.3l-137.4 137.4c-12.5 12.5-32.75 12.5-45.25 0s-12.5-32.75 0-45.25l160-160c12.5-12.5 32.75-12.5 45.25 0l160 160c12.5 12.5 12.5 32.75 0 45.25C368.4 348.9 360.2 352 352 352z\"><\/path><\/svg><\/span><h4 class=\"uagb-question\">2024<\/h4><\/div><div class=\"uagb-faq-content\"><p>Pushkareva E., <strong>Hejdukov\u00e1 E.<\/strong>, Elster J. &amp; Becker B. (2024) Microbial response to seasonal variation in Arctic biocrusts with a focus on fungi and cyanobacteria. <em>Environmental Research<\/em> 263(2): 1\u20139. <a href=\"https:\/\/doi.org\/10.1016\/j.envres.2024.120110\">DOI: 10.1016\/j.envres.2024.120110<\/a><br><br>Goeyers, C., K. Sabbe, E. Verleyen, P.B. Hamilton, <strong>T.J. Kohler<\/strong> &amp; B. Van de Vijver. (2024) The genus <em>Humidophila <\/em>(Bacillariophyta) in Greenland with the description of 2 new species. <em>Fottea <\/em>24(2): 198\u2013221. <a href=\"https:\/\/fottea.czechphycology.cz\/artkey\/fot-202402-0003_the_genus_humidophila_bacillariophyta_in_greenland_with_the_description_of_2_new_species.php\" data-type=\"link\" data-id=\"https:\/\/fottea.czechphycology.cz\/artkey\/fot-202402-0003_the_genus_humidophila_bacillariophyta_in_greenland_with_the_description_of_2_new_species.php\">DOI: 10.5507\/fot.2024.004<\/a><br><br><strong>Hejdukov\u00e1 E.<\/strong>, <strong>Koll\u00e1r J<\/strong>. &amp; Nedbalov\u00e1 L. (2024) Freezing stress tolerance of benthic freshwater diatoms from the genus <em>Pinnularia<\/em>: comparison of strains from polar, alpine and temperate habitats. <em>Journal of Phycology<\/em> 60: 1105-1120. <a href=\"https:\/\/doi.org\/10.1111\/jpy.13486\" data-type=\"link\" data-id=\"https:\/\/doi.org\/10.1111\/jpy.13486\">DOI: 10.1111\/jpy.13486<\/a><br><br>Roman M., P\u00ed\u0161kov\u00e1 A., Sanderson D.C., Cresswell A.J., Bul\u00ednov\u00e1 M., Pokorn\u00fd M., Kavan J., Jennings S.J., Lirio J.M., Nedbalov\u00e1 L., Sacherov\u00e1 V., <strong>Kopalov\u00e1 K.<\/strong>, Glasser N.F. &amp; N\u00fdvlt D. (2024). The Late-Holocene deglaciation of James Ross Island, Antarctic Peninsula: OSL and 14C-dated multi-proxy sedimentary record from Monolith Lake. <em>Quaternary Science Reviews<\/em> 333: 108693. <a href=\"https:\/\/www.sciencedirect.com\/science\/article\/pii\/S027737912400194X\" data-type=\"link\" data-id=\"https:\/\/www.sciencedirect.com\/science\/article\/pii\/S027737912400194X\">DOI: 10.1016\/j.quascirev.2024.108693<\/a><br><br>Stanish L.F., <strong>Kohler <strong>T.J.<\/strong><\/strong>, Darling J., &amp; McKnight D.M. (2024). Drifting along: Using diatoms to track the contribution of microbial mats to particulate organic matter transport in a glacial meltwater stream in the McMurdo Dry Valleys, Antarctica. <em>Frontiers in Microbiology<\/em> 15: 1352666. <a href=\"https:\/\/www.frontiersin.org\/journals\/microbiology\/articles\/10.3389\/fmicb.2024.1352666\/abstract\" data-type=\"link\" data-id=\"https:\/\/www.frontiersin.org\/journals\/microbiology\/articles\/10.3389\/fmicb.2024.1352666\/abstract\">DOI: 10.3389\/fmicb.2024.1352666<\/a><br><br><strong>Kohler T.J.<\/strong>, Bourquin M., Peter H., Yvon-Durocher G., Sinsabaugh R.L., Deluigi N., Styllas M., Vanishing Glaciers Field Team &amp; Battin T.J. (2024). Global emergent responses of stream microbial metabolism to glacier shrinkage. <em>Nature Geoscience<\/em> 17: 309\u2013315. <a href=\"https:\/\/www.nature.com\/articles\/s41561-024-01393-6\" data-type=\"link\" data-id=\"https:\/\/www.nature.com\/articles\/s41561-024-01393-6\">DOI: 10.1038\/s41561-024-01393-6<\/a><br><br>Busi S.B., Peter H., Brandani J., <strong>Kohler T.J.<\/strong>, Fodelianakis S., Pramateftaki P., Bourquin M., Michoud G., Ezzat L., Lane S., Wilmes P. &amp; Battin T.J. (2024) Cross-domain interactions confer stability to benthic biofilms in proglacial streams. <em>Frontiers in Microbiomes<\/em> 2: 1280809. <a href=\"https:\/\/www.frontiersin.org\/articles\/10.3389\/frmbi.2023.1280809\/full\" data-type=\"link\" data-id=\"https:\/\/www.frontiersin.org\/articles\/10.3389\/frmbi.2023.1280809\/full\">DOI: 10.3389\/frmbi.2023.1280809<\/a><\/p><\/div><\/div>\n\n\n\n<div class=\"wp-block-uagb-faq-child uagb-faq-child__outer-wrap uagb-faq-item uagb-block-9257779f\" role=\"tab\" tabindex=\"0\"><div class=\"uagb-faq-questions-button uagb-faq-questions\"><span class=\"uagb-icon uagb-faq-icon-wrap\"><svg xmlns=\"https:\/\/www.w3.org\/2000\/svg\" viewBox=\"0 0 384 512\"><path d=\"M192 384c-8.188 0-16.38-3.125-22.62-9.375l-160-160c-12.5-12.5-12.5-32.75 0-45.25s32.75-12.5 45.25 0L192 306.8l137.4-137.4c12.5-12.5 32.75-12.5 45.25 0s12.5 32.75 0 45.25l-160 160C208.4 380.9 200.2 384 192 384z\"><\/path><\/svg><\/span><span class=\"uagb-icon-active uagb-faq-icon-wrap\"><svg xmlns=\"https:\/\/www.w3.org\/2000\/svg\" viewBox=\"0 0 384 512\"><path d=\"M352 352c-8.188 0-16.38-3.125-22.62-9.375L192 205.3l-137.4 137.4c-12.5 12.5-32.75 12.5-45.25 0s-12.5-32.75 0-45.25l160-160c12.5-12.5 32.75-12.5 45.25 0l160 160c12.5 12.5 12.5 32.75 0 45.25C368.4 348.9 360.2 352 352 352z\"><\/path><\/svg><\/span><h4 class=\"uagb-question\">2023<\/h4><\/div><div class=\"uagb-faq-content\"><p>Brandani J., Peter H., Fodelianakis S., <strong>Kohler T.J.<\/strong>, Bourquin M., Michoud G., Busi S.B., Ezzat L., Lane S. &amp; Battin T.J. 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(2023) Glacier-fed stream biofilms harbour diverse resistomes and biosynthetic gene clusters. <em>Microbiology Spectrum<\/em> 11(1): e04069-22. <a href=\"https:\/\/journals.asm.org\/doi\/full\/10.1128\/spectrum.04069-22\" data-type=\"link\" data-id=\"https:\/\/journals.asm.org\/doi\/full\/10.1128\/spectrum.04069-22\">DOI: 10.1128\/spectrum.04069-22<\/a><br><br><strong>Kohler T.J.<\/strong>, Singley J.G., Wlostowski A.N. &amp; McKnight D.M. (2023) Nitrogen fixation facilitates stream microbial mat biomass across the McMurdo Dry Valleys, Antarctica. <em>Biogeochemistry<\/em> 166: 247\u2013268. <a href=\"https:\/\/link.springer.com\/article\/10.1007\/s10533-023-01069-0#article-info\" data-type=\"link\" data-id=\"https:\/\/link.springer.com\/article\/10.1007\/s10533-023-01069-0#article-info\">DOI: 10.1007\/s10533-023-01069-0<br><\/a><br><strong>Koll\u00e1r J.<\/strong>, <strong>Kopalov\u00e1 K.<\/strong>, Kavan J., Vrbick\u00e1 K., N\u00fdvlt D., Nedbalov\u00e1 L., Stibal M. &amp; <strong>Kohler T.J.<\/strong> (2023) Recently-formed Antarctic lakes host less diverse bacterial and diatom communities than their older counterparts. <em>FEMS Microbiology Ecology<\/em><a> <\/a>99(9): fiad087. <a href=\"https:\/\/academic.oup.com\/femsec\/article\/99\/9\/fiad087\/7233717\" data-type=\"link\" data-id=\"https:\/\/academic.oup.com\/femsec\/article\/99\/9\/fiad087\/7233717\">DOI: 10.1093\/femsec\/fiad087<\/a><br><br>Michoud G, <strong>Kohler T.J.<\/strong>, Ezzat L., Peter H., Kigongo Nattabi J., Nalwanga R., Pramateftaki P., Styllas M., Tolosano M., De Staercke V., Sch\u00f6n M., Marasco R., Daffonchio D., Bourquin M., Busi S.B. &amp; Battin T.J. (2023) The dark side of the moon: first insights into the microbiome structure and function of one of the last glacier-fed streams in Africa. <em>Royal Society Open Science <\/em>10(8): 230329. <a href=\"https:\/\/royalsocietypublishing.org\/doi\/full\/10.1098\/rsos.230329\" data-type=\"link\" data-id=\"https:\/\/royalsocietypublishing.org\/doi\/full\/10.1098\/rsos.230329\">DOI: 10.1098\/rsos.230329<\/a><br><br>Michoud G., <strong>Kohler T.J.<\/strong>, Peter H., Brandani J., Busi S.B. &amp; Battin T.J. (2023) Unexpected functional diversity of stream biofilms within and across proglacial floodplains despite close spatial proximity. <em>Limnology and Oceanography <\/em>68(9): 2183-2194. <a href=\"https:\/\/aslopubs.onlinelibrary.wiley.com\/doi\/full\/10.1002\/lno.12415\" data-type=\"link\" data-id=\"https:\/\/aslopubs.onlinelibrary.wiley.com\/doi\/full\/10.1002\/lno.12415\">DOI: 10.1002\/lno.12415<\/a><br><br>Tytgat B., Verleyen E., Sweetlove M., Van den Berge K.,\u00a0Pinseel E., Hodgson D.A., Chown S.L., Sabbe K., Wilmotte A., Willems A., <strong>Polar lake Sampling Consortium<\/strong>, Vyverman W.\u00a0(2023)\u00a0Polar lake microbiomes have distinct evolutionary histories. <em>Science Advances<\/em> 9(46): eade7130. <a href=\"https:\/\/www.science.org\/doi\/full\/10.1126\/sciadv.ade7130#abstract\" data-type=\"link\" data-id=\"https:\/\/www.science.org\/doi\/full\/10.1126\/sciadv.ade7130#abstract\">DOI: 10.1126\/sciadv.ade7130<\/a><\/p><\/div><\/div>\n\n\n\n<div class=\"wp-block-uagb-faq-child uagb-faq-child__outer-wrap uagb-faq-item uagb-block-a6c7f612\" role=\"tab\" tabindex=\"0\"><div class=\"uagb-faq-questions-button uagb-faq-questions\"><span class=\"uagb-icon uagb-faq-icon-wrap\"><svg xmlns=\"https:\/\/www.w3.org\/2000\/svg\" viewBox=\"0 0 384 512\"><path d=\"M192 384c-8.188 0-16.38-3.125-22.62-9.375l-160-160c-12.5-12.5-12.5-32.75 0-45.25s32.75-12.5 45.25 0L192 306.8l137.4-137.4c12.5-12.5 32.75-12.5 45.25 0s12.5 32.75 0 45.25l-160 160C208.4 380.9 200.2 384 192 384z\"><\/path><\/svg><\/span><span class=\"uagb-icon-active uagb-faq-icon-wrap\"><svg xmlns=\"https:\/\/www.w3.org\/2000\/svg\" viewBox=\"0 0 384 512\"><path d=\"M352 352c-8.188 0-16.38-3.125-22.62-9.375L192 205.3l-137.4 137.4c-12.5 12.5-32.75 12.5-45.25 0s-12.5-32.75 0-45.25l160-160c12.5-12.5 32.75-12.5 45.25 0l160 160c12.5 12.5 12.5 32.75 0 45.25C368.4 348.9 360.2 352 352 352z\"><\/path><\/svg><\/span><h4 class=\"uagb-question\">2022<\/h4><\/div><div class=\"uagb-faq-content\"><p>Bourquin M., Busi S.B., Fodelianakis S., Peter H., Washburne A., <strong>Kohler T.J.<\/strong>, Ezzat L., Wilmes P. &amp; Battin T.J. 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(2022) Spatial patterns of benthic biofilm diversity among streams draining proglacial floodplains. <em>Frontiers in Microbiology<\/em> 13: 948165. <a href=\"https:\/\/www.frontiersin.org\/articles\/10.3389\/fmicb.2022.948165\/full\" data-type=\"link\" data-id=\"https:\/\/www.frontiersin.org\/articles\/10.3389\/fmicb.2022.948165\/full\">DOI: 10.3389\/fmicb.2022.948165<\/a><br><br>Busi S.B., Bourquin M., Fodelianakis S., Michoud G., <strong>Kohler<\/strong> <strong>T.J.<\/strong>, Peter H., Pramateftaki P., Styllas M., Tolosano M., de Staercke V., Sch\u00f6n M., de Nies L., Marasco R., Daffonchio D., Ezzat L., Wilmes P. &amp; Battin T.J. (2022) Genomic and metabolic adaptations of biofilms to ecological windows of opportunities in glacier-fed streams. <em>Nature Communications<\/em> 13: 2168. <a href=\"https:\/\/www.nature.com\/articles\/s41467-022-29914-0\" data-type=\"link\" data-id=\"https:\/\/www.nature.com\/articles\/s41467-022-29914-0\">DOI: 10.1038\/s41467-022-29914-0<\/a><br><br>Chattov\u00e1 B., Cahov\u00e1 T., Pinseel E., <strong>Kopalov\u00e1 K.<\/strong>, <strong>Kohler T.J.<\/strong>, Hrb\u00e1\u010dek F., Van de Vijver B. &amp; N\u00fdvlt D. (2022) Diversity, ecology, and community structure of the terrestrial diatom flora from Ulu Peninsula (James Ross Island, NE Antarctic Peninsula). <em>Polar Biology <\/em>45(5): 873\u2013894. <a href=\"https:\/\/link.springer.com\/article\/10.1007\/s00300-022-03038-z\" data-type=\"link\" data-id=\"https:\/\/link.springer.com\/article\/10.1007\/s00300-022-03038-z\">DOI: 10.1007\/s00300-022-03038-z<\/a><br><br>Ezzat L., Fodelianakis S., <strong>Kohler T.J.<\/strong>, Bourquin M., Brandani J., Busi S.B., Daffonchio D., de Staercke V., Marasco R., Michoud G., Oppliger E., Peter H., Pramateftaki P., Sch\u00f6n M., Styllas M., Tadei V., Tolosano M. &amp; Battin T.J. (2022) Benthic biofilms in glacier-fed streams from Scandinavia to the Himalayas host distinct bacterial communities compared to the streamwater. <em>Applied and Environmental Microbiology <\/em>88(12): e00421-22.\u00a0<a href=\"https:\/\/journals.asm.org\/doi\/full\/10.1128\/aem.00421-22\" data-type=\"link\" data-id=\"https:\/\/journals.asm.org\/doi\/full\/10.1128\/aem.00421-22\">DOI: 10.1128\/aem.00421-22<\/a><br><br>Fodelianakis S., Washburne A.D., Bourquin M., Pramateftaki P., <strong>Kohler T.J.<\/strong>, Styllas M., Tolosano M., de Staercke V., Sch\u00f6n M., Busi S.B., Brandani J., Wilmes P., Peter H. &amp; Battin T.J. (2022) Microdiversity characterizes prevalent phylogenetic clades in the glacier-fed stream microbiome. <em>The ISME Journal <\/em>16: 666\u2013675. <a href=\"https:\/\/www.nature.com\/articles\/s41396-021-01106-6\" data-type=\"link\" data-id=\"https:\/\/www.nature.com\/articles\/s41396-021-01106-6\">DOI: 10.1038\/s41396-021-01106-6<\/a><br><br><strong>Kohler T.J.<\/strong>, Fodelianakis S., Michoud G., Ezzat L., Bourquin M., Peter H., Busi S.B., Pramateftaki P., Deluigi N., Styllas M., Tolosano M., de Staercke V., Sch\u00f6n M., Brandani J., Marasco R., Daffonchio D., Wilmes P. &amp; Battin T.J. 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(2022) On the relativity of species, or the probabilistic solution to the species problem. <em>Molecular Ecology<\/em> 31: 411-418. <a href=\"https:\/\/onlinelibrary.wiley.com\/doi\/full\/10.1111\/mec.16218\" data-type=\"link\" data-id=\"https:\/\/onlinelibrary.wiley.com\/doi\/full\/10.1111\/mec.16218\">DOI: 0.1111\/mec.16218<\/a><br><br>Roncoroni M., Mancini D., <strong>Kohler T.J.<\/strong>, Miesen F., Gianini M., Battin T.J. &amp; Lane S.N.<sup> <\/sup>(2022) Centimeter-scale mapping of phototrophic biofilms in glacial forefields using visible band ratios and UAV imagery. <em>International Journal of Remote Sensing <\/em>43(13): 4723-4757. <a href=\"https:\/\/www.tandfonline.com\/doi\/full\/10.1080\/01431161.2022.2079963\" data-type=\"link\" data-id=\"https:\/\/www.tandfonline.com\/doi\/full\/10.1080\/01431161.2022.2079963\">DOI: 10.1080\/01431161.2022.2079963<\/a><br><br>Vin\u0161ov\u00e1 P., <strong>Kohler<\/strong> <strong>T.J.<\/strong>, Simpson M.J., Hajdas I., Yde J.C., Falteisek L., \u017d\u00e1rsk\u00fd J.D., Yuan T., Tejneck\u00fd V., Mercl F., Hood E. &amp; Stibal M. (2022) The biogeochemical legacy of Arctic subglacial sediments exposed by glacier retreat. <em>Global Biogeochemical Cycles <\/em>36(3): e2021GB007126. <a href=\"https:\/\/agupubs.onlinelibrary.wiley.com\/doi\/full\/10.1029\/2021GB007126?casa_token=81SYiPbXo_QAAAAA%3AKTPW63KB3XKjQwCtCK2_l6SS6IV1L54Wu32LnVlcPDea0x2FJlywMuhe63fvHvTk8tT0ZQqEuFb3joc\" data-type=\"link\" data-id=\"https:\/\/agupubs.onlinelibrary.wiley.com\/doi\/full\/10.1029\/2021GB007126?casa_token=81SYiPbXo_QAAAAA%3AKTPW63KB3XKjQwCtCK2_l6SS6IV1L54Wu32LnVlcPDea0x2FJlywMuhe63fvHvTk8tT0ZQqEuFb3joc\">DOI: 10.1029\/2021GB007126<\/a><br><br>Vrbick\u00e1 K., <strong>Kohler T.J.<\/strong>, Falteisek L., Hawkings J.R., Vin\u0161ov\u00e1 P., Bul\u00ednova M., Lamarche-Gagnon G., Hofer S., Kellerman A.M., Holt A.D., Cameron K.A., Sch\u00f6n M., Wadham J.L. &amp; Stibal M. (2022) Catchment characteristics and seasonality control the composition of microbial assemblages exported from three outlet glaciers of the Greenland Ice Sheet. <em>Frontiers in Microbiology<\/em> 13: 1035197. <a href=\"https:\/\/www.frontiersin.org\/articles\/10.3389\/fmicb.2022.1035197\/full\" data-type=\"link\" data-id=\"https:\/\/www.frontiersin.org\/articles\/10.3389\/fmicb.2022.1035197\/full\">DOI: 10.3389\/fmicb.2022.1035197<\/a><\/p><\/div><\/div>\n\n\n\n<div class=\"wp-block-uagb-faq-child uagb-faq-child__outer-wrap uagb-faq-item uagb-block-a7f67d35\" role=\"tab\" tabindex=\"0\"><div class=\"uagb-faq-questions-button uagb-faq-questions\"><span class=\"uagb-icon uagb-faq-icon-wrap\"><svg xmlns=\"https:\/\/www.w3.org\/2000\/svg\" viewBox=\"0 0 384 512\"><path d=\"M192 384c-8.188 0-16.38-3.125-22.62-9.375l-160-160c-12.5-12.5-12.5-32.75 0-45.25s32.75-12.5 45.25 0L192 306.8l137.4-137.4c12.5-12.5 32.75-12.5 45.25 0s12.5 32.75 0 45.25l-160 160C208.4 380.9 200.2 384 192 384z\"><\/path><\/svg><\/span><span class=\"uagb-icon-active uagb-faq-icon-wrap\"><svg xmlns=\"https:\/\/www.w3.org\/2000\/svg\" viewBox=\"0 0 384 512\"><path d=\"M352 352c-8.188 0-16.38-3.125-22.62-9.375L192 205.3l-137.4 137.4c-12.5 12.5-32.75 12.5-45.25 0s-12.5-32.75 0-45.25l160-160c12.5-12.5 32.75-12.5 45.25 0l160 160c12.5 12.5 12.5 32.75 0 45.25C368.4 348.9 360.2 352 352 352z\"><\/path><\/svg><\/span><h4 class=\"uagb-question\">2021<\/h4><\/div><div class=\"uagb-faq-content\"><p>Bishop J.M., Wasley J., Waterman M.J., <strong>Kohler T.J.<\/strong>, Van de Vijver B., Robinson S.A.\u00a0&amp;\u00a0 <strong>Kopalov\u00e1 K<\/strong>. (2021) Diatom communities differ among Antarctic moss and lichen vegetation types. <em>Antarctic Science<\/em> 33(2): 118\u2013132. <a href=\"https:\/\/www.cambridge.org\/core\/journals\/antarctic-science\/article\/abs\/diatom-communities-differ-among-antarctic-moss-and-lichen-vegetation-types\/BD954AA77C477537CB6B747181093FC4\" data-type=\"link\" data-id=\"https:\/\/www.cambridge.org\/core\/journals\/antarctic-science\/article\/abs\/diatom-communities-differ-among-antarctic-moss-and-lichen-vegetation-types\/BD954AA77C477537CB6B747181093FC4\">DOI: 10.1017\/S0954102020000620<br><\/a><br>Hawkings J.R., Linhoff B.S., Wadham J.L., Stibal M., Lamborg C.H., Carling G.T., Falteisek L., Ward R., Hendry K.R., Lamarche-Gagnon G., <strong>Kohler T.J.<\/strong>, Kellerman A.M., Cameron K., Hatton J.E., Tingey S., Holt A., Vin\u0161ov\u00e1 P., Hofer S., Bul\u00ednov\u00e1 M., V\u011btrovsk\u00fd T., Meire L. &amp; Spencer R.G.M. (2021) Large subglacial source of mercury from the southwestern margin of the Greenland Ice Sheet. <em>Nature Geoscience <\/em>14: 496\u2013502. <a href=\"https:\/\/www.nature.com\/articles\/s41561-021-00753-w\" data-type=\"link\" data-id=\"https:\/\/www.nature.com\/articles\/s41561-021-00753-w\">DOI: 10.1038\/s41561-021-00753-w<\/a><br><br><strong>Hejdukov\u00e1 E.<\/strong> &amp; Nedbalov\u00e1 L. (2021) Experimental freezing of freshwater pennate diatoms from polar habitats. <em>Protoplasma<\/em> 258(6): 1213-1229. <a href=\"https:\/\/link.springer.com\/article\/10.1007\/s00709-021-01648-8\" data-type=\"link\" data-id=\"https:\/\/link.springer.com\/article\/10.1007\/s00709-021-01648-8\">DOI:\u00a010.1007\/s00709-021-01648-8<\/a><br><br><strong>Koll\u00e1r J.<\/strong>, Pinseel E., Vyverman W. &amp; Poul\u00ed\u010dkov\u00e1 A. (2021) A time-calibrated phylogeny provides an insight into the evolution, taxonomy and DNA barcoding of the <em>Pinnularia subgibba<\/em> group (Bacillariophyta). <em>Fottea<\/em> 21(1): 62-72. <a href=\"https:\/\/fottea.czechphycology.cz\/artkey\/fot-202101-0007_a_time-calibrated_multi-gene_phylogeny_provides_insights_into_the_evolution_taxonomy_and_dna_barcoding_of_the.php\" data-type=\"link\" data-id=\"https:\/\/fottea.czechphycology.cz\/artkey\/fot-202101-0007_a_time-calibrated_multi-gene_phylogeny_provides_insights_into_the_evolution_taxonomy_and_dna_barcoding_of_the.php\">DOI: 10.5507\/fot.2020.017<\/a><br><br><strong>Kohler T.J.<\/strong>, Howkins A.,\u00a0Sokol E.R., <strong>Kopalov\u00e1 K.<\/strong>, Cox A.,\u00a0Darling J.P.,\u00a0Gooseff M.N.\u00a0&amp; \u00a0McKnight D.M. 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(2019).\u00a0Kuannersuit Glacier revisited: Constraining ice dynamics, landform formations and glaciomorphological changes in the early quiescent phase following the 1995-98 surge event. <em>Geomorphology<\/em> 330: 89\u201399. <a href=\"https:\/\/www.sciencedirect.com\/science\/article\/pii\/S0169555X19300121?casa_token=sDbILZyjs0QAAAAA:IFYL3J0fw62u8PjECBwg1UU6Vs6UlQIPAsI9wwdW_H3i81f54H-nbwYvg8VlSu6VtDtzro7OpQ\" data-type=\"link\" data-id=\"https:\/\/www.sciencedirect.com\/science\/article\/pii\/S0169555X19300121?casa_token=sDbILZyjs0QAAAAA:IFYL3J0fw62u8PjECBwg1UU6Vs6UlQIPAsI9wwdW_H3i81f54H-nbwYvg8VlSu6VtDtzro7OpQ\">DOI: 10.1016\/j.geomorph.2019.01.012<\/a><\/p><\/div><\/div>\n\n\n\n<div class=\"wp-block-uagb-faq-child uagb-faq-child__outer-wrap uagb-faq-item uagb-block-8a0571f4\" role=\"tab\" tabindex=\"0\"><div class=\"uagb-faq-questions-button uagb-faq-questions\"><span class=\"uagb-icon uagb-faq-icon-wrap\"><svg xmlns=\"https:\/\/www.w3.org\/2000\/svg\" viewBox=\"0 0 384 512\"><path d=\"M192 384c-8.188 0-16.38-3.125-22.62-9.375l-160-160c-12.5-12.5-12.5-32.75 0-45.25s32.75-12.5 45.25 0L192 306.8l137.4-137.4c12.5-12.5 32.75-12.5 45.25 0s12.5 32.75 0 45.25l-160 160C208.4 380.9 200.2 384 192 384z\"><\/path><\/svg><\/span><span class=\"uagb-icon-active uagb-faq-icon-wrap\"><svg xmlns=\"https:\/\/www.w3.org\/2000\/svg\" viewBox=\"0 0 384 512\"><path d=\"M352 352c-8.188 0-16.38-3.125-22.62-9.375L192 205.3l-137.4 137.4c-12.5 12.5-32.75 12.5-45.25 0s-12.5-32.75 0-45.25l160-160c12.5-12.5 32.75-12.5 45.25 0l160 160c12.5 12.5 12.5 32.75 0 45.25C368.4 348.9 360.2 352 352 352z\"><\/path><\/svg><\/span><h4 class=\"uagb-question\">2018<\/h4><\/div><div class=\"uagb-faq-content\"><p>Bul\u00ednov\u00e1 M., Kochman-K\u0119dziora N., <strong>Kopalov\u00e1 K.<\/strong> &amp; Van de Vijver B. (2018) Three new <em>Hantzschia species<\/em> (Bacillariophyta) from the Maritime Antarctic Region. <em>Phytotaxa<\/em> 371(3): 168\u2013184. <a href=\"https:\/\/www.biotaxa.org\/Phytotaxa\/article\/view\/phytotaxa.371.3.2\" data-type=\"link\" data-id=\"https:\/\/www.biotaxa.org\/Phytotaxa\/article\/view\/phytotaxa.371.3.2\">DOI: 10.11646\/phytotaxa.371.3.2<\/a><br><br>Hawkings J.R., Hatton J., Hendry K.R., De Souza G., Wadham J.L., Ivanovic R.F., <strong>Kohler T.J.<\/strong>, Stibal M., Beaton A., Lamarche-Gagnon G., Tedstone A., Hain M., Bagshaw E., Pike J. &amp; Tranter M. (2018) The silicon cycle impacted by past ice sheets. <em>Nature Communications<\/em> 9(1):\u00a03210. <a href=\"https:\/\/www.nature.com\/articles\/s41467-018-05689-1\" data-type=\"link\" data-id=\"https:\/\/www.nature.com\/articles\/s41467-018-05689-1\">DOI: 10.1038\/s41467-018-05689-1<\/a><br><br>Kulichov\u00e1 J., Neustupa J., Vrbov\u00e1 K., Levkov Z.\u00a0&amp; <strong>Kopalov\u00e1, K<\/strong>. (2018) Asymmetry in <em>Luticola<\/em> species. <em>Diatom Research<\/em> 34(2): 67\u201374. <a href=\"https:\/\/www.tandfonline.com\/doi\/full\/10.1080\/0269249X.2019.1604435?casa_token=K90UGoLYIi0AAAAA%3A4oqZsAonuHBfW9afAthANXCLXCjb9DYQiUgPYhJc-BA2D1sn45hY6Bjvr8nZYeI9iIHOxNK8Xqm7\" data-type=\"link\" data-id=\"https:\/\/www.tandfonline.com\/doi\/full\/10.1080\/0269249X.2019.1604435?casa_token=K90UGoLYIi0AAAAA%3A4oqZsAonuHBfW9afAthANXCLXCjb9DYQiUgPYhJc-BA2D1sn45hY6Bjvr8nZYeI9iIHOxNK8Xqm7\">DOI: 10.1080\/0269249X.2019.1604435<\/a><br><br><strong>Kohler T.J.<\/strong>, Stanish L.F., Liptzin D., Barrett J.E. &amp; McKnight D.M. (2018) Catch and release: hyporheic retention and mineralization of N-fixing Nostoc sustains downstream microbial mat biomass in two polar desert streams. <em>Limnology and Oceanography Letters <\/em>3(4): 357\u2013364. <a href=\"https:\/\/aslopubs.onlinelibrary.wiley.com\/doi\/full\/10.1002\/lol2.10087\" data-type=\"link\" data-id=\"https:\/\/aslopubs.onlinelibrary.wiley.com\/doi\/full\/10.1002\/lol2.10087\">DOI: 10.1002\/lol2.10087<\/a><br><br>Poul\u00ed\u010dkov\u00e1 A., <strong>Koll\u00e1r J.<\/strong>, Ha\u0161ler P., Dvo\u0159\u00e1k P. &amp; Mann D.G. 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(2018) Prokaryotic assemblages in suspended and subglacial sediments within a glacierized catchment on Qeqertarsuaq (Disko Island), west Greenland. <em>FEMS Microbiology Ecology <\/em>94(7): fiy100. <a href=\"https:\/\/academic.oup.com\/femsec\/article\/94\/7\/fiy100\/5017442\" data-type=\"link\" data-id=\"https:\/\/academic.oup.com\/femsec\/article\/94\/7\/fiy100\/5017442\">DOI: 10.1093\/femsec\/fiy100<\/a><\/p><\/div><\/div>\n\n\n\n<div class=\"wp-block-uagb-faq-child uagb-faq-child__outer-wrap uagb-faq-item uagb-block-bd4bd3c6\" role=\"tab\" tabindex=\"0\"><div class=\"uagb-faq-questions-button uagb-faq-questions\"><span class=\"uagb-icon uagb-faq-icon-wrap\"><svg xmlns=\"https:\/\/www.w3.org\/2000\/svg\" viewBox=\"0 0 384 512\"><path d=\"M192 384c-8.188 0-16.38-3.125-22.62-9.375l-160-160c-12.5-12.5-12.5-32.75 0-45.25s32.75-12.5 45.25 0L192 306.8l137.4-137.4c12.5-12.5 32.75-12.5 45.25 0s12.5 32.75 0 45.25l-160 160C208.4 380.9 200.2 384 192 384z\"><\/path><\/svg><\/span><span class=\"uagb-icon-active uagb-faq-icon-wrap\"><svg xmlns=\"https:\/\/www.w3.org\/2000\/svg\" viewBox=\"0 0 384 512\"><path d=\"M352 352c-8.188 0-16.38-3.125-22.62-9.375L192 205.3l-137.4 137.4c-12.5 12.5-32.75 12.5-45.25 0s-12.5-32.75 0-45.25l160-160c12.5-12.5 32.75-12.5 45.25 0l160 160c12.5 12.5 12.5 32.75 0 45.25C368.4 348.9 360.2 352 352 352z\"><\/path><\/svg><\/span><h4 class=\"uagb-question\">2017<\/h4><\/div><div class=\"uagb-faq-content\"><p>Cameron K.A., Stibal M., Hawkings J.R., Mikkelsen A.B., Telling J., <strong>Kohler T.J.<\/strong>, G\u00f6zdereliler E., \u017d\u00e1rsk\u00fd J.D., Wadham J.L. &amp; Jacobsen C.S. 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(2017) Freshwater diatom biogeography and the genus <em>Luticola<\/em>: an extreme case of endemism in Antarctica. <em>Polar Biology<\/em> 40(6): 1185\u20131196. \u00a0<a href=\"https:\/\/link.springer.com\/article\/10.1007\/s00300-017-2090-7\" data-type=\"link\" data-id=\"https:\/\/link.springer.com\/article\/10.1007\/s00300-017-2090-7\">DOI: 10.1007\/s00300-017-2090-7<br><\/a><br><strong>Kohler T.J.<\/strong>, \u017d\u00e1rsk\u00fd J.D., Yde J.C., Lamarche-Gagnon G., Hawkings J.R., Tedstone A.J., Wadham J.L., Box J.E., Beaton A.D. &amp; Stibal M. (2017) Carbon dating reveals a seasonal progression in the source of particulate organic carbon exported from the Greenland Ice Sheet. <em>Geophysical Research Letters <\/em>44(12): 6209\u20136217. <a href=\"https:\/\/agupubs.onlinelibrary.wiley.com\/doi\/full\/10.1002\/2017GL073219\" data-type=\"link\" data-id=\"https:\/\/agupubs.onlinelibrary.wiley.com\/doi\/full\/10.1002\/2017GL073219\">DOI: 10.1002\/2017GL073219<\/a><br><br>Pinseel E., <strong>Hejdukov\u00e1 E.<\/strong>, Vanormelingen P., <strong>Kopalov\u00e1 K.<\/strong>, Vyverman W. &amp; Van de Vijver B. (2017) <em>Pinnularia catenaborealis<\/em> sp. nov. (Bacillariophyceae), a new chain-forming Distantes from James Ross Island and Vega Island (Maritime Antarctica). <em>Phycologia<\/em> 56(1): 94\u2013107. <a href=\"https:\/\/www.tandfonline.com\/doi\/abs\/10.2216\/16-18.1\" data-type=\"link\" data-id=\"https:\/\/www.tandfonline.com\/doi\/abs\/10.2216\/16-18.1\">DOI: 10.2216\/16-18.1<\/a><br><br>Pinseel E., Van de Vijver B., Verleyen E., Kavan J. &amp; <strong>Kopalov\u00e1 K.<\/strong> (2017) Diversity, ecology and community sructure of the freshwater littoral diatom flora from petuniabukta (Spitsbergen). <em>Polar Biology<\/em> 40(3): 533\u2013551. <a href=\"https:\/\/link.springer.com\/article\/10.1007\/s00300-016-1976-0\" data-type=\"link\" data-id=\"https:\/\/link.springer.com\/article\/10.1007\/s00300-016-1976-0\">DOI: 10.1007\/s00300-016-1976-0<\/a><br><br>Pinseel E., Vanormelingen\u00a0 P.,\u00a0Hamilton\u00a0 P.B.,\u00a0 Vyverman W., Van de Vijver B. &amp; <strong>Kopalov\u00e1 K.<\/strong> (2017) Molecular and morphological characterization of the <em>Achnanthidium minutissimum<\/em> complex (Bacillariophyta) in Petuniabukta (Spitsbergen, High Arctic) including the description of <em>A. digitatum<\/em> sp nov. <em>European Journal of Phycology<\/em> 52(3): 264-280. <a href=\"https:\/\/www.tandfonline.com\/doi\/full\/10.1080\/09670262.2017.1283540\" data-type=\"link\" data-id=\"https:\/\/www.tandfonline.com\/doi\/full\/10.1080\/09670262.2017.1283540\">DOI:\u00a010.1080\/09670262.2017.1283540<\/a><br><br>Zandon\u00e0 E., Dalton C., El-Sabaawi R.W., Howard J.L., Marshall M.C., Kilham S.S., Reznick D.N., Travis J., <strong>Kohler T.J.<\/strong>, Flecker A.S., Thomas S.A. &amp; Pringle C.M. (2017) Population variation in the trophic niche of the Trinidadian guppy from different predation regimes. <em>Scientific Reports <\/em>7(1): 5770. <a href=\"https:\/\/www.nature.com\/articles\/s41598-017-06163-6\" data-type=\"link\" data-id=\"https:\/\/www.nature.com\/articles\/s41598-017-06163-6\">DOI: 10.1038\/s41598-017-06163-6<\/a><a href=\"https:\/\/www.tandfonline.com\/doi\/full\/10.1080\/09670262.2017.1283540\" data-type=\"link\" data-id=\"https:\/\/www.tandfonline.com\/doi\/full\/10.1080\/09670262.2017.1283540\"><\/a><\/p><\/div><\/div>\n\n\n\n<div class=\"wp-block-uagb-faq-child uagb-faq-child__outer-wrap uagb-faq-item uagb-block-b0cf87ba\" role=\"tab\" tabindex=\"0\"><div class=\"uagb-faq-questions-button uagb-faq-questions\"><span class=\"uagb-icon uagb-faq-icon-wrap\"><svg xmlns=\"https:\/\/www.w3.org\/2000\/svg\" viewBox=\"0 0 384 512\"><path d=\"M192 384c-8.188 0-16.38-3.125-22.62-9.375l-160-160c-12.5-12.5-12.5-32.75 0-45.25s32.75-12.5 45.25 0L192 306.8l137.4-137.4c12.5-12.5 32.75-12.5 45.25 0s12.5 32.75 0 45.25l-160 160C208.4 380.9 200.2 384 192 384z\"><\/path><\/svg><\/span><span class=\"uagb-icon-active uagb-faq-icon-wrap\"><svg xmlns=\"https:\/\/www.w3.org\/2000\/svg\" viewBox=\"0 0 384 512\"><path d=\"M352 352c-8.188 0-16.38-3.125-22.62-9.375L192 205.3l-137.4 137.4c-12.5 12.5-32.75 12.5-45.25 0s-12.5-32.75 0-45.25l160-160c12.5-12.5 32.75-12.5 45.25 0l160 160c12.5 12.5 12.5 32.75 0 45.25C368.4 348.9 360.2 352 352 352z\"><\/path><\/svg><\/span><h4 class=\"uagb-question\">2016<\/h4><\/div><div class=\"uagb-faq-content\"><p>Collins S.M., <strong>Kohler T.J.<\/strong>, Thomas S.A., Fetzer W.W. &amp; Flecker A.S. (2016) The importance of terrestrial subsidies in stream food webs varies along a stream size gradient. <em>Oikos <\/em>125(5): 674\u2013685. <a href=\"https:\/\/nsojournals.onlinelibrary.wiley.com\/doi\/abs\/10.1111\/oik.02713\" data-type=\"link\" data-id=\"https:\/\/nsojournals.onlinelibrary.wiley.com\/doi\/abs\/10.1111\/oik.02713\">DOI: 10.1111\/oik.02713<\/a><br><br>Hamsher S., <strong>Kopalov\u00e1 K.<\/strong>, Kociolek P.J., Zidarova R. &amp; Van de Vijver B. (2016) The genus <em>Nitzschia<\/em> on the South Shetland Islands and James Ross Island (Maritime Antarctica). <em>Fottea\u00a0<\/em>16(1): 79\u2013102. <a href=\"https:\/\/fottea.czechphycology.cz\/artkey\/fot-201601-0007_The_genus_Nitzschia_on_the_South_Shetland_Islands_and_James_Ross_Island.php\">DOI: 10.5507\/fot.2015.023<\/a><br><br>Kochman-K\u0119dziora N., Noga T., Zidarova R., <strong>Kopalov\u00e1 K. <\/strong>&amp; Van de Vijver B. (2016) <em>Humidophila komarekiana<\/em> sp. nov. (Bacillariophyta), a new limnoterrestrial diatom species from King George Island (Maritime Antarctica). <em>Phytotaxa<\/em> 272(3): 184\u2013190. <a href=\"https:\/\/www.biotaxa.org\/Phytotaxa\/article\/view\/phytotaxa.272.3.2\">DOI: 10.11646\/phytotaxa.272.3.2<\/a><br><br><strong>Kohler T.J.<\/strong>, Van Horn D.J., Darling J.P., Takacs-Vesbach C.D. &amp; McKnight D.M. (2016) Nutrient treatments alter microbial mat colonization in two glacial meltwater streams from the McMurdo Dry Valleys, Antarctica. <em>FEMS Microbiology Ecology <\/em>92(4): fiw049. <a href=\"https:\/\/academic.oup.com\/femsec\/article\/92\/4\/fiw049\/2197973\" data-type=\"link\" data-id=\"https:\/\/academic.oup.com\/femsec\/article\/92\/4\/fiw049\/2197973\">DOI: 10.1093\/femsec\/fiw049<\/a><br><br><strong>Kopalov\u00e1 K.<\/strong>, Zidarova R. &amp; Van de Vijver B. (2016) Four new monoraphid diatom species (Bacillariophyta, Achnanthaceae) from the Maritime Antarctic Region. <em>European Journal of Taxonomy<\/em> 217: 1\u201319. <a href=\"https:\/\/europeanjournaloftaxonomy.eu\/index.php\/ejt\/article\/view\/341\/0\">DOI: 10.5852\/ejt.2016.217<\/a><br><br>Lecomte K.L., Vignoni P., C\u00f3rdoba F.E., Chaparro Marcos A.E., Chaparro Mauro A.E., <strong>Kopalov\u00e1 K.<\/strong>, Gargiulo J.D., Lirio J.M., Irurzun M.A. &amp; B\u00f6hnel H.N. (2016) Hydrological systems from the Antarctic Peninsula under climate change: James Ross Archipelago as study case. <em>Environmental Earth Sciences <\/em>75(7): 623. <a href=\"https:\/\/link.springer.com\/article\/10.1007\/s12665-016-5406-y\">DOI: 10.1007\/s12665-016-5406-y<br><\/a><br>Sakaeva A., Sokol E.R., <strong>Kohler T.J.<\/strong>, Stanish L.F., Spaulding S.A., Howkins A., Welch K.A., Lyons W.B., Barrett J.E. &amp; McKnight D.M. (2016) Evidence for dispersal and habitat controls on pond diatom communities from the McMurdo Sound Region of Antarctica. <em>Polar Biology<\/em> 39(12): 2441\u20132456. <a href=\"https:\/\/link.springer.com\/article\/10.1007\/s00300-016-1901-6\" data-type=\"link\" data-id=\"https:\/\/link.springer.com\/article\/10.1007\/s00300-016-1901-6\">DOI: 10.1007\/s00300-016-1901-6<\/a><br><br>Van de Vijver B., <strong>Kopalov\u00e1 K. <\/strong>&amp; Zidarova R. (2016) Revision of the <em>Psammothidium germainii<\/em> complex (Bacillariophyta) in the Maritime Antarctic Region. <em>Fottea<\/em> 16(2): 145\u2013156. <a href=\"https:\/\/fottea.czechphycology.cz\/artkey\/fot-201602-0001_Revision_of_the_Psammothidium_germainii_complex_Bacillariophyta_in_the_Maritime_Antarctic_Region.php\">DOI:\u00a010.5507\/fot.2016.008<\/a><br><br>Van de Vijver B., <strong>Kopalov\u00e1 K.<\/strong>, Zidarova R. &amp; Kociolek J.P. (2016) Two new <em>Gomphonema<\/em> species (Bacillariophyta) from the Maritime Antarctic Region. <em>Phytotaxa<\/em> 269(3): 209\u2013220. <a href=\"https:\/\/www.biotaxa.org\/Phytotaxa\/article\/view\/phytotaxa.269.3.4\">DOI: 10.11646\/phytotaxa.269.3.4<\/a><br><br>Van Horn D.J., Wolf C.R., Colman D.R., Jiang X., <strong>Kohler T.J.<\/strong>, McKnight D.M., Stanish L.F., Yazzie T. &amp; Takacs-Vesbach C.D. (2016) Patterns of bacterial biodiversity in the glacial meltwater streams of the McMurdo Dry Valleys, Antarctica. <em>FEMS Microbiology Ecology<\/em> 92(10): fiw148. <a href=\"https:\/\/academic.oup.com\/femsec\/article\/92\/10\/fiw148\/2197762\" data-type=\"link\" data-id=\"https:\/\/academic.oup.com\/femsec\/article\/92\/10\/fiw148\/2197762\">DOI:\u00a010.1093\/femsec\/fiw148<\/a><br><br>Vin\u0161ov\u00e1 P., <strong>Kopalov\u00e1 K.<\/strong> &amp; Van de Vijver B. (2016) Morphological observations on <em>Pseudeunotia linearis<\/em> Carter (Bacillariophyta) and its transfer to the genus <em>Eunotia<\/em>. <em>Botany Letters <\/em>163(2): 117-123.<br><br>Zidarova R., <strong>Kopalova<\/strong> <strong>K.<\/strong> &amp; Van de Vijver B. (2016) Diatoms from the Antarctic Region. I: Maritime Antarctica.\u00a0Annotated Diatom Micrograph. Ed. by Horst Lange \u2013 Bertalot. Volume 24: 216 photographic plates. 509 p. Hardcover. (<a href=\"https:\/\/www.koeltz.com\/en\/iconographia-diatomologica24-zidarovaret-aldiatoms-from-the-ant-arctic-regionimaritime-antarctica2016\">ISBN 978-3-946583-05-9<\/a>)<br><br>Zidarova R., <strong>Kopalov\u00e1 K. <\/strong>&amp; Van de Vijver B. (2016) Ten new Bacillariophyta species from James Ross Island and the South Shetland Islands (Maritime Antarctic Region). <em>Phytotaxa<\/em> 272(1): 037\u2013062. <a href=\"https:\/\/www.biotaxa.org\/Phytotaxa\/article\/view\/phytotaxa.272.1.2\">DOI: 10.11646\/phytotaxa.272.1.2<\/a><\/p><\/div><\/div>\n\n\n\n<div class=\"wp-block-uagb-faq-child uagb-faq-child__outer-wrap uagb-faq-item uagb-block-19e0ed08\" role=\"tab\" tabindex=\"0\"><div class=\"uagb-faq-questions-button uagb-faq-questions\"><span class=\"uagb-icon uagb-faq-icon-wrap\"><svg xmlns=\"https:\/\/www.w3.org\/2000\/svg\" viewBox=\"0 0 384 512\"><path d=\"M192 384c-8.188 0-16.38-3.125-22.62-9.375l-160-160c-12.5-12.5-12.5-32.75 0-45.25s32.75-12.5 45.25 0L192 306.8l137.4-137.4c12.5-12.5 32.75-12.5 45.25 0s12.5 32.75 0 45.25l-160 160C208.4 380.9 200.2 384 192 384z\"><\/path><\/svg><\/span><span class=\"uagb-icon-active uagb-faq-icon-wrap\"><svg xmlns=\"https:\/\/www.w3.org\/2000\/svg\" viewBox=\"0 0 384 512\"><path d=\"M352 352c-8.188 0-16.38-3.125-22.62-9.375L192 205.3l-137.4 137.4c-12.5 12.5-32.75 12.5-45.25 0s-12.5-32.75 0-45.25l160-160c12.5-12.5 32.75-12.5 45.25 0l160 160c12.5 12.5 12.5 32.75 0 45.25C368.4 348.9 360.2 352 352 352z\"><\/path><\/svg><\/span><h4 class=\"uagb-question\">2015<\/h4><\/div><div class=\"uagb-faq-content\"><p><strong>Kohler T.J.<\/strong>, Chatfield E., Gooseff M.N., Barrett J.E. &amp; McKnight D.M. (2015) Recovery of Antarctic stream epilithon from simulated scouring events. <em>Antarctic Science<\/em> 27(4): 341\u2013354. <a href=\"https:\/\/www.cambridge.org\/core\/journals\/antarctic-science\/article\/abs\/recovery-of-antarctic-stream-epilithon-from-simulated-scouring-events\/9263E172156ADB7EDDCA5302EBF8D78A\" data-type=\"link\" data-id=\"https:\/\/www.cambridge.org\/core\/journals\/antarctic-science\/article\/abs\/recovery-of-antarctic-stream-epilithon-from-simulated-scouring-events\/9263E172156ADB7EDDCA5302EBF8D78A\">DOI: 10.1017\/S0954102015000024<\/a><br><br><strong>Kohler T.J.<\/strong>, <strong>Kopalov\u00e1 K<\/strong>., Van de Vijver B. &amp; Kociolek J.P. (2015) The genus <em>Luticola<\/em> D.G.Mann (Bacillariophyta) from the McMurdo Sound Region, Antarctica, with the description of 4 new species. <em>Phytotaxa<\/em> 208(2): 103\u2013134. <a href=\"https:\/\/www.biotaxa.org\/Phytotaxa\/article\/view\/phytotaxa.208.2.1\">DOI: 10.11646\/phytotaxa.208.2.1<\/a><br><br><strong>Kohler T.J.<\/strong>, Stanish L.F., Crisp S.W., Koch J.C., Liptzin D., Baeseman J.L. &amp; McKnight D.M. (2015) Life in the main channel: long-term hydrologic control of microbial mat abundance in McMurdo Dry Valley streams, Antarctica. <em>Ecosystems <\/em>18(2): 310\u2013327. <a href=\"https:\/\/link.springer.com\/article\/10.1007\/s10021-014-9829-6\" data-type=\"link\" data-id=\"https:\/\/link.springer.com\/article\/10.1007\/s10021-014-9829-6\">DOI: 10.1007\/s10021-014-9829-6<\/a><br><br><strong>Koll\u00e1r J.<\/strong>, Fr\u00e1nkov\u00e1 M., Ha\u0161ler P., Let\u00e1kov\u00e1 M. &amp; Poul\u00ed\u010dkov\u00e1 A. (2015) Epiphytic diatoms in lotic and lentic waters \u2013 diversity and representation of species complexes. <em>Fottea <\/em>15(2): 259-271. <a href=\"https:\/\/fottea.czechphycology.cz\/artkey\/fot-201502-0011_Epiphytic_diatoms_in_lotic_and_lentic_waters_-_diversity_and_representation_of_species_complexes.php\">DOI:\u00a010.5507\/fot.2015.022<\/a><br><br><strong>Kopalov\u00e1 K.<\/strong>, Kociolek P.J., Lowe R.L., Zidarova R. &amp; Van De Vijver B. (2015) Five new species of the genus <em>Humidophila<\/em> (Bacillariophyta) from the Maritime Antarctic Region. <em>Diatom Research<\/em> 30(2): 117\u2013131. <a href=\"https:\/\/www.tandfonline.com\/doi\/full\/10.1080\/0269249X.2014.998714\">DOI: 10.1080\/0269249X.2014.998714<\/a><br><br>Pinseel E., Van de Vijver B. &amp; <strong>Kopalov\u00e1 K.<\/strong> (2015) <em>Achnanthidium petuniabuktianum<\/em> sp. nov. Achnanthidiaceae, Bacillariophyta), a new representative of the <em>A. pyrenaicum<\/em> group from Spitsbergen (Svalbard Archipelago, High Arctic). <em>Phytotaxa<\/em> 226 (1): 063\u2013074. <a href=\"https:\/\/www.biotaxa.org\/Phytotaxa\/article\/view\/phytotaxa.226.1.6\">DOI: 10.11646\/phytotaxa.226.1.6<\/a><br><br>Van de Vijver B., <strong>Kopalov\u00e1 K.,<\/strong> Kociolek J.P. &amp; Ector L. (2015) <em>Denticula jamesrossensis<\/em>, a new freshwater diatom (Bacillariophyta) species from the Maritime Antarctic Region. <em>Fottea<\/em> 15(1): 105\u2013111. <a href=\"https:\/\/fottea.czechphycology.cz\/artkey\/fot-201501-0009_Denticula_jamesrossensis_a_new_freshwater_diatom_Bacillariophyta_species_from_the_Maritime_Antarctic_Region.php\">DOI:\u00a010.5507\/fot.2015.009<\/a><br><br>Van de Vijver B., <strong>Kopalov\u00e1 K. <\/strong>&amp; Zidarova R. (2015) Three new <em>Craticula<\/em> species (Bacillariophyta) from the Maritime Antarctic Region. <em>Phytotaxa<\/em> 213(1): 035\u2013045. <a href=\"https:\/\/www.biotaxa.org\/Phytotaxa\/article\/view\/phytotaxa.213.1.3\">DOI: 10.11646\/phytotaxa.213.1.3<\/a><br><br>Vin\u0161ov\u00e1 P., Pinseel E., <strong>Kohler T.J.<\/strong>, Van de Vijver B., \u017d\u00e1rsk\u00fd J.D., Kavan J. &amp; <strong>Kopalov\u00e1 K.<\/strong> (2015) Diatoms in cryoconite holes and adjacent proglacial freshwater sediments, Nordenski\u00f6ld glacier (Spitsbergen, High Arctic). <em>Czech Polar Reports <\/em>5(2): 112\u2013133. <a href=\"https:\/\/journals.muni.cz\/CPR\/article\/view\/12871\">DOI: 10.5817\/CPR2015-2-11<\/a><\/p><\/div><\/div>\n\n\n\n<div class=\"wp-block-uagb-faq-child uagb-faq-child__outer-wrap uagb-faq-item uagb-block-436e93ec\" role=\"tab\" tabindex=\"0\"><div class=\"uagb-faq-questions-button uagb-faq-questions\"><span class=\"uagb-icon uagb-faq-icon-wrap\"><svg xmlns=\"https:\/\/www.w3.org\/2000\/svg\" viewBox=\"0 0 384 512\"><path d=\"M192 384c-8.188 0-16.38-3.125-22.62-9.375l-160-160c-12.5-12.5-12.5-32.75 0-45.25s32.75-12.5 45.25 0L192 306.8l137.4-137.4c12.5-12.5 32.75-12.5 45.25 0s12.5 32.75 0 45.25l-160 160C208.4 380.9 200.2 384 192 384z\"><\/path><\/svg><\/span><span class=\"uagb-icon-active uagb-faq-icon-wrap\"><svg xmlns=\"https:\/\/www.w3.org\/2000\/svg\" viewBox=\"0 0 384 512\"><path d=\"M352 352c-8.188 0-16.38-3.125-22.62-9.375L192 205.3l-137.4 137.4c-12.5 12.5-32.75 12.5-45.25 0s-12.5-32.75 0-45.25l160-160c12.5-12.5 32.75-12.5 45.25 0l160 160c12.5 12.5 12.5 32.75 0 45.25C368.4 348.9 360.2 352 352 352z\"><\/path><\/svg><\/span><h4 class=\"uagb-question\">2014<\/h4><\/div><div class=\"uagb-faq-content\"><p>Hamilton P., De Haan M., <strong>Kopalov\u00e1 K.<\/strong>, Zidarova R. &amp; Van de Vijver B. (2014) An evaluation of selected <em>Neidium<\/em> species from the Antarctic Region. <em>Diatom Research<\/em> 29(1): 27\u201340. <a href=\"https:\/\/www.tandfonline.com\/doi\/abs\/10.1080\/0269249X.2013.822020\">DOI: 10.1080\/0269249X.2013.822020<\/a><br><br><strong>Kopalov\u00e1 K.,<\/strong> Ochyra R., Nedbalov\u00e1 L. &amp; Van de Vijver B. (2014) Moss-inhabiting diatoms from two contrasting Maritime Antarctic islands. <em>Plant Ecology and Evolution<\/em> 147(1): 67\u201384. DOI: 10.5091\/plecevo.2014.896<br><br><strong>Kopalov\u00e1 K.<\/strong> &amp; Van de Vijver B. (2013) Structure and ecology of freshwater benthic diatom communities from Byers Peninsula (Livingston Island, South Shetland Island). <em>Antarctic Science<\/em> 25(2): 239\u2013253. <a href=\"https:\/\/www.cambridge.org\/core\/journals\/antarctic-science\/article\/abs\/structure-and-ecology-of-freshwater-benthic-diatom-communities-from-byers-peninsula-livingston-island-south-shetland-islands\/2FB16DCEC4E735AAB23C225A3B3363D3\">DOI: 10.1017\/S0954102012000764<\/a><br><br>Lowe R.L., Kociolek P., Johansen J.R., Van de Vijver B., Lange-Bertalot H. &amp; <strong>Kopalov\u00e1 K.<\/strong> (2014) <em>Humidophila<\/em> gen. nov., a new genus for a clade of diatoms (Bacillariophyta) formerly within the genus <em>Diadesmis<\/em>: species from Hawai\u2019i, including one new species. <em>Diatom Research<\/em> 29(4): 351\u2013360. <a href=\"https:\/\/www.tandfonline.com\/doi\/abs\/10.1080\/0269249X.2014.889039\">DOI: 10.1080\/0269249X.2014.889039<\/a><br><br>Pinseel E.,<strong> Kopalov\u00e1 K.<\/strong>\u00a0 &amp; Van de Vijver B. (2014) <em>Gomphonema svalbardense<\/em> sp. nov., a new freshwater diatom species (Bacillariophyta) from the Arctic Region. <em>Phytotaxa<\/em> 170(4): 250\u2013258. <a href=\"https:\/\/www.biotaxa.org\/Phytotaxa\/article\/view\/phytotaxa.170.4.2\">DOI: 10.11646\/phytotaxa.170.4.2<\/a><br><br>Van de Vijver B. &amp; <strong>Kopalov\u00e1, K.<\/strong> (2014) Four <em>Achnanthidium<\/em> species (Bacillariophyta) formerly identified as <em>Achnanthes minutissima<\/em> from the Antarctic Region. <em>European Journal of Taxonomy<\/em> 79: 1\u201319. <a href=\"https:\/\/europeanjournaloftaxonomy.eu\/index.php\/ejt\/article\/view\/201\">DOI: 10.5852\/ejt.2014.79<\/a><br><br>Van de Vijver B., <strong>Kopalov\u00e1 K.<\/strong>, Zidarova R. &amp; Levkov Z. (2014) Revision of the genus\u00a0<em>Halamphora<\/em>\u00a0(Bacillariophyta) in the Antarctic Region.\u00a0<em>Plant Ecology and Evolution<\/em>\u00a0147: 374\u2013391.\u00a0<a href=\"https:\/\/plecevo.eu\/article\/32111\/\">DOI: 10.5091\/plecevo.2014.979<\/a><br><br>Van de Vijver B., Morales E.A. &amp; <strong>Kopalov\u00e1 K.<\/strong> (2014) Three new araphid diatoms (Bacillariophyta) from the Maritime Antarctic Region. <em>Phytotaxa<\/em> 167(30): 256\u2013266. <a href=\"https:\/\/www.biotaxa.org\/Phytotaxa\/article\/view\/phytotaxa.167.3.4\">DOI: 10.11646\/phytotaxa.167.3.4<\/a><br><br>Van de Vijver B., Zidarova R. &amp; <strong>Kopalov\u00e1 K.<\/strong> (2014) New species in the genus <em>Muelleria<\/em> (Bacillariophyta) from the Maritime Antarctic Region. <em>Fottea<\/em> 14(1): 77\u201390. <a href=\"https:\/\/fottea.czechphycology.cz\/artkey\/fot-201401-0006_New_species_in_the_genus_Muelleria_Bacillariophyta_from_the_Maritime_Antarctic_Region.php\">DOI:\u00a010.5507\/fot.2014.006<\/a><br><br>Wetzel C.E., Van de Vijver B., <strong>Kopalov\u00e1 K.<\/strong>, Hoffmann L., Pfister L. &amp; Ector L. (2014) Type analysis of the South American diatom\u00a0<em>Achnanthes haynaldii<\/em>\u00a0(Bacillariophyta) and description of\u00a0<em>Planothidium amphibium\u00a0<\/em>sp. nov., from aerial and aquatic environments of Oregon (USA).\u00a0<em>Plant Ecology and Evolution<\/em>\u00a014: 439\u2013454. <a href=\"https:\/\/plecevo.eu\/article\/32125\/\">DOI: 10.5091\/plecevo.2014.1058<\/a><br><br>Zidarova R., <strong>Kopalov\u00e1 K. <\/strong>&amp; Van de Vijver B. (2014) The genus <em>Stauroneis <\/em>(Bacillariophyta) from the South Shetland Islands and James Ross Island (Antarctica). <em>Fottea<\/em> 14(2): 201\u2013207. <a href=\"https:\/\/fottea.czechphycology.cz\/artkey\/fot-201402-0007_The_genus_Stauroneis_Bacillariophyta_from_the_South_Shetland_Islands_and_James_Ross_Island_Antarctica.php\">DOI:\u00a010.5507\/fot.2014.015<\/a><\/p><\/div><\/div>\n\n\n\n<div class=\"wp-block-uagb-faq-child uagb-faq-child__outer-wrap uagb-faq-item uagb-block-46b8249c\" role=\"tab\" tabindex=\"0\"><div class=\"uagb-faq-questions-button uagb-faq-questions\"><span class=\"uagb-icon uagb-faq-icon-wrap\"><svg xmlns=\"https:\/\/www.w3.org\/2000\/svg\" viewBox=\"0 0 384 512\"><path d=\"M192 384c-8.188 0-16.38-3.125-22.62-9.375l-160-160c-12.5-12.5-12.5-32.75 0-45.25s32.75-12.5 45.25 0L192 306.8l137.4-137.4c12.5-12.5 32.75-12.5 45.25 0s12.5 32.75 0 45.25l-160 160C208.4 380.9 200.2 384 192 384z\"><\/path><\/svg><\/span><span class=\"uagb-icon-active uagb-faq-icon-wrap\"><svg xmlns=\"https:\/\/www.w3.org\/2000\/svg\" viewBox=\"0 0 384 512\"><path d=\"M352 352c-8.188 0-16.38-3.125-22.62-9.375L192 205.3l-137.4 137.4c-12.5 12.5-32.75 12.5-45.25 0s-12.5-32.75 0-45.25l160-160c12.5-12.5 32.75-12.5 45.25 0l160 160c12.5 12.5 12.5 32.75 0 45.25C368.4 348.9 360.2 352 352 352z\"><\/path><\/svg><\/span><h4 class=\"uagb-question\">2013<\/h4><\/div><div class=\"uagb-faq-content\"><p><strong>Kopalov\u00e1 K<\/strong>., Nedbalov\u00e1 L., N\u00fdvlt D., Elster J. &amp; Van de Vijver B. (2013) Diversity, ecology and biogeography of the freshwater diatom communities from Ulu Peninsula (James Ross Island, NE Antarctic Peninsula). <em>Polar Biology<\/em> 36(7): 933\u2013948. \u00a0<a href=\"https:\/\/link.springer.com\/article\/10.1007\/s00300-013-1317-5\">DOI: 10.1007\/s00300-013-1317-5<br><\/a><br>Van de Vijver B., Cocquyt C., De Haan M., <strong>Kopalov\u00e1 K<\/strong>. &amp; Zidarova R. (2013) The genus <em>Surirella<\/em> (Bacillariophyta) in the sub Antarctic and Maritime Antarctic region. <em>Diatom Research<\/em> 28(1): 92-108. <a href=\"https:\/\/www.tandfonline.com\/doi\/abs\/10.1080\/0269249X.2012.739975\">DOI: 10.1080\/0269249X.2012.739975<\/a><br><br>Van de Vijver B., <strong>Kopalov\u00e1 K<\/strong>., Zidarova R. &amp; Cox E. J. (2013) New and interesting small-celled naviculoid taxa from the Maritime Antarctic Region. <em>Nova Hedwigia <\/em>97(1-2): 189-208. <a href=\"https:\/\/www.schweizerbart.de\/papers\/nova_hedwigia\/detail\/97\/80529\/New_and_interesting_small_celled_naviculoid_diatoms_Bacillariophyta_from_the_Maritime_Antarctic_Region\">DOI: 10.1127\/0029-5035\/2013\/0101<\/a><br><br>Van de Vijver B., Wetzel C., <strong>Kopalov\u00e1 K<\/strong>., Zidarova R. &amp; Ector L. (2013) Analysis of the type material of <em>Achnanthidium lanceolatum<\/em> Br\u00e9bisson ex K\u00fctzing (Bacillariophyta) with the description of two new <em>Planothidium<\/em> species from the Antarctic Region. <em>Fottea<\/em> 13(2): 105-117. <a href=\"https:\/\/fottea.czechphycology.cz\/artkey\/fot-201302-0002_Analysis_of_the_type_material_of_Achnanthidium_lanceolatum_Brebisson_ex_K_tzing_Bacillariophyta_with_the_desc.php\">DOI:\u00a010.5507\/fot.2013.010<\/a><\/p><\/div><\/div>\n\n\n\n<div class=\"wp-block-uagb-faq-child uagb-faq-child__outer-wrap uagb-faq-item uagb-block-383ef6a6\" role=\"tab\" tabindex=\"0\"><div class=\"uagb-faq-questions-button uagb-faq-questions\"><span class=\"uagb-icon uagb-faq-icon-wrap\"><svg xmlns=\"https:\/\/www.w3.org\/2000\/svg\" viewBox=\"0 0 384 512\"><path d=\"M192 384c-8.188 0-16.38-3.125-22.62-9.375l-160-160c-12.5-12.5-12.5-32.75 0-45.25s32.75-12.5 45.25 0L192 306.8l137.4-137.4c12.5-12.5 32.75-12.5 45.25 0s12.5 32.75 0 45.25l-160 160C208.4 380.9 200.2 384 192 384z\"><\/path><\/svg><\/span><span class=\"uagb-icon-active uagb-faq-icon-wrap\"><svg xmlns=\"https:\/\/www.w3.org\/2000\/svg\" viewBox=\"0 0 384 512\"><path d=\"M352 352c-8.188 0-16.38-3.125-22.62-9.375L192 205.3l-137.4 137.4c-12.5 12.5-32.75 12.5-45.25 0s-12.5-32.75 0-45.25l160-160c12.5-12.5 32.75-12.5 45.25 0l160 160c12.5 12.5 12.5 32.75 0 45.25C368.4 348.9 360.2 352 352 352z\"><\/path><\/svg><\/span><h4 class=\"uagb-question\">2012<\/h4><\/div><div class=\"uagb-faq-content\"><p>Auer S.K., Lopez-Sepulcre A., Heatherly II T.N., <strong>Kohler T.J.<\/strong>, Bassar R.D., Thomas S.A. &amp; Reznick D.N. (2012) Life histories have a history: Effects of past and present conditions on somatic growth in wild Trinidadian guppies. <em>Journal of Animal Ecology <\/em>81(4): 818\u2013826. <a href=\"https:\/\/besjournals.onlinelibrary.wiley.com\/doi\/10.1111\/j.1365-2656.2012.01964.x\">DOI: 10.1111\/j.1365-2656.2012.01964.x<\/a><br><br>El-Sabaawi R.W., <strong>Kohler T.J.<\/strong>, Zandon\u00e0 E., Travis J., Marshall M.C., Thomas S.A., Reznick D.N., Walsh M., Gilliam J.F., Pringle C.M. &amp; Flecker A.S. (2012) Environmental and organismal predictors of intraspecific variation in the stoichiometry of a neotropical freshwater fish. <em>PLoS ONE<\/em> 7(3): e32713. <a href=\"https:\/\/journals.plos.org\/plosone\/article?id=10.1371\/journal.pone.0032713\">DOI: 10.1371\/journal.pone.0032713<\/a><br><br>El-Sabaawi R.W., Zandon\u00e0 E., <strong>Kohler T.J.<\/strong>, Marshall M.C., Moslemi J.M., Travis J., L\u00f3pez-Sepulcre A., Ferri\u00e9re R., Pringle C.M., Thomas S.A., Reznick D.N. &amp; Flecker A.S. (2012) Widespread intraspecific organismal stoichiometry among populations of the Trinidadian guppy (<em>Poecilia reticulata<\/em>). <em>Functional Ecology <\/em>26(3): 666\u2013676. <a href=\"https:\/\/besjournals.onlinelibrary.wiley.com\/doi\/10.1111\/j.1365-2435.2012.01974.x\">DOI:\u00a010.1111\/j.1365-2435.2012.01974.x<\/a><br><br><strong>Kohler T.J.<\/strong>, Heatherly II T.N., El-Sabaawi R.W., Zandon\u00e0 E., Marshall M.C., Flecker A.S., Pringle C.M., Reznick D.N. &amp; Thomas S.A. (2012) Flow, nutrients and light availability influence Neotropical epilithon biomass and stoichiometry. <em>Freshwater Science <\/em>31(4): 1019\u20131034. <a href=\"https:\/\/www.journals.uchicago.edu\/doi\/abs\/10.1899\/11-141.1?journalCode=fws\">DOI: 10.1899\/11-141.1<\/a><br><br><strong>Kopalov\u00e1 K.<\/strong>, Elster J., Kom\u00e1rek J., Vesel\u00e1 J., Nedbalov\u00e1 L. &amp; Van de Vijver B. (2012) Benthic diatoms (Bacillariophyta) from seepages and streams on James Ross Island (NW Weddell Sea, Antarctica). <em>Plant Ecology and Evolution<\/em> 145(2): 190\u2013208.<br><br>Stanish L.F., <strong>Kohler T.J.<\/strong>, Esposito R.M.M., Simmons B.L., Nielsen U.N., Wall D.H., Nemergut D.R. &amp; McKnight D.M. (2012) Extreme streams: flow intermittency as a control on diatom communities in meltwater streams in the McMurdo Dry Valleys, Antarctica. <em>Canadian Journal of Fisheries and Aquatic Sciences<\/em> 69(8): 1405\u20131419. <a href=\"https:\/\/cdnsciencepub.com\/doi\/abs\/10.1139\/f2012-022?mobileUi=0\">DOI: 10.1139\/f2012-022<\/a><br><br>Zidarova R., <strong>Kopalov\u00e1 K<\/strong>. &amp; Van de Vijver B. (2012) The genus <em>Pinnularia<\/em> (Bacillariophyta) excluding the sectio Distantes on Livingston Island (South Shetland Islands) with the description of the new taxa. <em>Phytotaxa<\/em> 44: 11\u201337. <a href=\"https:\/\/www.biotaxa.org\/Phytotaxa\/article\/view\/phytotaxa.44.1.2\">DOI: 10.11646\/phytotaxa.44.1.2<\/a><\/p><\/div><\/div>\n\n\n\n<div class=\"wp-block-uagb-faq-child uagb-faq-child__outer-wrap uagb-faq-item uagb-block-88fd6c6c\" role=\"tab\" tabindex=\"0\"><div class=\"uagb-faq-questions-button uagb-faq-questions\"><span class=\"uagb-icon uagb-faq-icon-wrap\"><svg xmlns=\"https:\/\/www.w3.org\/2000\/svg\" viewBox=\"0 0 384 512\"><path d=\"M192 384c-8.188 0-16.38-3.125-22.62-9.375l-160-160c-12.5-12.5-12.5-32.75 0-45.25s32.75-12.5 45.25 0L192 306.8l137.4-137.4c12.5-12.5 32.75-12.5 45.25 0s12.5 32.75 0 45.25l-160 160C208.4 380.9 200.2 384 192 384z\"><\/path><\/svg><\/span><span class=\"uagb-icon-active uagb-faq-icon-wrap\"><svg xmlns=\"https:\/\/www.w3.org\/2000\/svg\" viewBox=\"0 0 384 512\"><path d=\"M352 352c-8.188 0-16.38-3.125-22.62-9.375L192 205.3l-137.4 137.4c-12.5 12.5-32.75 12.5-45.25 0s-12.5-32.75 0-45.25l160-160c12.5-12.5 32.75-12.5 45.25 0l160 160c12.5 12.5 12.5 32.75 0 45.25C368.4 348.9 360.2 352 352 352z\"><\/path><\/svg><\/span><h4 class=\"uagb-question\">2011<\/h4><\/div><div class=\"uagb-faq-content\"><p><strong>Kohler T.J<\/strong>., Murdock J.N, Gido K.B. &amp; Dodds W.K. (2011) Nutrient loading and grazing by the minnow <em>Phoxinus erythrogaster<\/em> shift periphyton abundance and stoichiometry in mesocosms. <em>Freshwater Biology<\/em> 56(6): 1133\u20131146. <a href=\"https:\/\/onlinelibrary.wiley.com\/doi\/abs\/10.1111\/j.1365-2427.2010.02557.x\">DOI:\u00a010.1111\/j.1365-2427.2010.02557.x<\/a><br><br><strong>Kopalov\u00e1 K.,<\/strong> Nedbalov\u00e1 L., de Haan M. &amp; Van de Vijver B. (2011) Description of five new species of the diatom genus <em>Luticola<\/em> (Bacillariophyta, Diadesmidaceae) found in lakes of James Ross Island (Maritime Antarctic Region). <em>Phytotaxa<\/em> 27: 44\u201360. <a href=\"https:\/\/www.biotaxa.org\/Phytotaxa\/article\/view\/phytotaxa.27.1.5\">DOI: 10.11646\/phytotaxa.27.1.5<\/a><\/p><\/div><\/div>\n\n\n\n<div class=\"wp-block-uagb-faq-child uagb-faq-child__outer-wrap uagb-faq-item uagb-block-46d8a1be\" role=\"tab\" tabindex=\"0\"><div class=\"uagb-faq-questions-button uagb-faq-questions\"><span class=\"uagb-icon uagb-faq-icon-wrap\"><svg xmlns=\"https:\/\/www.w3.org\/2000\/svg\" viewBox=\"0 0 384 512\"><path d=\"M192 384c-8.188 0-16.38-3.125-22.62-9.375l-160-160c-12.5-12.5-12.5-32.75 0-45.25s32.75-12.5 45.25 0L192 306.8l137.4-137.4c12.5-12.5 32.75-12.5 45.25 0s12.5 32.75 0 45.25l-160 160C208.4 380.9 200.2 384 192 384z\"><\/path><\/svg><\/span><span class=\"uagb-icon-active uagb-faq-icon-wrap\"><svg xmlns=\"https:\/\/www.w3.org\/2000\/svg\" viewBox=\"0 0 384 512\"><path d=\"M352 352c-8.188 0-16.38-3.125-22.62-9.375L192 205.3l-137.4 137.4c-12.5 12.5-32.75 12.5-45.25 0s-12.5-32.75 0-45.25l160-160c12.5-12.5 32.75-12.5 45.25 0l160 160c12.5 12.5 12.5 32.75 0 45.25C368.4 348.9 360.2 352 352 352z\"><\/path><\/svg><\/span><h4 class=\"uagb-question\">2010<\/h4><\/div><div class=\"uagb-faq-content\"><p>Van de Vijver B., Sterken M., Vyverman W., Mataloni G., Nedbalov\u00e1 L., <strong>Kopalov\u00e1 K<\/strong>., Elster J., Verleyen E. &amp; Sabbe K. (2010)\u00a0Four new non-marine diatom taxa from the Subantarctic and Antarctic Regions. <em>Diatom Research<\/em> 25(2): 431\u2013443. <a href=\"https:\/\/www.tandfonline.com\/doi\/abs\/10.1080\/0269249X.2010.9705861\">DOI: 10.1080\/0269249X.2010.9705861<\/a><\/p><\/div><\/div>\n\n\n\n<div class=\"wp-block-uagb-faq-child uagb-faq-child__outer-wrap uagb-faq-item uagb-block-6c9fdccc\" role=\"tab\" tabindex=\"0\"><div class=\"uagb-faq-questions-button uagb-faq-questions\"><span class=\"uagb-icon uagb-faq-icon-wrap\"><svg xmlns=\"https:\/\/www.w3.org\/2000\/svg\" viewBox=\"0 0 384 512\"><path d=\"M192 384c-8.188 0-16.38-3.125-22.62-9.375l-160-160c-12.5-12.5-12.5-32.75 0-45.25s32.75-12.5 45.25 0L192 306.8l137.4-137.4c12.5-12.5 32.75-12.5 45.25 0s12.5 32.75 0 45.25l-160 160C208.4 380.9 200.2 384 192 384z\"><\/path><\/svg><\/span><span class=\"uagb-icon-active uagb-faq-icon-wrap\"><svg xmlns=\"https:\/\/www.w3.org\/2000\/svg\" viewBox=\"0 0 384 512\"><path d=\"M352 352c-8.188 0-16.38-3.125-22.62-9.375L192 205.3l-137.4 137.4c-12.5 12.5-32.75 12.5-45.25 0s-12.5-32.75 0-45.25l160-160c12.5-12.5 32.75-12.5 45.25 0l160 160c12.5 12.5 12.5 32.75 0 45.25C368.4 348.9 360.2 352 352 352z\"><\/path><\/svg><\/span><h4 class=\"uagb-question\">2009<\/h4><\/div><div class=\"uagb-faq-content\"><p><strong>Kopalov\u00e1 K.<\/strong>, Elster J., Nedbalov\u00e1 L. &amp; Van de Vijver B. (2009) Three new terrestrial diatom species from seepage areas on James Ross Island (Maritime Antarctic Region). <em>Diatom Research<\/em> 24(1): 113\u2013122. <a href=\"https:\/\/www.tandfonline.com\/doi\/abs\/10.1080\/0269249X.2009.9705786\">DOI: 10.1080\/0269249X.2009.9705786<\/a><br><br>Zidarova R., Van de Vijver B., Mataloni G., <strong>Kopalov\u00e1 K<\/strong>. &amp; Nedbalov\u00e1 L. (2009) Four new freshwater diatom species (Bacillariophyceae) from Antarctica. <em>Cryptogamie Algologie<\/em> 30(4): 295\u2013310.<\/p><\/div><\/div>\n\n\n\n<div class=\"wp-block-uagb-faq-child uagb-faq-child__outer-wrap uagb-faq-item uagb-block-40f89ecc\" role=\"tab\" tabindex=\"0\"><div class=\"uagb-faq-questions-button uagb-faq-questions\"><span class=\"uagb-icon uagb-faq-icon-wrap\"><svg xmlns=\"https:\/\/www.w3.org\/2000\/svg\" viewBox=\"0 0 384 512\"><path d=\"M192 384c-8.188 0-16.38-3.125-22.62-9.375l-160-160c-12.5-12.5-12.5-32.75 0-45.25s32.75-12.5 45.25 0L192 306.8l137.4-137.4c12.5-12.5 32.75-12.5 45.25 0s12.5 32.75 0 45.25l-160 160C208.4 380.9 200.2 384 192 384z\"><\/path><\/svg><\/span><span class=\"uagb-icon-active uagb-faq-icon-wrap\"><svg xmlns=\"https:\/\/www.w3.org\/2000\/svg\" viewBox=\"0 0 384 512\"><path d=\"M352 352c-8.188 0-16.38-3.125-22.62-9.375L192 205.3l-137.4 137.4c-12.5 12.5-32.75 12.5-45.25 0s-12.5-32.75 0-45.25l160-160c12.5-12.5 32.75-12.5 45.25 0l160 160c12.5 12.5 12.5 32.75 0 45.25C368.4 348.9 360.2 352 352 352z\"><\/path><\/svg><\/span><h4 class=\"uagb-question\">2008<\/h4><\/div><div class=\"uagb-faq-content\"><p>Esposito R.M.M., Spaulding S.A., McKnight D.M., Van de Vijver B., <strong>Kopalov\u00e1 K.<\/strong>, Lubinski D., Hall B. &amp; Whittaker T. (2008) Inland diatoms from the McMurdo Dry Valleys and James Ross Island, Antarctica. <em>Botany<\/em> 86(12): 1378\u20131392. <a href=\"https:\/\/cdnsciencepub.com\/doi\/10.1139\/B08-100\">DOI: 10.1139\/B08-100<\/a><br><br>Van de Vijver B. &amp; <strong>Kopalov\u00e1 K<\/strong>. (2008) <em>Orthoseira gremmenii<\/em> sp. nov., a new aerophilic diatom from Gough Island (Southern Atlantic Ocean). <em>Cryptogamie Algologie<\/em> 29(2): 105\u2013118.<\/p><\/div><\/div>\n<\/div>\n","protected":false},"excerpt":{"rendered":"","protected":false},"author":1,"featured_media":0,"parent":0,"menu_order":0,"comment_status":"closed","ping_status":"closed","template":"","meta":{"_uag_custom_page_level_css":"","footnotes":""},"class_list":["post-4983","page","type-page","status-publish","hentry"],"uagb_featured_image_src":{"full":false,"thumbnail":false,"medium":false,"medium_large":false,"large":false,"1536x1536":false,"2048x2048":false},"uagb_author_info":{"display_name":"admin","author_link":"https:\/\/web.natur.cuni.cz\/ecology\/DiCE\/author\/admin\/"},"uagb_comment_info":0,"uagb_excerpt":null,"_links":{"self":[{"href":"https:\/\/web.natur.cuni.cz\/ecology\/DiCE\/wp-json\/wp\/v2\/pages\/4983","targetHints":{"allow":["GET"]}}],"collection":[{"href":"https:\/\/web.natur.cuni.cz\/ecology\/DiCE\/wp-json\/wp\/v2\/pages"}],"about":[{"href":"https:\/\/web.natur.cuni.cz\/ecology\/DiCE\/wp-json\/wp\/v2\/types\/page"}],"author":[{"embeddable":true,"href":"https:\/\/web.natur.cuni.cz\/ecology\/DiCE\/wp-json\/wp\/v2\/users\/1"}],"replies":[{"embeddable":true,"href":"https:\/\/web.natur.cuni.cz\/ecology\/DiCE\/wp-json\/wp\/v2\/comments?post=4983"}],"version-history":[{"count":95,"href":"https:\/\/web.natur.cuni.cz\/ecology\/DiCE\/wp-json\/wp\/v2\/pages\/4983\/revisions"}],"predecessor-version":[{"id":6587,"href":"https:\/\/web.natur.cuni.cz\/ecology\/DiCE\/wp-json\/wp\/v2\/pages\/4983\/revisions\/6587"}],"wp:attachment":[{"href":"https:\/\/web.natur.cuni.cz\/ecology\/DiCE\/wp-json\/wp\/v2\/media?parent=4983"}],"curies":[{"name":"wp","href":"https:\/\/api.w.org\/{rel}","templated":true}]}}