Sea-ice eukaryotes of the Gulf of Finland, Baltic Sea, and evidence for herbivory on weakly shade-adapted ice algae

Majaneva, Markus; Blomster, Jaanika; Müller, Susann; Autio, Riitta; Majaneva, Sanna; Hyytiäinen, Kirsi; Nagai, Satoshi; Rintala, Janne-Markus

doi:10.1016/j.ejop.2016.10.005

Cited by 11 publications

(25 citation statements)

References 72 publications

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“…Cells are round or elongated, ~ 7 µ m in diameter or 10 µ m long, respectively (Figure 7H). Chlamydomonas is a common genus found in the Arctic during the spring and summer months (Balzano et al, 2012; Lovejoy et al, 2002), that can occur in association with sea-ice (Majaneva et al, 2017).…”

Section: Resultsmentioning

confidence: 99%

“…The nucleus, stigma and two 7 µ m flagella can be observed (Figure 7L). Although mainly isolated from coastal and estuarine environments (Bendif et al, 2013), this genus has also been reported as characteristic of sea-ice environments (Majaneva et al, 2017).…”

Section: Resultsmentioning

confidence: 99%

“…Ice, under-ice and open water Arctic phytoplankton communities differ in diversity, biomass, growth rate and tolerance to environmental conditions (Arrigo et al, 2012). Similarly, different types of ice provide different substrates, and therefore harbor different communities (Comeau et al, 2013; Majaneva et al, 2017). The same is true for the stages of ice formation (Kauko et al, 2018; Olsen et al, 2017).…”

Section: Resultsmentioning

confidence: 99%

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Culturable diversity of Arctic phytoplankton during pack ice melting

Ribeiro¹,

Santos²,

Gourvil³

et al. 2019

Preprint

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14Massive phytoplankton blooms develop at the Arctic ice edge, sometimes extend- 15 ing far under the pack ice. An extensive culturing effort was conducted before and 16 during a phytoplankton bloom in Baffin Bay between April and July 2016. Differ-17 ent isolation strategies were applied, including flow cytometry cell sorting, man-18 ual single cell pipetting and serial dilution. Although all three techniques yielded 19 the most common organisms, each technique retrieved specific taxa, highlight-20 ing the importance of using several methods to maximize the number and diver-21 sity of isolated strains. More than 1,000 cultures were obtained, characterized by 22 18S rRNA sequencing and optical microscopy and de-replicated to a subset of 23 276 strains presented in this work. Strains grouped into 57 genotypes defined by 24 100% 18S rRNA sequence similarity. These genotypes spread across five divi-25 sions: Heterokontophyta, Chlorophyta, Cryptophyta, Haptophyta and Dinophyta. 26 Diatoms were the most abundant group (193 strains), mostly represented by the 27 genera Chaetoceros and Attheya. The genera Rhodomonas and Pyramimonas were 28 the most abundant non-diatom nanoplankton strains, while Micromonas polaris 29 dominated the picoplankton. Diversity at the class level was higher during the 30 peak of the bloom. Potentially new species were isolated, in particular within the 31 genera Navicula, Nitzschia, Coscinodiscus, Thalassiosira, Pyramimonas, Man-32 toniella and Isochrysis.33

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Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

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Culturable diversity of Arctic phytoplankton during pack ice melting

Ribeiro¹,

Santos²,

Gourvil³

et al. 2019

Preprint

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“…Studies of the biomass plankton algae dynamics from January to April in Kandalaksha Bay also revealed the highest values in April [50]. The values of Chl a concentration obtained in the under-ice water of the White Sea are comparable to those in the under-ice water of the Baltic Sea in March (0.5-1.0 µg L −1 ) [51].…”

Section: Discussionmentioning

confidence: 84%

Photosynthetic Picoeukaryotes Diversity in the Underlying Ice Waters of the White Sea, Russia

et al. 2020

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The White Sea is a unique basin combining features of temperate and arctic seas. The current state of its biocenoses can serve as a reference point in assessing the expected desalination of the ocean as a result of climate change. A metagenomic study of under-ice ice photosynthetic picoeukaryotes (PPEs) was undertaken by Illumina high-throughput sequencing of the 18S rDNA V4 region from probes collected in March 2013 and 2014. The PPE biomass in samples was 0.03–0.17 µg C·L−1 and their abundance varied from 10 cells·mL−1 to 140 cells·mL−1. There were representatives of 16 algae genera from seven classes and three supergroups, but Chlorophyta, especially Mamiellophyceae, dominated. The most represented genera were Micromonas and Mantoniella. For the first time, the predominance of Mantoniella (in four samples) and Bolidophyceae (in one sample) was observed in under-ice water. It can be assumed that a change in environmental conditions will lead to a considerable change in the structure of arctic PPE communities.

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“…These centric diatoms are supplemented by large contributions of Melosira arctica and the cyanobacterium Aphanizomenon sp. that can predominate abundances in the brine channels (Majaneva et al 2017). In contrast to Arctic and Antarctic sea ice communities, dinoflagellates and green algae contribute to a large fraction of the biomass in Baltic Sea ice and open water (Kaartokallio et al 2007;Piiparinen et al 2010).…”

Section: Microalgaementioning

confidence: 99%

Progress in Microbial Ecology in Ice-Covered Seas

Vonnahme

Dietrich

Hassett

2019

YOUMARES 9 - The Oceans: Our Research, Our Future

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Sea ice seasonally covers 10% of the earth's oceans and shapes global ocean chemistry. The unique physical processes associated with sea ice growth and development shape the associated biological diversity and ecosystem function. Microbes make up the base of all marine food webs and the overwhelming majority of biomass in the sea ice ecosystem. Despite their biomass, microbial processes are not fully integrated into marine ecosystem models. Recent applications of novel molecular biology technologies to studies of marine ecology have elucidated numerous microbial-mediated processes interfaced by previously unknown organisms and processes. These discoveries are yielding more in-depth studies on the relevance of mixotrophy, the ecology of fungi, and the interplay between major microbial clades. In ecosystem studies, the basis of the food web is frequently neglected even though the accessibility of energy, recycling of nutrients, and parasitism are crucial factors shaping the environment for grazers and higher trophic levels. In this review, we focus on the species composition, abundance, and functions of microalgae, bacteria, archaea, fungi, and viruses in the sea ice-covered seas throughout the year. A strong emphasis will be put on advances in molecular methods that empower scientists to further investigate microorganisms in more detail. Since microbes make up the majority of all oceanic biomass, we believe that it is impossible to accurately forecast the biological fate of polar marine ecosystems without placing a proportional emphasis on microbes relative to their biomass.

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Sea-ice eukaryotes of the Gulf of Finland, Baltic Sea, and evidence for herbivory on weakly shade-adapted ice algae

Cited by 11 publications

References 72 publications

Culturable diversity of Arctic phytoplankton during pack ice melting

Culturable diversity of Arctic phytoplankton during pack ice melting

Photosynthetic Picoeukaryotes Diversity in the Underlying Ice Waters of the White Sea, Russia

Progress in Microbial Ecology in Ice-Covered Seas

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