Proton‐pumping rhodopsins are abundantly expressed by microbial eukaryotes in a high‐Arctic fjord

Vader, Anna; Laughinghouse, Haywood Dail; Griffiths, Colin; Jakobsen, Kjetill S.; Gabrielsen, Tove M.

doi:10.1111/1462-2920.14035

Cited by 17 publications

(25 citation statements)

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“…PR in dinoflagellates is highly similar to proteorhodopsin, which are globally abundant in bacteria (Béja et al 2013;Gómez-Consarnau et al 2010) and well characterized as a proton pump (Béja et al 2000;Inoue et al 2016). Since its first discovery in dinoflagellates (Lin et al 2010), eukaryotic homologs of PR have also been found in other eukaryotes microorganisms, such as diatoms, haptophytes and cryptophytes (Marchetti et al 2015), and recently found in arctic microbial eukaryotes (Vader et al 2018). The dinoflagellate homologs share the highly conserved residues with bacterial PR, including residues to bind retinal, absorbing light spectrum tuning, and proton donor and receptor residues (Lin et al 2010); this is true for the two homologs studied here, Pd-PR (Shi et al 2015), and Ac-PR (Supplementary Figure S1).…”

Section: Discussionmentioning

confidence: 99%

Heterologous expression and cell membrane localization of dinoflagellate rhodopsins in mammalian cells

Shi

Lin

2020

Preprint

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Rhodopsins are now found in all domains of life, and are classified into two large groups: type I, found in animals and type II found in microbes including Bacteria, Archaea, and Eukarya. While type I rhodopsin functions in many photodependent signaling processes including vision, type II among others contains rhodopsins that function as a light-driven proton pump to convert light into ATP as in proteobacteria (named proteorhodopsin). Proteorhodopsin homologs have been documented in dinoflagellates, but their subcellular localizations and functions are still poorly understood. Even though sequence analyses suggest that it is a membrane protein, experimental evidence that dinoflagellate rhodopsins are localized on the plasma membrane or endomembranes is still lacking. As no robust dinoflagellate gene transformation tool is available, we used HEK 293T cells to construct a mammalian expression system for two dinoflagellate rhodopsin genes. The success of expressing these genes in the system shows that this mammalian cell type is suitable for expressing dinoflagellate genes.Immunofluorescence of the expressed protein locates these dinoflagellate rhodopsins on the cell membrane. This result indicates that the protein codons and membrane targeting signal of the dinoflagellate genes are compatible with the mammalian cells, and the proteins' subcellular localization is consistent with proton pump rhodopsins.

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Section: Discussionmentioning

confidence: 99%

Heterologous expression and cell membrane localization of dinoflagellate rhodopsins in mammalian cells

Shi

Lin

2020

Preprint

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“…So far, only several studies have applied metagenomic shotgun sequencing to sea ice samples (e.g., Bowman et al 2014;Yergeau et al 2017), but the potential to elucidate complex polar microbial ecology questions is generally unrealized. Metagenomic sequencing efforts have demonstrated bacterial-mediated chemical cycling in frost flowers (Bowman et al 2014) and the importance of select photoreceptors in Antarctic and Arctic sea ice (Koh et al 2010;Vader et al 2018). With increasing throughput of sequence generation and decreasing costs, deep sequencing (i.e., sequencing the same locus multiple times) of the environment should allow comparative studies of full metagenomes to describe the metabolic potential (including uncultured strains) and strain level microbial diversity (e.g., Delmont et al 2017) in sea ice ecosystems.…”

Section: Advances In Microbial Ecologymentioning

confidence: 99%

“…While metagenomics can demonstrate the genetic potential of microbes, RNA-based studies, such as metatranscriptomics, can show whether the genes are expressed. For example, Koh et al (2010) and Vader et al (2018) showed that the genes for proteorhodopsin are actively transcribed in Antarctic and Arctic sea ice, indicating an active phototrophic bacterial community. Interdisciplinary research with biochemists identified the functions of translated proteins and ascribed a functional purpose for gene products used in survival and metabolism in sea ice (reviewed by Feller and Gerday 2003;Feng et al 2014).…”

Section: Advances In Microbial Ecologymentioning

confidence: 99%

“…Micromonas sp., Cyanobacteria, and Ostreococcus sp. have been found to be abundant phytoplankton species in the polar night (Joli et al 2017; Amargant Arumí 2018) but only constitute a small fraction of the biomass during spring and summer (Riedel et al 2008;Niemi et al 2011;Vader et al 2018) and therefore have not been studied in more detail until recently. Still, reliable identification and quantification of pico-and nanosized eukaryotes are lacking (Piwosz et al 2013) or are purely based on sequencing (Vader et al 2018).…”

Section: Microalgaementioning

confidence: 99%

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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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“…With that, there is limited information on the expression of rhodopsins compared to other light-harvesting mechanisms. In contrast with the established global distribution and abundance of rhodopsin taxonomic clades, very few studies have compared their expression in environmental samples (Shi et al, 2011;Kopf et al, 2015;Boeuf et al, 2016;Brindefalk et al, 2016;Vader et al, 2018). Additionally, the vast majority of studies were based on single time-points, with the exception of Sabehi et al (2007), which compared winter and summer expression at two sites (Mediterranean and Sargasso Sea) and Nguyen et al (2015), which compared early-and late-winter expression in the arctic.…”

Section: Study Of Abundance and Expression Of Light-harvesting Mechanmentioning

confidence: 99%

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Supplemental Information 8: Read Recruitment to Functional Genes Using a Hidden Markov Model (HMM) vs. Reciprocal Blast

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Proton‐pumping rhodopsins are abundantly expressed by microbial eukaryotes in a high‐Arctic fjord

Cited by 17 publications

References 83 publications

Heterologous expression and cell membrane localization of dinoflagellate rhodopsins in mammalian cells

Heterologous expression and cell membrane localization of dinoflagellate rhodopsins in mammalian cells

Progress in Microbial Ecology in Ice-Covered Seas

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