Cryopreservation of six Symbiodiniaceae genera and assessment of fatty acid profiles in response to increased salinity treatments

Kihika, Joseph Kanyi; Wood, Susanna A.; Rhodes, Lesley; Smith, Kirsty F.; Miller, Matthew R.; Pochon, Xavier; Thompson, L. M.; Butler, Juliette; Schattschneider, Jessica; Oakley, Clint; Ryan, Ken G.

doi:10.1038/s41598-022-16735-w

Cited by 6 publications

(2 citation statements)

References 62 publications

(99 reference statements)

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“…Although monoclonal cultures are available from major culture collections, most dinoflagellate strains are cryo‐recalcitrant (Paredes et al, 2021), limiting their tractability as models. Attempts at cryopreservation have been successful for some Symbiodiniaceae strains (Di Genio et al, 2021; Kihika et al, 2022), but generalizability to other dinoflagellate taxa remains to be investigated.…”

Section: Where Do We Go From Here?mentioning

confidence: 99%

Developing model systems for dinoflagellates in the post‐genomic era

Ishida,

John,

Murray

et al. 2023

Journal of Phycology

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Dinoflagellates are a diverse group of eukaryotic microbes that are ubiquitous in aquatic environments. Largely photosynthetic, they encompass symbiotic, parasitic, and free‐living lineages with a broad spectrum of trophism. Many free‐living taxa can produce bioactive secondary metabolites such as biotoxins, some of which cause harmful algal blooms. In contrast, most symbiotic species are crucial for sustaining coral reef health. The year 2023 marked a decade since the first genome data of dinoflagellates became available. The growing genome‐scale resources for these taxa are highlighting their remarkable evolutionary and genomic complexities. Here, we discuss the prospect of developing dinoflagellate models using the criteria of accessibility, tractability, resources, research support, and promise. Moving forward in the post‐genomic era, we argue for the development of fit‐to‐purpose models that tailor to specific biological contexts, and that a one‐size‐fits‐all model is inadequate for encapsulating the complex biology, ecology, and evolutionary history of dinoflagellates.

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Section: Where Do We Go From Here?mentioning

confidence: 99%

Developing model systems for dinoflagellates in the post‐genomic era

Ishida,

John,

Murray

et al. 2023

Journal of Phycology

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“…In vitrification, the sample solidifies without ice crystals, and multiple (Tsai et al, 2016b;Jang et al, 2017;Magnotti et al, 2018) or no CPAs (Isachenko et al, 2003;Spis et al, 2019) are used for biological samples that require extremely high cooling rates (Bojic et al, 2021). Vitrification was first used in mouse (Mus musculus) embryos (Rall and Fahy, 1985) and then plants (Stiles, 1930), erythrocytes (Rapatz and Luyet, 1968), mammalian embryos (Rall and Fahy, 1985;Massip et al, 1986;Yuswiati and Holtz, 1990;Rall, 1993;Schiewe and Anderson, 2017), fish (Cuevas- Uribe et al, 2013;Figueroa et al, 2013;Godoy et al, 2013), invertebrates (Guo and Weng, 2020;Heres et al, 2021), and now corals (Tsai et al, 2015) and their unicellular dinoflagellate symbionts (di Genio et al, 2020;Kihika et al, 2022a;Kihika et al, 2022b). Researchers are striving to cryobank genetic materials from endangered coral species and save regional populations in decline.…”

Section: Introductionmentioning

confidence: 99%

First successful production of adult corals derived from cryopreserved larvae

Narida

Tsai

Hsieh³

et al. 2023

Front. Mar. Sci.

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Coral reefs worldwide are declining due to increasing concentrations of greenhouse gases, which, combined with local anthropogenic pressure, are exacerbating unprecedented mass coral bleaching. For corals to survive, restoring coral reefs through cryopreservation is crucial. The aim of this study was to vitrify and laser-warm Stylophora pistillata planulae to allow for feasible settlement, post-settlement survival, and the production of adult corals. The no-observed-effect concentrations were used to determine the best cryoprotective agents for S. pistillata. The larvae were then subjected to cooling and nanolaser warming (300 V, 10 ms pulse width, 2 mm beam diameter) by using two vitrification solutions (VSs; VS1: 2 M dimethyl sulfoxide and 1 M ethylene glycol [EG]; VS2: 2 M propylene glycol and 1 M EG) and gold nanoparticles. The results revealed that VS1-treated larvae had a higher vitrification rate (65%), swimming rate (23.1%), settlement rate (11.54%), and post settlement survival rate (11.54%) than those treated with VS2. Seasonal variations also affected the cryopreservation of the planulae; VS1 was more favorable for the planulae in spring than in fall. Although laser-warmed larvae developed slower morphologically than their controlled counterparts, the production of cryopreserved adult S. pistillata corals was achieved. The proposed technique can improve the cryopreservation of corals and advance efforts to protect endangered coral species.

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