Phytoplankton in extreme environments: importance and consequences of habitat permanency

Padisák, Judit; Naselli-Flores, Luigi

doi:10.1007/s10750-020-04353-4

Cited by 47 publications

(31 citation statements)

References 179 publications

(178 reference statements)

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“…Terrestrial algae, abundant in both extreme and temperate environments, are exposed to several abiotic stressors related to their habitat outside the aquatic environment such as UV radiation, freezing, and unpredictable water availability, where periods of drought of several weeks or even months punctuated by rains are common [ 1 , 2 , 3 ]. The subsequent success of terrestrial algae is partly due to their ability to withstand the stress of undergoing repeated and extended drying–rewetting cycles [ 4 ].…”

Section: Introductionmentioning

confidence: 99%

The Ecophysiological Performance and Traits of Genera within the Stichococcus-like Clade (Trebouxiophyceae) under Matric and Osmotic Stress

2021

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Changes in water balance are some of the most critical challenges that aeroterrestrial algae face. They have a wide variety of mechanisms to protect against osmotic stress, including, but not limited to, downregulating photosynthesis, the production of compatible solutes, spore and akinete formation, biofilms, as well as triggering structural cellular changes. In comparison, algae living in saline environments must cope with ionic stress, which has similar effects on the physiology as desiccation in addition to sodium and chloride ion toxicity. These environmental challenges define ecological niches for both specialist and generalist algae. One alga known to be aeroterrestrial and euryhaline is Stichococcus bacillaris Nägeli, possessing the ability to withstand both matric and osmotic stresses, which may contribute to wide distribution worldwide. Following taxonomic revision of Stichococcus into seven lineages, we here examined their physiological responses to osmotic and matric stress through a salt growth challenge and desiccation experiment. The results demonstrate that innate compatible solute production capacity under salt stress and desiccation tolerance are independent of one another, and that salt tolerance is more variable than desiccation tolerance in the Stichococcus-like genera. Furthermore, algae within this group likely occupy similar ecological niches, with the exception of Pseudostichococcus.

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Section: Introductionmentioning

confidence: 99%

The Ecophysiological Performance and Traits of Genera within the Stichococcus-like Clade (Trebouxiophyceae) under Matric and Osmotic Stress

2021

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“…The green unicellular algae Dunaliella salina and D. parva are usually the most frequently observed hypersaline planktonic species, occurring over a wide salt range from 9 to 250 g/l (Esmaeili Dahesht et al ., 2010; Oren, 2020). Interestingly, eco‐physiological experiments showed that Dunaliella growth optima are lower (up to 90–150 g/l) than the salinity range of their occurrence in nature, indicating plastic responses to changes in salinity levels (Padisák & Naselli‐Flores, 2021) and also potentially due to relaxation of trophic pressures as has been suggested for invertebrates (Arribas et al ., 2019). As a result, a wide spectrum of abundances of Dunaliella were recorded across hypersaline waters in different regions: up to 1 × 10 10 cells/m 3 in Mexican saltern ponds (Olmos et al ., 2009), 5 × 10 9 cells/m 3 in Greek salterns (Dolapsakis et al ., 2005), 4 × 10 10 cells/m 3 in the Dead Sea (Oren et al ., 1995), 7 × 10 7 cells/m 3 at Lake Tyrell (Australia) (Heidelberg et al ., 2013) and up to more than 50 × 10 7 cells/m 3 in Crimean saline lakes (Senicheva et al ., 2008).…”

Section: Hypersaline Biota: Diversity Adaptations and Metabolismsmentioning

confidence: 95%

Salt to conserve: a review on the ecology and preservation of hypersaline ecosystems

et al. 2021

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When it comes to the investigation of key ecosystems in the world, we often omit salt from the ecological recipe. In fact, despite occupying almost half of the volume of inland waters and providing crucial services to humanity and nature, inland saline ecosystems are often overlooked in discussions regarding the preservation of global aquatic resources of our planet. As a result, our knowledge of the biological and geochemical dynamics shaping these environments remains incomplete and we are hesitant in framing effective protective strategies against the increasing natural and anthropogenic threats faced by such habitats. Hypersaline lakes, water bodies where the concentration of salt exceeds 35 g/l, occur mainly in arid and semiarid areas resulting from hydrological imbalances triggering the accumulation of salts over time. Often considered the ‘exotic siblings’ within the family of inland waters, these ecosystems host some of the most extremophile communities worldwide and provide essential habitats for waterbirds and many other organisms in already water‐stressed regions. These systems are often highlighted as natural laboratories, ideal for addressing central ecological questions due to their relatively low complexity and simple food web structures. However, recent studies on the biogeochemical mechanisms framing hypersaline communities have challenged this archetype, arguing that newly discovered highly diverse communities are characterised by specific trophic interactions shaped by high levels of specialisation. The main goal of this review is to explore our current understanding of the ecological dynamics of hypersaline ecosystems by addressing four main research questions: (i) why are hypersaline lakes unique from a biological and geochemical perspective; (ii) which biota inhabit these ecosystems and how have they adapted to the high salt conditions; (iii) how do we protect biodiversity from increasing natural and anthropogenic threats; and (iv) which scientific tools will help us preserve hypersaline ecosystems in the future? First, we focus on the ecological characterisation of hypersaline ecosystems, illustrate hydrogeochemical dynamics regulating such environments, and outline key ecoregions supporting hypersaline systems across the globe. Second, we depict the diversity and functional aspects of key taxa found in hypersaline lakes, from microorganisms to plants, invertebrates, waterbirds and upper trophic levels. Next, we describe ecosystem services and discuss possible conservation guidelines. Finally, we outline how cutting‐edge technologies can provide new insights into the study of hypersaline ecology. Overall, this review sheds further light onto these understudied ecosystems, largely unrecognised as important sources of unique biological and functional diversity. We provide perspectives for key future research avenues, and advocate that the conservation of hypersaline lakes should not be taken with ‘a grain of salt’.

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“…Arthrospira and Limnospira species are well known for their applications ranging from food supplements to industrial polymers ( 2 – 4 ). The East African Rift Valley Region contains a number of saline lakes that are among the most productive ecosystems in the world ( 5 , 6 ), albeit with very few studies being done there ( 6 , 7 ). As a part of our investigations on identifying the genomes of potentially industrial halophiles constituting part of the Big Momela microbiome, we report here the first draft genome sequence of a Limnospira species from that ecosystem.…”

Section: Announcementmentioning

confidence: 99%

Draft Genome Sequence of Limnospira sp. Strain BM01, Isolated from a Hypersaline Lake of the Momela Ecosystem in Tanzania

Maghembe

Michael

Harish

et al. 2021

Microbiol Resour Announc

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Phytoplankton in extreme environments: importance and consequences of habitat permanency

Cited by 47 publications

References 179 publications

The Ecophysiological Performance and Traits of Genera within the Stichococcus-like Clade (Trebouxiophyceae) under Matric and Osmotic Stress

The Ecophysiological Performance and Traits of Genera within the Stichococcus-like Clade (Trebouxiophyceae) under Matric and Osmotic Stress

Salt to conserve: a review on the ecology and preservation of hypersaline ecosystems

Draft Genome Sequence of Limnospira sp. Strain BM01, Isolated from a Hypersaline Lake of the Momela Ecosystem in Tanzania

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