Mechanisms of Acido-Tolerance and Characteristics of Photosystems in an Acidophilic and Thermophilic Red Alga, Cyanidium Caldarium

Enami, Isao; Adachi, Hayamitsu; Shen, Jian‐Ren

doi:10.1007/978-90-481-3795-4_20

Cited by 11 publications

(9 citation statements)

References 44 publications

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“…The lowering of pH was presumably by the previously described mechanism of rapid ATP‐dependent H + efflux (Kura‐Hotta and Enami, 1981; 1984; Enami and Kura‐Hotta, ; Enami et al ., ).…”

Section: Discussionmentioning

confidence: 97%

The lowering of external pH in confined environments by thermo‐acidophilic algae (class: Cyanidiophyceae)

Lowell

Castenholz

2013

Environ Microbiol Rep

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The unicellular, asexual thermo-acidophilic algae of the class Cyanidiophyceae, order Cyanidiales (the 'cyanidia') include only three genera, walled Cyanidium and Galdieria, and 'naked' Cyanidioschyzon, names based on morphological and cytological characters. Most species and strains of this class live in acid hot springs or acid soils or steam vents associated with these springs at pH 0.5 to ~ 4.0 at temperatures of ~ 38-56 °C. No other phototrophs live in this combination of factors in these habitats, except for a small overlap with other acidophilic algae at the highest pH and the lowest temperature. The optimum pH for growth of the 'cyanidia' in this study was ~ 2.3. Galdieria-like walled cells of Cyanidioschyzon and naked Cyanidioschyzon cells were exposed in culture to higher pH conditions of 6.0, 5.5 and 5.0 in confined, illuminated environments (cotton plugged flasks). The subsequent acidification of the medium towards or to 2.3 occurred as growth and biomass increased. There was a direct correlation with final biomass (Chl a) and lower pH. All eight strains isolated from Yellowstone acidic conditions were able to lower the supra-optimal pH of their medium, while only two from other continents and none of the three from Japan were competent. It is probable that the ability to lower pH to an optimal level has survival value in some niches in natural habitats.

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Section: Discussionmentioning

confidence: 97%

The lowering of external pH in confined environments by thermo‐acidophilic algae (class: Cyanidiophyceae)

Lowell

Castenholz

2013

Environ Microbiol Rep

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“…through several adaptations, including a plasma membrane with reduced permeability to protons, active ATP-dependent proton export, and/or coupled export, where a symporter or antiporter uses the driving force of a different ion to remove protons (Beardall and Entwisle, 1984;Messerli et al, 2005;Enami et al, 2010;Madigan et al 2018). Thus, PBPs from acidophiles are generally not exposed to acidic environments, such that PBPs extracted from acidophilic species show similar stability characteristics to mesophilic species under low pH conditions (Patel et al, 2004;Antelo et al, 2008;Chaiklahan et al, 2012;Patel et al, 2018).…”

Section: Phycobiliproteins In Thermoacidophilesmentioning

confidence: 99%

Phycobiliproteins from extreme environments and their potential applications

Puzorjov

McCormick²

2020

Journal of Experimental Botany

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The light-harvesting phycobilisome complex is an important component of photosynthesis in cyanobacteria and red algae. Phycobilisomes are composed of phycobiliproteins, including the blue phycobiliprotein phycocyanin, that are considered high-value products with applications in several industries. Remarkably, several cyanobacteria and red algal species retain the capacity to harvest light and photosynthesise under highly selective environments such as hot springs, and flourish in extremes of pH and elevated temperatures. These thermophilic organisms produce thermostable phycobiliproteins, which have superior qualities much needed for wider adoption of these natural pigment–proteins in the food, textile, and other industries. Here we review the available literature on the thermostability of phycobilisome components from thermophilic species and discuss how a better appreciation of phycobiliproteins from extreme environments will benefit our fundamental understanding of photosynthetic adaptation and could provide a sustainable resource for several industrial processes.

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“…merolae belongs to the rhodophytan order Cyanidiales, whose members thrive in acidic hot springs (18) and are unique among phototrophs in the ability to live at extremely low pH (pH 0.2-4) and moderately high temperatures (40 -56°C). Despite such an extremely acidic environment, the intracellular pH of these algae is most likely neutral due to the active H ϩ efflux across the plasma membrane (19). C. merolae is considered to be one of the most primitive eukaryotic phototrophs because it diverged near the root of the red algal lineage that forms a basal group within the photosynthetic eukaryotes (20).…”

Section: Photosystem II (Psii)mentioning

confidence: 99%

A Reaction Center-dependent Photoprotection Mechanism in a Highly Robust Photosystem II from an Extremophilic Red Alga, Cyanidioschyzon merolae

Krupnik

Kotabová

Bezouwen

et al. 2013

Journal of Biological Chemistry

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Background: PSII is a protein complex that captures sunlight to drive water oxidation. Results: Cyanidioschyzon merolae PSII is protected by reversible reaction center-based non-photochemical quenching. Conclusion: C. merolae PSII employs reaction center non-photochemical quenching as the main photoprotective mechanism. Significance: We provide the first direct evidence of the PSII reaction center as the primary locus of non-photochemical quenching in the extremophilic red algae.

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Mechanisms of Acido-Tolerance and Characteristics of Photosystems in an Acidophilic and Thermophilic Red Alga, Cyanidium Caldarium

Cited by 11 publications

References 44 publications

The lowering of external pH in confined environments by thermo‐acidophilic algae (class: Cyanidiophyceae)

The lowering of external pH in confined environments by thermo‐acidophilic algae (class: Cyanidiophyceae)

Phycobiliproteins from extreme environments and their potential applications

A Reaction Center-dependent Photoprotection Mechanism in a Highly Robust Photosystem II from an Extremophilic Red Alga, Cyanidioschyzon merolae

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