Xanthophyll cycles in the juniper haircap moss (Polytrichum juniperinum) and Antarctic hair grass (Deschampsia antarctica) on Livingston Island (South Shetland Islands, Maritime Antarctica)

García-Plazaola, J. I.; López‐Pozo, Marina; Fernández‐Marín, Beatriz

doi:10.1007/s00300-022-03068-7

Cited by 6 publications

(6 citation statements)

References 46 publications

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“…This range is 6-to 35-fold higher than those described for grapevine [98] or Quercus ilex [99]. However, our values were 99% lower than those described for two Antarctic species [100]. Moreover, it should be noted that the simple expression of VAZ in the chlorophyll base is not a sufficient argument to support the greater or lesser VAZ:Chl ratio.…”

Section: Discussioncontrasting

confidence: 90%

Stevia rebaudiana under a CO2 Enrichment Atmosphere: Can CO2 Enrichment Overcome Stomatic, Mesophilic and Biochemical Barriers That Limit Photosynthesis?

et al. 2022

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Due to the desire to live a healthier lifestyle, the search for nonglycosidic sweeteners has increased stevioside production in recent years. The main goal of this study was to demonstrate that S. rebaudiana grown in a CO2-enriched environment can overcome stomatic, mesophilic and biochemical barriers that limit photosynthesis (AN). We show that in an environment with a CO2-enriched atmosphere (800 and 1200 µmol CO2 mol−1), the genotype 16 (G16) shows an increase of 17.5% in AN and 36.2% in stomatal conductance in plants grown in 800 µmol CO2 mol−1 when compared to non-enriched plants. In conjunction with this issue, the plants show an efficient mechanism of dissipating excess energy captured by the photosystems. Photosystem II efficiency was increased at 1200 µmol CO2 mol−1 when compared to non-enriched plants, both in genotype 4 (25.4%) and G16 (211%). In addition, a high activity of Calvin–Benson enzymes, a high production of sugars and an enhanced production of steviosides were combined with high horticultural yield. Both genotypes (G4 and G16) showed excellent physiological indicators, with high superiority in G16. Thus, our study has demonstrated that S. rebaudiana could adapt to global climate change scenarios with higher temperatures caused by higher atmospheric CO2.

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Section: Discussioncontrasting

confidence: 90%

Stevia rebaudiana under a CO2 Enrichment Atmosphere: Can CO2 Enrichment Overcome Stomatic, Mesophilic and Biochemical Barriers That Limit Photosynthesis?

et al. 2022

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“…VAZ) is variable in response to cumulative demanding requirements (Esteban et al., 2015). So, the high VAZ/Chl repeatedly found in different species at high latitudes may indicate a pre‐emptive protective stage of the photosynthetic membranes in these harsh environments where low temperature, intermittent water availability and irradiance converge (Fernández‐Marín, Gago, et al., 2019; Fernández‐Marín, López‐Pozo, et al., 2019; García‐Plazaola, López‐Pozo, & Fernández‐Marín, 2022). The elevated VAZ/Chl values obtained in P. antarctica are in agreement with previous reports at high latitudes, where most photosynthetic organisms are subjected to high thylakoid protection requirements.…”

Section: Discussionmentioning

confidence: 99%

“…In that sense, a large pool of the carotenoids involved in the so-called xanthophyll cycle, with relevant roles in excess energy dissipation, thylakoid membrane stabilisation and as antioxidants, seems to be determinant in environments with high photoprotective demand such as polar tundra (Fern andez-Mar ın, Atherton, et al, 2018;Fern andez-Mar ın, Gago, et al, 2019;Magney et al, 2017;Schroeter et al, 2012). Fast and dynamic de-epoxidation of the violaxanthin into the protective zeaxanthin within the xanthophyll cycle, in response to either increasing irradiance, sub-zero temperatures or severe desiccation, it is equally relevant for suitable photoprotection of the photosynthetic machinery in species tolerant to either desiccation, intra-tissular ice formation, or both (Fern andez-Mar ın, Arzac, et al, 2021;Fern andez-Mar ın, Neuner, et al, 2018) and for species in polar tundra too (Fern andez-Mar ın, Gago, et al, 2019;Garc ıa-Plazaola, L opez-Pozo, & Fern andez-Mar ın, 2022). The fine tuning and responsiveness of the xanthophyll cycle to the environmental conditions acquires even more relevance when considering that too slow re-epoxidation of zeaxanthin back to violaxanthin represents an important payback for net photosynthesis estimated in a 20% reduction for crop-plants (Kromdijk et al, 2016).…”

Section: Introductionmentioning

confidence: 99%

The outstanding capacity of Prasiola antarctica to thrive in contrasting harsh environments relies on the constitutive protection of thylakoids and on morphological plasticity

Arzac,

Miranda‐Apodaca,

de los Ríos

et al. 2024

The Plant Journal

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SUMMARYThe determination of physiological tolerance ranges of photosynthetic species and of the biochemical mechanisms underneath are fundamental to identify target processes and metabolites that will inspire enhanced plant management and production for the future. In this context, the terrestrial green algae within the genus Prasiola represent ideal models due to their success in harsh environments (polar tundras) and their extraordinary ecological plasticity. Here we focus on the outstanding Prasiola antarctica and compare two natural populations living in very contrasting microenvironments in Antarctica: the dry sandy substrate of a beach and the rocky bed of an ephemeral freshwater stream. Specifically, we assessed their photosynthetic performance at different temperatures, reporting for the first time gnsd values in algae and changes in thylakoid metabolites in response to extreme desiccation. Stream population showed lower α‐tocopherol content and thicker cell walls and thus, lower gnsd and photosynthesis. Both populations had high temperatures for optimal photosynthesis (around +20°C) and strong constitutive tolerance to freezing and desiccation. This tolerance seems to be related to the high constitutive levels of xanthophylls and of the cylindrical lipids di‐ and tri‐galactosyldiacylglycerol in thylakoids, very likely related to the effective protection and stability of membranes. Overall, P. antarctica shows a complex battery of constitutive and plastic protective mechanisms that enable it to thrive under harsh conditions and to acclimate to very contrasting microenvironments, respectively. Some of these anatomical and biochemical adaptations may partially limit photosynthesis, but this has a great potential to rise in a context of increasing temperature.

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“…However, in the austral summer, mosses lose their protective cover and are exposed to high light stress, compounded by cold temperatures and desiccation events. At this point, the percentage of VAZ sustained as Z is usually high in Antarctic mosses (Lovelock et al 1995b ; Lovelock and Robinson 2002 ; Martínez-Abaigar and Núñez-Olivera 2022 ; García-Plazaola et al 2022 ), similar to that of sun plants (Demmig-Adams and Adams III 1992 ; Lovelock and Robinson 2002 ; García-Plazaola et al 2022 ). For instance, when S. antarctici samples were moved from the field into the laboratory, 50% of the VAZ pool remained as A+Z after 24 h in low light (Lovelock et al 1995a ).…”

Section: Introductionmentioning

confidence: 96%

“…Antarctic mosses acclimate their pigment concentrations to seasonal changes and between sites presumably in response to microclimate variation (see above) (Schroeter et al 2012 ; Snell et al 2007 ; Lovelock and Robinson 2002 ; Robinson et al 2005 ; García-Plazaola et al 2022 ). When mosses are covered by ice and snow during the long winter, their pigments adjust to cope with the shaded environment by reducing photosynthetic rates and carotenoid concentrations whilst increasing chlorophyll levels (Post 1990 ; Post and Vesk 1992 ; Robinson et al 2005 ).…”

Section: Introductionmentioning

confidence: 99%

Basking in the sun: how mosses photosynthesise and survive in Antarctica

et al. 2023

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The Antarctic environment is extremely cold, windy and dry. Ozone depletion has resulted in increasing ultraviolet-B radiation, and increasing greenhouse gases and decreasing stratospheric ozone have altered Antarctica’s climate. How do mosses thrive photosynthetically in this harsh environment? Antarctic mosses take advantage of microclimates where the combination of protection from wind, sufficient melt water, nutrients from seabirds and optimal sunlight provides both photosynthetic energy and sufficient warmth for efficient metabolism. The amount of sunlight presents a challenge: more light creates warmer canopies which are optimal for photosynthetic enzymes but can contain excess light energy that could damage the photochemical apparatus. Antarctic mosses thus exhibit strong photoprotective potential in the form of xanthophyll cycle pigments. Conversion to zeaxanthin is high when conditions are most extreme, especially when water content is low. Antarctic mosses also produce UV screening compounds which are maintained in cell walls in some species and appear to protect from DNA damage under elevated UV-B radiation. These plants thus survive in one of the harshest places on Earth by taking advantage of the best real estate to optimise their metabolism. But survival is precarious and it remains to be seen if these strategies will still work as the Antarctic climate changes.

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Xanthophyll cycles in the juniper haircap moss (Polytrichum juniperinum) and Antarctic hair grass (Deschampsia antarctica) on Livingston Island (South Shetland Islands, Maritime Antarctica)

Cited by 6 publications

References 46 publications

Stevia rebaudiana under a CO2 Enrichment Atmosphere: Can CO2 Enrichment Overcome Stomatic, Mesophilic and Biochemical Barriers That Limit Photosynthesis?

Stevia rebaudiana under a CO2 Enrichment Atmosphere: Can CO2 Enrichment Overcome Stomatic, Mesophilic and Biochemical Barriers That Limit Photosynthesis?

The outstanding capacity of Prasiola antarctica to thrive in contrasting harsh environments relies on the constitutive protection of thylakoids and on morphological plasticity

Basking in the sun: how mosses photosynthesise and survive in Antarctica

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