Antarctic Studies Show Lichens to be Excellent Biomonitors of Climate Change

Sancho, Leopoldo G.; Pintado, Ana; Green, T. G. Allan

doi:10.3390/d11030042

Cited by 65 publications

(51 citation statements)

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“…Photosynthetic performance of lichens generally increases 1-2 h after sunrise, and then rapidly decreases because high irradiation and an increase in temperature cause CO 2 exchange to cease under the desiccating conditions [42]. Indeed, the growth rate of Usnea antarctica was sensitive to decreasing mean temperatures [23,24], and approximately 1000 µmol/m 2 /s light intensity was insufficient to induce photoinhibition [26,27]. Such photosynthetic features of Usnea sp.…”

Section: Borealis Photosynthetic Activity At Night and Dawnmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

“…In recent decades, lichens have been widely used in environmental monitoring, especially to study the effect of air pollution; however, their role as a bio-indicator reflecting climate changes in the Antarctic region was recently reassessed [23,24]. Approximately 400 species of lichens reside on dry and rocky surfaces rather than in wet habitats in the Antarctic Peninsula [24]. Members of the lichen genus Usnea are distributed across most dry habitats of Antarctica and have been used to investigate ecophysiology, antioxidant production, and photoinhibition responses and in long-term and short-term monitoring studies [23][24][25][26][27][28].…”

Section: Introductionmentioning

confidence: 99%

“…Members of the lichen genus Usnea are distributed across most dry habitats of Antarctica and have been used to investigate ecophysiology, antioxidant production, and photoinhibition responses and in long-term and short-term monitoring studies [23][24][25][26][27][28]. In U. antarctica, for example, their growth rate is strongly correlated with mean summer temperature changes, and photoinhibitory quenching (qI)-a component of NPQ-mainly works to protect photosystems from high light intensity [23,24,26,27]. In addition, a low NPQ response is consistent with the finding that a small amount of glutathione is induced by high light levels, indicating that U. antarctica is likely to produce secondary compounds to protect against excess light [28].…”

Section: Introductionmentioning

confidence: 99%

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Study of Ecophysiological Responses of the Antarctic Fruticose Lichen Cladonia borealis Using the PAM Fluorescence System under Natural and Laboratory Conditions

Cho

Choi

Hong

et al. 2020

Plants

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Antarctic lichens have been used as indicators of climate change for decades, but only a few species have been studied. We assessed the photosynthetic performance of the fruticose lichen Cladonia borealis under natural and laboratory conditions using the PAM fluorescence system. Compared to that of sun-adapted Usnea sp., the photosynthetic performance of C. borealis exhibits shade-adapted lichen features, and its chlorophyll fluorescence does not occur during dry days without rain. To understand its desiccation-rehydration responses, we measured changes in the PSII photochemistry in C. borealis under the average light intensity of dawn light and daylight and the desiccating conditions of its natural microclimate. Interestingly, samples under daylight and rapid-desiccation conditions showed a delayed reduction in Fv’/Fm’ and rETRmax, and an increase in Y(II) and Y(NPQ) levels. These results suggest that the photoprotective mechanism of C. borealis depends on sunlight and becomes more efficient with improved desiccation tolerance. Amplicon sequencing revealed that the major photobiont of C. borealis was Asterochloris irregularis, which has not been reported in Antarctica before. Collectively, these results from both field and laboratory could provide a better understanding of specific ecophysiological responses of shade-adapted lichens in the Antarctic region.

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Section: Borealis Photosynthetic Activity At Night and Dawnmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Study of Ecophysiological Responses of the Antarctic Fruticose Lichen Cladonia borealis Using the PAM Fluorescence System under Natural and Laboratory Conditions

Cho

Choi

Hong

et al. 2020

Plants

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“…Thus, it appears that symbiotic interactions in lichens can react very sensitively to environmental change although this conclusion is based on a small database, and these responses have been investigated only in a few species (Allen and Lendemer 2016;Colesie et al 2014b;Sancho et al 2017). In general, there is agreement that climatic changes will influence the diversity, abundance and growth of lichens (Sancho et al 2017) and that lichens therefore represent excellent bioindicators for processes associated with global warming (Alatalo et al 2015;Allen and Lendemer 2016;Bassler et al 2016;Sancho et al 2019).…”

Section: Introductionmentioning

confidence: 99%

Myco- and photobiont associations in crustose lichens in the McMurdo Dry Valleys (Antarctica) reveal high differentiation along an elevational gradient

Wagner

Bathke²,

Cary

et al. 2019

Preprint

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The climate conditions of the McMurdo Dry Valleys (78° S) are characterized by low temperatures and low precipitation. The annual temperatures at the valley bottoms have a mean range from -30 °C to -15 °C and decrease with elevation. Precipitation occurs mostly in form of snow (3-50 mm a -1 water equivalent) and, liquid water is rare across much of the landscape for most of the year and represents the primary limitation to biological activity. Snow delivered off the polar plateau by drainage winds, dew and humidity provided by clouds and fog are important water sources for rock inhibiting crustose lichens. In addition, the combination of the extremely low humidity and drying caused by foehn winds, confined to lower areas of the valleys, with colder and moister air at higher altitudes creates a strongly improving water availability gradient with elevation.We investigated the diversity and interaction specificity of myco-/photobiont associations of a total of 232 crustose lichen specimens, collected along an elevational gradient (171-959 m a.s.l.) within the McMurdo Dry Valleys with regard to the spatial distribution caused by climatological and geographical factors. For the identification of the mycobiont and photobiont species three markers each were amplified (nrITS, mtSSU, RPB1 and nrITS, COX2, respectivley). Elevation, associated with a water availability gradient, turned out to be the key factor explaining most of the distribution patterns of the mycobionts. Pairwise comparisons showed Lecidea cancriformis and Rhizoplaca macleanii to be significantly more common at higher, and Carbonea vorticosa and Lecidea polypycnidophora at lower, elevations. Lichen photobionts were dominated by the globally distributed Trebouxia OTU, Tr_A02 which occurred at all habitats. Network specialization resulting from mycobiont-photobiont bipartite network structure varied with elevation and associated abiotic factors.Along an elevational gradient, the spatial distribution, diversity and genetic variability of the lichen symbionts appear to be mainly influenced by improved water relations at higher altitudes.

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