Biological Interactions and Simulated Climate Change Modulates the Ecophysiological Performance of Colobanthus quitensis in the Antarctic Ecosystem

Torres-Díaz, Cristián; Gallardo-Cerda, Jorge; Lavín, Paris; Oses, Rómulo; Carrasco-Urra, Fernando; Átala, Cristian; Acuña‐Rodríguez, Ian S.; Convey, Peter; Molina‐Montenegro, Marco A.

doi:10.1371/journal.pone.0164844

Cited by 40 publications

(40 citation statements)

References 66 publications

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“…Around the world, climate change has had significant direct and indirect impacts on terrestrial species, by being a major cause of speciation and species extirpation (Pound & Salzmann, 2017). Many studies have recently focused on the ecological (Etterson & Mazer, 2016;Wikelski & Tertitski, 2016), ethological (Munoz, Marquez, & Real, 2015) and biological changes (Torres-Diaz et al, 2016;Hulme, 2016) in relation to climatic change. For example, various ecosystems are vulnerable to climate change which may induce a broad array of adverse effects such as disturbances of phenological events, food web disruptions, pathogens and disease spread and ultimately, in worst case scenarios, may include extinction risks (Wu, Lu, Zhou, Chen, & Xu, 2016).…”

Section: Introductionmentioning

confidence: 99%

Decreasing brown bear (Ursus arctos) habitat due to climate change in Central Asia and the Asian Highlands

Aryal

Hegab

et al. 2018

Ecology and Evolution

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Around the world, climate change has impacted many species. In this study, we used bioclimatic variables and biophysical layers of Central Asia and the Asian Highlands combined with presence data of brown bear (Ursus arctos) to understand their current distribution and predict their future distribution under the current rate of climate change. Our bioclimatic model showed that the current suitable habitat of brown bear encompasses 3,430,493 km2 in the study area, the majority of which (>65%) located in China. Our analyses demonstrated that suitable habitat will be reduced by 11% (378,861.30 km2) across Central Asia and the Asian Highlands by 2,050 due to climate change, predominantly (>90%) due to the changes in temperature and precipitation. The spatially averaged mean annual temperature of brown bear habitat is currently −1.2°C and predicted to increase to 1.6°C by 2,050. Mean annual precipitation in brown bear habitats is predicted to increase by 13% (from 406 to 459 mm) by 2,050. Such changes in two critical climatic variables may significantly affect the brown bear distribution, ethological repertoires, and physiological processes, which may increase their risk of extirpation in some areas. Approximately 32% (1,124,330 km2) of the total suitable habitat falls within protected areas, which was predicted to reduce to 1,103,912 km2 (1.8% loss) by 2,050. Future loss of suitable habitats inside the protected areas may force brown bears to move outside the protected areas thereby increasing their risk of mortality. Therefore, more protected areas should be established in the suitable brown bear habitats in future to sustain populations in this region. Furthermore, development of corridors is needed to connect habitats between protected areas of different countries in Central Asia. Such practices will facilitate climate migration and connectivity among populations and movement between and within countries.

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Section: Introductionmentioning

confidence: 99%

Decreasing brown bear (Ursus arctos) habitat due to climate change in Central Asia and the Asian Highlands

Aryal

Hegab

et al. 2018

Ecology and Evolution

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“…Antarctica is one of the regions on the planet with extreme environment [1]. The establishment and survival of living organisms are limited by conditions such as low temperature and nutrient availability, strong winds, high sublimation and evaporation, frequent freezing-thawing cycles, low annual precipitation, high solar incidence and ultraviolet radiation, and low water availability [2][3][4][5].…”

Section: Introductionmentioning

confidence: 99%

First Record of Juncaceicola as Endophytic Fungi Associated with Deschampsia antarctica Desv.

et al. 2018

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In the current study, we present the molecular characterization of an endophyte fungus associated with the leaves of Deschampsia antarctica Desv. (Poaceae), a monocot species native to Antarctica. The isolate was obtained from 90 leaf fragments from two distinct collection sites, both located on Half Moon Island, South Shetland Islands and Maritime Antarctica. The internal transcribed spacer region (ITS) was sequenced and the endophytic fungus was identified as belonging to the genus Juncaceicola Tennakoon, Camporesi, Phook and K.D. Hyde (99% nucleotide sequence identity). When compared to all fungi of the genus Juncaceicola deposited in data base, our isolate showed greater proximity with Juncaceicola typharum, however, because it presents a low bootstrap value to be considered a new species, we treat it as Juncaceicola cf. typharum. Moreover, the identification of our isolate as belonging to the genus Juncaceicola makes this the first occurrence of a species of this genus to be associated with the leaves of Antarctic plants. This work is considered as a starting point for other studies with fungi of this genus associated with leaves of Deschampsia antarctica, as it presents results from two collection points on a single Antarctic island, suggesting that new sites and new Antarctic islands should be explored.

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“…Thus, this particular combination of environmental stresses is expected to favors symbiotic associations between soil microorganisms and Antarctic vascular plants though natural selection. A growing number of studies have shown that plant-microorganism’s mutualisms are common at extreme environments such as deserts (Oelmüller et al, 2009; Sangamesh et al, 2018), high-mountain (Molina-Montenegro et al, 2015; Kotilinèk et al, 2017) or polar ecosystems (Upson et al, 2009b; Newsham, 2011a; Torres-Díaz et al, 2016), for which those microbial symbionts appear to be great candidates for biotechnological applications (Khan et al, 2013; Rho et al, 2017).…”

Section: Discussionmentioning

confidence: 99%

“…As they did also here, those endophytes improved plant physiological parameters (i.e., A max and WUE) and the accumulation of the amino acid proline (Molina-Montenegro et al, 2016a), an osmotic molecule that has been previously associated to other symbionts conferring plant tolerance to water deficit (Nagabhyru et al, 2013; Ortiz et al, 2015). Interestingly, the beneficial effects of these Antarctic fungal endophytes seems to be ubiquitous as they are also able to establish functional symbioses with plant species from phylogenetically unrelated plant families such as the native Antarctic vascular plant Colobanthus quitensis (Torres-Díaz et al, 2016), three endangered shrubs from semiarid environments Flourensia thurifera (Asteraceae), Puya berteroniana (Bromeliacae) and Senna cumingii (Fabacae) (Molina-Montenegro et al, 2016b; Fardella et al, 2014) and the endangered south American tree Nothofagus alessandrii (Torres-Díaz, unpublished results).…”

Section: Discussionmentioning

confidence: 99%

Root endophytes improve physiological performance and yield in crops under salt stress by up-regulating the foliar sodium concentration

Molina‐Montenegro

Acuña‐Rodríguez

Torres-Díaz

et al. 2018

Preprint

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1 2 Root endophytes improve physiological performance and yield in crops under 3 salt stress by up-regulating the foliar sodium concentration 4 5 3 1performance. In addition, the presence of fungal endophytes was correlated with a higher regulation of ion 3 2 homeostasis by enhanced expression of NHX1 gene. Our results suggest that presence of fungal endophytes 3 3 could minimize the negative effect of salt by improving osmotic tolerance through ecophysiological and 3 4 molecular mechanisms. Thus, root-endophytes might be a successful biotechnological tool to maintain high 3 5 levels of ecophysiological performance and productivity in zones under osmotic stress, acting as potential 3 6solution to maintain the global food security.3 7 3 8

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Biological Interactions and Simulated Climate Change Modulates the Ecophysiological Performance of Colobanthus quitensis in the Antarctic Ecosystem

Cited by 40 publications

References 66 publications

Decreasing brown bear (Ursus arctos) habitat due to climate change in Central Asia and the Asian Highlands

Decreasing brown bear (Ursus arctos) habitat due to climate change in Central Asia and the Asian Highlands

First Record of Juncaceicola as Endophytic Fungi Associated with Deschampsia antarctica Desv.

Root endophytes improve physiological performance and yield in crops under salt stress by up-regulating the foliar sodium concentration

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