Your search keyword '"Atala, Cristian"' showing total 5 results

1. Fungal endophytes improve the performance of host plants but do not eliminate the growth/defence trade-off.

Author

Atala C, Acuña-Rodríguez IS, Torres-Díaz C, and Molina-Montenegro MA

Subjects

Fungi, Plants microbiology, Symbiosis, Biological Phenomena, Endophytes

Published

2022

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

Author

Torres-Díaz C, Gallardo-Cerda J, Lavin P, Oses R, Carrasco-Urra F, Atala C, Acuña-Rodríguez IS, Convey P, and Molina-Montenegro MA

Subjects

Antarctic Regions, Biomass, Caryophyllaceae chemistry, Caryophyllaceae microbiology, Climate Change, Ecosystem, Temperature, Caryophyllaceae physiology, Endophytes physiology, Phytochemicals analysis

Abstract

Most climate and environmental change models predict significant increases in temperature and precipitation by the end of the 21st Century, for which the current functional output of certain symbioses may also be altered. In this context we address the following questions: 1) How the expected changes in abiotic factors (temperature, and water) differentially affect the ecophysiological performance of the plant Colobanthus quitensis? and 2) Will this environmental change indirectly affect C. quitensis photochemical performance and biomass accumulation by modifying its association with fungal endophytes? Plants of C. quitensis from King George Island in the South Shetland archipelago (62°09' S), and Lagotellerie Island in the Antarctic Peninsula (65°53' S) were put under simulated abiotic conditions in growth chambers following predictive models of global climate change (GCC). The indirect effect of GCC on the interaction between C. quitensis and fungal endophytes was assessed in a field experiment carried out in the Antarctica, in which we eliminated endophytes under contemporary conditions and applied experimental watering to simulate increased precipitation input. We measured four proxies of plant performance. First, we found that warming (+W) significantly increased plant performance, however its effect tended to be less than watering (+W) and combined warming and watering (+T°+W). Second, the presence of fungal endophytes improved plant performance, and its effect was significantly decreased under experimental watering. Our results indicate that both biotic and abiotic factors affect ecophysiological performance, and the directions of these influences will change with climate change. Our findings provide valuable information that will help to predict future population spread and evolution through using ecological niche models under different climatic scenarios., Competing Interests: The authors have declared that no competing interests exist.

Published

2016

3. Root endophytic Penicillium promotes growth of Antarctic vascular plants by enhancing nitrogen mineralization

Author

Oses-Pedraza, Rómulo, Torres-Díaz, Cristian, Lavín, Paris, Retamales-Molina, Patricio, Atala, Cristian, Gallardo-Cerda, Jorge, Acuña-Rodríguez, Ian S., and Molina-Montenegro, Marco A.

Published

2020

4. Inoculation with extreme endophytes improves performance and nutritional quality in crop species grown under exoplanetary conditions.

Author

Molina-Montenegro, Marco A., Escobedo, Victor M., and Atala, Cristian

Subjects

CROP quality, ENDOPHYTES, ENDOPHYTIC fungi, SPINACH, SPECIES, EDIBLE plants, MONOCULTURE agriculture, LETTUCE

Abstract

Introduction: Technological advances have made possible long space travels and even exoplanetary colonies in the future. Nevertheless, the success of these activities depends on our ability to produce edible plants in stressful conditions such as high radiation, extreme temperatures and low oxygen levels. Since beneficial microorganisms, such as fungal endophytes from extreme environments, have helped agriculture cope with those difficulties, endophytic fungi may be a putative tool to ensure plant growth under exoplanetary conditions. Additionally, growing crops in polyculture has been shown to increase productivity and spatial efficiency, which is essential given the likely space restrictions in such conditions. Methods: We evaluated the effect of the inoculation with a mix of two fungal endophytes from the Atacama Desert on performance (survival and biomass) and nutritional quality of three crop species (lettuce, chard and spinach) grown under exoplanetary conditions. In addition, we measured the amount of antioxidants (flavonoids and phenolics) as possible mechanisms to cope with such abiotic conditions. The exoplanetary conditions were; high UV radiation, low temperature, low water availability, and low oxygen levels. These crops were put in growing chambers in monoculture, dual culture and polyculture (the three species in the same pot) for 30 days. Results and Discussion: Our results show that inoculation with extreme endophytes improved survival by ca. 15 - 35% and biomass by ca. 30 - 35% in all crop species. The most evident increase was when grown in polyculture, except for survival in spinach, where inoculated plants had higher survival only in dual culture. Nutritional quality and the amount of the antioxidant compounds antioxidants increased in all crop species when inoculated with the endophytes. Overall, fungal endophytes isolated from extreme environments such as the Atacama Desert, the driest desert in the world, could be a key biotechnological tool for future space agriculture, helping plants cope with environmental stress. Additionally, inoculated plants should be grown in polyculture to increase crop turnover and space-use efficiency. Lastly, these results provide useful insights to face the future challenges of space-farming. [ABSTRACT FROM AUTHOR]

Published

2023

5. Fungal Symbionts Enhance N-Uptake for Antarctic Plants Even in Non-N Limited Soils.

Author

Acuña-Rodríguez, Ian S., Galán, Alexander, Torres-Díaz, Cristian, Atala, Cristian, and Molina-Montenegro, Marco A.

Subjects

SOILS, HOST plants, VASCULAR plants, PLANT biomass, RHIZOSPHERE, ISOTOPIC signatures

Abstract

Plant-fungi interactions have been identified as fundamental drivers of the plant host performance, particularly in cold environments where organic matter degradation rates are slow, precisely for the capacity of the fungal symbiont to enhance the availability of labile nitrogen (N) in the plant rhizosphere. Nevertheless, these positive effects appear to be modulated by the composition and amount of the N pool in the soil, being greater when plant hosts are growing where N is scarce as is the case of Antarctic soils. Nevertheless, in some coastal areas of this continent, seabirds and marine mammal colonies exert, through their accumulated feces and urine a strong influence on the edaphic N content surrounding their aggregation points. To evaluate if the fungal symbionts (root endophytes), associated to the only two Antarctic vascular plants Colobanthus quitensis and Deschampsia antarctica , act as N-uptake enhancers, even in such N-rich conditions as those found around animal influence, we assessed, under controlled conditions, the process of N mineralization in soil by the accumulation of NH4+ in the rizhosphere and the biomass accumulation of plants with (E+) and without (E−) fungal symbionts. Complementarily, taking advantage of the isotopic N-fractionation that root-fungal symbionts exert on organic N molecules during its acquisition process, we also determined if endophytes actively participate in the Antarctic plants N-uptake, when inorganic N is not a limiting factor, by estimating the δ15N isotopic signatures in leaves. Overall, symbiotic interaction increased the availability of NH4+ in the rhizosphere of both species. As expected, the enhanced availability of inorganic N resulted in a higher final biomass in E + compared with E− plants of both species. In addition, we found that the positive role of fungal symbionts was also actively linked to the process of N-uptake in both species, evidenced by the contrasting δ15N signatures present in E+ (−0.4 to −2.3‰) relative to E− plants (2.7–3.1‰). In conclusion, despite being grown under rich N soils, the two Antarctic vascular plants showed that the presence of root-fungal endophytes, furthermore enhanced the availability of inorganic N sources in the rhizosphere, has a positive impact in their biomass, remarking the active participation of these endophytes in the N-uptake process for plants inhabiting the Antarctic continent. [ABSTRACT FROM AUTHOR]

Published

2020