Abstract

Antarctic plants have developed mechanisms to deal with one or more adverse factors which allow them to successfully survive extreme environments. Certain effective mechanisms to face adverse environmental factors can arise through the establishment of functional symbiosis with endophytic foliar fungi. In this work, we explored the role of foliar endophytes on host plant performance under high level of UV-B radiation. To unveil the underlying mechanisms, we identified and characterized the expression of genes associated to UV-B photoreception, accumulation of key flavonoids, and response to physiological stress in plants Colobanthus quitensis, grown with (E+) and without (E-) endophytes. The deduced proteins of CqUVR8, CqHY5 and CqFLS share the characteristic domains and display high degrees of similarity with other described corresponding proteins from plants. Physiological analysis showed that E+ plants display lower lipid peroxidation and higher Fv/Fm ratios under high UV-B radiation. In addition, compared to E-, E+ plants showed lower CqUVR8, CqHY5 and CqFLS transcript levels. On the other hand, the content of the flavonoid quercetin in plant leaves exposed to high UV-B was almost 8-fold higher in E- than in E+ plants 48 h after treatment; however, this pattern was reverted one week later. The results suggests that Antarctic endophytic fungi minimize cell damage, boost physiological performance, and positively influence plant tolerance to UV-B radiation. We propose that fungal endophytes could be an effective biological partnership for Antarctic plants to cope with high UV-B radiation.

Highlights

  • Ultraviolet B radiation (UV-B) is a minor component of the solar radiation, it has a disproportionately harmful effect on plants (Jansen et al, 1998)

  • ultraviolet B radiation (UV-B) Radiation Affects Photochemical Performance and Reduce Oxidative Damage of C. quitensis Depending on Endophyte Presence

  • Plants without endophytes (E-) showed significantly higher content of thiobarbituric acid reactivity and, cell damage caused by exposure to UV-B radiation (Table 2)

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Summary

Introduction

Ultraviolet B radiation (UV-B) is a minor component of the solar radiation, it has a disproportionately harmful effect on plants (Jansen et al, 1998). UV-B radiation (280 to 315 nm) is absorbed by the ozone layer, permitting that a small proportion reaches surface of the Earth. The levels of UV-B radiation that reach the earth’s surface depends on several factors such as latitude, altitude, season, time of day as well as cloudiness (Seckmeyer et al, 2008). Plant exposure to high levels of UV-B radiation causes a decrease in the photosynthetic efficiency of photosystem (PS) II (Fv/Fm) due to the degradation of the PSII protein D1 (Caldwell et al, 2007; Shourie et al, 2014). The final consequences at individual level, is a reduction in biomass and reproduction output, while even generating mutations in germinal lines with clear effects on the following generations (Kaling et al, 2015)

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