What Antarctic Plants Can Tell Us about Climate Changes: Temperature as a Driver for Metabolic Reprogramming

• Published in: Biomolecules (Basel, Switzerland) Vol. 11; no. 8; p. 1094
• Main Authors: Bertini, Laura, Cozzolino, Flora, Proietti, Silvia, Falconieri, Gaia Salvatore, Iacobucci, Ilaria, Salvia, Rosanna, Falabella, Patrizia, Monti, Maria, Caruso, Carla
• Format: Journal Article
• Language: English
• Published: Basel MDPI AG 23.07.2021; MDPI
• Subjects: Carbon dioxide; Cell walls; Climate change; Colobanthus quitensis; Colonization; differential proteomic analysis; Environmental conditions; Flowers & plants; Global warming; Mesophyll; Metabolism; Metabolites; Mimicry; open top chambers; Oxidative stress; Physiology; Plants; Polyamines; Proteins; response to stress; temperature changes; Italy; Antarctica; Antarctic Peninsula; United States > US
• ISSN: 2218-273X; 2218-273X
• DOI: 10.3390/biom11081094

Global warming is strongly affecting the maritime Antarctica climate and the consequent melting of perennial snow and ice covers resulted in increased colonization by plants. Colobanthus quitensis is a vascular plant highly adapted to the harsh environmental conditions of Antarctic Peninsula and understanding how the plant is responding to global warming is a new challenging target for modern cell physiology. To this aim, we performed differential proteomic analysis on C. quitensis plants grown in natural conditions compared to plants grown for one year inside open top chambers (OTCs) which determine an increase of about 4 °C at midday, mimicking the effect of global warming. A thorough analysis of the up- and downregulated proteins highlighted an extensive metabolism reprogramming leading to enhanced photoprotection and oxidative stress control as well as reduced content of cell wall components. Overall, OTCs growth seems to be advantageous for C. quitensis plants which could benefit from a better CO2 diffusion into the mesophyll and a reduced ROS-mediated photodamage.