Susanna Pollastri1, Andreas Savvides2, Massimo Pesando1, Erica Lumini1, Maria Grazia Volpe3, Elif Aylin Ozudogru4, Antonella Faccio1, Fausta De Cunzo3, Marco Michelozzi5, Maurizio Lambardi4, Vasileios Fotopoulos2, Francesco Loreto6, Mauro Centritto4, Raffaella Balestrini7. 1. The National Research Council of Italy (CNR), Institute for Sustainable Plant Protection (IPSP), 10125 Turin (M.P., E.L., A.F., R.B.), 50019, Sesto Fiorentino, SP, Italy. 2. Cyprus University of Technology (CUT), Limassol, Cyprus. 3. CNR, Institute of Food Sciences, Avellino, Italy. 4. CNR, Institute of Trees and Timber (IVALSA), Sesto Fiorentino, Italy. 5. CNR, Institute of Biosciences and Bioresources, Sesto Fiorentino, Italy. 6. CNR, Department of Biology, Agriculture and Food Sciences (DiSBA), Rome, Italy. 7. The National Research Council of Italy (CNR), Institute for Sustainable Plant Protection (IPSP), 10125 Turin (M.P., E.L., A.F., R.B.), 50019, Sesto Fiorentino, SP, Italy. raffaella.balestrini@ipsp.cnr.it.
Abstract
MAIN CONCLUSION: AM symbiosis did not strongly affect Arundo donax performances under salt stress, although differences in the plants inoculated with two different fungi were recorded. The mechanisms at the basis of the improved tolerance to abiotic stresses by arbuscular mycorrhizal (AM) fungi have been investigated mainly focusing on food crops. In this work, the potential impact of AM symbiosis on the performance of a bioenergy crop, Arundo donax, under saline conditions was considered. Specifically, we tried to understand whether AM symbiosis helps this fast-growing plant, often widespread in marginal soils, withstand salt. A combined approach, involving eco-physiological, morphometric and biochemical measurements, was used and the effects of two different AM fungal species (Funneliformis mosseae and Rhizophagus irregularis) were compared. Results indicate that potted A. donax plants do not suffer permanent damage induced by salt stress, but photosynthesis and growth are considerably reduced. Since A. donax is a high-yield biomass crop, reduction of biomass might be a serious agronomical problem in saline conditions. At least under the presently experienced growth conditions, and plant-AM combinations, the negative effect of salt on plant performance was not rescued by AM fungal colonization. However, some changes in plant metabolisms were observed following AM-inoculation, including a significant increase in proline accumulation and a trend toward higher isoprene emission and higher H2O2, especially in plants colonized by R. irregularis. This suggests that AM fungal symbiosis influences plant metabolism, and plant-AM fungus combination is an important factor for improving plant performance and productivity, in presence or absence of stress conditions.
MAIN CONCLUSION: AM symbiosis did not strongly affect Arundo donax performances under salt stress, although differences in the plants inoculated with two different fungi were recorded. The mechanisms at the basis of the improved tolerance to abiotic stresses by arbuscular mycorrhizal (AM) fungi have been investigated mainly focusing on food crops. In this work, the potential impact of AM symbiosis on the performance of a bioenergy crop, Arundo donax, under saline conditions was considered. Specifically, we tried to understand whether AM symbiosis helps this fast-growing plant, often widespread in marginal soils, withstand salt. A combined approach, involving eco-physiological, morphometric and biochemical measurements, was used and the effects of two different AM fungal species (Funneliformis mosseae and Rhizophagus irregularis) were compared. Results indicate that potted A. donax plants do not suffer permanent damage induced by salt stress, but photosynthesis and growth are considerably reduced. Since A. donax is a high-yield biomass crop, reduction of biomass might be a serious agronomical problem in saline conditions. At least under the presently experienced growth conditions, and plant-AM combinations, the negative effect of salt on plant performance was not rescued by AM fungal colonization. However, some changes in plant metabolisms were observed following AM-inoculation, including a significant increase in proline accumulation and a trend toward higher isoprene emission and higher H2O2, especially in plants colonized by R. irregularis. This suggests that AM fungal symbiosis influences plant metabolism, and plant-AM fungus combination is an important factor for improving plant performance and productivity, in presence or absence of stress conditions.
Authors: Elisabeth Armada; Rosario Azcón; Olga M López-Castillo; Mónica Calvo-Polanco; Juan Manuel Ruiz-Lozano Journal: Plant Physiol Biochem Date: 2015-03-18 Impact factor: 4.270
Authors: Jihai Gu; Jun Yao; Gyozo Jordan; Beenish Roha; Ning Min; Hao Li; Chao Lu Journal: Environ Sci Pollut Res Int Date: 2018-08-18 Impact factor: 4.223
Authors: Katarína Ondreičková; Marcela Gubišová; Michaela Piliarová; Miroslav Horník; Pavel Matušinský; Jozef Gubiš; Lenka Klčová; Martina Hudcovicová; Ján Kraic Journal: Microorganisms Date: 2019-10-29