RÉSUMÉ
Arbuscular mycorrhizal fungi (AMF) establish symbiotic interaction with 80% of known land plants. It has a pronounced impact on plant growth, water absorption, mineral nutrition, and protection from abiotic stresses. Plants are very dynamic systems having great adaptability under continuously changing drying conditions. In this regard, the function of AMF as a biological tool for improving plant drought stress tolerance and phenotypic plasticity, in terms of establishing mutualistic associations, seems an innovative approach towards sustainable agriculture. However, a better understanding of these complex interconnected signaling pathways and AMF-mediated mechanisms that regulate the drought tolerance in plants will enhance its potential application as an innovative approach in environmentally friendly agriculture. This paper reviews the underlying mechanisms that are confidently linked with plant-AMF interaction in alleviating drought stress, constructing emphasis on phytohormones and signaling molecules and their interaction with biochemical, and physiological processes to maintain the homeostasis of nutrient and water cycling and plant growth performance. Likewise, the paper will analyze how the AMF symbiosis helps the plant to overcome the deleterious effects of stress is also evaluated. Finally, we review how interactions between various signaling mechanisms governed by AMF symbiosis modulate different physiological responses to improve drought tolerance. Understanding the AMF-mediated mechanisms that are important for regulating the establishment of the mycorrhizal association and the plant protective responses towards unfavorable conditions will open new approaches to exploit AMF as a bioprotective tool against drought.
Sujet(s)
Mycorhizes/physiologie , Stress physiologique , Adaptation physiologique , Sécheresses , Mycorhizes/métabolisme , Facteur de croissance végétal/métabolismeRÉSUMÉ
By using traditional staining and DNA cloning and sequencing techniques, this paper studied the effects of fertilization on the arbuscular mycorrhizal (AM) colonization and AM fungal community in Elymus nutans roots across an 8-year nitrogen (N) and phosphorus (P) fertilization gradient. With the increasing level of fertilization, the AM colonization and arbuscular colonization per unit root length reduced from 67.5% to 7.3% and from 5.2% to 0.1%, respectively. A total of 24 AM fungal phylotypes were detected in E. nutans roots, whilst the mean AM fungal richness reduced from 6 to 2.6 across the fertilization gradient. Different fertilization had significant effects on the AM fungal community composition, and there existed significant correlations between the AM fungal community composition and the soil available P and root N contents. The availability of N and P increased gradually across the fertilization gradient, and had significant negative correlations with both AM colonization and AM fungal richness. It was suggested that high level fertilization would reduce the activity of AM symbionts, and result in the large loss of AM fungal biodiversity.