Abstract
Aegilops tauschii Coss. (2n = 2x = 14, DD) is a problematic weed and a rich source of genetic material for wheat crop improvement programs. We used physiological traits (plant height, dry weight biomass, Na+ and K+ concentration) and 14 microsatellite markers to evaluate the genetic diversity and salinity tolerance in 40 Ae. tauschii populations. The molecular marker allied with salinity stress showed polymorphisms, and a cluster analysis divided the populations into different groups, which indicated diversity among populations. Results showed that the expression level of AeHKT1;4 and AeNHX1 were significantly induced during salinity stress treatments (50 and 200 mM), while AeHKT1;4 showed relative expression in roots, and AeNHX1 was expressed in leaves under the control conditions. Compared with the control conditions, the expression level of AeHKT1;4 significantly increased 1.7-fold under 50 mM salinity stress and 4.7-fold under 200 mM salinity stress in the roots of Ae. tauschii. AeNHX1 showed a relative expression level of 1.6-fold under 50 mM salinity stress and 4.6-fold under 200 mM salinity stress compared with the control conditions. The results provide strong evidence that, under salinity stress conditions, AeHKT1;4 and AeNHX1 synergistically regulate the Na+ homeostasis through regulating Na+ transport in Ae. tauschii. AeNHX1 sequestrated the Na+ into vacuoles, which control the regulation of Na+ transport from roots to leaves under salinity stress conditions in Ae. tauschii.
Highlights
Soil salinity is one of the major environmental factors which limits the agriculture productivity [1]
Our results indicated that all physiological parameters were signifaffected by salinity stress conditions
Microsatellite markers allied with salinity tolerance showed polymorphism and diversity between these populations
Summary
Soil salinity is one of the major environmental factors which limits the agriculture productivity [1]. Plants have developed various mechanisms against salinity stress including sequestering Na+ concentration in vacuoles, decreasing Na+ accumulation in the cytosol, and extruding cytoplasmic Na+ out of the cell aided by (bifunctional K:H/Na: H antiporter) NHX1 [5]. Na+ is a fundamental strategy for plants to overcome salinity stress, and the related phenotypes, facilitated by different Na+ transport-related genes, including HKT1, play an important role in vital functions in Na+ homeostasis [9]. In Arabidopsis thaliana, the HKT; is responsible for Na+ movement in xylem vessels and decreases Na+ concentration in leaves [11]. Proteins located on plasma membranes of surrounding cells remove Na+ from the xylem, reducing its transport towards plant leaves [13]
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