Abstract
The plant root is the first organ to encounter salinity stress, but the effect of salinity on root system architecture (RSA) remains elusive. Both the reduction in main root (MR) elongation and the redistribution of the root mass between MRs and lateral roots (LRs) are likely to play crucial roles in water extraction efficiency and ion exclusion. To establish which RSA parameters are responsive to salt stress, we performed a detailed time course experiment in which Arabidopsis (Arabidopsis thaliana) seedlings were grown on agar plates under different salt stress conditions. We captured RSA dynamics with quadratic growth functions (root-fit) and summarized the salt-induced differences in RSA dynamics in three growth parameters: MR elongation, average LR elongation, and increase in number of LRs. In the ecotype Columbia-0 accession of Arabidopsis, salt stress affected MR elongation more severely than LR elongation and an increase in LRs, leading to a significantly altered RSA. By quantifying RSA dynamics of 31 different Arabidopsis accessions in control and mild salt stress conditions, different strategies for regulation of MR and LR meristems and root branching were revealed. Different RSA strategies partially correlated with natural variation in abscisic acid sensitivity and different Na(+)/K(+) ratios in shoots of seedlings grown under mild salt stress. Applying root-fit to describe the dynamics of RSA allowed us to uncover the natural diversity in root morphology and cluster it into four response types that otherwise would have been overlooked.
Highlights
The plant root is the first organ to encounter salinity stress, but the effect of salinity on root system architecture (RSA) remains elusive
We identify the RSA components that are responsive to salt stress, but we describe the natural variation in dynamics of salt-induced changes leading to redistribution of root mass and different root morphology
To determine which RSA parameters are most responsive to salt stress treatment, a dose-response experiment was performed on four different natural Arabidopsis accessions (Col-0, Burren [Bur-0], C24, and Tsushima [Tsu-0]), previously described to differ in their salinity tolerance (Jha et al, 2010; Katori et al, 2010; Galpaz and Reymond, 2010)
Summary
The plant root is the first organ to encounter salinity stress, but the effect of salinity on root system architecture (RSA) remains elusive. We identify the RSA components that are responsive to salt stress, but we describe the natural variation in dynamics of salt-induced changes leading to redistribution of root mass and different root morphology. Studying saltinduced changes in RSA dynamics of 31 Arabidopsis accessions revealed four major strategies conserved among the accessions Those four strategies were due to differences in salt stress sensitivity of individual RSA components (i.e. growth rates of MRs and LRs, and increases in the number of emerged LRs). This diversity in root morphology responses caused by salt stress was observed to be partially associated with differences in ABA, but not ethylene sensitivity. Our results imply that different RSA strategies identified in this study reflect diverse adaptations to different soil conditions and might contribute to efficient water extraction and ion compartmentalization in their native environments
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