Abstract
Phosphorus, one of the essential elements for plants, is often a limiting nutrient in soils. Low phosphate (Pi) availability induces sugar-dependent systemic expression of genes and modulates the root system architecture (RSA). Here, we present the differential effects of sucrose (Suc) and auxin on the Pi deficiency responses of the primary and lateral roots of Arabidopsis (Arabidopsis thaliana). Inhibition of primary root growth and loss of meristematic activity were evident in seedlings grown under Pi deficiency with or without Suc. Although auxin supplementation also inhibited primary root growth, loss of meristematic activity was observed specifically under Pi deficiency with or without Suc. The results suggested that Suc and auxin do not influence the mechanism involved in localized Pi sensing that regulates growth of the primary root and therefore delineates it from sugar-dependent systemic Pi starvation responses. However, the interaction between Pi and Suc was evident on the development of the lateral roots and root hairs in the seedlings grown under varying levels of Pi and Suc. Although the Pi+ Suc- condition suppressed lateral root development, induction of few laterals under the Pi- Suc- condition point to increased sensitivity of the roots to auxin during Pi deprivation. This was supported by expression analyses of DR5uidA, root basipetal transport assay of auxin, and RSA of the pgp19 mutant exhibiting reduced auxin transport. A significant increase in the number of lateral roots under the Pi- Suc- condition in the chalcone synthase mutant (tt4-2) indicated a potential role for flavonoids in auxin-mediated Pi deficiency-induced modulation of RSA. The study thus demonstrated differential roles of Suc and auxin in the developmental responses of ontogenetically distinct root traits during Pi deprivation. In addition, lack of cross talk between local and systemic Pi sensing as revealed by the seedlings grown under either the Pi- Suc- condition or in the heterogeneous Pi environment highlighted the coexistence of Suc-independent and Suc-dependent regulatory mechanisms that constitute Pi starvation responses.
Highlights
Phosphorus, one of the essential elements for plants, is often a limiting nutrient in soils
The effects of Suc and Pi availability on the growth and development of Arabidopsis were evaluated by analyzing the morphophysiological traits of seedlings grown under Pi1 Suc1 (P1S1), Pi1 Suc2 (P1S2), Pi2 Suc1 (P2S1), and Pi2 Suc2 (P2S2) conditions for 7 d (Fig. 1)
Relative to P1S1 and P2S1 seedlings, there was a significant reduction of about 40% to 45% in the fresh weight of P1S2 and P2S2 seedlings
Summary
Phosphorus, one of the essential elements for plants, is often a limiting nutrient in soils. Low phosphate (Pi) availability induces sugar-dependent systemic expression of genes and modulates the root system architecture (RSA). The study demonstrated differential roles of Suc and auxin in the developmental responses of ontogenetically distinct root traits during Pi deprivation. Cross talk between sugar sensing and systemic Pi starvation responses has been explicitly demonstrated in several studies (Franco-Zorrilla et al, 2005; Liu et al, 2005; Karthikeyan et al, 2007). It appears that lack of sugar suppresses the expression of a host of PSI genes. Little is known about the specific involvement of sugars in sensing of local availability of Pi and consequent developmental responses of ontogenetically distinct RSA traits
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