Abstract
A plants’ fitness to a large extent depends on its capacity to adapt to spatio-temporally varying environmental conditions. One such environmental condition to which plants display extensive phenotypic plasticity is soil nitrate levels and patterns. In response to heterogeneous nitrate distribution, plants show a so-called preferential foraging response. Herein root growth is enhanced in high nitrate patches and repressed in low nitrate locations beyond a level that can be explained from local nitrate sensing. Although various molecular players involved in this preferential foraging behavior have been identified, how these together shape root system adaptation has remained unresolved. Here we use a simple modeling approach in which we incrementally incorporate the known molecular pathways to investigate the combination of regulatory mechanisms that underly preferential root nitrate foraging. Our model suggests that instead of involving a growth suppressing supply signal, growth reduction on the low nitrate side may arise from reduced root foraging and increased competition for carbon. Additionally, our work suggests that the long distance CK signaling involved in preferential root foraging may function as a supply signal modulating demand signaling strength. We illustrate how this integration of demand and supply signals prevents excessive preferential foraging under conditions in which demand is not met by sufficient supply and a more generic foraging in search of nitrate should be maintained.
Highlights
Phenotypic plasticity is of critical importance for sessile plants to adapt to and survive in a variable, heterogeneous environment
Local and Systemic C-terminally encoded peptide (CEP) Dynamics To model the effect of nitrate demand signaling on preferential root foraging, we extended our model with a local nitrate dependent, decreasing, non-linear production of CEP
In the current study we investigated the case of preferential foraging for nitrate
Summary
Phenotypic plasticity is of critical importance for sessile plants to adapt to and survive in a variable, heterogeneous environment. For somewhat less low internal nitrate levels plants instead display a foraging response, promoting root growth via the induction of TAR2, which results in enhanced local auxin biosynthesis (Ma et al, 2014). This foraging response likely involves the low nitrate status induced expression of WAK4 and the downstream auxin transporter MDR4/PGP4 (Giehl et al, 2014) known to promote lateral root formation (Lally et al, 2001; Terasaka et al, 2005) (Figure 1A, second from left). Root growth may be further repressed through the HNI9 dependent repression of nitrate transport (Girin et al, 2010) (Figure 1A, right)
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