Abstract
Ammonium acquisition by plant roots is mediated by AMMONIUM TRANSPORTERs (AMTs), ubiquitous membrane proteins with essential roles in nitrogen nutrition in all organisms. In microbial and plant cells, ammonium transport activity is controlled by ammonium-triggered feedback inhibition to prevent cellular ammonium toxicity. Data from heterologous expression in yeast indicate that oligomerization of plant AMTs is critical for allosteric regulation of transport activity, in which the conserved cytosolic C terminus functions as a trans-activator. Employing the coexpressed transporters AMT1;1 and AMT1;3 from Arabidopsis thaliana as a model, we show here that these two isoforms form functional homo- and heterotrimers in yeast and plant roots and that AMT1;3 carrying a phosphomimic residue in its C terminus regulates both homo- and heterotrimers in a dominant-negative fashion in vivo. (15)NH4(+) influx studies further indicate that allosteric inhibition represses ammonium transport activity in roots of transgenic Arabidopsis expressing a phosphomimic mutant together with functional AMT1;3 or AMT1;1. Our study demonstrates in planta a regulatory role in transport activity of heterooligomerization of transporter isoforms, which may enhance their versatility for signal exchange in response to environmental triggers.
Highlights
Ammonium is the predominant N form in most soils, supporting the highest growth rates when present in a mixed supply with nitrate
Uptake of ammonium into plant roots is mediated by AMMONIUM TRANSPORTERs (AMTs), which belong to the AMT/MEP/Rh protein superfamily that includes bacterial, fungal, and human homologs (Loqué and von Wirén, 2004)
Episomal coexpression of AMT1;3TD led to inhibition of ammonium transport activity by wild-type AMT1;3, Figure 1
Summary
Ammonium is the predominant N form in most soils, supporting the highest growth rates when present in a mixed supply with nitrate. Supply of ammonium as the sole N form has a negative impact on root growth: The elongation of the primary and lateral roots is severely repressed, resulting in a stunted root phenotype while lateral root branching is stimulated (Lima et al, 2010; Rogato et al, 2010). Uptake of ammonium into plant roots is mediated by AMMONIUM TRANSPORTERs (AMTs), which belong to the AMT/MEP/Rh protein superfamily that includes bacterial, fungal, and human homologs (Loqué and von Wirén, 2004). Plant AMTs may be transceptors: AMT1;3, highly similar in structure and transport properties to AMT1;1, has the ability to regulate lateral root branching in response to localized ammonium supplies (Lima et al, 2010)
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