Abstract
Ammonium transport across plant plasma membranes is facilitated by AMT/Rh-type ammonium transporters (AMTs), which also have homologs in most organisms. In the roots of the plant Arabidopsis (Arabidopsis thaliana), AMTs have been identified that function directly in the high-affinity NH4+ acquisition from soil. Here, we show that AtAMT1;2 has a distinct role, as it is located in the plasma membrane of the root endodermis. AtAMT1;2 functions as a comparatively low-affinity NH4+ transporter. Mutations at the highly conserved carboxyl terminus (C terminus) of AMTs, including one that mimics phosphorylation at a putative phosphorylation site, impair NH4+ transport activity. Coexpressing these mutants along with wild-type AtAMT1;2 substantially reduced the activity of the wild-type transporter. A molecular model of AtAMT1;2 provides a plausible explanation for the dominant inhibition, as the C terminus of one monomer directly contacts the neighboring subunit. It is suggested that part of the cytoplasmic C terminus of a single monomer can gate the AMT trimer. This regulatory mechanism for rapid and efficient inactivation of NH4+ transporters may apply to several AMT members to prevent excess influx of cytotoxic ammonium.
Highlights
Ammonium transport across plant plasma membranes is facilitated by AMT/Rh-type ammonium transporters (AMTs), which have homologs in most organisms
It is suggested that part of the cytoplasmic C terminus of a single monomer can gate the AMT trimer
This regulatory mechanism for rapid and efficient inactivation of NH41 transporters may apply to several AMT members to prevent excess influx of cytotoxic ammonium
Summary
Ammonium transport across plant plasma membranes is facilitated by AMT/Rh-type ammonium transporters (AMTs), which have homologs in most organisms. In the roots of the plant Arabidopsis (Arabidopsis thaliana), AMTs have been identified that function directly in located in the plasma the high-affinity NH41 acquisition from soil. It is suggested that part of the cytoplasmic C terminus of a single monomer can gate the AMT trimer This regulatory mechanism for rapid and efficient inactivation of NH41 transporters may apply to several AMT members to prevent excess influx of cytotoxic ammonium. The ammonium transporters (AMTs) from different species appear to have contrasting transport mechanisms, depending on their physiological role (Ludewig, 2006). The genome of many species contains several homologous AMT/Rh genes and six AMTs are found in the model plant Arabidopsis (Arabidopsis thaliana; Loque and von Wiren, 2004). [C] Some figures in this article are displayed in color online but in black and white in the print edition
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