Optimization of Nitrogen Acquisition, and Metabolism, by Potassium in Rice, and Barley

Balkos, Konstantine Dino

16 December 2009

We present the first characterization of K+ optimization of N uptake and metabolism in an NH4+-tolerant species, tropical lowland rice (cv. IR-72). 13N radiotracing showed that increased K+ supply reduces futile NH4+ cycling at the plasma membrane, diminishing the excessive rates of both unidirectional influx and efflux. Pharmacological testing showed that low-affinity NH4+ influx may be mediated by both K+ and non-selective cation channels. Suppression of NH4+ influx by K+ occurred within minutes of increasing K+ supply. Increased K+ reduced free [NH4+] in roots and shoots by 50-75%. Plant biomass was maximized on 10 mM NH4+ and 5 mM K+, with growth 160% higher than 10 mM NO3--grown plants, and 220% higher than plants grown at 10 mM NH4+ and 0.1 mM K+. Unlike in NH4+-sensitive barley, growth optimization was not attributed to a reduced energy cost of futile NH4+ cycling at the plasma membrane. Activities of the key enzymes glutamine synthetase (GS) and phosphoenolpyruvate carboxylase (PEPC) were strongly stimulated by elevated K+, mirroring plant growth and protein content. Improved plant performance through optimization of K+ and NH4+ is likely to be of substantial agronomic significance in the world’s foremost crop species.

Plant nutrition

Nitrogen

Potassium

Ion channel

Influx

Efflux

Rice

Barley

Futile cycling

0309

0285

0817

Optimization of Nitrogen Acquisition, and Metabolism, by Potassium in Rice, and Barley

Balkos, Konstantine Dino

16 December 2009

We present the first characterization of K+ optimization of N uptake and metabolism in an NH4+-tolerant species, tropical lowland rice (cv. IR-72). 13N radiotracing showed that increased K+ supply reduces futile NH4+ cycling at the plasma membrane, diminishing the excessive rates of both unidirectional influx and efflux. Pharmacological testing showed that low-affinity NH4+ influx may be mediated by both K+ and non-selective cation channels. Suppression of NH4+ influx by K+ occurred within minutes of increasing K+ supply. Increased K+ reduced free [NH4+] in roots and shoots by 50-75%. Plant biomass was maximized on 10 mM NH4+ and 5 mM K+, with growth 160% higher than 10 mM NO3--grown plants, and 220% higher than plants grown at 10 mM NH4+ and 0.1 mM K+. Unlike in NH4+-sensitive barley, growth optimization was not attributed to a reduced energy cost of futile NH4+ cycling at the plasma membrane. Activities of the key enzymes glutamine synthetase (GS) and phosphoenolpyruvate carboxylase (PEPC) were strongly stimulated by elevated K+, mirroring plant growth and protein content. Improved plant performance through optimization of K+ and NH4+ is likely to be of substantial agronomic significance in the world’s foremost crop species.

Plant nutrition

Nitrogen

Potassium

Ion channel

Influx

Efflux

Rice

Barley

Futile cycling

0309

0285

0817