The latest major group of plants to evolve were the grasses. These became important in the mid-Paleogene�about 40 million years ago. During evolution, leaf CO2 uptake and transpirational water loss were optimized by the acquisition of grass-specific stomatal complexes. In contrast to the kidney-shaped�guard cells (GCs) typical of the dicots such as Arabidopsis, in the grasses and agronomically important cereals, the GCs are dumbbell shaped and are associated with morphologically distinct subsidiary cells (SCs). We studied the molecular basis of GC action in the major cereal crop barley. Upon feeding ABA to xylem sap of an intact barley leaf, stomata closed in a nitrate-dependent manner. This process was initiated by activation of GC SLAC-type anion channel currents. HvSLAC1 expressed in Xenopus oocytes gave rise to S-type anion currents that increased several-fold upon stimulation with >3�mM nitrate. We identified a tandem amino acid residue motif that within the SLAC1 channels differs fundamentally between monocots and dicots. When the motif of nitrate-insensitive dicot Arabidopsis SLAC1 was replaced by the monocot signature, AtSLAC1 converted into a grass-type like nitrate-sensitive channel. Our work reveals a fundamental difference between monocot and dicot GCs and prompts questions into the selective pressures during evolution that resulted in fundamental changes in the regulation of SLAC1 function.
Description
A Tandem Amino Acid Residue Motif in Guard Cell SLAC1 Anion Channel of Grasses Allows for the Control of Stomatal Aperture by Nitrate. - PubMed - NCBI
%0 Journal Article
%1 Schafer:2018:Curr-Biol:29706511
%A Schäfer, N
%A Maierhofer, T
%A Herrmann, J
%A Jorgensen, M E
%A Lind, C
%A von Meyer, K
%A Lautner, S
%A Fromm, J
%A Felder, M
%A Hetherington, A M
%A Ache, P
%A Geiger, D
%A Hedrich, R
%D 2018
%J Curr Biol
%K imported myown
%N 9
%P 1370-1379
%R 10.1016/j.cub.2018.03.027
%T A Tandem Amino Acid Residue Motif in Guard Cell SLAC1 Anion Channel of Grasses Allows for the Control of Stomatal Aperture by Nitrate
%U https://www.ncbi.nlm.nih.gov/pubmed/29706511
%V 28
%X The latest major group of plants to evolve were the grasses. These became important in the mid-Paleogene�about 40 million years ago. During evolution, leaf CO2 uptake and transpirational water loss were optimized by the acquisition of grass-specific stomatal complexes. In contrast to the kidney-shaped�guard cells (GCs) typical of the dicots such as Arabidopsis, in the grasses and agronomically important cereals, the GCs are dumbbell shaped and are associated with morphologically distinct subsidiary cells (SCs). We studied the molecular basis of GC action in the major cereal crop barley. Upon feeding ABA to xylem sap of an intact barley leaf, stomata closed in a nitrate-dependent manner. This process was initiated by activation of GC SLAC-type anion channel currents. HvSLAC1 expressed in Xenopus oocytes gave rise to S-type anion currents that increased several-fold upon stimulation with >3�mM nitrate. We identified a tandem amino acid residue motif that within the SLAC1 channels differs fundamentally between monocots and dicots. When the motif of nitrate-insensitive dicot Arabidopsis SLAC1 was replaced by the monocot signature, AtSLAC1 converted into a grass-type like nitrate-sensitive channel. Our work reveals a fundamental difference between monocot and dicot GCs and prompts questions into the selective pressures during evolution that resulted in fundamental changes in the regulation of SLAC1 function.
@article{Schafer:2018:Curr-Biol:29706511,
abstract = {The latest major group of plants to evolve were the grasses. These became important in the mid-Paleogene�about 40 million years ago. During evolution, leaf CO2 uptake and transpirational water loss were optimized by the acquisition of grass-specific stomatal complexes. In contrast to the kidney-shaped�guard cells (GCs) typical of the dicots such as Arabidopsis, in the grasses and agronomically important cereals, the GCs are dumbbell shaped and are associated with morphologically distinct subsidiary cells (SCs). We studied the molecular basis of GC action in the major cereal crop barley. Upon feeding ABA to xylem sap of an intact barley leaf, stomata closed in a nitrate-dependent manner. This process was initiated by activation of GC SLAC-type anion channel currents. HvSLAC1 expressed in Xenopus oocytes gave rise to S-type anion currents that increased several-fold upon stimulation with >3�mM nitrate. We identified a tandem amino acid residue motif that within the SLAC1 channels differs fundamentally between monocots and dicots. When the motif of nitrate-insensitive dicot Arabidopsis SLAC1 was replaced by the monocot signature, AtSLAC1 converted into a grass-type like nitrate-sensitive channel. Our work reveals a fundamental difference between monocot and dicot GCs and prompts questions into the selective pressures during evolution that resulted in fundamental changes in the regulation of SLAC1 function.},
added-at = {2018-05-24T12:24:20.000+0200},
author = {Schäfer, N and Maierhofer, T and Herrmann, J and Jorgensen, M E and Lind, C and von Meyer, K and Lautner, S and Fromm, J and Felder, M and Hetherington, A M and Ache, P and Geiger, D and Hedrich, R},
biburl = {https://www.bibsonomy.org/bibtex/2043fa22fd70ce8009d0a80f64ba1b55c/pache},
description = {A Tandem Amino Acid Residue Motif in Guard Cell SLAC1 Anion Channel of Grasses Allows for the Control of Stomatal Aperture by Nitrate. - PubMed - NCBI},
doi = {10.1016/j.cub.2018.03.027},
interhash = {bae09f71fb1a07310a386c8acbb7750d},
intrahash = {043fa22fd70ce8009d0a80f64ba1b55c},
journal = {Curr Biol},
keywords = {imported myown},
month = may,
number = 9,
pages = {1370-1379},
pmid = {29706511},
timestamp = {2018-05-25T14:19:32.000+0200},
title = {A Tandem Amino Acid Residue Motif in Guard Cell SLAC1 Anion Channel of Grasses Allows for the Control of Stomatal Aperture by Nitrate},
url = {https://www.ncbi.nlm.nih.gov/pubmed/29706511},
volume = 28,
year = 2018
}