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Guard cell

February 16, 2024

Guard cells are specialized plant cells in the epidermis of leaves, stems and other organs that are used to control gas exchange. They are produced in pairs with a gap between them that forms a stomatal pore. The stomatal pores are largest when water is freely available and the guard cells become turgid, and closed when water availability is critically low and the guard cells become flaccid. Photosynthesis depends on the diffusion of carbon dioxide (CO2) from the air through the stomata into the mesophyll tissues. Oxygen (O2), produced as a byproduct of photosynthesis, exits the plant via the stomata. When the stomata are open, water is lost by evaporation and must be replaced via the transpiration stream, with water taken up by the roots. Plants must balance the amount of CO2 absorbed from the air with the water loss through the stomatal pores, and this is achieved by both active and passive control of guard cell turgor pressure and stomatal pore size.[1][2][3][4]

Opening and Closing of Stoma.

Guard cell function edit

Guard cells are cells surrounding each stoma. They help to regulate the rate of transpiration by opening and closing the stomata. Light is the main trigger for the opening or closing. Each guard cell has a relatively thick and thinner cuticle on the pore-side and a thin one opposite it. As water enters the cell, the thin side bulges outward like a balloon and draws the thick side along with it, forming a crescent; the combined crescents form the opening of the pore.

Guard cells contain phototropin proteins which are serine and threonine kinases with blue-light photoreceptor activity. Phototrophins contain two light, oxygen, and voltage sensor (LOV) domains, and are part of the PAS domain superfamily.[5] The phototropins trigger many responses such as phototropism, chloroplast movement and leaf expansion as well as stomatal opening.[5] Not much was known about how these photoreceptors worked prior to around 1998. The mechanism by which phototropins work was elucidated through experiments with broad bean (Vicia faba). Immunodetection and far-western blotting showed blue light excites phototropin 1 and phototropin 2, causing protein phosphatase 1 to begin a phosphorylation cascade, which activates H+-ATPase, a pump responsible for pumping H+ ions out of the cell.[3] The phosphorylated H+-ATPase allows the binding of a 14-3-3 protein to an autoinhibitory domain of the H+-ATPase at the C terminus.[6] Serine and threonine are then phosphorylated within the protein, which induces H+-ATPase activity.[5] The same experiment also found that upon phosphorylation, a 14-3-3 protein was bound to the phototropins before the H+-ATPase had been phosphorylated.[5] In a similar experiment they concluded that the binding of 14-3-3 protein to the phosphorylation site is essential for the activation of plasma membrane H+-ATPase activity.[6] This was done by adding phosphopeptides such as P-950, which inhibits the binding of 14-3-3 protein, to phosphorylated H+-ATPase and observing the amino acid sequence. As protons are being pumped out, a negative electrical potential was formed across the plasma membrane. This hyperpolarization of the membrane allowed the accumulation of charged potassium (K+) ions and chloride (Cl) ions, which in turn, increases the solute concentration causing the water potential to decrease. The negative water potential allows for osmosis to occur in the guard cell, so that water enters, allowing the cell to become turgid.[citation needed]

Opening and closure of the stomatal pore is mediated by changes in the turgor pressure of the two guard cells. The turgor pressure of guard cells is controlled by movements of large quantities of ions and sugars into and out of the guard cells. Guard cells have cell walls of varying thickness(its inner region, adjacent to the stomatal pore is thicker and highly cutinized[7]) and differently oriented cellulose microfibers, causing them to bend outward when they are turgid, which in turn, causes stomata to open. Stomata close when there is an osmotic loss of water, occurring from the loss of K+ to neighboring cells, mainly potassium (K+) ions.[8][9][10]

Water loss and water use efficiency edit

Water stress (drought and salt stress) is one of the major environmental problems causing severe losses in agriculture and in nature. Drought tolerance of plants is mediated by several mechanisms that work together, including stabilizing and protecting the plant from damage caused by desiccation and also controlling how much water plants lose through the stomatal pores during drought. A plant hormone, abscisic acid (ABA), is produced in response to drought. A major type of ABA receptor has been identified.[11][12] The plant hormone ABA causes the stomatal pores to close in response to drought, which reduces plant water loss via transpiration to the atmosphere and allows plants to avoid or slow down water loss during droughts. The use of drought-tolerant crop plants would lead to a reduction in crop losses during droughts.[citation needed] Since guard cells control water loss of plants, the investigation on how stomatal opening and closure is regulated could lead to the development of plants with improved avoidance or slowing of desiccation and better water use efficiency.[1]

ABA is the trigger for the closure of the stomatal opening. To trigger this it activates the release of anions and potassium ions. This influx in anions causes a depolarization of the plasma membrane. This depolarization triggers potassium plus ions in the cell to leave the cell due to the unbalance in the membrane potential. This sudden change in ion concentrations causes the guard cell to shrink which causes the stomata to close which in turn decreases the amount of water lost. All this is a chain reaction according to his research. The increase in ABA causes there to be an increase in calcium ion concentration. Although at first, they thought it was a coincidence they later discovered that this calcium increase is important. They found Ca2+ ions are involved in anion channel activation, which allows for anions to flow into the guard cell. They also are involved in prohibiting proton ATPase from correcting and stopping the membrane from being depolarized. To support their hypothesis that calcium was responsible for all these changes in the cell they did an experiment where they used proteins that inhibited the calcium ions for being produced. If their assumption that calcium is important in these processes they'd see that with the inhibitors they'd see less of the following things. Their assumption was correct and when the inhibitors were used they saw that the proton ATPase worked better to balance the depolarization. They also found that the flow of anions into the guard cells were not as strong. This is important for getting ions to flow into the guard cell. These two things are crucial in causing the stomatal opening to close preventing water loss for the plant.[13]

Ion uptake and release edit

 
Ion channels and pumps regulating stomatal opening and closure.

Ion uptake into guard cells causes stomatal opening: The opening of gas exchange pores requires the uptake of potassium ions into guard cells. Potassium channels and pumps have been identified and shown to function in the uptake of ions and opening of stomatal apertures.[1][14][15][16][17][18][19][20] Ion release from guard cells causes stomatal pore closing: Other ion channels have been identified that mediate release of ions from guard cells, which results in osmotic water efflux from guard cells due to osmosis, shrinking of the guard cells, and closing of stomatal pores (Figures 1 and 2). Specialized potassium efflux channels participate in mediating release of potassium from guard cells.[16][21][22][23][24] Anion channels were identified as important controllers of stomatal closing.[25][26][27][28][29][30][31] Anion channels have several major functions in controlling stomatal closing:[26] (a) They allow release of anions, such as chloride and malate from guard cells, which is needed for stomatal closing. (b) Anion channels are activated by signals that cause stomatal closing, for example by intracellular calcium and ABA.[26][29][32] The resulting release of negatively charged anions from guard cells results in an electrical shift of the membrane to more positive voltages (depolarization) at the intracellular surface of the guard cell plasma membrane. This electrical depolarization of guard cells leads to activation of the outward potassium channels and the release of potassium through these channels. At least two major types of anion channels have been characterized in the plasma membrane: S-type anion channels and R-type anion channels.[25][26][28][33]

Vacuolar ion transport edit

Vacuoles are large intracellular storage organelles in plants cells. In addition to the ion channels in the plasma membrane, vacuolar ion channels have important functions in regulation of stomatal opening and closure because vacuoles can occupy up to 90% of guard cell's volume. Therefore, a majority of ions are released from vacuoles when stomata are closed.[34] Vascuolar K+ (VK) channels and fast vacuolar channels can mediate K+ release from vacuoles.[35][36][37] Vacuolar K+ (VK) channels are activated by elevation in the intracellular calcium concentration.[35] Another type of calcium-activated channel, is the slow vacuolar (SV) channel.[38] SV channels have been shown to function as cation channels that are permeable to Ca2+ ions,[35] but their exact functions are not yet known in plants.[39]

Guard cells control gas exchange and ion exchange through opening and closing. K+ is one ion that flows both into and out of the cell, causing a positive charge to develop. Malate is one of the main anions used to counteract this positive charge, and it is moved through the AtALMT6 ion channel.[40] AtALMT6 is an aluminum-activated malate transporter that is found in guard cells, specifically in the vacuoles. This transport channel was found to cause either an influx or efflux of malate depending on the concentrations of calcium.[40] In a study by Meyer et al, patch-clamp experiments were conducted on mesophyll vacuoles from arabidopsis rdr6-11 (WT) and arabidopsis that were overexpressing AtALMT6-GFP.[40] It was found from these experiments that in the WT there were only small currents when calcium ions were introduced, while in the AtALMT6-GFP mutant a huge inward rectifying current was observed.[40] When the transporter is knocked out from guard cell vacuoles there is a significant reduction in malate flow current. The current goes from a huge inward current to not much different than the WT, and Meyer et al hypothesized that this is due to residual malate concentrations in the vacuole.[40] There is also a similar response in the knockout mutants to drought as in the WT. There was no phenotypic difference observed between the knockout mutants, the wild type, or the AtALMT6-GFP mutants, and the exact cause for this is not fully known. [40]

Signal transduction edit

Guard cells perceive and process environmental and endogenous stimuli such as light, humidity, CO2 concentration, temperature, drought, and plant hormones to trigger cellular responses resulting in stomatal opening or closure. These signal transduction pathways determine for example how quickly a plant will lose water during a drought period. Guard cells have become a model for single cell signaling. Using Arabidopsis thaliana, the investigation of signal processing in single guard cells has become open to the power of genetics.[29] Cytosolic and nuclear proteins and chemical messengers that function in stomatal movements have been identified that mediate the transduction of environmental signals thus controlling CO2 intake into plants and plant water loss.[1][2][3][4] Research on guard cell signal transduction mechanisms is producing an understanding of how plants can improve their response to drought stress by reducing plant water loss.[1][41][42] Guard cells also provide an excellent model for basic studies on how a cell integrates numerous kinds of input signals to produce a response (stomatal opening or closing). These responses require coordination of numerous cell biological processes in guard cells, including signal reception, ion channel and pump regulation, membrane trafficking, transcription, cytoskeletal rearrangements and more. A challenge for future research is to assign the functions of some of the identified proteins to these diverse cell biological processes.[citation needed]

Development edit

During the development of plant leaves, the specialized guard cells differentiate from "guard mother cells".[43][44] The density of the stomatal pores in leaves is regulated by environmental signals, including increasing atmospheric CO2 concentration, which reduces the density of stomatal pores in the surface of leaves in many plant species by presently unknown mechanisms. The genetics of stomatal development can be directly studied by imaging of the leaf epidermis using a microscope. Several major control proteins that function in a pathway mediating the development of guard cells and the stomatal pores have been identified.[35][44]

References edit

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February 16, 2024
guard, cell, specialized, plant, cells, epidermis, leaves, stems, other, organs, that, used, control, exchange, they, produced, pairs, with, between, them, that, forms, stomatal, pore, stomatal, pores, largest, when, water, freely, available, guard, cells, bec. Guard cells are specialized plant cells in the epidermis of leaves stems and other organs that are used to control gas exchange They are produced in pairs with a gap between them that forms a stomatal pore The stomatal pores are largest when water is freely available and the guard cells become turgid and closed when water availability is critically low and the guard cells become flaccid Photosynthesis depends on the diffusion of carbon dioxide CO2 from the air through the stomata into the mesophyll tissues Oxygen O2 produced as a byproduct of photosynthesis exits the plant via the stomata When the stomata are open water is lost by evaporation and must be replaced via the transpiration stream with water taken up by the roots Plants must balance the amount of CO2 absorbed from the air with the water loss through the stomatal pores and this is achieved by both active and passive control of guard cell turgor pressure and stomatal pore size 1 2 3 4 Opening and Closing of Stoma Contents 1 Guard cell function 2 Water loss and water use efficiency 3 Ion uptake and release 4 Vacuolar ion transport 5 Signal transduction 6 Development 7 ReferencesGuard cell function editGuard cells are cells surrounding each stoma They help to regulate the rate of transpiration by opening and closing the stomata Light is the main trigger for the opening or closing Each guard cell has a relatively thick and thinner cuticle on the pore side and a thin one opposite it As water enters the cell the thin side bulges outward like a balloon and draws the thick side along with it forming a crescent the combined crescents form the opening of the pore Guard cells contain phototropin proteins which are serine and threonine kinases with blue light photoreceptor activity Phototrophins contain two light oxygen and voltage sensor LOV domains and are part of the PAS domain superfamily 5 The phototropins trigger many responses such as phototropism chloroplast movement and leaf expansion as well as stomatal opening 5 Not much was known about how these photoreceptors worked prior to around 1998 The mechanism by which phototropins work was elucidated through experiments with broad bean Vicia faba Immunodetection and far western blotting showed blue light excites phototropin 1 and phototropin 2 causing protein phosphatase 1 to begin a phosphorylation cascade which activates H ATPase a pump responsible for pumping H ions out of the cell 3 The phosphorylated H ATPase allows the binding of a 14 3 3 protein to an autoinhibitory domain of the H ATPase at the C terminus 6 Serine and threonine are then phosphorylated within the protein which induces H ATPase activity 5 The same experiment also found that upon phosphorylation a 14 3 3 protein was bound to the phototropins before the H ATPase had been phosphorylated 5 In a similar experiment they concluded that the binding of 14 3 3 protein to the phosphorylation site is essential for the activation of plasma membrane H ATPase activity 6 This was done by adding phosphopeptides such as P 950 which inhibits the binding of 14 3 3 protein to phosphorylated H ATPase and observing the amino acid sequence As protons are being pumped out a negative electrical potential was formed across the plasma membrane This hyperpolarization of the membrane allowed the accumulation of charged potassium K ions and chloride Cl ions which in turn increases the solute concentration causing the water potential to decrease The negative water potential allows for osmosis to occur in the guard cell so that water enters allowing the cell to become turgid citation needed Opening and closure of the stomatal pore is mediated by changes in the turgor pressure of the two guard cells The turgor pressure of guard cells is controlled by movements of large quantities of ions and sugars into and out of the guard cells Guard cells have cell walls of varying thickness its inner region adjacent to the stomatal pore is thicker and highly cutinized 7 and differently oriented cellulose microfibers causing them to bend outward when they are turgid which in turn causes stomata to open Stomata close when there is an osmotic loss of water occurring from the loss of K to neighboring cells mainly potassium K ions 8 9 10 Water loss and water use efficiency editWater stress drought and salt stress is one of the major environmental problems causing severe losses in agriculture and in nature Drought tolerance of plants is mediated by several mechanisms that work together including stabilizing and protecting the plant from damage caused by desiccation and also controlling how much water plants lose through the stomatal pores during drought A plant hormone abscisic acid ABA is produced in response to drought A major type of ABA receptor has been identified 11 12 The plant hormone ABA causes the stomatal pores to close in response to drought which reduces plant water loss via transpiration to the atmosphere and allows plants to avoid or slow down water loss during droughts The use of drought tolerant crop plants would lead to a reduction in crop losses during droughts citation needed Since guard cells control water loss of plants the investigation on how stomatal opening and closure is regulated could lead to the development of plants with improved avoidance or slowing of desiccation and better water use efficiency 1 ABA is the trigger for the closure of the stomatal opening To trigger this it activates the release of anions and potassium ions This influx in anions causes a depolarization of the plasma membrane This depolarization triggers potassium plus ions in the cell to leave the cell due to the unbalance in the membrane potential This sudden change in ion concentrations causes the guard cell to shrink which causes the stomata to close which in turn decreases the amount of water lost All this is a chain reaction according to his research The increase in ABA causes there to be an increase in calcium ion concentration Although at first they thought it was a coincidence they later discovered that this calcium increase is important They found Ca2 ions are involved in anion channel activation which allows for anions to flow into the guard cell They also are involved in prohibiting proton ATPase from correcting and stopping the membrane from being depolarized To support their hypothesis that calcium was responsible for all these changes in the cell they did an experiment where they used proteins that inhibited the calcium ions for being produced If their assumption that calcium is important in these processes they d see that with the inhibitors they d see less of the following things Their assumption was correct and when the inhibitors were used they saw that the proton ATPase worked better to balance the depolarization They also found that the flow of anions into the guard cells were not as strong This is important for getting ions to flow into the guard cell These two things are crucial in causing the stomatal opening to close preventing water loss for the plant 13 Ion uptake and release edit nbsp Ion channels and pumps regulating stomatal opening and closure Ion uptake into guard cells causes stomatal opening The opening of gas exchange pores requires the uptake of potassium ions into guard cells Potassium channels and pumps have been identified and shown to function in the uptake of ions and opening of stomatal apertures 1 14 15 16 17 18 19 20 Ion release from guard cells causes stomatal pore closing Other ion channels have been identified that mediate release of ions from guard cells which results in osmotic water efflux from guard cells due to osmosis shrinking of the guard cells and closing of stomatal pores Figures 1 and 2 Specialized potassium efflux channels participate in mediating release of potassium from guard cells 16 21 22 23 24 Anion channels were identified as important controllers of stomatal closing 25 26 27 28 29 30 31 Anion channels have several major functions in controlling stomatal closing 26 a They allow release of anions such as chloride and malate from guard cells which is needed for stomatal closing b Anion channels are activated by signals that cause stomatal closing for example by intracellular calcium and ABA 26 29 32 The resulting release of negatively charged anions from guard cells results in an electrical shift of the membrane to more positive voltages depolarization at the intracellular surface of the guard cell plasma membrane This electrical depolarization of guard cells leads to activation of the outward potassium channels and the release of potassium through these channels At least two major types of anion channels have been characterized in the plasma membrane S type anion channels and R type anion channels 25 26 28 33 Vacuolar ion transport editVacuoles are large intracellular storage organelles in plants cells In addition to the ion channels in the plasma membrane vacuolar ion channels have important functions in regulation of stomatal opening and closure because vacuoles can occupy up to 90 of guard cell s volume Therefore a majority of ions are released from vacuoles when stomata are closed 34 Vascuolar K VK channels and fast vacuolar channels can mediate K release from vacuoles 35 36 37 Vacuolar K VK channels are activated by elevation in the intracellular calcium concentration 35 Another type of calcium activated channel is the slow vacuolar SV channel 38 SV channels have been shown to function as cation channels that are permeable to Ca2 ions 35 but their exact functions are not yet known in plants 39 Guard cells control gas exchange and ion exchange through opening and closing K is one ion that flows both into and out of the cell causing a positive charge to develop Malate is one of the main anions used to counteract this positive charge and it is moved through the AtALMT6 ion channel 40 AtALMT6 is an aluminum activated malate transporter that is found in guard cells specifically in the vacuoles This transport channel was found to cause either an influx or efflux of malate depending on the concentrations of calcium 40 In a study by Meyer et al patch clamp experiments were conducted on mesophyll vacuoles from arabidopsis rdr6 11 WT and arabidopsis that were overexpressing AtALMT6 GFP 40 It was found from these experiments that in the WT there were only small currents when calcium ions were introduced while in the AtALMT6 GFP mutant a huge inward rectifying current was observed 40 When the transporter is knocked out from guard cell vacuoles there is a significant reduction in malate flow current The current goes from a huge inward current to not much different than the WT and Meyer et al hypothesized that this is due to residual malate concentrations in the vacuole 40 There is also a similar response in the knockout mutants to drought as in the WT There was no phenotypic difference observed between the knockout mutants the wild type or the AtALMT6 GFP mutants and the exact cause for this is not fully known 40 Signal transduction editGuard cells perceive and process environmental and endogenous stimuli such as light humidity CO2 concentration temperature drought and plant hormones to trigger cellular responses resulting in stomatal opening or closure These signal transduction pathways determine for example how quickly a plant will lose water during a drought period Guard cells have become a model for single cell signaling Using Arabidopsis thaliana the investigation of signal processing in single guard cells has become open to the power of genetics 29 Cytosolic and nuclear proteins and chemical messengers that function in stomatal movements have been identified that mediate the transduction of environmental signals thus controlling CO2 intake into plants and plant water loss 1 2 3 4 Research on guard cell signal transduction mechanisms is producing an understanding of how plants can improve their response to drought stress by reducing plant water loss 1 41 42 Guard cells also provide an excellent model for basic studies on how a cell integrates numerous kinds of input signals to produce a response stomatal opening or closing These responses require coordination of numerous cell biological processes in guard cells including signal reception ion channel and pump regulation membrane trafficking transcription cytoskeletal rearrangements and more A challenge for future research is to assign the functions of some of the identified proteins to these diverse cell biological processes citation needed Development editDuring the development of plant leaves the specialized guard cells differentiate from guard mother cells 43 44 The density of the stomatal pores in leaves is regulated by environmental signals including increasing atmospheric CO2 concentration which reduces the density of stomatal pores in the surface of leaves in many plant species by presently unknown mechanisms The genetics of stomatal development can be directly studied by imaging of the leaf epidermis using a microscope Several major control proteins that function in a pathway mediating the development of guard cells and the stomatal pores have been identified 35 44 References edit a b c d e Schroeder JI Kwak JM amp Allen GJ 2001 Guard cell abscisic acid signaling and engineering drought hardiness in plants Nature 410 327 330 a b Hetherington AM amp Woodward FI 2003 The role of stomata in sensing and driving environmental change Nature 424 901 908 a b c Shimazaki K Doi M Assmann SM amp Kinoshita T 2007 Light regulation of stomatal movement Annu Rev Plant Biol 58 219 247 a b Kwak JM Maser P amp Schroeder JI 2008 The clickable guard cell version II Interactive model of guard cell signal transduction mechanisms and pathway The Arabidopsis Book eds Last R Chang C Graham I Leyser O McClung R amp Weinig C American Society of Plant Biologists Rockville pp 1 17 a b c d Kinoshita Toshinori Emi Takashi Tominaga Misumi Sakamoto Koji Shigenaga Ayako Doi Michio Shimazaki Ken ichiro 2003 12 01 Blue Light and Phosphorylation Dependent Binding of a 14 3 3 Protein to Phototropins in Stomatal Guard Cells of Broad Bean Plant Physiology 133 4 1453 1463 doi 10 1104 pp 103 029629 ISSN 0032 0889 PMC 300702 PMID 14605223 a b Kinoshita Toshinori Shimazaki Ken ichiro 2002 11 15 Biochemical Evidence for the Requirement of 14 3 3 Protein Binding in Activation of the Guard cell Plasma Membrane H ATPase by Blue Light Plant and Cell Physiology 43 11 1359 1365 doi 10 1093 pcp pcf167 ISSN 1471 9053 PMID 12461136 Digitalis Tankonyvtar Structure of Plants and Fungi regi tankonyvtar hu in Hungarian Retrieved 2021 04 02 Imamura S 1943 Untersuchungen uber den mechanismus der turgorschwankung der spaltoffnungs schliesszellen Jap J Bot 12 251 346 Humble GD amp Raschke K 1971 Stomatal opening quantitatively related to potassium transport Evidence from electron probe analysis Plant Physiol 48 447 453 Schroeder JI Hedrich R amp Fernandez JM 1984 Potassium selective single channels in guard cell protoplasts of Vicia faba Nature 312 361 362 Ma Y Szostkiewicz I Korte A Moes D Yang Y Christmann A amp Grill E 2009 Regulators of PP2C phosphatase activity function as abscisic acid sensors Science 324 1064 1068 Park SY Fung P Nishimura N Jensen DR Fujii H Zhao Y Lumba S Santiago J Rodrigues A Chow TF Alfred SE Bonetta D Finkelstein R Provart NJ Desveaux D Rodriguez PL McCourt P Zhu JK Schroeder JI Volkman BF amp Cutler SR 2009 Abscisic acid inhibits type 2C protein phosphatases via the PYR PYL family of START proteins Science 324 1068 1071 Meimoun Patrice Vidal Guillaume Bohrer Anne Sophie Lehner Arnaud Tran Daniel Briand Joel Bouteau Francois Rona Jean Pierre September 2009 Intracellular ca2 stores could participate to abscisic acid induced depolarization and stomatal closure in Arabidopsis thaliana Plant Signaling amp Behavior 4 9 830 835 doi 10 4161 psb 4 9 9396 ISSN 1559 2316 PMC 2802785 PMID 19847112 Assmann SM Simoncini L amp Schroeder JI 1985 Blue light activates electrogenic ion pumping in guard cell protoplasts of Vicia faba Nature 318 285 287 Shimazaki K Iino M amp Zeiger E 1986 Blue light dependent proton extrusion by guard cell protoplasts of Vicia faba Nature 319 324 326 a b Schroeder JI Raschke K amp Neher E 1987 Voltage dependence of K channels in guard cell protoplasts Proc Natl Acad Sci USA 84 4108 4112 Blatt MR Thiel G amp Trentham DR 1990 Reversible inactivation of K channels of Vicia stomatal guard cells following the photolysis of caged 1 4 5 trisphosphate Nature 346 766 769 Thiel G MacRobbie EAC amp Blatt MR 1992 Membrane transport in stomatal guard cells The importance of voltage control J Memb Biol 126 1 18 Kwak JM Murata Y Baizabal Aguirre VM Merrill J Wang M Kemper A Hawke SD Tallman G amp Schroeder JI 2001 Dominant negative guard cell K channel mutants reduce inward rectifying K currents and light induced stomatal opening in Arabidopsis Plant Physiol 127 473 485 Lebaudy A Vavasseur A Hosy E Dreyer I Leonhardt N Thibaud JB Very AA Simonneau T amp Sentenac H 2008 Plant adaptation to fluctuating environment and biomass production are strongly dependent on guard cell potassium channels Proc Natl Acad Sci USA 105 5271 5276 Schroeder JI 1988 K transport properties of K channels in the plasma membrane of Vicia faba guard cells J Gen Physiol 92 667 683 Blatt MR amp Armstrong F 1993 K channels of stomatal guard cells Abscisic acid evoked control of the outward rectifier mediated by cytoplasmic pH Planta 191 330 341 Ache P Becker D Ivashikina N Dietrich P Roelfsema MR amp Hedrich R 2000 GORK a delayed outward rectifier expressed in guard cells of Arabidopsis thaliana is a K selective K sensing ion channel FEBS Lett 486 93 98 Hosy E Vavasseur A Mouline K Dreyer I Gaymard F Poree F Boucherez J Lebaudy A Bouchez D Very AA Simonneau T Thibaud JB amp Sentenac H 2003 The Arabidopsis outward K channel GORK is involved in regulation of stomatal movements and plant transpiration Proc Natl Acad Sci U S A 100 5549 5554 a b Keller BU Hedrich R amp Raschke K 1989 Voltage dependent anion channels in the plasma membrane of guard cells Nature 341 450 453 a b c d Schroeder JI amp Hagiwara S 1989 Cytosolic calcium regulates ion channels in the plasma membrane of Vicia faba guard cells Nature 338 427 430 Hedrich R Busch H amp Raschke K 1990 Ca2 and nucleotide dependent regulation of voltage dependent anion channels in the plasma membrane of guard cells EMBO J 9 3889 3892 a b Schroeder JI amp Keller BU 1992 Two types of anion channel currents in guard cells with distinct voltage regulation Proc Natl Acad Sci USA 89 5025 5029 a b c Pei Z M Kuchitsu K Ward JM Schwarz M amp Schroeder JI 1997 Differential abscisic acid regulation of guard cell slow anion channels in Arabdiopsis wild type and abi1 and abi2 mutants Plant Cell 9 409 423 Negi J Matsuda O Nagasawa T Oba Y Takahashi H Kawai Yamada M Uchimiya H Hashimoto M amp Iba K 2008 CO2 regulator SLAC1 and its homologues are essential for anion homeostasis in plant cells Nature 452 483 486 Triin Vahisalu Kollist H Wang YF Nishimura N Chan WY Valerio G Lamminmaki A Brosche M Moldau H Desikan R Schroeder JI amp Kangasjarvi J 2008 SLAC1 is required for plant guard cell S type anion channel function in stomatal signalling Nature 452 487 491 Grabov A Leung J Giraudat J amp Blatt MR 1997 Alteration of anion channel kinetics in wild type and abi1 1 transgenic Nicotiana benthamiana guard cells by abscisic acid Plant J 12 203 213 Linder B amp Raschke K 1992 A slow anion channel in guard cells activation at large hyperpolarization may be principal for stomatal closing FEBS Lett 131 27 30 MacRobbie EAC 1998 Signal transduction and ion channels in guard cells Phil Trans Roy Soc London 1374 1475 1488 a b c d Ward JM amp Schroeder JI 1994 Calcium activated K channels and calcium induced calcium release by slow vacuolar ion channels in guard cell vacuoles implicated in the control of stomatal closure Plant Cell 6 669 683 Allen GJ amp Sanders D 1996 Control of ionic currents guard cell vacuoles by cytosolic and luminal calcium Plant J 10 1055 1069 Gobert A Isayenkov S Voelker C Czempinski K amp Maathuis FJ 2007 The two pore channel TPK1 gene encodes the vacuolar K conductance and plays a role in K homeostasis Proc Natl Acad Sci U S A 104 10726 10731 Hedrich R amp Neher E 1987 Cytoplasmic calcium regulates voltage dependent ion channels in plant vacuoles Nature 329 833 836 Peiter E Maathuis FJ Mills LN Knight H Pelloux J Hetherington AM amp Sanders D 2005 The vacuolar Ca2 activated channel TPC1 regulates germination and stomatal movement Nature 434 7031 404 408 a b c d e f Meyer Stefan Scholz Starke Joachim Angeli Alexis De Kovermann Peter Burla Bo Gambale Franco Martinoia Enrico 2011 Malate transport by the vacuolar AtALMT6 channel in guard cells is subject to multiple regulation PDF The Plant Journal 67 2 247 257 doi 10 1111 j 1365 313X 2011 04587 x ISSN 1365 313X PMID 21443686 Pei Z M Ghassemian M Kwak CM McCourt P amp Schroeder JI 1998 Role of farnesyltransferase in ABA regulation of guard cell anion channels and plant water loss Science 282 287 290 Wang Y Ying J Kuzma M Chalifoux M Sample A McArthur C Uchacz T Sarvas C Wan J Dennis DT McCourt P amp Huang Y 2005 Molecular tailoring of farnesylation for plant drought tolerance and yield protection Plant J 43 413 424 Bergmann DC amp Sack FD 2007 Stomatal development Annu Rev Plant Biol 58 163 181 a b Pillitteri LJ amp Torii KU 2007 Breaking the silence three bHLH proteins direct cell fate decisions during stomatal development Bioessays 29 861 870 Retrieved from https en wikipedia org w index php title Guard cell amp oldid 1187988828, wikipedia, wiki, book, books, library,

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