Abstract
Drought is one of the abiotic stresses which impairs the plant growth/development and restricts the yield of many crops throughout the world. Stomatal closure is a common adaptation response of plants to the onset of drought condition. Stomata are microscopic pores on the leaf epidermis, which regulate the transpiration/CO2 uptake by leaves. Stomatal guard cells can sense various abiotic and biotic stress stimuli from the internal and external environment and respond quickly to initiate closure under unfavorable conditions. Stomata also limit the entry of pathogens into leaves, restricting their invasion. Drought is accompanied by the production and/or mobilization of the phytohormone, abscisic acid (ABA), which is well-known for its ability to induce stomatal closure. Apart from the ABA, various other factors that accumulate during drought and affect the stomatal function are plant hormones (auxins, MJ, ethylene, brassinosteroids, and cytokinins), microbial elicitors (salicylic acid, harpin, Flg 22, and chitosan), and polyamines . The role of various signaling components/secondary messengers during stomatal opening or closure has been a matter of intense investigation. Reactive oxygen species (ROS) , nitric oxide (NO) , cytosolic pH, and calcium are some of the well-documented signaling components during stomatal closure. The interrelationship and interactions of these signaling components such as ROS, NO, cytosolic pH, and free Ca2+ are quite complex and need further detailed examination.
Low temperatures can have deleterious effects on plants. However, plants evolved protection mechanisms to overcome the impact of this stress. Cold temperature inhibits stomatal opening and causes stomatal closure. Cold-acclimated plants often exhibit marked changes in their lipid composition, particularly of the membranes. Cold stress often leads to the accumulation of ABA, besides osmolytes such as glycine betaine and proline. The role of signaling components such as ROS, NO, and Ca2+ during cold acclimation is yet to be established, though the effects of cold stress on plant growth and development are studied extensively. The information on the mitigation processes is quite limited. We have attempted to describe consequences of drought and cold stress in plants, emphasizing stomatal closure. Several of these factors trigger signaling components in roots, shoots, and atmosphere, all leading to stomatal closure. A scheme is presented to show the possible signaling events and their convergence and divergence of action during stomatal closure. The possible directions for future research are discussed.
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Abbreviations
- ABA:
-
Abscisic acid
- ABI1:
-
Abscisic acid insensitive 1
- ABI2:
-
Abscisic acid insensitive 2
- ASA/Acetyl-SA:
-
Acetylsalicylic acid
- CPKs:
-
Calcium-dependent protein kinases
- ET:
-
Ethylene
- H2S:
-
Hydrogen sulfide
- MAPKs:
-
Mitogen-activated protein kinases
- MeSA:
-
Methyl salicylate
- MJ:
-
Methyl jasmonate
- NO:
-
Nitric oxide
- NOA:
-
Nitric acid associated
- NR:
-
Nitrate reductase
- OST1:
-
Open stomata 1
- PAs:
-
Polyamines
- QUAC:
-
Quick anion channel
- ROS:
-
Reactive oxygen species
- SA:
-
Salicylic acid
- SLAC:
-
Slow anion channels
References
Acharya BR, Assmann SM (2009) Hormone interactions in stomatal function. Plant Mol Biol 69:451–462
Acharya BR, Jeon BW, Zhang W, Assmann SM (2013) Open stomata 1 (OST1) is limiting in abscisic acid responses of Arabidopsis guard cells. New Phytol 200:1049–1063
Agurla S, Raghavendra AS (2016) Convergence and divergence of signaling events in guard cells during stomatal closure by plant hormones or microbial elicitors. Front Plant Sci 7:1332
Agurla S, Gayatri G, Raghavendra AS (2014) Nitric oxide as a secondary messenger during stomatal closure as a part of plant immunity response against pathogens. Nitric Oxide 43:89–96
Agurla S, Gayatri G, Raghavendra AS (2017) Signal transduction components in guard cells during stomatal closure by plant hormones and microbial elicitors. In: Pandey GK (ed) Mechanism of plant hormone signaling under stress. Wiley, Hoboken
Agurla S, Gayatri G, Raghavendra AS (2018) Polyamines increase nitric oxide and reactive oxygen species in guard cells of Arabidopsis thaliana during stomatal closure. Protoplasma. https://doi.org/10.1007/s00709-017-1139-3 (In Press)
Albert B, Le Cahérec F, Niogret MF, Faes P, Avice JC, Leport L, Bouchereau A (2012) Nitrogen availability impacts oilseed rape (Brassica napus L.) plant water status and proline production efficiency under water-limited conditions. Planta 236:659–676
Alcázar R, Altabella T, Marco F, Bortolotti C, Reymond M, Koncz C, Carrasco P, Tiburcio AF (2010) Polyamines: molecules with regulatory functions in plant abiotic stress tolerance. Planta 231:1237–1249
Aliniaeifard S, van Meeteren U (2013) Can prolonged exposure to low VPD disturb the ABA signalling in stomatal guard cells? J Exp Bot 64:3551–3566
Allen DJ, Ratner K, Giller YE, Gussakovsky EE, Shahak Y, Ort DR (2000) An overnight chill induces a delayed inhibition of photosynthesis at midday in mango (Mangifera indica L.). J Exp Bot 51:1893–1902
An Z, Jing W, Liu Y, Zhang W (2008) Hydrogen peroxide generated by copper amine oxidase is involved in abscisic acid-induced stomatal closure in Vicia faba. J Exp Bot 59:815–825
Bak G, Lee EJ, Lee Y, Kato M, Segami S, Sze H, Maeshima M, Hwang JU, Lee Y (2013) Rapid structural changes and acidification of guard cell vacuoles during stomatal closure require phosphatidylinositol 3,5-bisphosphate. Plant Cell 25:2202–2216
Bright J, Desikan R, Hancock JT, Weir IS, Neill SJ (2006) ABA- induced NO generation and stomatal closure in Arabidopsis are dependent on H2O2 synthesis. Plant J 45:113–122
Chater C, Gray JE, Beerling DJ (2013) Early evolutionary acquisition of stomatal control and development gene signalling networks. Curr Opin Plant Biol 16:638–646
Chater CC, Oliver J, Casson S, Gray JE (2014) Putting the brakes on: abscisic acid as a central environmental regulator of stomatal development. New Phytol 202:376–391
Chen CC, Liang CS, Kao AL, Yang CC (2010) HHP1, a novel signaling component in the cross-talk between the cold and osmotic signaling pathways in Arabidopsis. J Exp Bot 61:3305–3320
Choi Y, Lee Y, Jeon BW, Staiger CJ, Lee Y (2008) Phosphatidylinositol 3-and 4-phosphate modulate actin filament reorganization in guard cells of day flower. Plant Cell Environ 31:366–377
Christmann A, Weiler EW, Steudle E, Grill E (2007) A hydraulic signal in root-to-shoot signaling of water shortage. Plant J 52:167–174
Cona A, Rea G, Botta M, Corelli F, Federico R, Angelini R (2006) Flavin-containing polyamine oxidase is a hydrogen peroxide source in the oxidative response to the protein phosphatase inhibitor cantharidin in Zea mays L. J Exp Bot 57:2277–2289
Coursol S, Fan LM, Stunff HL, Spiegel S, Gilroy S, Assmann SM (2003) Sphingolipid signaling in Arabidopsis guard cells involves heterotrimeric G proteins. Nature 423:651–654
Coursol S, Stunff H, Lynch DV, Gilroy S, Assmann SM, Spiegel S (2005) Arabidopsis sphingosine kinase and the effects of phytosphingosine-1-phosphate on stomatal aperture. Plant Physiol 137:724–737
Crawford AJ, McLachlan DH, Hetherington AM, Franklin KA (2012) High temperature exposure increases plant cooling capacity. Curr Biol 22:R396–R397
Cummins WR, Kende H, Raschke K (1971) Specificity and reversibility of the rapid stomatal response to abscisic acid. Planta 99:347–351
Daszkowska-Golec A, Szarejko I (2013) Open or close the gate-stomata action under the control of phytohormones in drought stress condition. Front Plant Sci 4:1–10
de Zelicourt A, Colcombet J, Hirt H (2016) The role of MAPK modules and ABA during abiotic stress signaling. Trend Plant Sci 21:677–685
Dempsey DMA, Klessig DF (2017) How does the multifaceted plant hormone salicylic acid combat disease in plants and are similar mechanisms utilized in humans. BMC Biol 15:23
Dempsey DMA, Vlot AC, Wildermuth MC, Klessig DF (2011) Salicylic acid biosynthesis and metabolism. Arabidopsis Book 9:e0156
Desikan R, Griffiths R, Hancock J, Neill S (2002) A new role for an old enzyme: nitrate reductase mediated nitric oxide generation is required for abscisic acid-induced stomatal closure in Arabidopsis thaliana. Proc Natl Acad Sci U S A 99:16314–16318
Desikan R, Last K, Harrett-Williams R, Tagliavia C, Harter K, Hooley R, Hancock JT, Neill SJ (2006) Ethylene-induced stomatal closure in Arabidopsis occurs via AtrbohF-mediated hydrogen peroxide synthesis. Plant J 47:907–916
Ding Y, Li H, Zhang X, Xie Q, Gong Z, Yang S (2015) OST1 kinase modulates freezing tolerance by enhancing ICE1 stability in Arabidopsis. Dev Cell 32:278–289
DistĂ©fano AM, GarcĂa-Mata C, Lamattina L, Laxalt AM (2008) Nitric oxide-induced phosphatidic acid accumulation: a role for phospholipases C and D in stomatal closure. Plant Cell Environ 31:187–194
DistĂ©fano AM, Scuffi D, GarcĂa-Mata C, Lamattina L, Laxalt AM (2012) Phospholipase Dδ is involved in nitric oxide induced stomatal closure. Planta 236:1899–1907
Drerup MM, Schlücking K, Hashimoto K, Manishankar P, Steinhorst L, Kuchitsu K, Kudla J (2013) The calcineurin B-like calcium sensors CBL1 and CBL9 together with their interacting protein kinase CIPK26 regulate the Arabidopsis NADPH oxidase RBOHF. Mol Plant 6:559–569
Drew AP, Bazzaz FA (1982) Effect of night temperature on daytime stomatal conductance in early and late successional plants. Oecologia 54:76–79
Du H, Wu N, Chang Y, Li X, Xiao J, Xiong L (2013) Carotenoid deficiency impairs ABA and IAA biosynthesis and differentially affects drought and cold tolerance in rice. Plant Mol Biol 83:475–488
Du S, Jin Z, Liu D, Yang G, Pei Y (2017) Hydrogen sulphide alleviates the cold stress through MPK4 in Arabidopsis thaliana. Plant Physiol 120:112–119
Eremina M, Rozhon W, Poppenberger B (2016) Hormonal control of cold stress responses in plants. Cell Mol Life Sci 73:797–810
Finkelstein R (2013) Abscisic acid synthesis and response. Arabidopsis Book 11:e0166
Fujita Y, Nakashima K, Yoshida T, Katagiri T, Kidokoro S, Kanamori N et al (2009) Three SnRK2 protein kinases are the main positive regulators of abscisic acid signaling in response to water stress in Arabidopsis. Plant Cell Physiol 50:2123–2132
Gao XQ, Wang XL, Ren F, Chen J, Wang XC (2009) Dynamics of vacuoles and actin filaments in guard cells and their roles in stomatal movement. Plant Cell Environ 32:1108–1116
GarcĂa-Mata C, Lamattina L (2013) Gasotransmitters are emerging as new guard cell signaling molecules and regulators of leaf gas exchange. Plant Sci 202:66–73
Gayatri G, Agurla S, Raghavendra AS (2013) Nitric oxide in guard cells as an important secondary messenger during stomatal closure. Front Plant Sci 4:1–11
Gayatri G, Agurla S, Kuchitsu K, Anil K, Podile AR, Raghavendra AS (2017) Stomatal closure and rise in ROS/NO of Arabidopsis guard cells by tobacco microbial elicitors: Cryptogein and Harpin. Front Plant Sci 8:1096
Gilroy S, Read N, Trewavas AJ (1990) Elevation of cytoplasmic calcium by caged calcium or caged inositol trisphosphate initiates stomatal closure. Nature 346:769–771
Goh CH, Kinoshita T, Oku T, Shimazaki KI (1996) Inhibition of blue light-dependent H+ pumping by abscisic acid in Vicia guard-cell protoplasts. Plant Physiol 111:433–440
Gonugunta VK, Srivastava N, Puli MR, Raghavendra AS (2008) Nitric oxide production occurs after cytosolic alkalinization during stomatal closure induced by abscisic acid. Plant Cell Environ 31:1717–1724
Guo L, Mishra G, Markham JE, Li M, Tawfall A, Welti R, Wang X (2012) Connections between sphingosine kinase and phospholipase D in the abscisic acid signaling pathway in Arabidopsis. J Biol Chem 287:8286–8296
Hanstein SM, Felle HH (2002) CO2-triggered chloride release from guard cells in intact fava bean leaves. Kinetics of the onset of stomatal closure. Plant Physiol 130:940–950
Hao F, Zhao S, Dong H, Zhang H, Sun L, Miao C (2010) Nia1 and Nia2 are involved in exogenous salicylic acid-induced nitric oxide generation and stomatal closure in Arabidopsis. J Integr Plant Biol 52:298–307
Hayat S, Hayat Q, Alyemeni MN, Wani AS, Pichtel J, Ahmad A (2012) Role of proline under changing environments: a review. Plant Signal Behav 7:1456–1466
He JM, Ma XG, Zhang Y, Sun TF, Xu FF, Chen YP, Liu X, Yue M (2013) Role and interrelationship of Gα protein, hydrogen peroxide, and nitric oxide in ultraviolet B-induced stomatal closure in Arabidopsis leaves. Plant Physiol 161:1570–1583
Hetherington AM, Woodward FI (2003) The role of stomata in sensing and driving environmental change. Nature 424:901–908
Hossain MA, Ye W, Munemasa S, Nakamura Y, Mori IC, Murata Y (2014) Cyclic adenosine 5′-diphosphoribose (cADPR) cyclic guanosine 3′, 5′-monophosphate positively function in Ca2+ elevation in methyl jasmonate-induced stomatal closure, cADPR is required for methyl jasmonate-induced ROS accumulation NO production in guard cells. Plant Biol 16:1140–1144
Hou Q, Ufer G, Bartels D (2016) Lipid signalling in plant responses to abiotic stress. Plant Cell Environ 39:1029–1048
Hua D, Wang C, He J, Liao H, Duan Y, Zhu Z, Guo Y, Chen Z, Gong Z (2012) A plasma membrane receptor kinase, GHR1, mediates abscisic acid and hydrogen peroxide-regulated stomatal movement in Arabidopsis. Plant Cell 24:2546–2561
Hwang JU, Jeon BW, Hong D, Lee Y (2011) Active ROP2 GTPase inhibits ABA-and CO2-induced stomatal closure. Plant Cell Environ 34:2172–2182
Irving HR, Gehring CA, Parish RW (1992) Changes in cytosolic pH and calcium of guard cells precede stomatal movements. Proc Natl Acad Sci U S A 89:1790–1794
Islam MM, Ye W, Matsushima D, Munemasa S, Okuma E, Nakamura Y, Biswas S, Mano JI, Murata Y (2016) Reactive carbonyl species mediate aba signaling in guard cells. Plant Cell Physiol 57:2552–2563
Jacob T, Ritchie S, Assmann SM, Gilroy S (1999) Abscisic acid signal transduction in guard cells is mediated by phospholipase D activity. Proc Natl Acad Sci U S A 96:12192–12197
Jammes F, Song C, Shin D, Munemasa S, Takeda K, Gu D, Cho D, Lee S, Giordo R, Sritubtim S, Leonhardt N, Ellis BE, Murata Y, Kwak JM (2009) MAP kinases MPK9 and MPK12 are preferentially expressed in guard cells and positively regulate ROS mediated ABA signaling. Proc Natl Acad Sci U S A 106:20520–20525
Jing LI, Hou ZH, Liu GH, Hou LX, Xin LI (2012) Hydrogen sulfide may function downstream of nitric oxide in ethylene-induced stomatal closure in Vicia faba L. J Integr Agric 11:1644–1653
Joudoi T, Shichiri Y, Kamizono N, Akaike T, Sawa T, Yoshitake J, Yamada N, Iwai S (2013) Nitrated cyclic GMP modulates guard cell signaling in Arabidopsis. Plant Cell 25:558–571
Jung C, Seo JS, Han SW, Koo YJ, Kim CH, Song SI, Nahm BH, Do Choi Y, Cheong JJ (2008) Overexpression of AtMYB44 enhances stomatal closure to confer abiotic stress tolerance in transgenic Arabidopsis. Plant Physiol 146:623–635
Kamatham S, Neela KB, Pasupulati AK, Pallu R, Singh SS, Gudipalli P (2016) Benzoylsalicylic acid isolated from seed coats of Givotia rottleriformis induces systemic acquired resistance in tobacco and Arabidopsis. Phytochemistry 126:11–22
Khan MIR, Fatma M, Per TS, Anjum NA, Khan NA (2015) Salicylic acid-induced abiotic stress tolerance and underlying mechanisms in plants. Front Plant Sci 6:462
Khokon MA, Jahan MS, Rahman T, Hossain MA, Muroyama D, Minami I, Munemasa S, Mori IC, Nakamura Y, Murata Y (2011a) Allyl isothiocyanate (AITC) induces stomatal closure in Arabidopsis. Plant Cell Environ 34:1900–1906
Khokon MAR, Okuma E, Hossain MA, Munemasa S, Uraji M, Nakamura Y, Mori IC, Murata Y (2011b) Involvement of extracellular oxidative burst in salicylic acid-induced stomatal closure in Arabidopsis. Plant Cell Environ 34:434–443
Khokon MA, Salam MA, Jammes F, Ye W, Hossain MA, Uraji M, Nakamura Y, Mori IC, Kwak JM, Murata Y (2015) Two guard cell mitogen-activated protein kinases, MPK9 and MPK12, function in methyl jasmonate-induced stomatal closure in Arabidopsis thaliana. Plant Biol 17:946–952
Kim JS, Jung HJ, Lee HJ, Kim K, Goh CH, Woo Y, Oh SH, Han YS, Kang H (2008) Glycine-rich RNA-binding protein7 affects abiotic stress responses by regulating stomata opening and closing in Arabidopsis thaliana. Plant J 55:455–466
Kim TH, Bӧhmer M, Hu H, Nishimura N, Schroeder JL (2010) Guard cell signal transduction network: advance in understanding abscisic acid, CO2 and Ca2+ signaling. Annu Rev Plant Biol 61:561–191
Klessig DF, Tian M, Choi HW (2016) Multiple targets of salicylic acid and its derivatives in plants and animals. Front Immunol 7:206
Kolla VA, Vavasseur A, Raghavendra AS (2007) Hydrogen peroxide production is an early event during bicarbonate induced stomatal closure in abaxial epidermis of Arabidopsis. Planta 225:1421–1429
Kollist H, Nuhkat M, Roelfsema MR (2014) Closing gaps: linking elements that control stomatal movement. New Phytol 203:44–62
Kurbidaeva AS, Novokreshchenova MG (2011) Genetic control of plant resistance to cold. Russ J Genet 47:646–661
Kwak JM, Mori I, Pei ZM, Leonhardt N, Torres MA, Dangl JL et al (2003) NADPH oxidase AtrbohD and AtrbohF genes function in ROS-dependent ABA signaling in Arabidopsis. EMBO J 22:2623–2633
Larqué-Saavedra A (1978) Antitranspirant effect of acetylsalicylic acid on Phaseolus vulgaris. Physiol Plant 43:126–128
Larqué-Saavedra A (1979) Stomatal closure in response to acetyl salicylic acid treatment. Z Pflanzenphysiol 93:371–375
Lawson T, Blatt MR (2014) Stomatal size, speed, and responsiveness impact on photosynthesis and water use efficiency. Plant Physiol 164:1556–1570
Laxalt AM, GarcĂa-Mata C, Lamattina L (2016) The dual role of nitric oxide in guard cells: promoting and attenuating the ABA and phospholipid-derived signals leading to the stomatal closure. Front Plant Sci 7:476
Leckie CP, McAinsh MR, Allen GJ, Sanders D, Hetherington AM (1998) Abscisic acid-induced stomatal closure mediated by cyclic ADP-ribose. Proc Natl Acad Sci U S A 95:15837–15842
Lee SC, Luan S (2012) ABA signal transduction at the crossroad of biotic and abiotic stress responses. Plant Cell Environ 35:53–60
Lee A, Lee SS, Jung WY, Park HJ, Lim BR, Kim HS, Ahn JC, Cho HS (2016) The OsCYP19-4 gene is expressed as multiple alternatively spliced transcripts encoding isoforms with distinct cellular localizations and PPIase activities under cold stress. Int J Mol Sci 17:1154
Li J, Wang XQ, Watson MB, Assmann SM (2000) Regulation of abscisic acid-induced stomatal closure and anion channels by guard cell AAPK kinase. Science 287:300–303
Li M, Ji L, Yang X, Meng Q, Guo S (2012) The protective mechanisms of CaHSP26 in transgenic tobacco to alleviate photoinhibition of PSII during chilling stress. Plant Cell Rep 31:1969–1979
Lim CW, Baek W, Han SW, Lee SC (2013) Arabidopsis PYL8 plays an important role for ABA signaling and drought stress responses. Plant Pathol J 29:471
Lim CW, Baek W, Jung J, Kim JH, Lee SC (2015) Function of ABA in stomatal defense against biotic and drought stresses. Int J Mol Sci 16:15251–15270
Liu K, Fu H, Bei Q, Luan S (2000) Inward potassium channel in guard cells as a target for polyamine regulation of stomatal movements. Plant Physiol 124:1315–1326
Liu J, Xia Z, Wang M, Zhang X, Yang T, Wu J (2013) Overexpression of a maize E3 ubiquitin ligase gene enhances drought tolerance through regulating stomatal aperture and antioxidant system in transgenic tobacco. Plant Physiol Biochem 73:114–120
Ma Y, Szostkiewicz I, Korte A, Moes D, Yang Y, Christmann A, Grill E (2009) Regulators of PP2C phosphatase activity function as abscisic acid sensors. Science 324:1064–1068
Ma Y, She XP, Yang SS (2012) Sphingosine-1-phosphate (S1P) mediates darkness-induced stomatal closure through raising cytosol pH and hydrogen peroxide (H2O2) levels in guard cells in Vicia faba. Sci China Life Sci 55:974–983
MacRobbie EA (1998) Signal transduction and ion channels in guard cells. Philos Trans R Soc Lond Ser B Biol Sci 353:1475
Malcheska F, Ahmad A, Batool S, Müller HM, Ludwig-Müller J, Kreuzwieser J, Randewig D, Hänsch R, Mendel RR, Hell R, Wirtz M (2017) Drought-enhanced xylem sap sulfate closes stomata by affecting ALMT12 and guard cell ABA synthesis. Plant Physiol 174:798–814
Medeiros DB, Daloso DM, Fernie AR, Nikoloski Z, Araújo WL (2015) Utilizing systems biology to unravel stomatal function and the hierarchies underpinning its control. Plant Cell Environ 38:1457–1470
Meijer HJG, Munnik T (2003) Phospholipid-based signaling in plants. Annu Rev Plant Biol 54:265–306
Melotto M, Underwood W, He SY (2008) Role of stomata in plant innate immunity and foliar bacterial diseases. Annu Rev Phytopathol 46:101–122
Merlot S, Gosti F, Guerrier D, Vavasseur A, Giraudat J (2001) The ABI1 and ABI2 protein phosphatases 2C act in a negative feedback regulatory loop of the abscisic acid signaling pathway. Plant J 25:295–303
Misra BB, Acharya BR, Granot D, Assmann SM, Chen S (2015) The guard cell metabolome: functions in stomatal movement and global food security. Front Plant Sci 6:334
Miura K, Tada Y (2014) Regulation of water, salinity, and cold stress responses by salicylic acid. Front Plant Sci 5:4
Mori IC, Pinontoan R, Kawano T, Muto S (2001) Involvement of superoxide generation in salicylic acid-induced stomatal closure in Vicia faba. Plant Cell Physiol 42:1383–1388
Mori IC, Murata Y, Yang Y, Munemasa S, Wang Y-F, Andreoli S, Tiriac H, Alonso JM, Harper JF, Ecker JR, Kwak JM, Schroeder JI (2006) CDPKs CPK6 and CPK3 function in ABA regulation of guard cell S-type anion and Ca2+- permeable channels and stomatal closure. PLoS Biol 4:1749–1762
Moschou PN, Roubelakis-Angelakis KA (2014) Polyamines and programmed cell death. J Exp Bot 65:1285–1296
Munemasa S, Oda K, Watanabe-Sugimoto M, Nakamura Y, Shimoishi Y, Murata Y (2007) The coronatine-insensitive 1 mutation reveals the hormonal signaling interaction between abscisic acid and methyl jasmonate in Arabidopsis guard cells. Specific impairment of ion channel activation and second messenger production. Plant Physiol 143:1398–1407
Munemasa S, Mori IC, Murata Y (2011) Methyl jasmonate signaling and signal crosstalk between methyl jasmonate and abscisic acid in guard cells. Plant Signal Behav 6:939–941
Munemasa S, Hauser F, Park J, Waadt R, Brandt B, Schroeder JI (2015) Mechanisms of abscisic acid-mediated control of stomatal aperture. Curr Opin Plant Biol 28:154–162
Murata Y, Mori IC, Munemasa S (2015) Diverse stomatal signaling and the signal integration mechanism. Annu Rev Plant Biol 66:369–392
Navarro M, Ayax C, Martinez Y, Laur J, El Kayal W, Marque C, Teulieres C (2011) Two EguCBF1 genes overexpressed in Eucalyptus display a different impact on stress tolerance and plant development. Plant Biotechnol J 9:50–63
Ng CKY, Carr K, McAinsh MR, Powell B, Hetherington AM (2001) Drought-induced guard cell signal transduction involves sphingosine-1-phosphate. Nature 410:596–599
Nishimura N, Sarkeshik A, Nito K, Park S-Y, Wang A, Carvalho PC et al (2010) PYR/PYL/RCAR family members are major in-vivo ABI1 protein phosphatase 2C-interacting proteins in Arabidopsis. Plant J 61:290–299
Nogués S, Allen DJ, Morison JI, Baker NR (1999) Characterization of stomatal closure caused by ultraviolet-B radiation. Plant Physiol 121:489–496
Pandey P, Irulappan V, Bagavathiannan MV, Senthil-Kumar M (2017) Impact of combined abiotic and biotic stresses on plant growth and avenues for crop improvement by exploiting physio-morphological traits. Front Plant Sci 8:537
Park SW, Kaimoyo E, Kumar D, Mosher S, Klessig DF (2007) Methyl salicylate is a critical mobile signal for plant systemic acquired resistance. Science 318:113–116
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, Cutler SR (2009) Abscisic acid inhibits type 2C protein phosphatases via the PYR/PYL family of START proteins. Science 324:1068–1071
Pornsiriwong W, Estavillo GM, Chan KX, Tee EE, Ganguly D, Crisp PA, Phua SY, Zhao C, Qiu J, Park J, Yong MT (2017) A chloroplast retrograde signal, 3′-phosphoadenosine 5′-phosphate, acts as a secondary messenger in abscisic acid signaling in stomatal closure and germination. ELife 6:e23361
Pottosin I, Velarde-BuendĂa AM, Bose J, Zepeda-Jazo I, Shabala S, Dobrovinskaya O (2014) Cross-talk between reactive oxygen species and polyamines in regulation of ion transport across the plasma membrane: implications for plant adaptive responses. J Exp Bot 65:1271–1283
Puli MR, Rajsheel P, Aswani V, Agurla S, Kuchitsu K, Raghavendra AS (2016) Stomatal closure induced by phytosphingosine-1-phosphate and sphingosine-1-phosphate depends on nitric oxide and pH of guard cells in Pisum sativum. Planta 244:831–841
Raghavendra AS, Reddy KB (1987) Action of proline on stomata differs from that of abscisic acid, G-substances, or methyl jasmonate. Plant Physiol 83:732–734
Raghavendra AS, Gonugunta VK, Christmann A, Grill E (2010) ABA perception and signaling. Trends Plant Sci 15:395–401
Rai VK, Sharma SS, Sharma S (1986) Reversal of ABA-induced stomatal closure by phenolic compounds. J Exp Bot 37:129–134
Roychoudhury A, Paul S, Basu S (2013) Cross-talk between abscisic acid-dependent and abscisic acid-independent pathways during abiotic stress. Plant Cell Rep 32:985–1006
Saradadevi R, Palta JA, Siddique KHM (2017) ABA-mediated stomatal response in regulating water use during the development of terminal drought in wheat. Front Plant Sci 8:1251
Sawinski K, Mersmann S, Robatzek S, Böhmer M (2013) Guarding the green: pathways to stomatal immunity. Mol Plant Microbe Interact 26:626–632
Schiøtt M, Palmgren MG (2005) Two plant Ca2+ pumps expressed in stomatal guard cells show opposite expression patterns during cold stress. Physiol Plant 124:278–283
Schroeder JI, Hagiwara S (1990) Repetitive increases in cytosolic Ca2+ of guard cells by abscisic acid activation of nonselective Ca2+ permeable channels. Proc Natl Acad Sci U S A 87:9305–9309
Schroeder JI, Allen GJ, Hugouvieux V, Kwak JM, Waner D (2001) Guard cell signal transduction. Annu Rev Plant Physiol Plant Mol Biol 52:627–658
Seo M, Koshiba T (2011) Transport of ABA from the site of biosynthesis to the site of action. J Plant Res 124:501–507
She XP, Song XG (2008) Carbon monoxide-induced stomatal closure involves generation of hydrogen peroxide in Vicia faba guard cells. J Integr Plant Biol 50:1539–1548
Shi H, Ye T, Zhu JK, Chan Z (2014) Constitutive production of nitric oxide leads to enhanced drought stress resistance and extensive transcriptional reprogramming in Arabidopsis. J Exp Bot 65:4119–4131
Shimazaki K, Doi M, Assmann SM, Kinoshita T (2007) Light regulation of stomatal movement. Ann Rev Plant Biol 58:219–247
Song XG, She XP, Zhang B (2008) Carbon monoxide-induced stomatal closure in Vicia faba is dependent on nitric oxide synthesis. Physiol Plant 132:514–525
Song Y, Miao Y, Song CP (2014) Behind the scenes: the roles of reactive oxygen species in guard cells. New Phytol 202:1121–1140
Staxén I, Pical C, Montgomery LT, Gray JE, Hetherington AM, McAinsh MR (1999) Abscisic acid induces oscillations in guard-cell cytosolic free calcium that involve phosphoinositide-specific phospholipase C. Proc Natl Acad Sci U S A 96:1779–1784
Suhita D, Raghavendra AS, Kwak JM, Vavasseur A (2004) Cytoplasmic alkalization precedes reactive oxygen species production during methyl jasmonate-and abscisic acid-induced stomatal closure. Plant Physiol 134:1536–1545
Sussmilch FC, McAdam SAM (2017) Surviving a dry future: abscisic acid (ABA)-mediated plant mechanisms for conserving water under low humidity. Plants 6:54
Testerink C, Munnik T (2005) Phosphatidic acid: a multifunctional stress signaling lipid in plants. Trends Plant Sci 10:368–375
Uraji M, Katagiri T, Okuma E, Ye W, Hossain MA, Masuda C, Miura A, Nakamura Y, Mori IC, Shinozaki K, Murata Y (2012) Cooperative function of PLDδ and PLDα1 in abscisic acid induced stomatal closure in Arabidopsis. Plant Physiol 159:450–460
Vatén A, Bergmann DC (2012) Mechanisms of stomatal development: an evolutionary view. Evo Devo 3:11
Vavasseur A, Raghavendra AS (2005) Guard cell metabolism and CO2 sensing. New Phytol 165:665–682
Vilela B, Pagès M, Riera M (2015) Emerging roles of protein kinase CK2 in abscisic acid signaling. Front Plant Sci 6:966
Wang X (2005) Regulatory functions of phospholipase D and phosphatidic acid in plant growth, development, and stress responses. Plant Physiol 139:566–573
Wang P, Song CP (2008) Guard-cell signaling for hydrogen peroxide and abscisic acid. New Phytol 178:703–718
Wang P, Du Y, Hou YJ, Zhao Y, Hsu CC, Yuan F, Zhu X, Tao WA, Song CP, Zhu JK (2015) Nitric oxide negatively regulates abscisic acid signaling in guard cells by S-nitrosylation of OST1. Proc Natl Acad Sci U S A 112:613–618
Wilkinson S (1999) pH as a stress signal. Plant Growth Regul 29:87–99
Wilkinson S, Davies WJ (1997) Xylem sap pH increase: a drought signal received at the apoplastic face of the guard cell that involves the suppression of saturable abscisic acid uptake by the epidermal symplast. Plant Physiol 113:559–573
Wilkinson S, Clephan AL, Davies WJ (2001) Rapid low temperature-induced stomatal closure occurs in cold-tolerant Commelina communis leaves but not in cold-sensitive tobacco leaves, via a mechanism that involves apoplastic calcium but not abscisic acid. Plant Physiol 126:1566–1578
Willmer C, Fricker M (1996) Stomata, 2nd edn. Springer, Dordrecht
Xie Y, Mao Y, Zhang W, Lai D, Wang Q, Shen W (2014) Reactive oxygen species-dependent nitric oxide production contributes to hydrogen-promoted stomatal closure in Arabidopsis. Plant Physiol 165:759–773
Yin Y, Adachi Y, Nakamura Y, Munemasa S, Mori IC, Murata Y (2016) Involvement of OST1 protein kinase and PYR/PYL/RCAR receptors in methyl jasmonate-induced stomatal closure in Arabidopsis guard cells. Plant Cell Physiol 57:1779–1790
Zeng W, Melotto M, He SY (2010) Plant stomata: a checkpoint of host immunity and pathogen virulence. Curr Opin Biotechnol 21:599–603
Zhang W, Qin C, Zhao J, Wang X (2004) Phospholipase D alpha 1-derived phosphatidic acid interacts with ABI1 phosphatase 2C and regulates abscisic acid signaling. Proc Natl Acad Sci U S A 101:9508–9513
Zhang T, Chen S, Harmon AC (2014) Protein phosphorylation in stomatal movement. Plant Signal Behav 9:e972845
Zhu M, Dai S, Chen S (2012a) The stomata frontline of plant interaction with the environment-perspectives from hormone regulation. Front Biol 7:96–112
Zhu M, Dai S, Zhu N, Booy A, Simons B, Yi S, Chen S (2012b) Methyl jasmonate responsive proteins in Brassica napus guard cells revealed by iTRAQ-based quantitative proteomics. J Proteome Res 11:3728–3742
Zou JJ, Wei FJ, Wang C, Wu JJ, Ratnasekera D, Liu WX, Wu WH (2010) Arabidopsis calcium-dependent protein kinase CPK10 functions in abscisic acid-and Ca2+-mediated stomatal regulation in response to drought stress. Plant Physiol 154:1232–1243
Zou JJ, Li XD, Ratnasekera D, Wang C, Liu WX, Song LF, Zhang WZ, Wu WH (2015) Arabidopsis CALCIUM-DEPENDENT PROTEIN KINASE8 and CATALASE3 function in abscisic acid-mediated signaling and H2O2 homeostasis in stomatal guard cells under drought stress. Plant Cell 27:445–460
Acknowledgments
Our work on stomatal guard cells is supported by grants to ASR of a JC Bose National Fellowship (No. SR/S2/JCB-06/2006) from the Department of Science and Technology and another from the Council of Scientific and Industrial Research (CSIR) (No. 38 (1404)/15/EMR-II), both in New Delhi. SA is supported by a Senior Research Fellowship of University Grants Commission. SG is supported by BBL fellowship (UoH). We also thank DBT-CREBB, DST-FIST, and UGC-SAP for support of infrastructure in department/school.
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Agurla, S., Gahir, S., Munemasa, S., Murata, Y., Raghavendra, A.S. (2018). Mechanism of Stomatal Closure in Plants Exposed to Drought and Cold Stress. In: Iwaya-Inoue, M., Sakurai, M., Uemura, M. (eds) Survival Strategies in Extreme Cold and Desiccation. Advances in Experimental Medicine and Biology, vol 1081. Springer, Singapore. https://doi.org/10.1007/978-981-13-1244-1_12
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