Hexokinase mediates stomatal closure

Kelly, Gilor; Moshelion, Menachem; David‐Schwartz, Rakefet; Halperin, О. І.; Wallach, Rony; Attia, Ziv; Belausov, Eduard; Granot, David

doi:10.1111/tpj.12258

Cited by 183 publications

(275 citation statements)

References 67 publications

(116 reference statements)

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“…This has also been described previously by transpiration (Lu et al, 1997;Outlaw 2003;Kang et al, 2007;Kelly et al, 2013;Lawson et al, 426 2014;Daloso et al, 2016). However, no significant acclimation of the slow decrease in A and 427 g s through the day by growth light intensity and pattern was observed in this experiment.…”

supporting

confidence: 82%

Acclimation to Fluctuating Light Impacts the Rapidity of Response and Diurnal Rhythm of Stomatal Conductance

2018

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supporting

confidence: 82%

Acclimation to Fluctuating Light Impacts the Rapidity of Response and Diurnal Rhythm of Stomatal Conductance

2018

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“…Importantly, it was shown that catalytically inactive HXK1 mutant forms still have a signaling function, supporting the view that the role of HKX1 in signaling high sugar availability is independent of its role in Glc metabolism (Moore et al, 2003). More recent work has shown that HXK1 also mediates stomatal closure, thereby contributing to the feedback effect of sugar accumulation on photosynthesis (Kelly et al, 2012;Kelly et al, 2013).…”

mentioning

confidence: 54%

Transitioning to the Next Phase: The Role of Sugar Signaling throughout the Plant Life Cycle

Wingler

2017

Plant Physiol.

126

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“…Initially proposed by Outlaw and coworkers (Outlaw and Manchester, 1979;Lu et al, 1995Lu et al, , 1997Ewert et al, 2000;Outlaw and De Vlieghere-He, 2001;Kang et al, 2007), Suc generated by mesophyll photosynthesis is uploaded to the phloem and transported away from sources to sinks driven by transpiration (Outlaw and De Vlieghere-He, 2001). Excess Suc (when photosynthesis is high) is carried toward the stomata by the apoplast, stimulating stomatal closure either through some signaling mechanism or by acting as an osmoticum (Lu et al, 1997;Outlaw, 2003;Kang et al, 2007;Kelly et al, 2013). Such a process could only occur over longer time scales, as high rates of photosynthesis are not associated with low g s ; however, decreases in g s often are seen toward the end of the diurnal period, despite environmental conditions being similar to morning conditions .…”

Section: Mechanisms Of Coordination Between Stomatal Behavior and Mesmentioning

confidence: 99%

“…Over the diurnal period, a number of species display a decrease in g s and A that is not driven by decreases in light intensity or the temporal response of g s (Mott and Parkhurst, 1991;Allen and Pearcy, 2000;Mencuccini et al, 2000;Moriana et al, 2002;Dodd et al, 2006;de Dios et al, 2012), but the exact mechanism for this requires further investigation. As discussed earlier, sugar accumulation due to high A is believed to provide a long-term photosynthetic feedback on g s (Lu et al, 1995(Lu et al, , 1997Outlaw, 2003;Kang et al, 2007;Kelly et al, 2013), which also needs to be taken into account when considering the incorporation of temporal responses into models of stomatal behavior. Noe and Giersch (2004) proposed a model based on the assumption that the pool of sugars, resulting from the difference between the rate of sugar production by photosynthesis and their rate of export, increasingly inhibited A over the diurnal period.…”

Section: Diurnal Impact On Stomatal Behavior and Implications For Futmentioning

confidence: 99%

Diurnal Variation in Gas Exchange: The Balance between Carbon Fixation and Water Loss

2017

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Stomatal control of transpiration is critical for maintaining important processes, such as plant water status, leaf temperature, as well as permitting sufficient CO 2 diffusion into the leaf to maintain photosynthetic rates (A). Stomatal conductance often closely correlates with A and is thought to control the balance between water loss and carbon gain. It has been suggested that a mesophyll-driven signal coordinates A and stomatal conductance responses to maintain this relationship; however, the signal has yet to be fully elucidated. Despite this correlation under stable environmental conditions, the responses of both parameters vary spatially and temporally and are dependent on species, environment, and plant water status. Most current models neglect these aspects of gas exchange, although it is clear that they play a vital role in the balance of carbon fixation and water loss. Future efforts should consider the dynamic nature of whole-plant gas exchange and how it represents much more than the sum of its individual leaf-level components, and they should take into consideration the long-term effect on gas exchange over time.As the waxy surface of most leaves makes them virtually impermeable to CO 2 and water, nearly all CO 2 absorbed by the plant and water lost pass through the stomatal pores (Cowan and Troughton, 1971;Caird et al., 2007;Jones, 2013). Although these pores represent only a small fraction of the leaf surface, stomatal behavior has major consequences for photosynthetic CO 2 fixation and water loss from leaf to canopy levels, influencing carbon and hydrological cycles at global scales (Hetherington and Woodward, 2003;Keenan et al., 2013). Guard cells that surround the stomatal pore open and close in response to environmental stimuli, controlling the flux of gas between the leaf interior and the bulk atmosphere. Stomatal conductance (g s ) appears to be closely linked with mesophyll demands for CO 2 , and a strong correlation between photosynthetic rate (A) and g s is often observed (Wong et al., 1979;Farquhar and Sharkey, 1982;Mansfield et al., 1990;Buckley and Mott, 2013), and although conserved, it is not always constant (Lawson and Morison, 2004;Bonan et al., 2014). However, the A and properties of each leaf may not be identical and depend on acclimation to the surrounding microclimatic conditions; therefore, each leaf could be considered unique (Niinemets, 2016).In order to maintain an appropriate water status, plants must balance water loss between leaves with different properties depending on the availability of soil water, which raises the question about the regulation of g s at the whole-plant level. Early experiments by Meinzer and Grantz (1990) showed that the balance between water loss and water transport capacity enables the maintenance of a constant leaf water status over a wide range of plant sizes and growing conditions. Therefore, plants regulate the transpiration of each leaf independently in response to variations in microclimate by constantly adjusting stomatal aperture. The sto...

show abstract

Hexokinase mediates stomatal closure

Cited by 183 publications

References 67 publications

Acclimation to Fluctuating Light Impacts the Rapidity of Response and Diurnal Rhythm of Stomatal Conductance

Acclimation to Fluctuating Light Impacts the Rapidity of Response and Diurnal Rhythm of Stomatal Conductance

Transitioning to the Next Phase: The Role of Sugar Signaling throughout the Plant Life Cycle

Diurnal Variation in Gas Exchange: The Balance between Carbon Fixation and Water Loss

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