No Entry: SIF2 Closes Stomatal “Doors” to Bacteria by Making Guard Cells SLAC(1)[OPEN]

Bacteria use stomatal pores as a point of entry to invade plant leaves. As a first line of defense, plants attempt to counteract this attack by restricting bacterial entry simply by closing the stomata. This happens via reduction in turgor pressure of the two guard cells flanking the stomatal pore, the “double doors” of the entryway, causing the guard cells to become slack and thereby reducing the pore size. It is well known that this stomatal immunity mechanism in Arabidopsis (Arabidopsisthaliana)occurswhentheFLAGELLIN SENSING2 (FLS2) and BRASSINOSTEROID INSENSITIVE1-ASSOCIATED KINASE1 (BAK1) receptor complex recognizes the flg22moiety (a pathogen-associated molecularpattern [PAMP])ofbacterial flagellin and transmits downstream signals bringing about PAMP-triggered immunity (Sun et al., 2013). And, for almost 15 years, it has been recognized that virulent bacterial strains can re-open the stomatal pores as a counter measure to the initial stomatal closure mediated by defense, perpetuatingplant invasionby themicrobes (Melotto et al., 2006). But only now have Chan et al. (2020) identifiedanotherplant defensepartner to FLS2andBAK1:STRESS INDUCEDFACTOR2 (SIF2). The authors compellingly demonstrate thatSIF2promotesstomatal immunity by interacting with FLS2 and BAK1 to phosphorylate and activate the SLOW ANION CHANNEL1 (SLAC1) protein in the guard cell plasma membrane. Activation of anion channels in guard cells allows anions to leak out, depolarizing the membrane, thereby preventing influx of K1and thedownstream increase in turgor pressure necessary to cause guard cell swelling and stomatal pore opening. Stomatal immunity in plants converges with the well-known abscisic acid (ABA)– mediated pathway classically known to close stomata in response to drought (see Munemasa et al., 2015 for a review), andSIF2-inducedstomatal closure is likewise ABA dependent. The positive role of SIF2 in stomatal immunity was shown by the finding that compared to the wild type, the sif2-1 knockout mutant was more susceptible and SIF2 overexpression lines were more resistant to the bacterial pathogen Pseudomonas syringaepv. tomato (Pst) DC3000 (see figure). These phenotypes were observed when plants were surface inoculated with Pst DC3000, but not when the bacteria were directly delivered into the apoplast, demonstrating the role of SIF2 in preventing pathogen invasion. In epidermal peels exposed to Pst DC3000, rapid stomatal closure occurred in the wild-type, but not in sif2-1 plants (see figure). The sif2-1 mutant was also defective in stomatal closure to ABA and specifically to flg22, but not to chitin and lipopolysaccharide, two other PAMPs,while the wild type displayed stomatal closure in all cases. Coimmunoprecipitation and bimolecular fluorescence complementation experiments demonstrated that SIF2 not only interacts with FLS2 and BAK1 but also with SLAC1, in an flg22-independent manner. Mechanistically, SIF2 action requires a functional kinase domain, as the wild-type form, but not a kinase-inactive form, of SIF2 complemented both the immunity and the stomatal aperture phenotypes of the sif2-1 mutant. Indeed, kinase assays and patch-clamp analyses demonstrated that the wild-type SIF2, but not the kinase-inactive SIF2, phosphorylated and activated SLAC1. When SLAC1 was mutated to abolish putative phosphorylation sites identified with liquid chromatography/tandemmass spectrometry, itexhibitedreducedanionchannel current. On the other hand, a phosphomimic mutant form of the SLAC1 protein exhibited constitutive high current and stomatal closure phenotypes. Additionally, ABA induced S-type anion channel currents in thewild type,butnot in thesif21mutant. Importantly, while overexpressing SIF2 in the wild type caused constitutive stomatal closure, stomata remained open when SIF2 was overexpressed in the slac1-4mutant, indicating that stomatal closure by SIF2 requires functional SLAC1. Taken together, the authors propose amodel by which plants fend off bacterial invaders by initially sensing bacterial flagellin via the FLS2–BAK1 coreceptor complex that then activates SIF2 kinase activity that, in turn, phosphorylates the anionchannelSLAC1.This lastphosphorylation step triggers the outflow of anions and hence the deflation of guard cells, SIF2 Is Required for Stomatal Immunity to Virulent Bacteria.

Bacteria use stomatal pores as a point of entry to invade plant leaves. As a first line of defense, plants attempt to counteract this attack by restricting bacterial entry simply by closing the stomata. This happens via reduction in turgor pressure of the two guard cells flanking the stomatal pore, the "double doors" of the entryway, causing the guard cells to become slack and thereby reducing the pore size.
It is well known that this stomatal immunity mechanism in Arabidopsis (Arabidopsis thaliana) occurs when the FLAGELLIN SENSING2 (FLS2) and BRASSINOSTEROID INSENSITIVE1-ASSOCIATED KINASE1 (BAK1) receptor complex recognizes the flg22 moiety (a pathogen-associated molecular pattern [PAMP]) of bacterial flagellin and transmits downstream signals bringing about PAMP-triggered immunity (Sun et al., 2013). And, for almost 15 years, it has been recognized that virulent bacterial strains can re-open the stomatal pores as a counter measure to the initial stomatal closure mediated by defense, perpetuating plant invasion by the microbes (Melotto et al., 2006).
But only now have Chan et al. (2020) identified another plant defense partner to FLS2 and BAK1: STRESS INDUCED FAC-TOR2 (SIF2). The authors compellingly demonstrate that SIF2 promotes stomatal immunity by interacting with FLS2 and BAK1 to phosphorylate and activate the SLOW ANION CHANNEL1 (SLAC1) protein in the guard cell plasma membrane. Activation of anion channels in guard cells allows anions to leak out, depolarizing the membrane, thereby preventing influx of K 1 and the downstream increase in turgor pressure necessary to cause guard cell swelling and stomatal pore opening. Stomatal immunity in plants converges with the well-known abscisic acid (ABA)mediated pathway classically known to close stomata in response to drought (see Munemasa et al., 2015 for a review), and SIF2-induced stomatal closure is likewise ABA dependent.
The positive role of SIF2 in stomatal immunity was shown by the finding that compared to the wild type, the sif2-1 knockout mutant was more susceptible and SIF2 overexpression lines were more resistant to the bacterial pathogen Pseudomonas syringae pv. tomato (Pst) DC3000 (see figure). These phenotypes were observed when plants were surface inoculated with Pst DC3000, but not when the bacteria were directly delivered into the apoplast, demonstrating the role of SIF2 in preventing pathogen invasion. In epidermal peels exposed to Pst DC3000, rapid stomatal closure occurred in the wild-type, but not in sif2-1 plants (see figure). The sif2-1 mutant was also defective in stomatal closure to ABA and specifically to flg22, but not to chitin and lipopolysaccharide, two other PAMPs, while the wild type displayed stomatal closure in all cases.
Coimmunoprecipitation and bimolecular fluorescence complementation experiments demonstrated that SIF2 not only interacts with FLS2 and BAK1 but also with SLAC1, in an flg22-independent manner. Mechanistically, SIF2 action requires a functional kinase domain, as the wild-type form, but not a kinase-inactive form, of SIF2 complemented both the immunity and the stomatal aperture phenotypes of the sif2-1 mutant. Indeed, kinase assays and patch-clamp analyses demonstrated that the wild-type SIF2, but not the kinase-inactive SIF2, phosphorylated and activated SLAC1. When SLAC1 was mutated to abolish putative phosphorylation sites identified with liquid chromatography/tandem mass spectrometry, it exhibited reduced anion channel current. On the other hand, a phosphomimic mutant form of the SLAC1 protein exhibited constitutive high current and stomatal closure phenotypes. Additionally, ABA induced S-type anion channel currents in the wild type, but not in the sif2-1 mutant. Importantly, while overexpressing SIF2 in the wild type caused constitutive stomatal closure, stomata remained open when SIF2 was overexpressed in the slac1-4 mutant, indicating that stomatal closure by SIF2 requires functional SLAC1.
Taken together, the authors propose a model by which plants fend off bacterial invaders by initially sensing bacterial flagellin via the FLS2-BAK1 coreceptor complex that then activates SIF2 kinase activity that, in turn, phosphorylates the anion channel SLAC1. This last phosphorylation step triggers the outflow of anions and hence the deflation of guard cells, SIF2 Is Required for Stomatal Immunity to Virulent Bacteria.
The sif2-1 mutant is more susceptible than the wild type (Col-0) to Pst DC3000 (A) and fails to close stomata after 1 h of exposure to the bacterial pathogen (B). Black bars, mock treatment; light bars, Pst DC3000 treatment. (Adapted from Chan et al. [2020], Figures 1A and 1C.) [OPEN] Articles can be viewed without a subscription. www.plantcell.org/cgi/doi/10.1105/tpc.20.00404 slamming the doors shut on unwanted guests.