Xiao-Ping She scite author profile

Previous studies have showed that UV-B can stimulate closure as well as opening of stomata. However, the mechanism of this complex effect of UV-B is not clear. The purpose of this paper is to investigate the role and the interrelationship of H2O2 and NO in UV-B-induced stomatal closure in broad bean (Vicia faba L.). By epidermal strip bioassay and laser-scanning confocal microscopy, we observed that UV-B-induced stomatal closure could be largely prevented not only by NO scavenger c-PTIO or NO synthase (NOS) inhibitor l-NAME, but also by ascorbic acid (ASC, an important reducing substrate for H2O2 removal) or catalase (CAT, the H2O2 scavenger), and that UV-B-induced NO and H2O2 production in guard cells preceded UV-B-induced stomatal closure. These results indicate that UV-B radiation induces stomatal closure by promoting NO and H2O2 production. In addition, c-PTIO, l-NAME, ASC and CAT treatments could effectively inhibit not only UV-B-induced NO production, but also UV-B-induced H2O2 production. Exogenous H2O2-induced NO production and stomatal closure were partly abolished by c-PTIO and l-NAME. Similarly, exogenous NO donor sodium nitroprusside-induced H2O2 production and stomatal closure were also partly reversed by ASC and CAT. These results show a causal and interdependent relationship between NO and H2O2 during UV-B-regulated stomatal movement. Furthermore, the l-NAME data also indicate that the NO in guard cells of Vicia faba is probably produced by a NOS-like enzyme.

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Strigolactone‐triggered stomatal closure requires hydrogen peroxide synthesis and nitric oxide production in an abscisic acid‐independent manner

Zhang

et al. 2017

New Phytologist

131

106

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SummaryAccumulating data indicate that strigolactones (SLs) are implicated in the response to environmental stress, implying a potential effect of SLs on stomatal response and thus stress acclimatization. In this study, we investigated the molecular mechanism underlying the effect of SLs on stomatal response and their interrelation with abscisic acid (ABA) signaling.The impact of SLs on the stomatal response was investigated by conducting SL-feeding experiments and by analyzing SL-related mutants. The involvement of endogenous ABA and ABA-signaling components in SL-mediated stomatal closure was physiologically evaluated using genetic mutants. Pharmacological and genetic approaches were employed to examine hydrogen peroxide (H 2 O 2 ) and nitric oxide (NO) production.SL-related mutants exhibited larger stomatal apertures, while exogenous SLs were able to induce stomatal closure and rescue the more widely opening stomata of SL-deficient mutants. The SL-biosynthetic genes were induced by abiotic stress in shoot tissues. Disruption of ABA-biosynthetic genes, as well as genes that function in guard cell ABA signaling, resulted in no impairment in SL-mediated stomatal response. However, disruption of MORE AXILLARY GROWTH2 (MAX2), DWARF14 (D14), and the anion channel gene SLOW ANION CHANNEL-ASSOCIATED 1 (SLAC1) impaired SL-triggered stomatal closure. SLs stimulated a marked increase in H 2 O 2 and NO contents, which is required for stomatal closure.Our results suggest that SLs play a prominent role, together with H 2 O 2 /NO production and SLAC1 activation, in inducing stomatal closure in an ABA-independent mechanism.

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Ethylene mediates brassinosteroid‐induced stomatal closure via Gα protein‐activated hydrogen peroxide and nitric oxide production in Arabidopsis

et al. 2015

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SUMMARYBrassinosteroids (BRs) are essential for plant growth and development; however, whether and how they promote stomatal closure is not fully clear. In this study, we report that 24-epibrassinolide (EBR), a bioactive BR, induces stomatal closure in Arabidopsis (Arabidopsis thaliana) by triggering a signal transduction pathway including ethylene synthesis, the activation of Ga protein, and hydrogen peroxide (H 2 O 2 ) and nitric oxide (NO) production. EBR initiated a marked rise in ethylene, H 2 O 2 and NO levels, necessary for stomatal closure in the wild type. These effects were abolished in mutant bri1-301, and EBR failed to close the stomata of gpa1 mutants. Next, we found that both ethylene and Ga mediate the inductive effects of EBR on H 2 O 2 and NO production. EBR-triggered H 2 O 2 and NO accumulation were canceled in the etr1 and gpa1 mutants, but were strengthened in the eto1-1 mutant and the cGa line (constitutively overexpressing the G protein a-subunit AtGPA1). Exogenously applied H 2 O 2 or sodium nitroprusside (SNP) rescued the defects of etr1-3 and gpa1 or etr1 and gpa1 mutants in EBR-induced stomatal closure, whereas the stomata of eto1-1/AtrbohF and cGa/AtrbohF or eto1-1/nia1-2 and cGa/nia1-2 constructs had an analogous response to H 2 O 2 or SNP as those of AtrbohF or Nia1-2 mutants. Moreover, we provided evidence that Ga plays an important role in the responses of guard cells to ethylene. Ga activator CTX largely restored the lesion of the etr1-3 mutant, but ethylene precursor ACC failed to rescue the defects of gpa1 mutants in EBR-induced stomatal closure. Lastly, we demonstrated that Ga-activated H 2 O 2 production is required for NO synthesis. EBR failed to induce NO synthesis in mutant AtrbohF, but it led to H 2 O 2 production in mutant Nia1-2. Exogenously applied SNP rescued the defect of AtrbohF in EBR-induced stomatal closure, but H 2 O 2 did not reverse the lesion of EBR-induced stomatal closure in Nia1-2. Together, our results strongly suggest a signaling pathway in which EBR induces ethylene synthesis, thereby activating Ga, and then promotes AtrbohF-dependent H 2 O 2 production and subsequent Nia1-catalyzed NO accumulation, and finally closes stomata.

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EMS1 and BRI1 control separate biological processes via extracellular domain diversity and intracellular domain conservation

Zheng

Bai

et al. 2019

Nat Commun

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In flowering plants, EMS1 (Excess Microsporocytes 1) perceives TPD1 (Tapetum Determinant 1) to specify tapeta, the last somatic cell layer nurturing pollen development. However, the signaling components downstream of EMS1 are relatively unknown. Here, we use a molecular complementation approach to investigate the downstream components in EMS1 signaling. We show that the EMS1 intracellular domain is functionally interchangeable with that of the brassinosteroid receptor BRI1 (Brassinosteroid Insensitive 1). Furthermore, expressing EMS1 together with TPD1 in the BRI1 expression domain could partially rescue bri1 phenotypes, and led to the dephosphorylation of BES1, a hallmark of active BRI1 signaling. Conversely, expressing BRI1 in the EMS1 expression domain could partially rescue ems1 phenotypes. We further show that PpEMS1 and PpTPD1 from the early land plant Physcomitrella patens could completely rescue ems1 and tpd1 phenotypes, respectively. We propose that EMS1 and BRI1 have evolved distinct extracellular domains to control different biological processes but can act via a common intracellular signaling pathway.

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Induction of antiviral resistance and stimulary effect by oligochitosan in tobacco

Zhao

She

et al. 2007

Pesticide Biochemistry and Physiology

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Xiao-Ping She

The role and the interrelationship of hydrogen peroxide and nitric oxide in the UV-B-induced stomatal closure in broad bean

Strigolactone‐triggered stomatal closure requires hydrogen peroxide synthesis and nitric oxide production in an abscisic acid‐independent manner

Ethylene mediates brassinosteroid‐induced stomatal closure via Gα protein‐activated hydrogen peroxide and nitric oxide production in Arabidopsis

EMS1 and BRI1 control separate biological processes via extracellular domain diversity and intracellular domain conservation

Induction of antiviral resistance and stimulary effect by oligochitosan in tobacco

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