Stomatal Density is Controlled by a Mesophyll-Derived Signaling Molecule

Kondo, Toshiyuki; Kajita, Ryoko; Miyazaki, Aya; Hokoyama, Mayumi; Nakamura-Miura, Touko; Mizuno, Satoko; Masuda, Yuichi; Irie, Kazuhiro; Tanaka, Yuki; Takada, Shinobu; Kakimoto, Tatsuo; Sakagami, Youji

doi:10.1093/pcp/pcp180

Cited by 195 publications

(223 citation statements)

References 26 publications

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“…The anti-parallel β-sheet is packed with the amino-terminal region, which contains a one-turn 3 10 -helix (residues 10-13), supported by three disulphide bonds, the locations of which (Cys8-Cys41, Cys13-Cys20, and Cys16-Cys43) were identical to those previously obtained by enzymatic digestion and mass spectrometry (MS) 11 . This stomagen core, consisting of the β-sheet and a one-turn 3 10 -helix, does not correspond to a single continuous stretch in the aminoacid sequence; it is separated into N-and carboxy-terminal regions (residues 8-24 and 39-44).…”

Section: Structure Of Stomagensupporting

confidence: 54%

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The NMR structure of stomagen reveals the basis of stomatal density regulation by plant peptide hormones

2011

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stomatal development in plants is regulated by defensin-like secretory epidermal patterning factor (EPF) peptide hormones. only one of these, stomagen, is a positive regulator, whereas EPF1, EPF2, and possibly others are negative regulators. Here we explore the structure-function relationships of EPFs, by integrating nmR and semi-in vitro stomagen experiments. We show that stomagen is composed of a loop and a scaffold containing three disulphide bonds. A mutant composed of the stomagen loop and the EPF2 scaffold positively regulates the stomatal density on Arabidopsis cotyledons. The reciprocal mutant composed of the EPF2 loop and the stomagen scaffold acts negatively. Deletion of the disulphide bond introduces unfolding and inactivity. our results suggest that the loop confers the functional specificity of EPFs and that the scaffold is structurally required for their activity. This structural decomposition approach to elucidating the functional site could be adapted for the analysis of other cysteine-rich peptide families.

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Section: Structure Of Stomagensupporting

confidence: 54%

“…The functions of the other members remain unclear. Interestingly, it is currently known that stomagen (EPFL9) acts as a positive regulator [10][11][12] . One of the most intriguing questions in this area is how and why peptides from the same family can produce opposite effects on stomatal density.…”

mentioning

confidence: 99%

The NMR structure of stomagen reveals the basis of stomatal density regulation by plant peptide hormones

2011

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“…However, the CHALf proteins are similar in sequence to stomatal regulators EPF1, EPF2, and STOMAGEN Kondo et al, 2009), and CHAL itself was originally identified in a stomatal screen (Abrash and Bergmann, 2010). In overexpression assays, CHAL confers distinct, quantifiable stomatal phenotypes (Abrash and Bergmann, 2010), and Hara et al (2009) report in an EFPL family survey that CLL1 and CLL2 can similarly repress stomatal production.…”

Section: Chal Family Overexpression Phenotypes Are Erf Dependentmentioning

confidence: 99%

“…The EPFLs are small proteins predicted (and in one case, demonstrated) to be processed into ;45-to 75-amino acid long secreted peptides with compact Cys knot structures (Kondo et al, 2009;Sugano et al, 2009). Three members of the gene family, EPF1, EPF2, and EPFL9/STOMAGEN, have clear roles in stomatal development.…”

Section: Introductionmentioning

confidence: 99%

“…Three members of the gene family, EPF1, EPF2, and EPFL9/STOMAGEN, have clear roles in stomatal development. EPF1 and EPF2 are expressed specifically within subsets of stomatal lineage cells, and STO-MAGEN is expressed in leaf mesophyll; all three depend largely upon TMM for their ability to affect stomatal development (Hara et al, 2007Hunt and Gray, 2009;Kondo et al, 2009;Sugano et al, 2009). A fourth member of the family, EPFL6/ CHALLAH (CHAL), however, exhibits different behaviors.…”

Section: Introductionmentioning

confidence: 99%

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Generation of Signaling Specificity in Arabidopsis by Spatially Restricted Buffering of Ligand–Receptor Interactions

2011

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Core signaling pathways function in multiple programs during multicellular development. The mechanisms that compartmentalize pathway function or confer process specificity, however, remain largely unknown. In Arabidopsis thaliana, ERECTA (ER) family receptors have major roles in many growth and cell fate decisions. The ER family acts with receptor TOO MANY MOUTHS (TMM) and several ligands of the EPIDERMAL PATTERNING FACTOR LIKE (EPFL) family, which play distinct yet overlapping roles in patterning of epidermal stomata. Here, our examination of EPFL genes EPFL6/CHALLAH (CHAL), EPFL5/CHALLAH-LIKE1, and EPFL4/CHALLAH-LIKE2 (CLL2) reveals that this family may mediate additional ERdependent processes. chal cll2 mutants display growth phenotypes characteristic of er mutants, and genetic interactions are consistent with CHAL family molecules acting as ER family ligands. We propose that different classes of EPFL genes regulate different aspects of ER family function and introduce a TMM-based discriminatory mechanism that permits simultaneous, yet compartmentalized and distinct, function of the ER family receptors in growth and epidermal patterning.

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Stomatal Patterning

Bringmann

Bergmann

2013

Encyclopedia of Life Sciences

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Stomatal development is a model for understanding the integration of multiple inputs into a simple cell fate choice. Intense research during the past decade has revealed mechanisms that govern stomatal development including inter‐ and intracellular signalling, transcriptional regulation, cell polarisation and asymmetric cell divisions. Recent discoveries in Arabidopsis include conserved families of transcription factors that drive differentiation and morphogenesis in the stomatal lineage. Specific proteins and pathways that mediate the transduction of signals, and thereby contribute to fate decisions such as secreted protein ligands, receptor kinases, mitogen activated protein kinase kinases and light and hormones have also recently been described. Studies in Arabidopsis and maize revealed novel proteins polarised within dividing stomatal lineage precursors. Together, these discoveries set the foundation to untangle mechanisms that lead to pattern and cell fate acquisition in plant systems. Key Concepts: Stomata are cellular pores that regulate gas exchange in plant leaves. Stomatal density and distribution is modulated by the environment and responds to changes in light, CO 2 and humidity. Stomatal development provides a framework for the understanding of cell fate, cell–cell signalling and cell polarity in plants. Progression through the stages of stomatal development in Arabidopsis requires a balance of fate promoting transcription factors, and fate and division repressing cell–cell signalling. Based on genetic studies, plants and animals display considerable conservation in the molecules and mechanisms used for developmental fates, but plant‐specific modules are used to generate physically asymmetric cell divisions that characterise early stomatal development.

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Stomatal Density is Controlled by a Mesophyll-Derived Signaling Molecule

Cited by 195 publications

References 26 publications

The NMR structure of stomagen reveals the basis of stomatal density regulation by plant peptide hormones

The NMR structure of stomagen reveals the basis of stomatal density regulation by plant peptide hormones

Generation of Signaling Specificity in Arabidopsis by Spatially Restricted Buffering of Ligand–Receptor Interactions

Stomatal Patterning

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