Transcriptional control of cell fate in the stomatal lineage

Simmons, Abigail R.; Bergmann, Dominique C.

doi:10.1016/j.pbi.2015.09.008

Cited by 75 publications

(63 citation statements)

References 47 publications

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“…Striking differences in stomatal patterning are noted in comparisons of monocot and eudicot leaves. Namely, stomata appear to be randomly distributed across the epidermis of eudicot leaves, whereas monocot stomata are arranged in evenly distributed, parallel rows (Han & Torii, 2016;Simmons & Bergmann, 2016;Hepworth et al, 2018). Genetic analyses in Arabidopsis have provided detailed, molecular genetic descriptions of the mechanisms of stomatal development (Han & Torii, 2016;Simmons & Bergmann, 2016).…”

Section: Stomatal Development: Shared and Diverged Mechanisms Fmentioning

confidence: 99%

“…Namely, stomata appear to be randomly distributed across the epidermis of eudicot leaves, whereas monocot stomata are arranged in evenly distributed, parallel rows (Han & Torii, 2016;Simmons & Bergmann, 2016;Hepworth et al, 2018). Genetic analyses in Arabidopsis have provided detailed, molecular genetic descriptions of the mechanisms of stomatal development (Han & Torii, 2016;Simmons & Bergmann, 2016). Comparative studies are shedding light on the shared and divergent mechanisms of angiosperm stomatal development, including new insights into stomatal patterning in monocots (Chater et al, 2011(Chater et al, , 2013Hepworth et al, 2018).…”

Section: Stomatal Development: Shared and Diverged Mechanisms Fmentioning

confidence: 99%

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On the mechanisms of development in monocot and eudicot leaves

Conklin

Strable

et al. 2018

New Phytologist

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Contents Summary I. Introduction II. Leaf zones in monocot and eudicot leaves III. Monocot and eudicot leaf initiation: differences in degree and timing, but not kind IV. Reticulate and parallel venation: extending the model? V. Flat laminar growth: patterning and coordination of adaxial-abaxial and mediolateral axes VI. Stipules and ligules: ontogeny of primordial elaborations VII. Leaf architecture VIII. Stomatal development: shared and diverged mechanisms for making epidermal pores IX. Conclusion Acknowledgements References SUMMARY: Comparisons of concepts in monocot and eudicot leaf development are presented, with attention to the morphologies and mechanisms separating these angiosperm lineages. Monocot and eudicot leaves are distinguished by the differential elaborations of upper and lower leaf zones, the formation of sheathing/nonsheathing leaf bases and vasculature patterning. We propose that monocot and eudicot leaves undergo expansion of mediolateral domains at different times in ontogeny, directly impacting features such as venation and leaf bases. Furthermore, lineage-specific mechanisms in compound leaf development are discussed. Although models for the homologies of enigmatic tissues, such as ligules and stipules, are proposed, tests of these hypotheses are rare. Likewise, comparisons of stomatal development are limited to Arabidopsis and a few grasses. Future studies may investigate correlations in the ontogenies of parallel venation and linear stomatal files in monocots, and the reticulate patterning of veins and dispersed stoma in eudicots. Although many fundamental mechanisms of leaf development are shared in eudicots and monocots, variations in the timing, degree and duration of these ontogenetic events may contribute to key differences in morphology. We anticipate that the incorporation of an ever-expanding number of sequenced genomes will enrich our understanding of the developmental mechanisms generating eudicot and monocot leaves.

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Section: Stomatal Development: Shared and Diverged Mechanisms Fmentioning

confidence: 99%

Section: Stomatal Development: Shared and Diverged Mechanisms Fmentioning

confidence: 99%

On the mechanisms of development in monocot and eudicot leaves

Conklin

Strable

et al. 2018

New Phytologist

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“…These cell fate transitions and divisions, which ultimately control the number and proportions of stomata and pavement cells in the mature leaf epidermis, are controlled by a subgroup of related basic helix-loop-helix (bHLH) transcription factors; SPCH, MUTE, and FAMA (Ohashi-Ito and Bergmann, 2006;MacAlister et al, 2007;Pillitteri and Torii, 2007). SPCH primarily directs expression of genes controlling meristemoid formation including members of the Cys-rich EPIDERMAL PATTERNING FACTOR (EPF) family of secreted signaling peptides, which in turn activate a pathway that regulates SPCH stability, thus forming a feedback loop that regulates the number of cells entering the stomatal lineage (Adrian et al, 2015;Simmons and Bergmann, 2016). The best characterized negative regulators of stomatal density in this peptide family are EPF1 and EPF2, which are numbered in order of their discovery (Hara et al, 2007(Hara et al, , 2009Hunt and Gray, 2009).…”

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confidence: 99%

Reducing Stomatal Density in Barley Improves Drought Tolerance without Impacting on Yield

et al. 2017

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The epidermal patterning factor (EPF) family of secreted signaling peptides regulate the frequency of stomatal development in model dicot and basal land plant species. Here, we identify and manipulate the expression of a barley (Hordeum vulgare) ortholog and demonstrate that when overexpressed HvEPF1 limits entry to, and progression through, the stomatal development pathway. Despite substantial reductions in leaf gas exchange, barley plants with significantly reduced stomatal density show no reductions in grain yield. In addition, HvEPF1OE barley lines exhibit significantly enhanced water use efficiency, drought tolerance, and soil water conservation properties. Our results demonstrate the potential of manipulating stomatal frequency for the protection and optimization of cereal crop yields under future drier environments.

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“…Although we discuss the origins of stomatal function in the context of these new discoveries, the evolution of guard cell signaling and stomatal behavior has recently been reviewed (Assmann and Jegla, 2016;Chen et al, 2017;Xu et al, 2016). The complex cellular processes underpinning stomatal development, also the subject of several recent reviews (Torii, 2015;Han and Torii, 2016;Simmons and Bergmann, 2016), will be outlined briefly to provide the background to the evo-devo context.…”

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confidence: 99%

Origins and Evolution of Stomatal Development

et al. 2017

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The fossil record suggests stomata-like pores were present on the surfaces of land plants over 400 million years ago. Whether stomata arose once or whether they arose independently across newly evolving land plant lineages has long been a matter of debate. In Arabidopsis, a genetic toolbox has been identified that tightly controls stomatal development and patterning. This includes the basic helix-loop-helix (bHLH) transcription factors SPEECHLESS (SPCH), MUTE, FAMA, and ICE/SCREAMs (SCRMs), which promote stomatal formation. These factors are regulated via a signaling cascade, which includes mobile EPIDERMAL PATTERNING FACTOR (EPF) peptides to enforce stomatal spacing. Mosses and hornworts, the most ancient extant lineages to possess stomata, possess orthologs of these Arabidopsis (Arabidopsis thaliana) stomatal toolbox genes, and manipulation in the model bryophyte Physcomitrella patens has shown that the bHLH and EPF components are also required for moss stomatal development and patterning. This supports an ancient and tightly conserved genetic origin of stomata. Here, we review recent discoveries and, by interrogating newly available plant genomes, we advance the story of stomatal development and patterning across land plant evolution. Furthermore, we identify potential orthologs of the key toolbox genes in a hornwort, further supporting a single ancient genetic origin of stomata in the ancestor to all stomatous land plants.

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Transcriptional control of cell fate in the stomatal lineage

Cited by 75 publications

References 47 publications

On the mechanisms of development in monocot and eudicot leaves

On the mechanisms of development in monocot and eudicot leaves

Reducing Stomatal Density in Barley Improves Drought Tolerance without Impacting on Yield

Origins and Evolution of Stomatal Development

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