Abscisic acid controlled sex before transpiration in vascular plants

McAdam, Scott A. M.; Brodribb, Timothy J.; Banks, Jo Ann; Hedrich, Rainer; Atallah, Nadia M.; Cai, Chao; Geringer, Michael A.; Lind, Christof; Nichols, David S.; Stachowski, Kye; Geiger, Dietmar; Sussmilch, Frances C.

doi:10.1073/pnas.1606614113

Cited by 84 publications

(107 citation statements)

References 45 publications

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“…The components of the core stomatal ABA signaling pathway have been shown to be present in mosses, lycophytes, ferns, and angiosperms (Hanada et al, 2011;Cai et al, 2017), indicating an early origin of ABA signal transduction. Nevertheless, it is possible that not all of these proteins have strictly stomata-related functions in ferns, as was shown recently for a homolog of the OST1 kinase that participates in sex determination in a fern (McAdam et al, 2016). However, other kinases besides OST1 can activate anion channels toward stomatal closure, and although OST1 is the most important among them in Arabidopsis (Kollist et al, 2014), ABAinduced signaling pathways do not have to be identical in ferns and angiosperms.…”

Section: Resultsmentioning

confidence: 97%

“…These data indicate that the core stomatal ABA-signaling pathway is conserved in plants. Recently, a homolog of OST1 was shown to regulate sex determination in the fern Ceratopteris richardii (McAdam et al, 2016), suggesting that at least some of the components of the ABA-signaling pathway that control stomatal responses in angiosperms could have different or additional functions in ferns. Moreover, the ABA signal transduction pathways of ferns and angiosperms may be at least partly different; thus, the analysis of fern homologs of components involved in ABA-response pathways of angiosperms is not sufficient to fully understand the mechanisms of ABA responsiveness in ferns.…”

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confidence: 99%

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Fern Stomatal Responses to ABA and CO₂ Depend on Species and Growth Conditions

2017

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, climate, and air humidity affect plant gas exchange that is controlled by stomata, small pores on plant leaves and stems formed by guard cells. Evolution has shaped the morphology and regulatory mechanisms governing stomatal movements to correspond to the needs of various land plant groups over the past 400 million years. Stomata close in response to the plant hormone abscisic acid (ABA), elevated CO 2 concentration, and reduced air humidity. Whether the active regulatory mechanisms that control stomatal closure in response to these stimuli are present already in mosses, the oldest plant group with stomata, or were acquired more recently in angiosperms remains controversial. It has been suggested that the stomata of the basal vascular plants, such as ferns and lycophytes, close solely hydropassively. On the other hand, active stomatal closure in response to ABA and CO 2 was found in several moss, lycophyte, and fern species. Here, we show that the stomata of two temperate fern species respond to ABA and CO 2 and that an active mechanism of stomatal regulation in response to reduced air humidity is present in some ferns. Importantly, fern stomatal responses depend on growth conditions. The data indicate that the stomatal behavior of ferns is more complex than anticipated before, and active stomatal regulation is present in some ferns and has possibly been lost in others. Further analysis that takes into account fern species, life history, evolutionary age, and growth conditions is required to gain insight into the evolution of land plant stomatal responses.

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Section: Resultsmentioning

confidence: 97%

mentioning

confidence: 99%

Fern Stomatal Responses to ABA and CO₂ Depend on Species and Growth Conditions

2017

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“…2). However, some disagreement remains on whether stomatal ABA sensitivity is universal (McAdam et al, 2016).…”

Section: Stomata Evolved As Land Plants Diversified But All Plant DImentioning

confidence: 99%

Stomatal Function across Temporal and Spatial Scales: Deep-Time Trends, Land-Atmosphere Coupling and Global Models

et al. 2017

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“…Moreover, it is difficult to determine if the responses noted are due to passive movement of water or active hormonal control. Several studies point to passive closing of stomata in response to low water status in lycophytes and ferns without ABA involvement (Brodribb & McAdam 2011, McAdam et al 2016. Higher concentrations of ABA in liverworts and hornworts are associated with dry conditions suggesting that stomatal closure may be an overall stress response (Hartung et al 1987).…”

Section: Function and Physiology Of Bryophyte Stomatamentioning

confidence: 99%

“…Closing of stomata in response to ABA involves activation of SLAC1 anion channel by OST1 and although genes that encode these elements are present in the green alga Klebsormidium, the liverwort Marchantia and the moss Physcomitrella, only in Physcomitrella do both elements, PpOST1 and PpSLAC1, form a functional complex that activates the anion channel similar to angiosperms (Lind et al 2015). These components of the ABA dependent drought stress response originated before the diversification of embryophytes but it is still controversial when the use of this gene regulatory network was employed for stomata function , Lind et al 2015, McAdam et al 2016.…”

Section: Function and Physiology Of Bryophyte Stomatamentioning

confidence: 99%

<div class="page" title="Page 1"><div class="layoutArea"><div class="column">Structure, function and evolution of stomata from a bryological perspective</div></div></div>

Merced

Renzaglia

2017

BDE

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Stomata are key innovations for the diversification of land plants. They consist of two differentiated epidermal cells or guard cells and a pore between that leads to an internal cavity. Mosses and hornworts are the earliest among extant land plants to have stomata, but unlike those in all other plants, bryophyte stomata are located exclusively on the sporangium of the sporophyte. Liverworts are the only group of plants that are entirely devoid of stomata. Stomata on leaves and stems of tracheophytes are involved in gas exchange and water transport. The function of stomata in bryophytes is highly debated and differs from that in tracheophytes in that they have been implicated in drying and dehiscence of the sporangium. Over the past decade, anatomical, physiological, developmental, and molecular studies have provided new insights on the function of stomata in bryophytes. In this review, we synthesize the contributions of these studies and provide new data on bryophyte stomata. We evaluate the potential role of stomata in moss and hornwort life histories and we identify areas that will provide valuable data in ascertaining the evolutionary history and function of stomata across land plants.

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Abscisic acid controlled sex before transpiration in vascular plants

Cited by 84 publications

References 45 publications

Fern Stomatal Responses to ABA and CO₂ Depend on Species and Growth Conditions

Fern Stomatal Responses to ABA and CO₂ Depend on Species and Growth Conditions

Stomatal Function across Temporal and Spatial Scales: Deep-Time Trends, Land-Atmosphere Coupling and Global Models

<div class="page" title="Page 1"><div class="layoutArea"><div class="column">Structure, function and evolution of stomata from a bryological perspective</div></div></div>

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Abscisic acid controlled sex before transpiration in vascular plants

Cited by 84 publications

References 45 publications

Fern Stomatal Responses to ABA and CO2 Depend on Species and Growth Conditions

Fern Stomatal Responses to ABA and CO2 Depend on Species and Growth Conditions

Stomatal Function across Temporal and Spatial Scales: Deep-Time Trends, Land-Atmosphere Coupling and Global Models

<div class="page" title="Page 1"><div class="layoutArea"><div class="column">Structure, function and evolution of stomata from a bryological perspective</div></div></div>

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Fern Stomatal Responses to ABA and CO₂ Depend on Species and Growth Conditions

Fern Stomatal Responses to ABA and CO₂ Depend on Species and Growth Conditions