Organelle-nuclear retrograde signaling regulates gene expression, but its roles in specialized cells and integration with hormonal signaling remain enigmatic. Here we show that the SAL1-PAP (3′-phosphoadenosine 5′- phosphate) retrograde pathway interacts with abscisic acid (ABA) signaling to regulate stomatal closure and seed germination in Arabidopsis. Genetically or exogenously manipulating PAP bypasses the canonical signaling components ABA Insensitive 1 (ABI1) and Open Stomata 1 (OST1); priming an alternative pathway that restores ABA-responsive gene expression, ROS bursts, ion channel function, stomatal closure and drought tolerance in ost1-2. PAP also inhibits wild type and abi1-1 seed germination by enhancing ABA sensitivity. PAP-XRN signaling interacts with ABA, ROS and Ca2+; up-regulating multiple ABA signaling components, including lowly-expressed Calcium Dependent Protein Kinases (CDPKs) capable of activating the anion channel SLAC1. Thus, PAP exhibits many secondary messenger attributes and exemplifies how retrograde signals can have broader roles in hormone signaling, allowing chloroplasts to fine-tune physiological responses.DOI: http://dx.doi.org/10.7554/eLife.23361.001
Chloroplast retrograde signaling networks are vital for chloroplast biogenesis, operation, and signaling, including excess light and drought stress signaling. To date, retrograde signaling has been considered in the context of land plant adaptation, but not regarding the origin and evolution of signaling cascades linking chloroplast function to stomatal regulation. We show that key elements of the chloroplast retrograde signaling process, the nucleotide phosphatase (SAL1) and 3′-phosphoadenosine-5′-phosphate (PAP) metabolism, evolved in streptophyte algae—the algal ancestors of land plants. We discover an early evolution of SAL1-PAP chloroplast retrograde signaling in stomatal regulation based on conserved gene and protein structure, function, and enzyme activity and transit peptides of SAL1s in species including flowering plants, the fern Ceratopteris richardii, and the moss Physcomitrella patens. Moreover, we demonstrate that PAP regulates stomatal closure via secondary messengers and ion transport in guard cells of these diverse lineages. The origin of stomata facilitated gas exchange in the earliest land plants. Our findings suggest that the conquest of land by plants was enabled by rapid response to drought stress through the deployment of an ancestral SAL1-PAP signaling pathway, intersecting with the core abscisic acid signaling in stomatal guard cells.
The plant immune system relies on the perception of molecules that signal the presence of a microbe threat. This triggers signal transduction that mediates a range of cellular responses via a collection of molecular machinery including receptors, small molecules, and enzymes. One response to pathogen perception is the restriction of cell-to-cell communication by plasmodesmal closure. We previously found that while chitin and flg22 trigger specialized immune signaling cascades in the plasmodesmal plasma membrane, both execute plasmodesmal closure via callose synthesis at the plasmodesmata. This indicates the signaling pathways ultimately converge at or upstream of callose synthesis. To establish the hierarchy of signaling at plasmodesmata and characterize points of convergence in microbe elicitor-triggered signaling, we profiled the dependence of plasmodesmal responses triggered by different elicitors on a range of plasmodesmal signaling machinery. We identified that, like chitin, flg22 signals via RBOHD to induce plasmodesmal closure. Further, we found that PDLP1, PDLP5 and CALS1 are common to microbe- and SA-triggered responses, identifying PDLPs as a candidate signaling nexus. To understand how PDLPs relay a signal to CALS1, we screened for PDLP5 interactors and found NHL3, which is also required for chitin-, flg22- and SA-triggered plasmodesmal responses and PDLP-mediated activation of callose synthesis. We conclude that a PDLP-NHL3 complex acts as an integrating node of plasmodesmal signaling cascades, transmitting multiple immune signals to activate CALS1 and plasmodesmata closure.
The plant immune system relies on the perception of molecules that signal the presence of a microbe threat. This triggers signal transduction that mediates a range of cellular responses via a collection of molecular machinery including receptors, small molecules, and enzymes. One response to pathogen perception is the restriction of cell-to-cell communication by plasmodesmal closure. We previously found that while chitin and flg22 trigger specialized immune signaling cascades in the plasmodesmal plasma membrane, both execute plasmodesmal closure via callose synthesis at the plasmodesmata. Therefore, the signaling pathways ultimately converge at or upstream of callose synthesis. To establish the hierarchy of signaling at plasmodesmata and characterize points of convergence in microbe elicitor-triggered signaling, we profiled the dependence of plasmodesmal responses triggered by different elicitors on a range of plasmodesmal signaling machinery. We identified that, like chitin, flg22 signals via RESPIRATORY BURST OXIDASE HOMOLOGUE D (RBOHD) to induce plasmodesmal closure. Further, we found that PLASMODESMATA-LOCATED PROTEIN 1 (PDLP1), PDLP5, and CALLOSE SYNTHASE 1 (CALS1) are common to microbe- and salicylic acid (SA)-triggered responses, identifying PDLPs as a candidate signaling nexus. To understand how PDLPs relay a signal to CALS1, we screened for PDLP5 interactors and found NON-RACE SPECIFIC DISEASE RESISTANCE/HIN1 HAIRPIN-INDUCED-LIKE protein 3 (NHL3), which is also required for chitin-, flg22- and SA-triggered plasmodesmal responses and PDLP-mediated activation of callose synthesis. We conclude that a PDLP–NHL3 complex acts as an integrating node of plasmodesmal signaling cascades, transmitting multiple immune signals to activate CALS1 and plasmodesmata closure.
Cellular responses to abiotic stress involve multiple secondary messengers including reactive oxygen species (ROS), Ca2+, phytohormones such as abscisic acid (ABA) and chloroplast-to-nucleus retrograde signals such as 3’-phosphoadenosine 5’-phosphate (PAP). Mechanism(s) by which these messengers, produced in different subcellular compartments, intersect for cell regulation remain enigmatic. Here we demonstrate a mechanistic link enabling ABA and the chloroplast retrograde signal PAP to coordinate both chloroplast and plasma membrane ROS production. In whole leaves, PAP alters various ROS-related processes including plasmodesmal permeability as well as responses to ozone and the bacterial elicitor flg22, but largely quenches ROS during oxidative stress. Conversely, in guard cells, both PAP and ABA induce a ROS burst in both chloroplasts via photosynthetic electron transport, and the apoplast via the RESPIRATORY BURST OXIDASE HOMOLOG (RBOH). Both subcellular ROS sources were necessary for ABA- and PAP-mediated stomatal closure. However, PAP signaling diverges from ABA by activating RBOHD, instead of RBOHF, for apoplastic ROS production. We identify calcium-dependent protein kinases (CPKs) transcriptionally induced by PAP as the post-translational activators of RBOHD-mediated ROS production. CPK13, CPK32, and CPK34 concurrently activate RBOHD and the slow anion channel SLAC1 by phosphorylating two Serine (S) residues, including S120 which is also targeted by the core ABA signaling kinase OPEN STOMATA 1 (OST1). Consequently, overexpressing the PAP-induced CPKs rescues stomatal closure inost1.Our data identify chloroplasts, as sources and mediators of ROS and retrograde signals such PAP, to be critical environmental sensors and focal node in the multifaceted cellular stress response network.Significance StatementThe chloroplast is an important node to coordinate multiple plant signaling pathways in response to stresses such as drought. However, how does it function in specialized cells for which carbon fixation is secondary? Here we show that the chloroplast retrograde signal 3’-phosphoadenosine 5’-phosphate (PAP) plays multiple roles in reactive oxygen species (ROS) signaling and homeostasis. While PAP suppresses ROS in photosynthetic tissue, surprisingly PAP induces ROS in chloroplasts and extracellular space of guard cells to induce stomatal closure. We decipher how PAP-induced proteins activate both extracellular ROS production and anion channels for stomatal closure, thus providing a mechanism by which chloroplasts provide a strategic complement to canonical hormonal pathways in regulating plant physiological responses in specialized cells.
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