- 1Department of Plant Pathology and Microbiology, Texas A&M University, College Station, TX, United States
- 2Department of Pomology, Hunan Agricultural University, Changsha, China
- 3Department of Plant Pathology, Washington State University, Pullman, WA, United States
- 4Department of Horticulture, Washington State University, Pullman, WA, United States
Cytoplasmic calcium (Ca2+) transients and nuclear Ca2+ oscillations act as hubs during root nodulation and arbuscular mycorrhizal symbioses. Plants perceive bacterial Nod factors or fungal signals to induce the Ca2+ oscillation in the nucleus of root hair cells, and subsequently activate calmodulin (CaM) and Ca2+/CaM-dependent protein kinase (CCaMK). Ca2+ and CaM-bound CCaMK phosphorylate transcription factors then initiate down-stream signaling events. In addition, distinct Ca2+ signatures are activated at different symbiotic stages: microbial colonization and infection; nodule formation; and mycorrhizal development. Ca2+ acts as a key signal that regulates a complex interplay of downstream responses in many biological processes. This short review focuses on advances in Ca2+ signaling-regulated symbiotic events. It is meant to be an introduction to readers in and outside the field of bacterial and fungal symbioses. We summarize the molecular mechanisms underlying Ca2+/CaM-mediated signaling in fine-tuning both local and systemic symbiotic events.
Introduction
Sessile plants have evolved complex signaling networks to cope with various environmental changes (Laplaze et al., 2015; Tian et al., 2020). Calcium (Ca2+) signals play a central role in the networks that regulate various physiological responses of all eukaryotes, including plants (Berridge et al., 2003; Yuan et al., 2018a; Yuan et al., 2018b; Luan and Wang, 2021). Ca2+ signaling is also crucial in plant-pathogen interactions. Ca2+ influxes are induced when plants perceive pathogen-/microbe-associated molecular patterns (PAMPs/MAMPs) through cell surface pattern recognition receptors (PRRs) to trigger basal defense responses. For example, the plant plasma membrane receptor flagellin-sensitive 2 (FLS2) recognizes the conserved bacterial PAMP, flg22, to induce transient Ca2+ influxes (Aslam et al., 2008; Ma et al., 2017; Yuan et al., 2020). A stronger and prolonged Ca2+ signature occurs when the bacterial pathogen Pst DC3000 carrying the effector AvrRpt2 is recognized in resistant plants, as compared to Pst DC3000 without this avirulent factor (Yuan et al., 2021). In another example of calcium’s role in plant resistance, the resistance protein ZAR1 forms a protein complex that triggers sustained calcium ion influx into the cell that subsequently leads to cell death and immune responses (Bi et al., 2021). The pathogen triggered Ca2+ signaling is perceived and relayed by various Ca2+ receptors, such as CaMs/calmodulin-like proteins (CMLs), calcineurin B-like protein (CBL)-CBL-interacting protein kinases (CIPK) and Ca2+calcium-dependent protein kinases (CDPKs or CPKs) (Tian et al., 2020; Köster et al., 2022; Yuan and Poovaiah, 2022). Interestingly, Ca2+ also plays a critical role in the symbiotic relationship between plants and beneficial microbes. The role of Ca2+ has been well described in legumes forming a symbiotic relationship with rhizobia bacteria and arbuscular mycorrhizal fungi.
In the Medicago-rhizobial symbiotic relationship, the symbiosis signaling pathway is initiated when the plant receptor complex LysM receptor kinase 3 (LYK3)-Nod factor perception (NFP) recognizes lipo-chitooligosaccharide signals (i.e., Nod factors) from rhizobial bacteria (Haney et al., 2011; Kang et al., 2011). The Does not Make Infections 2 (DMI2)/nodulation receptor-like kinase (NORK), also known as Symbiosis receptor kinase (SYMRK) in L. japonicus, interacts with the LYK3-NFP receptor complex; the DMI2-LYK3-NFP protein complex regulates rhizobial infection and nodule development (Ané et al., 2004; Lefebvre et al., 2010). DMI2 interacts with 3-hydroxy-3-methylglutaryl CoA reductase 1 (MtHMGR1), which is a key enzyme in the biosynthesis of many isoprenoid compounds, including cytokinin and mevalonate. Mevalonate is a secondary messenger, and the activation of the mevalonate pathway is important for the activation of the common symbiotic pathway (Kevei et al., 2007; Oldroyd, 2013; Venkateshwaran et al., 2015). The recognition of Nod factors (NFs) by the plant cells activates Ca2+ channels, such as the cyclic nucleotide gated channel 15 (CNGC15a, b, c) and DMI1 [which was initially reported as a potassium channel (Ané et al., 2004; Peiter et al., 2007)]. Nod factor recognition also activates the Ca2+ pump, a membrane Ca2+-ATPase 8 (MCA8). As a result, sharp oscillations of cytoplasmic and perinuclear Ca2+ occurs, a phenomenon called Ca2+ spiking (Ehrhardt et al., 1996; Wang et al., 2022). Following Nod factor induced Ca2+ influxes, some Ca2+ binding proteins, such as CCaMK, decode the symbiotic Ca2+ signal into down-stream phosphorylation events (Gleason et al., 2006). The Ca2+ and CaM-binding CCaMK phosphorylates transcription factors and induces symbiotic-related gene expression to initiate nodulation.
Ca2+-mediated local symbiotic signaling
Ca2+ mediates signal exchange between host and microbe
The first step in root symbiosis is the molecular signal exchange between roots and nitrogen-fixing rhizobia or mycorrhizae. Legume-derived flavonoids induce the biosynthesis of Nod factors in rhizobia, and some symbiosis-related flavonoids are accumulated at the colonization site. This suggests that Nod factors promote flavonoid biosynthesis in a positive feedback loop (Liu and Murray, 2016; Panche et al., 2016; Sharma et al., 2020). These root-excreted flavonoids serve as chemo-attractants to facilitate the movement of rhizobia (e.g., Sinorhizobium meliloti) to root hairs (Hassan and Mathesius, 2012). Interestingly, some specific host flavonoids, such as luteolin and naringenin, were shown to induce Ca2+ transients in rhizobia, which subsequently activates bacterial Nod-related genes (i.e., nodA, nodB, and nodC) in Rhizobium leguminosarum cv. viciae (Moscatiello et al., 2010; Cui et al., 2019). These findings suggest Ca2+ signaling in bacterial symbionts plays a role during plant symbiotic microbe interaction. When studying arbuscular mycorrhizal fungi (AMF)-peanut symbiosis, it was noted that exogenous Ca2+ application improved the colonization of peanut roots by AMF and induced the expression of plant genes, including those genes regulating flavonoid biosynthesis (Cui et al., 2019). The results from these studies suggest Ca2+ signaling is important during the initial interactions between plants and symbionts.
Plants perceive microbes via symbiotic microbe-induced cytoplasmic and nuclear Ca2+ transients
Nod factor-induced Ca2+ spikes in root hairs is essential for plant root-nodule symbiosis. Earlier studies have revealed that S. fredii-derived NGR234 Nod factor was able to induce Ca2+ concentration increases within root hairs of nodulating legumes, such as Chamaecrista fasciculata, Acacia retinoides, Cytisus proliferus, Lupinus pilosus, and Medicago truncatula (Granqvist et al., 2015). However, Nod factor failed to trigger Ca2+ oscillations in the non-nodulating legume Cercis siliquastrum (Granqvist et al., 2015). This observation suggests that Ca2+ transients are common events in rhizobia-compatible plants. To further investigate Ca2+ transients in non-leguminous plants, Granqvist et al. (2015) observed that non-leguminous plants (e.g., Parasponia andersonii) could form a symbiotic relationship with rhizobia and exhibit Ca2+ spiking in response to NGR234 Nod factors. However, Trema tomentosa, a non-nodulating plant related to Parasponia, did not exhibit Nod factor-induced Ca2+ oscillations (Granqvist et al., 2015). These results suggest that Nod-factor-triggered Ca2+ oscillations are a common feature in response to symbiotic bacteria in nodulating species.
Nitrogen fixation in endosymbiotic plant-bacterial associations is limited to the Fabid clade (e.g., squash, bean/pea and rose families). The most well-studied bacterial associations are between legumes and Rhizobium. The association between a nitrogen-fixing filamentous bacteria (Frankia) and a diverse range of trees and woody shrubs is less well characterized. However, a recent study found that a novel symbiotic factor from Frankia CcI3 strain was resistant to chitinase treatment and had relatively low molecular weight (i.e., in the range 0.5–5 KDa) (Chabaud et al., 2016). The novel symbiotic factor could trigger Ca2+ spikes in root hairs and induce nodule inception (CgNIN) gene expression in the actinorhizal plant Casuarina glauca. This finding suggests that certain symbiotic responses, such as Ca2+ spiking, are conserved across plants that can form symbiotic associations in the Fabid clade (Chabaud et al., 2016).
Ca2+ channels and Ca2+ pumps involved in beneficial microbes triggered Ca2+ influxes
Since nuclear Ca2+ oscillations are required for rhizobial and mycorrhizal symbioses, studies to better understand Ca2+ oscillations have mainly focused on ion channels and a pump located at the nuclear envelope (NE). The Ca2+ channels include CNGCs among which CNGC15s is crucial for the observed Ca2+ spiking triggered by rhizobia colonization in Medicago. The CNGCs are regulated by calmodulin (CaM) via its interaction with the CNGC isoleucine glutamine (IQ) motif. A recent study found that Ca2+-bound CaM2 regulates Ca2+ spiking by associating with the CNGC15s (e.g., CNGC15a, CNGC15b, and CNGC15c), which results in closed Ca2+ channels. The closing of the channel prevents it from releasing Ca2+ into the nucleoplasm, while a calcium pump (MCA8) drives calcium back to the nuclear envelope lumen; the opening and closing of the channels shape the nucleoplasmic calcium concentration (Cerro et al., 2022). A mutated CaM2, called CaM2R91A, displayed increased binding affinity to CNGC15s. When CaM2R91A was expressed in Medicago truncatula, the plants exhibited an increased Ca2+ oscillation frequency during early stage of colonization in both AM and rhizobia. Moreover, plants expressing CaM2R91A showed enhanced Nod-factor-mediated induction of nodulation-related genes, such as NIN and NF YA1. Although the CaM2R91A expressing plants were able to maintain enhanced bacterial symbiosis at later timepoints (14 and 28 dpi), they could not sustain AM intraradical hyphae and arbuscule formation in the roots (Cerro et al., 2022). Thus, the Ca2+-bound form of CaM2 plays an important role in modulating CNGC15 activity and the subsequent Ca2+ oscillations, but the downstream Ca2+-mediated signaling networks differ between AM and root nodule symbiosis (Figure 1).
Figure 1 Ca2+ signals mediate local symbiotic signaling pathways in the root. Plants recognize the Nod factor via Nod factor perception (NFP)/Nod Factor Receptor 5 (NFR5) and LysM receptor kinase 3 (LYK3)/NFR1 subsequently activate the leucine-rich repeat receptor-like kinases which include the symbiotic receptor kinase LjSYMRK in Lotus and MtDMI2 in Medicago truncatula. The activated LjSYMRK/MtDMI2 may directly open unknown cytoplasmic membrane-localized Ca2+ channels or indirectly regulate Ca2+ channels through ROS signaling pathway, to induce cytosolic Ca2+ influxes. Meanwhile, LjSYMRK/MtDMI2 interacts with 3-Hydroxy-3-Methylglutaryl Coenzyme A Reductase (HMGR) to initiate the biosynthesis of mevalonate. The mevalonate accumulation activates LjPOLLUX and LjCASTOR/MtDMI1. MtDM1/LjPOLLUX and LjCASTOR interact with the nuclear envelope (NE)-localized channels, CNGC15s (CNGC15a, b or c), to regulate Nod factor-induced Ca2+ inflex into the nucleus from the NE or endoplasmic reticulum. Ca2+-bound MtCaM2 interacts with CNGC15s, causing its closure and thus acting as a negative feedback loop for ion channels. Meanwhile, the nuclear localized Ca2+ pump, MtMCA8, uses ATP to transport the Ca2+ ions from the nucleus back to NE or ER to maintain the Ca2+ oscillation. In addition, a potential component of the nuclear pore complex (NPC), nucleoporins, such as NUP133 and UNP85, are essential for the Nod-factor-induced nuclear Ca2+ oscillation. The symbiotic Ca2+ signal is decoded by CaM to activate down-stream phosphorylation events, through the Ca2+- and CaM-dependent protein kinase, LjCCaMK or MtDMI3. The activated LjCCaMK or MtDMI3 phosphorylates LjCYCLOPS or MtIPD3, which is a transcription factor. The phosphorylated LjCYCLOPS or MtIPD3 associates with DELLA, NSP2 and NSP1 to form a complex, which binds to the promoter of symbiosis-associated genes to induce their expression, which ultimately leads to nodulation.
The nuclear pore complex (NPC) in Lotus japonicus is essential for Nod factor-induced nuclear Ca2+ oscillations (Kanamori et al., 2006). Nod factor triggered a weaker nuclear Ca2+ oscillation in mutant nup133 as compared to the wild-type control, and the nup133 mutants showed no mycorrhizal colonization and reduced nodulation by Rhizobium bacteria at permissive temperatures (Kanamori et al., 2006). In L. japonicus, the nucleoporin gene NUP85 was also required for Nod-factor-induced nuclear Ca2+ oscillation as well as bacterial nodulation and mycorrhizal colonization (Saito et al., 2007). The nuclear pore complex may mediate Nod factor-induced nuclear Ca2+ oscillations indirectly by modulating the transport of symbiosis-related mRNAs [such as Nod receptors and symbiosis-related Ca2+ channels (CASTOR, POLLUX/DMI1, CNGC15) or Ca2+pumps (MCA8)] from nucleus to ribosome for polypeptides or protein biosynthesis. Another possibility is that the NPCs regulate the localization of CASTOR, POLLUX/DMI1, CNGC15 to the nuclear membranes, although the biological mechanism involved deserves further study.
In addition to nuclear-localized Ca2+ channels and components of the nuclear pore complex (NUP85, NUP133), other cation channels are also required for nuclear Ca2+ oscillations. Medicago truncatula DMI1 and its two homologs CASTOR and POLLUX in L. japonicus were once thought to be potassium (K+) channels (Peiter et al., 2007; Charpentier et al., 2016) but more recent evidence shows that they were Ca2+ channels (Kim et al., 2019). Ca2+ binding to the CASTOR gating ring was required for root nodule symbiosis, and legumes carrying mutated CASTOR at either of two Ca2+ binding sites (D442A or E493Q) failed to form rhizobia-induced nodulation. This finding links defects in Ca2+ binding to Ca2+ channel regulation, which ultimately affects the legume-microbe symbiosis (Kim et al., 2019). However, this study was carried out in mammalian cells (HEK293), and to further characterize the function of DMI1 and clarify if it is a Ca2+ or K+ channel, future research should be performed in plant cells. Furthermore, Nod factor induced the association between C-terminal of DMI1 and N-terminal of CNGC15s. In addition, DMI1 associated with CNGC15s (CNGC15a, CNGC15b, CNGC15c) to form a complex protein in nuclear membranes which was required for the activation of nuclear Ca2+ spiking (Charpentier et al., 2016). The latest study further confirmed that the two cation channels, DMI1 and CNGC15, form a channel complex to regulate nuclear symbiotic Ca2+ oscillations and nodule development (Liu et al., 2022). Genetic testing showed that gain-of-function mutations in MtDMI1, DMI1 (S760N), displayed spontaneous nuclear Ca2+ spikes and constitutive activation of nodulation (Liu et al., 2022). The S760N mutation DMI1 caused nuclear Ca2+ oscillations in a CNGC15 dependent manner and spontaneous nodulation (Liu et al., 2022). These studies extend our understanding of activating cation channels complex to form nuclear Ca2+ oscillations during plant symbiotic microbe interaction.
Ca2+ pumps regulate Ca2+ changes in the nuclear region, like nuclear localized Ca2+ channels, during plant and symbiotic microbe interactions. Other than depending on the ion concentration or electrochemical gradient like Ca2+ channels, Ca2+ pumps consumed ATP to facilitate Ca2+ movement against it (Demidchik et al., 2018). A Ca2+ pump, MtMCA8, was involved in the formation of symbiosis-induced nuclear Ca2+ oscillation, and MCA8-silenced plants displayed decreased mycorrhizal colonization (Capoen et al., 2011). Unlike DMI1 being mainly distributed in the inner layer of nuclear membrane, MCA8 was equally localized at both inner and outer layers of the nuclear membrane and at the endoplasmic reticulum (ER). A hypothesis proposes that the inner-layer-localized MCA8 mediates the recapture of nuclear Ca2+ spikes, while the outer-layer- and the ER-localized MCA8 may reload the Ca2+ store at the ER or nuclear envelope from the cytoplasm (Capoen et al., 2011; Tian et al., 2020).
A key component of calcium regulation during plant symbiosis is the small guanosine triphosphatase (GTPase). The GTPase, belongs to the Rho/Rop family, directly regulates reactive oxygen species (ROS) production through activating the respiratory burst oxidase homolog B (RBOHB) (Wang et al., 2020). The ROS activates Ca2+ channels and triggers Ca2+ influxes, which subsequently activates plant immune responses (Wang et al., 2020), which suggests the GTPases play a role in plant defense (Rivero et al., 2019). Interestingly, the small GTPases [Rho-like GTPas (MtROPs)] and heterotrimeric G-proteins including Gα, Gβ, and Gγ subunits are also involved in root nodule symbiosis (Ke et al., 2012; Pandey, 2019; Bovin et al., 2021): the expressions of MtROP3, MtROP5 and MtROP6 were induced in rhizobia-infected roots (Liu et al., 2010); and genetic tests indicated that the Gα repressed nodule development, while the Gβ, Gγ and RGS promoted nodule development (Choudhury and Pandey, 2013). Further study revealed that ROP6 interacted with NFR5, but not with NFR1, to positively regulate infection thread development and nodulation formation in soybean (Ke et al., 2012). Another study revealed that ROP9 interacted with RACK1 and regulated root nodule development (Gao et al., 2021). Active NFR1 phosphorylated the regulator of G-protein signaling (RGS) proteins, which deactivated Gα, a negative regulator of root nodulation (Choudhury and Pandey, 2015). More studies are needed to reveal how small GTPases, together with Nod factor receptor complex, regulate symbiotic cytoplasmic and/or nuclear Ca2+ spiking.
Plants transduce and decode Ca2+ signals through CCaMK during symbiosis
In 1995, the Poovaiah laboratory cloned and characterized a novel protein kinase from lily, which turned out to be regulated by both Ca2+ and CaM. Hence, it was named Ca2+/CaM-dependent protein kinase (CCaMK; Patil et al., 1995). Unlike all the other Ca2+/CaM-dependent protein kinases (CaMKs) which were discovered in animal cells, the CCaMK reported from plants contained a C-terminal visinin-like domain, including three EF-hand motifs, which functioned as a Ca2+-sensitive molecular switch (Sathyanarayanan et al., 2001). The CCaMK involved in symbiosis is encoded by DMI3 in Medicago truncatula and LjCCaMK in L. japonicus (Patil et al., 1995). CCaMK is essential for root nodule formation and mycorrhizal associations. CCaMK has a serine/threonine kinase domain at the N-terminal and two Ca2+-mediated regulatory domains at the C-terminal. The two C-terminal domains include a visinin-like domain with three EF-hand motifs (i.e., identified as three Ca2+-binding domains) and one CaM-binding domain with autoinhibitory function (Sathyanarayanan et al., 2001; Yuan et al., 2017). Plants carrying the mutated CCaMK lacking the autoinhibitory domain exhibited spontaneous nodulation even without rhizobia infection (Gleason et al., 2006). This data indicates that the legume CCaMK is a master controller of nodulation and its autoinhibitory domain is important in regulating its activity. Further studies have shown that when basal levels of Ca2+ bind to CCaMK, the protein is kept in an inactive state. However, at elevated Ca2+ concentrations (e.g., Ca2+ spiking), Ca2+/CaM also binds to CCaMK, and the protein becomes activated (Miller et al., 2013). Thus, CCaMK is kept in an inactive state when there are no symbiotic microbes present. However, once symbiosis signals are perceived, Ca2+ spiking is induced, and the inactive CCaMK state is overridden by higher levels of Ca2+ and CaM binding (Miller et al., 2013).
Further studies in the Poovaiah laboratory and others revealed that a mutated CCaMK negatively affects root nodule symbiosis in Medicago truncatula (Sinharoy et al., 2009; Jauregui et al., 2017). Site-directed mutations in the CaM-binding domain of CCaMK altered its binding capacity to CaM, providing an effective approach to study how CaM regulates CCaMK during rhizobial symbiosis in Medicago truncatula. Mutating the tryptophan at position 342 to phenylalanine (W342F) increased the CaM-binding capability of the mutant, which underwent autophosphorylation and catalyzed substrate phosphorylation in the absence of Ca2+ and CaM. When the mutant W342F was expressed in ccamk-1 roots, the transgenic roots exhibited an altered nodulation phenotype. These results suggest that altering the CaM-binding domain of CCaMK could generate a constitutively activated kinase with a negative role in the physiological function of the CCaMK [(Jauregui et al., 2017) (Figure 2)].
Figure 2 Schematic presentation displaying the domain structure of Ca2+/CaM-dependent protein kinases (CCaMK). The kinase domain (KD) is colored in blue, the autoinhibitory domain (AID) and calmodulin (CaM)-binding domain (CaMBD) are colored in green, the visinin-like domain (VID) is colored in purple and the EF-hand motifs in VID are in yellow. When symbiotic microbes are absent, the auto-inhibitory domain interacts with the kinase domain through a hydrogen bond between amino acid Thr-271 in KD and Arg-323 in AID. The interaction keeps the CCaMK inactive. The basal Ca2+ concentrations in root cell may bind to one or two EF-hands in the visinin-like domain, but not to all three EF-hand motifs. When symbiotic bacteria are present, the Nod factors induce nuclear Ca2+ oscillations. Hence, Ca2+ is loaded onto the EF-hand motifs in VID and to CaM. Subsequently, the Ca2+-loaded CaM will interact with the CCaMK AID. Ca2+ and CaM trigger conformational changes in the tertiary structure of CCaMK resulting in the AID being detached from the KD and removing the auto-inhibition caused by the Thr-271 phosphorylation. Thus, the CCaMK is completely activated. When the amino acid Ser-343 and/or Ser-344 in the AID are phosphorylated, the interaction between CCaMK and Ca2+-bound CaM is blocked and the CCaMK becomes inactive. The gain-of-function T271A mutant displays a spontaneous nodulation phenotype; a possible explanation is the hydrogen bond between amino acid Thr-271 in KD and Arg-323 in AID is compromised.
The CCaMK phosphorylated symbiosis-related substrate has been identified, CYCLOPS in Lotus and interacting protein of DMI3 (IPD3) in Medicago truncatula (Lévy et al., 2004; Messinese et al., 2007; Yano et al., 2008). As with auto-active CCaMK, auto-active CYCLOPs causes spontaneous nodulation in the absence of rhizobia (Gleason et al., 2006; Hayashi et al., 2010; Miller et al., 2013; Singh et al., 2014). CCaMK phosphorylates CYCLOPS/IPD3 to form a complex that binds to promoter elements and induces the expression of symbiosis-involved genes (Yano et al., 2008; Singh et al., 2014). For example, in Lotus, CYCLOPS works with CCaMK and a DELLA transcription factor to regulate the expression of reduced (or required) arbuscular mycorrhiza1 (RAM1) (Gobbato et al., 2012; Pimprikar et al., 2016). RAM1 is a GRAS transcription factor which, when expressed, initiates the colonization of plant roots by arbuscular mycorrhiza (Gobbato et al., 2012). During Nod-factor signaling, CCaMK/IPD3 forms large complexes with two GRAS proteins, nodulation signaling pathway1 (NSP1) and NSP2, in addition to DELLA proteins. The DELLA proteins work as scaffolding to link the CCaMK-IPD3 complex with the NSP1-NSP2 complex, resulting in a complicated unit that regulates symbiotic signaling (Fonouni-Farde et al., 2016; Jin et al., 2016). This unit also activates the expression of two downstream transcription factors, NIN and ERN1 (ERF, required for nodulation 1) (Marsh et al., 2007). Furthermore, ERN1 and/or ERN2 regulate the expression of rhizobium-directed polar growth (RPG), cystathionine β-synthase like 1 (CBS1), nodule pectate lyase (NPL), and nuclear factor YA 1 (NF-YA1), while NIN regulates the expression of early nodulin 11 (ENOD11) and ENOD12 (Fonouni-Farde et al., 2016).
Another reported interactor of CCaMK is the Calf intestinal phosphatase 73 (CIP73) (Kang et al., 2011). CIP73 belongs to a large ubiquitin super family, and it contains a Scythe N ubiquitin-like domain. A report showed that CIP73 interacted with CCaMK in a Ca2+-independent manner (Kang et al., 2011). However, CIP73 is phosphorylated by CCaMK in a Ca2+/CaM-dependent manner (Kang et al., 2011). The cip73 silencing mutants displayed significantly reduced nodulation as compared to the wild-type control, indicating that it has a role in nodule formation (Kang et al., 2011). Notably, due to CIP73 having a scythe-N ubiquitin-like domain, it may be interesting to study whether the 26S proteasome mediates rhizobial/AM fungal infections. Known components of the Ca2+-mediated local symbiotic pathway in roots is described in Figures 1 and 2.
Phytohormone-mediates symbiosis through regulating the stability of the CCaMK-DELLA-CYCLOPS complex
To activate nodulation or arbuscule formation, the CaM-CCaMK-DELLA-CYCLOPS protein complex binds to the promoter of symbiosis-related genes (Pimprikar et al., 2016). The DELLAs are a key scaffold protein for symbiosis, but they are also critical transcription factors that regulate phytohormone signaling. Therefore, DELLAs may be the link between hormone signals and symbiosis (Liu et al., 2018). Studies about phytohormones involved in symbiosis focus on gibberellic acid (GA), auxin, cytokinin, and abscisic acid (ABA).
NFs-triggered the activation of nodulation requires an optimal level of GAs and exogenous high concentration (>0.01 μM) GA treatments inhibit AM and rhizobial symbioses (Ferguson et al., 2005; Ferguson et al., 2011). One hypothesis is that GA negatively regulates plant symbiosis through the disruption of the CCaMK-DELLA-CYCLOPS complex. This disruption occurs when GA-receptor GID1 (GA INSENSITIVE DWARF1) perceives GA, and then interacts with DELLA proteins (Nemoto et al., 2017). The GA-GID1-DELLA complex recruits a specific F-box protein that interacts with the SCF E3 ligase complex, resulting in the 26S proteasome-mediated ubiquitination and degradation of DELLA proteins. Recruiting E3 ligases to DELLAs (i.e., part of the CaM-CCaMK-DELLA-CYCLOPS complex) may lead to the degradation of the entire complex (Wang and Deng, 2011; Kudla et al., 2018).
Auxin has a positive role in nodulation (Suzaki et al., 2013; Breakspear et al., 2014; Bensmihen, 2015), and nodule numbers are regulated by shoot-to-root auxin transport (van Noorden et al., 2006). Auxin also seems to be positively involved in AM symbiosis (Hanlon and Coenen, 2011; Etemadi et al., 2014). However, a separate study revealed that indole-3-acetic acid (IAA), a class of auxin, promoted GA1 accumulation in pea (O’Neill and Ross, 2002); further studies are needed to extend our knowledge about GA and auxin crosstalk during plant symbiotic microbe interaction.
The role of Ca2+ in controlling cell division and growth is well recognized (Perris et al., 1968). It is becoming clear that there is also a linkage between cytokinin signaling and Ca2+ signaling. Cytokinin is an important hormone involved in symbiotic interactions between Rhizobium bacteria and leguminous plants. This interaction leads to the induction of the nitrogen-fixing nodule. It was proposed that cytokinin was the key differentiation signal for nodule organogenesis (Frugier et al., 2008). It was also proposed that cytokinin is involved in the regulation of NIN (Nodule Inception) expression to initiate nodule organogenesis and other transcriptional regulators through mechanisms operating both locally and systemically (Yano et al., 2008; Liu et al., 2019). Further study revealed that Ca2+ signaling involve cytokinin mediated nodule formation through regulating cytokinin biosynthesis (Reid et al., 2016; Reid et al., 2017). Nod factor induced cytokinin biosynthesis genes expression, including isopentenyl transferase 2 (LjIPT2) and lonely guy 4 (LjLog4), and CCaMK is required for this induction (Reid et al., 2017), although the underlying mechanism is still unclear.
ABA application can inhibit root nodulation, suggesting that ABA is a negative regulator of rhizobial symbiosis (Suzuki et al., 2004; Ding et al., 2008). Interestingly, arbuscule formation was compromised in an ABA biosynthesis-defective tomato mutant sitiens (Herrera-Medina et al., 2007) and further work in Medicago truncatula supported the idea that some components of ABA signaling were needed for AM symbiosis (Charpentier et al., 2014). Another study revealed that ABA contributed to root symbiosis in a dose-dependent manner: high concentrations of ABA repressed AM colonization, while low ABA (i.e., less than 200 μM) promoted AM development (Liu et al., 2018). ABA works in complex signaling pathways with other hormones, including GA. In fact, the interconnection between ABA and GA is illustrated by ABA negatively regulating GA biosynthesis-related gene expression and positively regulating GA catabolism (Nag et al., 2005; Martín-Rodríguez et al., 2016). Another study revealed that exogenous ABA application enhanced the stability of DELLA protein, even in the presence of GA (Achard et al., 2006). ABA maintains the stability and integrity of DELLAs and low doses of ABA may contribute to its positive impact on AM symbiosis (Bedini et al., 2018). High levels of ABA impair Ca2+ oscillations, which negatively affects symbiosis (Charpentier et al., 2014). Further studies could address whether SA and JA are also involved in root symbiosis through stabilizing the DELLA protein, although the underlying molecular mechanism remains unclear (Liu et al., 2018).
CCaMK also has a positive role in ABA-mediated responses (Ni et al., 2019; Chen et al., 2021). Work in rice showed that the type C protein phosphate (PP2C), also known as PP45, negatively affected CCaMK activity by dephosphorylating T263. However, ABA induced H2O2 accumulation suppressed the transcriptional expression of PP45 (Ni et al., 2019). Although this work was performed in rice, which does not form symbiotic relationships with rhizobia, it would be interesting to hypothesize that ABA is involved in the mediation of root symbiosis through CCaMK. Further studies are needed to better understand the interaction between CCaMK and ABA and their role in symbiosis.
Systemic symbiotic signaling
A number of studies have revealed that plants tightly regulate nodule development through a systemic signaling pathway (root-derived peptides and shoot-derived microRNA), also known as autoregulation of nodulation (AON) (Kassaw et al., 2015). During early rhizobial infection events, the small peptides, CLAVATA (CLV)/Embryo-surrounding region (CLE), accumulate in roots and are transported to the shoots through the xylem (Yamaguchi et al., 2016; Wang et al., 2022). The rhizobial-induced CLE (RIC) is recognized by a receptor complex in leaves, and this recognition initiates the biosynthesis of cytokinins and the shoot-derived microRNA, miR2111 (Kassaw et al., 2015; Gautrat et al., 2020; Okuma and Kawaguchi, 2021). The shoot-derived regulators are transported to the root through the phloem to repress or fine-tune nodule formation (Wang et al., 2022), although the role of Ca2+ signaling in these systemic regulators is not understood.
Recent studies indicate that photosynthesis and light signals participate in symbiotic nitrogen fixation in soybean through Ca2+ signaling. Root nodules formed when plants were grown under normal light conditions. However, when light was absent, nodule formation was disrupted. Moreover, root nodules were only formed when leaves were illuminated; only illuminating the roots failed to promote the formation of infection threads by rhizobia (Wang et al., 2021). Blue light was sufficient for nodule formation, and a known blue light receptor GmGRY1 was required for light-induced nodulation. Light signals facilitated the movement and transportation of two proteins, soybean TGACG-motif binding factor 3/4 (GmSTF3/4) and flowering locus T (GmFTs), from shoots to roots. Once these proteins are in roots, the transported GmSTF3 is phosphorylated and becomes a substrate for the active CCaMK. The phosphorylated GmSTF3 interacts with GmFT2 to form a complex. This complex targets the promoter regions of GmNF-YA1 and GmNF-YB1 and induce their expression, ultimately resulting in nodule formation. Thus, these findings using soybeans suggest that plants could interpret light signals in leaves and then signal roots that photosynthesis-derived carbohydrates are available to support symbiosis and enhance nitrogen fixation in roots (Figure 3). It is worthwhile to test whether Ca2+ signaling mediates the activation and formation of mobile signals and to determine the long-distance signal transport.
Figure 3 Systemic symbiotic signaling pathways in plants. Leaves perceive the blue light signal through the blue light receptor, GmCRY, which subsequently facilitates the long-distance transport of two symbiosis-associated transcription factors, GmSTF3/4 and GmFT, from shoots to roots. CCaMK, a Ca2+ and CaM-binding protein phosphorylates GmSTF3, which then facilitates the interaction between GmSTF3 and GmFT to form a complex. This complex binds to the promoter region of symbiosis-related genes, such as NIN, NF-YA1 or NF-YB1, to trigger nodule formation in leguminous plant roots.
Summary and outlook
We are starting to learn the complexity of Ca2+ signaling during plant-microbe symbiotic interactions. Previous studies have mainly focused on the individual, local signaling components. A recent study Wang et al. (2021) uncovered that not only the local signaling, but also the systemic signal integration coordinately regulates symbiotic responses. Further studies suggest the specific spatial and temporal Ca2+ signaling response is tightly regulated and sophisticated; it is likely that multiple symbiotic signaling pathways are involved in fine-tuning a precise symbiosis response in plants (Kudla et al., 2018).
Although exciting advances in Ca2+-mediated symbiotic signaling pathways are rapidly expanding our knowledge about how plants mediate symbiotic interactions, some questions remain to be answered. One question is whether Nod factor or symbiotic microbes induce the cytosolic Ca2+ transients (although nuclear Ca2+ oscillation has been well documented) and which Ca2+ component(s), Ca2+ channel or Ca2+ pumps that are localized in the cytoplasmic membrane is/are involved in this biological process. Another question is whether CCaMK is involved in the transport of ammonia from roots to shoots. More questions remain as to whether other novel Ca2+ signaling proteins [e.g., CaM-like proteins (CML) or calcineurin B-like proteins (CBLs)-CBL-interacting protein kinases (CIPKs)] participate in symbiotic regulation. The answers to the above questions should provide new insights into nodulation and arbuscular mycorrhizal colonization. This knowledge would empower us to develop strategies to improve and manipulate plant-microbe symbioses and, thus, increase crop yield and agricultural productivity.
Author contributions
PY, FL, CG and BP were involved in writing this review. All authors contributed to the article and approved the submitted version.
Funding
USDA NIFA (Hatch Project 1015621 to BWP) and past support of the National Science Foundation (grants 1021344 and 1557813 to BWP) are acknowledged. This publication was partly supported by Provincial Natural Science Foundation of Hunan (2021JJ40241) and the National Technology System for Grape Industry (CARS-29-ZP-9). This publication was supported in part by the USDA National Institute of Food and Agriculture, Hatch project 1015621 to CG.
Conflict of interest
The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.
Publisher’s note
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Keywords: Ca2+ signaling, local and systematic signaling, mycorrhizal development, plant-beneficial microbe interaction, rhizobial nodulation
Citation: Yuan P, Luo F, Gleason C and Poovaiah BW (2022) Calcium/calmodulin-mediated microbial symbiotic interactions in plants. Front. Plant Sci. 13:984909. doi: 10.3389/fpls.2022.984909
Received: 02 July 2022; Accepted: 23 September 2022;
Published: 18 October 2022.
Edited by:
Jianping Wang, University of Florida, United StatesReviewed by:
Chao Wang, University of California, Berkeley, United StatesElena A. Dolgikh, All-Russian Research Institute of Agricultural Microbiology of the Russian Academy of Agricultural Sciences, Russia
Copyright © 2022 Yuan, Luo, Gleason and Poovaiah. This is an open-access article distributed under the terms of the Creative Commons Attribution License (CC BY). The use, distribution or reproduction in other forums is permitted, provided the original author(s) and the copyright owner(s) are credited and that the original publication in this journal is cited, in accordance with accepted academic practice. No use, distribution or reproduction is permitted which does not comply with these terms.
*Correspondence: B. W. Poovaiah, cG9vdmFpYWhAd3N1LmVkdQ==