Abstract
The developmental program of roots is constantly modified according to environmental signals and often includes an elevation in the density of root hairs, which increases the root’s absorptive surface in an attempt to meet the ion and water demands of the plant. Root hairs emerge from certain epidermal cells and this depends on a complex genetic cascade. Once this has determined root hair cell fate, local wall loosening and turgor pressure initiate a bulge in the cell wall. The transition from root hair initiation to actual tip growth begins with the accumulation of secretory vesicles at the apical part of the bulge. A complex interplay between ion oscillations, cytoskeleton architecture, vesicle trafficking, cell wall metabolism and hormonal and environmental signals allows the root hair to maintain growth at the tip. This review summarizes the current knowledge on the core components regulating root hair tip growth, critically identifies challenges for future research and points to commonalities and differences with the current knowledge on pollen tube tip growth.
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1 Introduction
Two types of cell elongation, named diffuse and tip growth, are found in higher plants. Tip growth is a highly specific and conserved developmental process that governs both root hair (RH) and pollen tube (PT) growth. Following pollination, PTs emerge from the pollen grains and transport the male gametophytes towards the ovule to facilitate double fertilization. RHs on the other hand arise from the root’s epidermis, where they drastically increase the root’s absorption/contact area (Fig. 9.1). As such, tip growth lies at the basis of the plant’s ability to reproduce, acquire nutrients and water, anchor to the soil and interact with soil microbiota. RHs are often exploited to study tip growth since many mutations exist, they are easy to visualize and especially since their presence is not a requirement for plant survival.
The root epidermis is typically built up by RH (trichoblasts) and non-RH cells (atrichoblasts). Cell fate specification and initiation site determination are the processes that regulate whether and where RH bulges are formed on epidermal cells. A genetic cascade involving intra- and intercellular position-dependent signalling and complex feedback loops determines cellular fate, and local wall weakening coupled to turgor pressure initiates a highly localized bulge (reviewed in Balcerowicz et al. 2015). Next, fast tip growth is initiated. Unlike diffuse cell elongation where growth occurs over the whole cell’s surface, tip growth is restricted to the very apex of the tubular growing structure. The frequency and amplitude of PT and RH growth depends on extracellular conditions and a highly organized interplay between gene transcription, protein turnover and modification, the cytoskeleton, the cell wall, ion and reactive oxygen species (ROS) gradients and membrane-localized import and export proteins. At first sight, the process by which PTs and RHs grow appears to be highly similar. More so, comparing the RH and PT transcriptome revealed the existence of a common apical cell growth signature (Becker et al. 2014). However, several decades of research has shown that even though some central aspects are shared, multiple regulatory components differ between PT and RH development. Here, we review ROP GTPases, ROS, calcium and pH gradients, the actin and microtubule (MT) cytoskeleton and the cell wall, main molecular determinants controlling both PT and RH tip growth. We will not focus on the hormonal and genetic (mainly root hair specific-like 4; RSL4) regulation of these molecular players, but we will identify commonalities, differences and potential targets for future research based on the current knowledge available at the time of writing.
2 ROP GTPases as Master Regulatory Switches
2.1 ROPs Control Tip Growth
Plant Rho-like GTPases (ROPs) play a key role in the regulation of various developmental and cellular processes with emphasis on polarized growth of RHs and PTs. These small GTPases cycle between an inactive (GDP-bound) and an active (GTP-bound) state and thus act as molecular switches ‘turning on and off’ a wide range of signalling pathways (Fig. 9.2). ROP activity oscillates with the same frequency as tip growth oscillations (Monshausen et al. 2007; Hong et al. 2015) and depends on the action of several regulatory proteins. GTP-bound ROPs localize to the plasma membrane (PM) at the apex of elongating RHs and PTs (Kost et al. 1999; Molendijk et al. 2001; Jones et al. 2002), allowing them to relay extracellular signals from PM-associated receptors such as receptor-like kinases (RLKs; Nibau and Cheung 2011). ROPs interact with diverse effectors in order to mediate actin dynamics, MT organization, vesicle trafficking (reviewed in Nibau et al. 2006; Yalovsky et al. 2008; Yang 2008), ROS production (Carol et al. 2005) and the formation of a tip-focused Ca2+ gradient (Li et al. 1999).
The Arabidopsis genome encodes 11 ROPs from which ROP1, 2, 4 and 6 have been implicated in tip growth of RHs. In general, expression of constitutively active (CA) forms of ROPs leads to non-polarized RH growth, whereas overexpression of dominant negative (DN) variants results in reduced RH elongation (Molendijk et al. 2001; Tao et al. 2002; Jones et al. 2002, 2007; Carol et al. 2005). Furthermore, ROP1, ROP3 and ROP5 have been shown to regulate PT growth and perturbation of their expression, and activity causes similar effects to those observed in RHs (Kost et al. 1999; Fu et al. 2001; Chen et al. 2003; Gu et al. 2003). Interestingly, transcription of a common set of ROP-related genes defines both RH and PT development in Arabidopsis (Becker et al. 2014).
2.2 ROP-Associated Proteins Regulate ROP-GTPase Activity
Activity of ROPs is mainly regulated by guanine nucleotide exchange factors (GEFs), GTPase-activating proteins (GAPs) and guanine nucleotide dissociation inhibitors (GDIs) (Fig. 9.2; reviewed by Yang 2002; Nagawa et al. 2010).
2.2.1 Guanine Nucleotide Exchange Factors
GEFs are PRONE-domain-containing proteins which activate ROPs at the apical PM by catalysing the exchange of GDP to GTP (Fig. 9.2; Berken et al. 2005). In Arabidopsis, 3 of 14 members of the GEF family are implicated in RH development. The RH-specific ROPGEF4/RHS11 is involved in the RH elongation stage since loss of function causes a short RH phenotype (Won et al. 2009; Huang et al. 2013a), while knocking out ROPGEF10 mainly results in a reduced RH number. The fact that ROPGEF10 is expressed in all root epidermal cells (Won et al. 2009) and that no changes in the expression of RH-specific genes were found in gef10 plants indicates that ROPGEF10 rather plays a role during RH initiation. Truncation and domain-swapping experiments revealed that the distinct functions of ROPGEF4 and ROPGEF10 result from their noncatalytic domains (Huang et al. 2013a). On the other hand, both ROPGEFs are interacting partners for RLK FERONIA (FER) and seem to participate in a common pathway for ROS production which involves activation of ROP2 and ROP6 (see Sect. 9.3; Huang et al. 2013a). Shin et al. (2010) reported that overexpression of the third member, ROPGEF11/phytochrome-interacting ROPGEF1 (PIRF1), affects RH polarity and RH density. Furthermore, growing PTs, similarly to RHs, express seven members of the ROPGEF family and also require the action of ROP activators (Gu et al. 2006; Zhang and McCormick 2007). It has been demonstrated that the GFP-tagged RopGEF1, RopGEF8, RopGEF9, RopGEF12 and RopGEF14 localize to the PM of the PT apex and that overexpression of these GEFs causes loss of polar PT growth with the most severe phenotype seen for RopGEF1 (Gu et al. 2006). Notably, overexpression of RopGEF12 leads to dramatic changes in PT morphology only if RopGEF12 is C-terminally truncated, suggesting that the C-terminal region is auto-inhibitory to GEF activity (Zhang and McCormick 2007). According to more recent findings, the C-terminus of RopGEF1 is directly phosphorylated by the pollen RLK pollen receptor-like kinase 2 (PRK2) (Chang et al. 2013). The authors proposed a model in which PRK2 activates RopGEF1 through releasing its auto-inhibition by phosphorylation, which in turn leads to the activation of ROP1. In addition, interactions with ROPGEFs have also been reported for the RLKs from the Catharanthus roseus receptor-like kinase 1-like (CrRLK1L) subfamily (Duan et al. 2010).
2.2.2 GTPase-Activating Proteins
Activated ROPs are ‘switched off’ by GTPase-activating proteins (GAPs) which accelerate GTP hydrolysis. In Arabidopsis, nine genes have been found to encode for proteins with a GAP catalytic domain (Wu et al. 2000; Hwang et al. 2008). Among these, six members, termed ROPGAP1–ROPGAP6, contain a CRIB motif that is required for binding to ROPs and acts as a positive regulator of GAP activity (Wu et al. 2000). So far nothing is known about the role of ROPGAPs in RH growth. However, according to the Arabidopsis eFP Browser (Winter et al. 2007), ROPGAP1 and ROPGAP6 are specifically expressed in RH cell files. ROPGAP1 has been shown previously to regulate ROP1 activity in PTs since coexpression of this GAP restores polarized PT growth in ROP1-overexpressing plants (Hwang et al. 2010). Consistently, NtRhoGAP1, a tobacco homologue of ROPGAP1, suppresses a phenotype caused by NtRAC5 (a tobacco ROP) overexpression (Klahre and Kost 2006). ROPGAP6 is annotated as a pseudogene although it has an intact ORF and a normal structure. In addition, the ROPGAP6 protein lacks part of a conserved GAP motif (Kost 2010). Hence, it remains unclear whether ROPGAP6 encodes a functional ROPGAP. Furthermore, Hwang et al. (2008) have identified novel structurally distinct Arabidopsis ROPGAPs, termed REN1-3, which contain a conserved GAP motif, an N-terminal pleckstrin homology (PH) domain and C-terminal coiled-coil regions. It is likely that a PH domain regulates catalytic activity and/or localization of RENs through binding to phospholipids, as it was shown for non-plant GAPs (Harlan et al. 1994; Lemmon 2008). To date, REN1 is the only PH-type ROPGAP characterized in detail. Knocking out REN1 leads to formation of balloon-shaped PTs indicating that REN1 plays a major role in controlling PT growth polarity. The authors suggested a self-organizing mechanism in which REN1 associates with exocytic vesicles via the coiled-cold part and is targeted to the apical PM where it globally inhibits ROP1 activity. Vesicle trafficking is stimulated by ROP1 signalling which creates a negative feedback loop and prevents excessive ROP activation. It would be interesting to verify whether a similar mechanism involving REN1 exists in RHs.
2.2.3 Guanine Nucleotide Dissociation Inhibitors
Spatial control of ROP signalling also depends on RhoGDIs, small cytoplasmic proteins characterized by the presence of a C-terminal immunoglobulin-like domain (IG-like) and a regulatory arm (RA). The IG-like domain is responsible for transferring inactive ROPs from the PM to the cytoplasm, followed by the formation of ROP/RhoGDI heterodimers (Klahre et al. 2006; Kost 2010). The RA sequesters ROPs in their inactive state by preventing GDP dissociation and blocking interactions with regulators and effectors (DerMardirossian and Bokoch 2005). The Arabidopsis RhoGDI family consists of three members (RhoGDI1, 2a and 2b) that share high similarity with mammalian RhoGDIs (Bischoff et al. 2000). RhoGDI1/SUPERCENTIPEDE1 (SCN1) is involved in RH growth through promoting the tip-focused production of ROS by ROOT HAIR DEFECTIVE 2 (RHD2)/RBOHC (see Sect. 9.3; Carol et al. 2005). Yeast two-hybrid assay and FRET analysis revealed that RhoGDI1 interacts with ROP2, ROP4 and ROP6 (Bischoff et al. 2000; Wu et al. 2013). Further, it has been demonstrated that the phosphorylation of RhoGDI1 by calcium-dependent protein kinase 3 (CPK3) has an effect on the binding ability to ROPs (Wu et al. 2013). RhoGDI1 might regulate subcellular localizations of ROP2 since ROP2::YFP was ectopically localized at the trichoblast surface in scn1 (Carol et al. 2005). Similarly, depolarized localization of ROPs has also been observed in gdi2a-RNAi PTs (Hwang et al. 2010). Very recently, Feng et al. (2016) reported that all three RhoGDIs play redundant roles in sustaining cellular homeostasis during PT growth. In addition, RhoGDI2a and RhoGDI2b are mainly expressed in the male gametophyte suggesting that PTs have higher demands for GDI-mediated ROP signalling in comparison to RHs (Feng et al. 2016).
2.3 ROP Effector Proteins
In addition to ROP regulators, several ROP effector proteins such as ROP-INTERACTIVE CRIB MOTIF-CONTAINING PROTEINS (RICs), INTERACTORS OF CONSTITUTIVE ACTIVE ROPS (ICRs)/ROP INTERACTIVE PARTNERS (RIPs), receptor-like cytoplasmic kinases and cysteine-rich receptor kinase have been identified (reviewed in Nagawa et al. 2010).
2.3.1 ROP-Interactive CRIB Motif-Containing Proteins (RICs)
The Arabidopsis genome encodes 11 RICs, which interact with GTP-bound ROPs (Wu et al. 2001). To date, most of our knowledge about the involvement of RICs in tip growth comes from studies on PTs, where ROPs recruit several RICs to coordinate PT growth. Overexpression of RIC1, RIC2, RIC5, RIC6 and RIC7 inhibits, while overexpression of RIC10 promotes elongation of tobacco PTs (Wu et al. 2001). Moreover, elevated expression of RIC3 and RIC4 leads to non-polar PT growth and causes formation of bulbous tips. Phenotypes of RIC3 and RIC4 overexpression lines are associated with antagonist actions of these two effectors on F-actin dynamics, and co-overexpression of both RICs restores proper tip growth of PTs (Gu et al. 2005). RIC4 promotes actin assembly which is required for vesicle accumulation at the tube apex, whereas RIC3 mediates actin disassembly via activation of Ca2+ signalling which induces exocytosis in the growing tip. Importantly, both RICs are downstream components of ROP1 signalling demonstrating that a single ROP can act through activation of antagonist pathways (Gu et al. 2005; Lee et al. 2008). According to a recent report, regulation of F-actin dynamics in PTs also depends on the action of RIC1 (Zhou et al. 2015b). In vitro studies revealed that RIC1 has an ability to sever and cap F-actin in the presence of Ca2+. In addition, RIC1 localizes to the apical PM of PTs and its distribution oscillates together with growth oscillations. Noteworthy, previous studies have shown that ROP6 activates RIC1 in order to promote katanin-mediated MT severing in leaf pavement cells (Fu et al. 2005, 2009; Lin et al. 2013) and to inhibit PIN2 internalization through stabilization of AFs in roots (Lin et al. 2012). Thus, the action of RIC1 on the cytoskeleton seems to differ between tissues or cell types. It would be interesting to determine whether RICs also contribute to RH growth by regulating the actin and/or MT cytoskeleton (Jones et al. 2006; Cole and Fowler 2006).
2.3.2 Interactors of Constitutive Active ROPS (ICRs)/ROP Interactive Partners (RIPs)
Activated ROPs also interact with a novel class of plant-specific effector proteins known as ICRs/RIPs. All five members of the Arabidopsis ICR/RIP family are characterized by the presence of a highly conserved QWRKAA motif in their C-terminal region which is required for binding to ROPs (Li et al. 2008). Until now, the role of these effectors in RH growth remains unknown. ICR1/RIP1, the most extensively studied member of the group, has been identified from two independent yeast two-hybrid screens using CA forms of ROPs as bait (Lavy et al. 2007; Li et al. 2008). GFP-tagged ICR1/RIP1 localizes to the apical cortex of growing PTs and its distribution depends on the activity of ROP1. At the same time, overexpression of ICR1/RIP1 enhances recruitment of GFP-ROP1 to the PM what suggests that ICR1/RIC1 might participate in a positive feedback loop to ensure polar localization of ROP1 to the PM (Li et al. 2008). Furthermore, Lavy et al. (2007) have demonstrated that ICR1/RIP1 form complexes with the exocyst complex subunit SEC3A and that these complexes can interact with ROPs in vivo. This indicates that ICR1/RIP1 acts as a scaffold mediating interactions between different proteins. More recently, ICR1/RIP1 has also been shown to control polar localization of PIN auxin transporters in roots and embryos (Hazak et al. 2010). Thus, ICR1/RIP1 forms a link between auxin, ROPs and exocytosis. In addition, RIP3, which localizes to MTs, has been found to interact with active ROPs and the plant-specific kinesin-13A, thereby linking ROPs with the MT cytoskeleton (Mucha et al. 2010).
3 ROS as Diverse Signalling Molecules
3.1 ROS Production at the Tip
It is well established that RHs and PTs require production and accumulation of ROS at the tip in order to maintain polarized growth (Fig. 9.3). This process involves the activity of membrane-bound NADPH oxidases (NOX) which catalyse the reduction of molecular oxygen to the superoxide anion (O2 •−), a form of ROS (Sagi and Fluhr 2001). Monshausen et al. (2007) have demonstrated that Arabidopsis RHs exhibit oscillating increases in NOX-derived extracellular ROS levels which follow peaks in growth rate by approximately 7 s. Arabidopsis NOX, also named RBOH for respiratory burst oxidase homologues, are encoded by 10 genes (RBOHA-RBOHJ) (Torres and Dangl 2005). Generation of ROS in RHs is linked to RBOHC/RHD2 since mutations in RHD2 greatly reduce ROS levels and arrest RH development at the bulge formation stage. A similar effect on RH growth can be observed after treatment of wild-type roots with diphenyliodonium chloride (DPI), a NOX inhibitor (Foreman et al. 2003). Two other members, RBOHH and RBOHJ, share 81% amino acid identity and display partial redundancy in the regulation of PT growth. In vitro and in vivo studies have shown that rbohH rbohJ double mutants produce short and bursting PTs and exhibit reduced male fertility (Boisson-Dernier et al. 2013; Kaya et al. 2014). In Nicotiana, transfection of PTs with antisense NtNOX nucleotides downregulates the NtNOX level, decreases ROS formation and consequently inhibits tube growth (Potocký et al. 2007).
3.2 ROS Interacts with Calcium Signalling
Several lines of evidence support the hypothesis that NOX-derived ROS are involved in the activation of Ca2+ channels and Ca2+ flux into the cytoplasm at the tips of RHs and PTs (Fig. 9.3; reviewed in Wudick and Feijó 2014). First, rhd2 plants lack the tip-focused Ca2+ gradient in RHs, and exogenous application of ROS increases the level of cytosolic Ca2+ and partially restores RH growth (Foreman et al. 2003). Further, knocking out RBOHH and RBOHJ disrupts Ca2+ homeostasis in PTs although the effect is less severe than that caused in the rhd2 mutant. PTs of rbohH rbohJ retain the ability to form the tip-focused Ca2+ gradient, but this gradient is unsteady over time (Boisson-Dernier et al. 2013). In addition, it has been demonstrated that ROS activates Ca2+ channels in the PM of guard cells in response to abscisic acid (ABA; Pei et al. 2000). Furthermore, all Arabidopsis NOX proteins contain two putative EF-hand motifs in their N-terminal cytosolic part that are helix-loop-helix Ca2+-binding domains (Keller et al. 1998; Torres et al. 1998). Takeda et al. (2008) have reported the existence of a positive feedback loop between Ca2+ and ROS which results from binding of Ca2+ to EF-hand motifs within RHD2 and the Ca2+-dependent phosphorylation of RHD2. The authors demonstrated that point mutations in the EF-hands affect RH growth and that these mutations in both EF-hands and phosphorylation sites disrupt ROS formation in vitro. Ca2+-stimulated ROS production has also been confirmed for other NOX proteins including pollen-specific RBOHH and RBOHJ (Ogasawara et al. 2008; Kimura et al. 2012; Kaya et al. 2014).
3.3 ROS Regulates Cell Wall Properties
Given the fact that RHs of rhd2-1 burst when switching to tip growth, RHD2-generated ROS are proposed to stabilize the cell wall at the expanding tip. In this context ROS might act in a complementary manner with extracellular pH since increasing the growth medium pH to ≥6.0 rescues the rhd2-1 phenotype (Monshausen et al. 2007). Several studies indeed have shown that ROS affects cell wall properties although different forms of ROS may play opposite roles (Fig. 9.3). Extracellular superoxide produced by NOX can give rise to hydrogen peroxide (H2O2), a more stable type of ROS, either spontaneously or in the presence of superoxide dismutase (SOD; Halliwell and Gutteridge 1999). It has been shown that H2O2 causes cell wall stiffening by increasing cross-linking of wall polymers (Hohl et al. 1995; Schopfer 1996). Moreover, H2O2 can readily diffuse across the PM through aquaporins (Bienert et al. 2007; Hooijmaijers et al. 2012). Interestingly, a ROS gradient exists in the apical RH cytoplasm (Foreman et al. 2003; Bai et al. 2014b). However, no direct evidence exists for aquaporin-mediated transport of H2O2 at the tip of growing RHs. Most interestingly however, Di Giorgio et al. (2016) recently showed that the two aquaporins NOD26-LIKE INTRINSIC PROTEIN 4;1/2 (NIP4;1/2) are specifically expressed in PTs and that NIP4;1 can transport H2O2. Could aquaporins govern transmembrane H2O2 transport in tip-growing cells? In the presence of transition metals such as copper or iron, H2O2 can further be converted to hydroxyl radicals (•OH), the most reactive type of ROS (Fry 1998; Halliwell and Gutteridge 1999), which, in contrast, are involved in cell wall loosening through breakdown of wall polysaccharides (Fry 1998; Schopfer 2001; Liszkay et al. 2004). Thus, the proper balance between ROS species may be crucial for regulation of tip growth oscillations.
3.4 ROS and Kinase Signalling
Apart from the above-mentioned functions, ROS might also be involved in tip growth by participating in signal transduction pathways. Work by Rentel et al. (2004) has demonstrated that expression of OXIDATIVE SIGNAL-INDUCIBLE1 (OXI1), which encodes a serine/threonine protein kinase, is induced in response to H2O2 administration. In addition, H2O2 has an ability to stimulate OXI1 kinase activity in vivo. Phenotypic analysis revealed that loss-of-function mutation in OXI1 results in a slightly reduced RH length. Furthermore, OXI1 has been found to work upstream of mitogen-activated protein kinases (MAPKs) MPK3 and MPK6 since in the oxi1 mutant both MAPKs showed reduced activation after treatment with H2O2 and cellulase. Hence, it is likely that ROS may act as signalling molecules regulating activity of MAPKs by the intermediate of OXI1. The role of MAPK in RH growth has already been reported in Medicago sativa (Šamaj et al. 2002). SIMK, the homologue of MPK6, localizes to RH tips, and overexpression of its gain-of-function form has a stimulatory effect on RH growth. Besides, more recently, MPK3 and MPK6 have been implicated in funicular guidance of PTs (Guan et al. 2014).
ROS are downstream components of Catharanthus roseus receptor-like kinase (CrRLK1L) subfamily signalling pathways (Fig. 9.3). CrRLK1Ls are major regulators of cell expansion in response to extracellular signals and are likely to act as cell wall integrity sensors. In a current model, ligand-bound CrRLK1Ls interact with ROPGEFs in order to activate ROP GTPases. ROPs, in turn, stimulate NOX-dependent ROS production leading to the activation of Ca2+ channels and changes in cell wall properties (reviewed by Nibau and Cheung 2011; Wolf and Höfte 2014; Nissen et al. 2016). In RHs, ROS formation is controlled by PM-localized CrRLK1L FERONIA (FER) and fer mutants show RH defects similar to those seen in rhd2 plants (Duan et al. 2010). The FER signalling pathway in RHs involves ROPGEF1, ROPGEF4, ROPGEF10 and ROP2 and ROP6 (Duan et al. 2010; Huang et al. 2013a). Interestingly, FER is also expressed in the female gametophyte where it induces ROS-mediated PT rupture (Escobar-Restrepo et al. 2007; Duan et al. 2010, 2014). Furthermore, ERULUS/[Ca2+]cyt-ASSOCIATED PROTEIN KINASE 1 (CAP1), which unlike other CrRLK1Ls is localized at the tonoplast, also contributes to ROS-mediated RH growth since abnormal RH growth in the cap-1 mutant coincides with the absence of a ROS gradient in the hair tips (Haruta et al. 2014; Bai et al. 2014a, b). The ROS gradient in cap-1 can be restored in NH4 +-free growth medium suggesting a possible interplay between ROS and ammonium (Bai et al. 2014b). Besides, RHD2 activity also depends on the action of ROPGDI1/SCN1, a ROP regulatory protein. In scn1 mutants RH bulges are formed at ectopic positions on the trichoblast, which results from delocalized RHD2 accumulation and ROS production (Carol et al. 2005). Proper distribution of RHD2 relies on actin microfilaments because functional loss of ACTIN2 and treatment with microfilament-disrupting drug cytochalasin D (CytD) both lead to RHD2 accumulation in cytoplasmic clumps (Takeda et al. 2008). The fact that actin microfilament dynamics in RHs are regulated by ROP2, which is a target of SCN1, suggests that SCN1 might spatially control RHD2 localization via this ROP (Jones et al. 2002; Takeda et al. 2008). Similarly to RHs, ROS production in PTs is also controlled by CrRLK1L members. Pollen-specific ANXUR1 (ANX1) and ANXUR2 (ANX2) act redundantly to maintain PT growth within female tissue since PTs of anx1 anx2 double mutant burst after germinating in vitro and fail to reach the ovules in vivo (Boisson-Dernier et al. 2009). Given the fact that the phenotype of anx1 anx2 resembles that of rbohH rbohJ and that overexpression of ANXs and knockout of RBOHH and RBOHJ enhances exocytosis, it is proposed that ANXs regulate RBOHs to synchronize growth rate with cell wall exocytosis (Boisson-Dernier et al. 2009; Kaya et al. 2014; Lassig et al. 2014; Nissen et al. 2016).
4 Ion Oscillations Integrate Extra- and Intracellular Signalling
4.1 Calcium
4.1.1 Introduction
Calcium ions function as important second messenger in eukaryotic cells. In plants, Ca2+ is of crucial importance for signal transduction in processes such as long-distance propagation of electrical signals (reviewed in Steinhorst and Kudla 2014), the response to salt stress (Choi et al. 2014), regulation of exocytosis (Zorec and Tester 1992; Battey et al. 1999) and actin cytoskeleton dynamics (Battey and Blackbourn 1993; Chen et al. 2002; Braun et al. 2004), cell wall remodelling (Holdaway-clarke et al. 1997; Rounds et al. 2011), phosphoinositide signalling (Franklin-Tong 1999), stomatal aperture (Allen et al. 2001; Evans et al. 2001), mechanosensing (Monshausen et al. 2009) and gravitropism (Plieth and Trewavas 2002; Toyota et al. 2007).
Given the low diffusion constant of Ca2+ in the cytoplasm (10−7 cm−2 s−1; Thomas 1982), local Ca2+ concentration maxima can be maintained for a prolonged period of time. Ca2+ concentration peaks are often keys for local regulation of specific signalling pathways in the cell. For instance, in living systems, integration of biotic and abiotic stimulus perception often occurs through Ca2+ signalling by local elevation of the cytosolic free Ca2+ concentration ([Ca2+]cyt; Hetherington and Brownlee 2004; Trewavas 1999).The existence of Ca2+ maxima relies on a well-coordinated release and sequestration from and to inter- and intracellular Ca2+ stores, through a collection of Ca2+ transporters. Such elevations in [Ca2+]cyt can consist of a single transient peak, but often exhibit a more complex wave-like pattern. Highly specific differences in the temporal and spatial nature of these Ca2+ dynamics are often referred to as ‘Ca2+ signatures’ (Dodd et al. 2010). The characteristics (duration, frequency and amplitude) of these signatures determine downstream signal perception and propagation through a number of Ca2+-sensing and Ca2+-relaying proteins. Final perception of the Ca2+ signal steers multiple developmental pathways, often related to plant morphogenesis, including RH and PT development.
A central role for Ca2+ signalling in tip-growing cells was established over 20 years ago. For instance, both RHs and PTs rely on optimal extracellular Ca2+ concentrations ([Ca2+]ext) for successful tip growth. Generally, a lack of Ca2+ ions results in decreased RH growth in Arabidopsis (Schiefelbein et al. 1992). Also for PTs, a lack or excess of Ca2+ in the growth medium results in abnormal, stunted tubes (Boavida and McCormick 2007). Recently, advancements in spatial and temporal visualization of in vivo Ca2+ dynamics have further contributed to unraveling the complexity of Ca2+ signalling in RH and PT development. Whereas both cell types grow by the process of tip growth, some remarkable differences between PT and RH exist in the Ca2+-related machinery. More so, while our understanding has greatly improved, it is clear that the current knowledge is only scratching the surface, and many discoveries are yet to be made.
4.1.2 An Oscillating Tip-Focused Calcium Gradient Controls RH and PT Growth
Growing RHs and PTs exhibit a clear zone at their extreme apex. The clear zone delineates the region to which all tip growth-related machinery is concentrated. Numerous studies have now shown that the clear zone coincides with a tip-focused cytosolic Ca2+ gradient in both RHs (Fig. 9.4) and PTs of multiple species (Schiefelbein et al. 1992; Pierson et al. 1996; Holdaway-clarke et al. 1997; Felle and Hepler 1997; Michard et al. 2008; Fan et al. 2011). Relative to the RH tip, this gradient extents inward for 20–60 μm (Felle and Hepler 1997; Monshausen et al. 2008). In rapidly growing RHs, the [Ca2+]cyt ranges from 100 nM at the basal part (RH shank) to more than 1 μM at the apex (Wymer et al. 1997; Felle and Hepler 1997). In PTs, [Ca2+]cyt higher than 3 μM have been reported at the tip (Pierson et al. 1996).
Several pharmacological experiments showed that the existence of this tip-focused Ca2+ gradient is crucial for proper elongation of tip-growing cells. For instance, treatment of RHs with Ca2+ channel blockers such as verapamil, nifedipine or La3+ or the Ca2+ chelator EGTA resulted in dissipation of the Ca2+ gradient and subsequent RH growth inhibition or a sudden increase in growth rate followed by bursting of the RH tip (Herrmann and Felle 1995; Bates and Lynch 1996; Wymer et al. 1997; Monshausen et al. 2008).
The localization of the Ca2+ gradient also determines the directionality of growth in RHs and PTs. Using a caged Ca2+ ionophore (A23187) approach, a local and transient Ca2+ increase can be induced extracellularly, which stops RH growth immediately (Monshausen et al. 2008). Conversely, it was also shown that both RHs and PTs direct their growth towards a transiently induced [Ca2+]ext maximum (Malhó and Trewavas 1996; Bibikova et al. 1997). Curiously, whereas RHs redirect towards the original growth direction after reestablishment of the normal [Ca2+]ext distribution, PTs do not. At the time of writing, the mechanisms that lie at the basis of this difference between RH and PT development remain unidentified.
Together, these results show that the Ca2+ gradient is a key component of the tip growth machinery. Importantly however, tip growth does not occur as a linear process. Instead, RH and PT growth rates oscillate, with alternate periods of slower growth followed by periods of fast expansion. In RHs, growth rates range between 1 and 3.2 μm min−1 (Monshausen et al. 2008; Cárdenas 2009). PTs grow considerably faster, with growth rates ranging between 6 and 30 μm min−1 (Messerli et al. 1999, 2000). The tip-focused [Ca2+]cyt oscillates at the same frequency as the growth rate, but with a phase delay of several seconds. For instance, Arabidopsis RH growth rates and apical [Ca2+]cyt oscillate at a frequency of 2–4 min−1. By using the ratiometric calcium marker Yellow Cameleon 3.6 (YC3.6), Monshausen et al. (2008) demonstrated that the peak Ca2+ level lags the growth rate peak by approximately 5 s. It seems that the timing of these events is conserved between PT and RH development and among species. For instance, whereas the growth rate oscillations of PTs (period of 15–50 s) occur much faster compared to RHs, the phase lag in lily PTs was also found to be approximately 4–5 s (Pierson et al. 1996; Messerli et al. 2000).
4.1.3 Ca2+ Fluxes
4.1.3.1 An Oscillating, Tip-Focused Influx of Extracellular Ca2+
The presence of an oscillating tip-focused Ca2+ gradient in RHs and PTs relies on active Ca2+ transport of extracellular Ca2+ across the apical PM. Using non-invasive ion-selective vibrating probe analysis, several independent experiments reported on the existence of an apical Ca2+ influx both in RHs and PTs of several species. In RHs, the Ca2+ influx ranged from approx. 0.01 to 0.04 amol μm−2 s−1 at the tip, until reaching basal levels at a distance of ±20 μm from the apex (Schiefelbein et al. 1992; Jones et al. 1995; Felle and Hepler 1997). In growing PTs, inward Ca2+ fluxes ranged from 0.003 to 0.5 amol μm−2 s−1 (Kuhtreiber and Jaffe 1990; Pierson et al. 1996; Holdaway-clarke et al. 1997; Messerli et al. 1999; Michard et al. 2008, 2011). The study of Messerli et al. (1999) revealed that PTs grew at a steady rate (~0.2 μm s−1) until they reached a certain length (approx. 1 mm); after that PT growth rate and Ca2+ influx switched to an oscillating pattern. Similarly, Michard et al. (2011) observed strong Ca2+ influx oscillations at the tip of tobacco PTs (fluctuating between 0.06 and 0.5 amol μm−2 s−1). The rate of Ca2+ influx oscillations seemed to be correlated to the PT growth rate (Pierson et al. 1996) and is sensitive to extracellular stimuli such as d-serine (Michard et al. 2011).
Similar to the [Ca2+]cyt, the tip-focused Ca2+ influx also exhibits the same period, but cross-correlation analysis showed that the peak Ca2+ influx followed the peak growth rate with a lag time of approx. 15 s (Holdaway-Clarke et al. 1997; Messerli et al. 1999; Holdaway-Clarke and Hepler 2003).
The structural properties of the cell wall largely depend on the presence of Ca2+ (see Sect. 9.4.1.4). As such, the observed Ca2+ influx at the tip of growing RHs and PTs is expected to simultaneously provide Ca2+ for the cell wall and Ca2+ for active transport into the cytosol. Recently, Hepler et al. (2012) calculated the species-specific Ca2+ influx in growing PTs that would be needed to provide the required amount of structural Ca2+ to the cell wall (Hepler et al. 2012). Their findings implicate that the majority of vibrating microelectrode measurements likely underestimate the actual fluxes involved in tip growth (Table 9.1). Holdaway-Clarke et al. (1997) performed a similar analysis for Lilium PTs and found that, in perfect agreement with their experimental data, a flux of approx. 0.35 amol μm−2 s−1 would be needed to supply the cell wall with the required amount of Ca2+ (Holdaway-Clarke et al. 1997).
4.1.3.2 Ca2+ Transporters
Plants have evolved specific Ca2+ transport proteins, different from those found in other eukaryotic organisms (Steinhorst and Kudla 2014). Both in PTs and RHs, a Ca2+ influx is maintained by a specialized set of Ca2+ transport proteins (Fig. 9.4). Given the heterogeneity of the extracellular environment, it is expected that tip-growing cells contain several types of Ca2+ transporters that would allow for Ca2+ influx in different conditions. Great scientific effort has gone into identifying the precise characteristics of the Ca2+ influx, in order to narrow the search for the involved Ca2+ channels in both RH and PT development. The ability to perform patch-clamp analysis on either isolated protoplasts or intact tip-growing cells leads to the identification of a series of candidates, some of which are yet to be confirmed and others which are now believed to be crucial tip growth regulators.
Cyclic nucleotide-gated channels (CNGCs)
are non-specific, Ca2+-permeable cation channels regulated by cyclic nucleotides such as cAMP (Maser et al. 2001; Talke et al. 2003; Ward et al. 2009). CNGCs also have a binding site for calmodulin (Kohler and Neuhaus 2000). As such, they can form a direct relay system between cNMP and Ca2+ signal transduction pathways. The Arabidopsis genome contains 20 CNGCs, some of which have been shown to be involved in Ca2+-mediated PT growth. The latter is consistent with the fact that cNMP signals in pollen can affect growth in a Ca2+-dependent manner (Moutinho et al. 2001; Rato et al. 2004; Wu et al. 2011). Publicly available transcriptomics data shows that at least six Arabidopsis CNGCs are strongly expressed in in vivo grown PTs and nine CNGCs show strong expression in trichoblast cell files (Table 9.2). Alterations in expression levels of the PT-expressed CNGCs resulted in dramatic growth defects and reduced male fertility (Tunc-Ozdemir et al. 2013; Frietsch et al. 2007; Gao et al. 2016). The transcription of several CNGC genes is altered in a number of well-characterized RH developmental mutants (Bruex et al. 2012; Simon et al. 2013). Most notably, CNGC6 and CNGC9 show very high and specific transcription in RH cell files, and their transcription is strongly affected in several RH developmental mutants. At the time of writing, however, no studies have focused on the role of CNGCs in RH development.
Hyperpolarization- and depolarization-activated Ca2+ channels (HACCs and DACCs)
have been identified in the RH and PT apical PM. Over a decade ago, Véry and Davies identified a hyperpolarization-activated Ca2+ conductance in growing RH protoplasts, operative specifically at membrane potentials equal to and lower than the resting potential of growing Arabidopsis RHs (between −160 and −200 mV; Lew 1996), and within the range of physiological [Ca2+]cyt (Wymer et al. 1997; Felle and Hepler 1997; Véry and Davies 2000). Consistent with the model of tip-localized Ca2+ influx, this hyperpolarization-activated Ca2+ conductance was found to be much lower in the subapical RH region. Interestingly, the conductance increased in the presence of higher physiologically relevant [Ca2+]cyt (100–900 nM). The latter suggest that Ca2+ influx across the PM and subsequent Ca2+ accumulation in the cytosol could induce the Ca2+ influx even further. This mechanism might be part of a feedback loop, regulating Ca2+ oscillations. In 2003, Foreman et al. found a ROS-dependent HACC conductance in RHs, related to ROS originating from NADPH oxidase activity (RHD2; Foreman et al. 2003). The mechanism of ROS-controlled Ca2+ influx was also found in PTs (e.g. Wu et al. 2010), and is now considered to be a pivotal part of tip growth in general (see Sect. 9.3.2). HACCs have also been identified in PT protoplasts of several species, indicating a voltage-gated Ca2+ influx as a central player in establishing tip growth-related Ca2+ dynamics (Shang et al. 2005; Qu et al. 2007; Wu et al. 2007, 2011). Comparable to RHs, these channels typically open at a threshold voltage of approximately −100 mV, similar to the resting potential of PTs (Messerli et al. 1999). Next, a DACC conductance was identified in the apical region of Arabidopsis RHs (Miedema et al. 2008). DACCs are typically most active at −80 mV (in the presence of 30 mM external Ca2+; Thion et al. 1998, 1996).
Given the known membrane potential observed in growing RHs, HACCs seem to be the main component for tip growth-related Ca2+ influx. However, the co-occurrence of CNGCs, HACCs and DACCs could provide RHs with a mechanism for Ca2+ influx at a broad range of membrane potentials and intra- as well as extracellular Ca2+ concentrations. For instance, increase of the tip-focused [Ca2+]cyt by CNGC-mediated Ca2+ influx at moderately negative voltage values would lower the activation voltage needed for HACC activity (Demidchik et al. 2002). Despite the identification of HACC conductances in RHs, actual identification and thus functional characterization of the genes coding for these channels is still lacking. Notably, the presence of a cAMP-activated HACC was shown in Pyrus pyrifolia PTs using patch-clamp analysis (Wu et al. 2011). This finding might hint towards the family of CNGCs in the quest for HACCs.
Mechanosensitive calcium channels
are also involved in regulating Ca2+ fluxes in PT growth. Tradescantia virginiana PTs were found to reorient upon touch or relocalization of the Ca2+ maximum, strongly suggesting that PTs contain mechanosensitive regulation of Ca2+ fluxes (Bibikova et al. 1997). Indeed, a mechanosensitive Ca2+ conductance was identified in protoplasts of Lilium longiflorum PTs (Dutta and Robinson 2004). Upon application of 10 kPa suction force, these channels would open and preferentially allow Ca2+ to enter the cytosol. Interestingly, Bibikova et al. (1997) found that in RHs and PTs, the Ca2+ gradient maximum is reoriented away from a mechanical obstacle or a touch induction site. More so, local mechanical perturbation of RH cells elicits a transient Ca2+ peak 1–18 s after application of the stimulus (Monshausen et al. 2009). Finally, Wang and colleagues found that impalement of RH cells with a glass microelectrode results in a similar transient increase of the [Ca2+]cyt (Wang et al. 2015b). These data strongly suggest that also in RHs, despite the lack of further evidence, a mechanosensitive Ca2+-linked mechanism is in place. Identification of the possible gene(s) related to this mechanosensitive Ca2+ conductance in PTs and RHs is still lacking.
The consensus regarding Ca2+ dynamics and growth rate oscillations states that the phase of Ca2+ oscillations follows that of growth oscillations with a lag of approximately 4–5 s. It is therefore easy to speculate that a growth spurt would result in subsequent opening of mechanosensitive Ca2+ channels due to mechanical deformation of the PM at the tip.
The search for identification of mechanosensitive channels involved in tip growth is progressing. Recently, Hamilton and colleagues identified an anion-selective mechanosensitive channel named MSCS-LIKE 8 (MSL8), with a crucial role in male fertility through regulation of osmotic forces during pollen development (Hamilton et al. 2015). MID1-COMPLEMENTING ACTIVITY 1 and 2 (MCA1, MCA2) were shown to be Ca2+ conducting mechanosensitive channels involved in root growth (Nakagawa et al. 2007; Yamanaka et al. 2010). Transcriptomics data shows that at least MCA1 is expressed in RH cell files (Brady et al. 2007). More so, transcription of MSL2 and MSL3 was detected in both RHs and PTs, making these genes worthwhile candidates for further investigation.
Glutamate receptor-like channels (GLRs)
are other candidates for generating the Ca2+ influx in PTs and RHs. In Arabidopsis, 20 genes code for proteins with strong similarity to the mammalian Ca2+ conducting glutamate receptor (Ward et al. 2009). Pollen transcriptome data revealed that at least six GLRs are preferentially expressed in pollen and one in PTs. Interestingly, at least four GLRs are preferentially expressed in trichoblast cell files (Brady et al. 2007). Of these four genes, three (GLR3.5, GLR3.7 and GLR2.1) are differentially expressed in several RH developmental mutants (Bruex et al. 2012; Simon et al. 2013). Despite the implications for these genes in their involvement in tip growth, current knowledge on their function is still mostly lacking. Only GLR1.2 and GLR3.7 were shown to be important in PT growth (Michard et al. 2011). Loss-of-function mutations in both genes resulted in shorter PTs and reduced fertility. Moreover, glr1.2 mutant pollen resembled the morphology associated with GLR inhibition by CNQX treatment, a well-known inhibitor of mammalian glutamate receptors. Crucially, the results of Michard and colleagues show that GLRs are responsible for perception of d-serine and subsequent Ca2+ influx in PTs followed by growth stimulation. Upon exogenous application of d-serine (a rare amino acid present in the pistil and ovules) to growing PTs, YC3.6 monitoring of the [Ca2+]cyt revealed an increase in the amplitude of Ca2+ oscillations in the tip. This effect of d-serine was not seen in the presence of GLR inhibitors, and the Ca2+ signature was not detected in response to other amino acids such as glutamate. These data suggest that GLRs form another component of the apical Ca2+ influx machinery. Importantly, it also shows that the specificity of GLRs is diverse and not limited to glutamate. The latter is supported by the finding that GLR3.4 expressed in HEK cells shows highly selective Ca2+ transport in response to the amono acids Asn, Gly and Ser (Vincill et al. 2012).
Calcium-efflux transporters
have been largely neglected when it comes to studying tip growth. This is largely due to the fact that no outward Ca2+ currents have been observed at the PT or RH tip. However, Schiott and colleagues identified the autoinhibited Ca2+-ATPase efflux pump ACA9 as a crucial component of PT tip growth (Schiott et al. 2004). Aca9 knockout PTs grew slower in vivo and in vitro, eventually resulting in shorter PTs (75% reduction in length) and a strong reduction in fertilization efficiency. Given the fact that ACA9 is localized at the PT PM, Schiott et al. (2004) suggest that it might have a role in recycling cytosolic Ca2+ towards the cell wall during tip growth. Interestingly, ACA9 is strongly expressed in RH cell files in Arabidopsis. It would be interesting to see what in-depth analysis of Ca2+ dynamics in aca9 mutant RHs and PTs could reveal. In total, ten autoinhibited efflux Ca2+-ATPases are found in the genome of Arabidopsis thaliana. Besides ACA9, ACA7 is also localized to the PM and expressed (albeit relatively low) in PTs and RHs. Current knowledge states that ACA7 is involved in microsporogenesis (Lucca and León 2012), but no experiments have been performed on PT and RH development. Finally, ACA12 was recently found to be localized to the plant PM (Limonta et al. 2014). Ectopic expression of ACA12 in aca9 plants led to the rescue of the aca9 male sterility phenotype, showing that ACA12 is a functional PM-localized Ca2+-efflux pump. No ACA12 transcription has been documented in in vivo grown PTs. However, in roots, ACA12 is preferentially expressed in trichoblast cells (Brady et al. 2007).
4.1.4 Ca2+ Sources and Sinks
A large influx of Ca2+ is in place during RH and PT growth; however the subsequent fate of incoming Ca2+ is unknown. The nature of fluctuating Ca2+ dynamics in tip-growing cells inherently relies on active transport and sequestration of Ca2+ ions from and to Ca2+ sources and sinks (Fig. 9.4). Solely based on the major concentration differences observed between the cytosol, cell wall and subcellular organelles, it is expected that inter-compartment Ca2+ allocation takes place inside the cell. Illustratively, the typical resting [Ca2+]cyt is kept around 100–200 nM, whereas the free Ca2+ concentration in some of the major subcellular Ca2+ stores and the cell wall can easily reach 10 mM (Bush 1995). So which compartments are known to or could contribute to Ca2+ dynamics in tip growth?
The cell wall
has been considered the main source for tip-focused cytosolic Ca2+ in tip-growing cells. In support of this consensus is the presence of multiple Ca2+ channels and Ca2+ conductances, together with the discovery of a growth-correlated oscillating inward Ca2+ influx. More so, already very early in the research of PT tip growth, it was shown that radioactive 45Ca2+ incorporates mostly in the PT cell wall (Kwak 1967). The extracellular environment is considered to form the main source for cell wall accumulating Ca2+ in both RHs and PTs. This is illustrated by the fact that in vitro growth of RHs and PTs relies on a [Ca2+]ext optimum. Importantly, instead of simply diffusing through the cell wall, a large quantity of Ca2+ is used as a means of providing dynamic structural cell wall support during tip growth. As such, normal cell wall dynamics at the tip of growing PTs and RHs inherently rely on the maintained presence of Ca2+. Thus, in order to provide sufficient Ca2+ to the cytosol while maintaining proper Ca2+ levels in the cell wall, an intricate balance must be kept between Ca2+ export and import from and to the cell wall. An array of Ca2+ transport proteins provides tight control over the Ca2+ efflux (cytosolic influx) from the cell wall (see Sect. 9.4.1.3). But how is Ca2+ retained and released from the cell wall at the tip? The RH and PT cell wall consists partly of pectins which alternate between their methylesterified and de-esterified form during tip growth (Bosch and Hepler 2005). The Ca2+-binding capacity of pectins changes accordingly, as does the availability of Ca2+ for maintaining the influx into the cytoplasm. An autoregulatory feedback loop thus links oscillations in Ca2+ influx, Ca2+ cell wall cross-linking and [Ca2+]cyt (Franklin-Tong 1999). As such, experimental evidence suggests that a self-regulating interplay between cytosolic and extracellular Ca2+ controls Ca2+ fluxes from and to the cell wall and into the cytosol. Hepler et al. (2012), however, calculated that in theory most of the Ca2+ flux at the PT tip is used for structural cell wall support and only a small quantity can be used for cytosolic influx.
Hereafter, the potential role of subcellular compartments in Ca2+ release and sequestration is discussed. However, contrary to the belief that the cell wall acts solely as a source of cytosolic Ca2+, it is rarely considered that the cell wall might also act as a sink, receiving Ca2+ from the intracellular environment through active transport. As discussed earlier, a Ca2+-efflux pump was shown to be involved in regulating PT tip growth (Schiott et al. 2004). The authors hypothesized that ACA9 could be responsible for recycling Ca2+ back to the cell wall, thereby regulating peak/trough Ca2+ levels at the tip.
The vacuole
extents throughout tip-growing cells and is thought to be crucial for the generation of an outward-directed osmotic pressure that drives cell expansion (Schiefelbein et al. 1993). In general the vacuole maintains a much higher Ca2+ concentration than that found in the cytoplasm (Bush 1995). The role of the vacuole in regulating Ca2+ release/sequestration in plants has been questioned several times (Lommel and Felle 1997; Britto and Kronzucker 2002; Rocha and Vothknecht 2012; Schönknecht 2013; Nomura and Shiina 2014). Also in RH and PT tip growth, a prominent role might exist for vacuolar Ca2+ release and sequestration (Carol and Dolan 2002). However, given the distance between the vacuole and the tip-focused clear zone, it is unlikely that the vacuole would directly contribute to the fine regulation of Ca2+ oscillations in the tip. However, massive vacuolar Ca2+ release could have a pivotal role in Ca2+-induced Ca2+ release and subsequent intracellular signal transduction. Unfortunately, direct Ca2+ dynamics within the vacuolar lumen have not been observed at the time of writing, due to the fact that the vacuolar pH interferes with Ca2+ reporters. A hopeful study came from Wang and colleagues, where they describe vacuolar ion conductance and channel activity in response to cytosolic Ca2+ alterations (Wang et al. 2015b). Their findings suggest a vacuolar Ca2+ release in RHs following a cytosolic Ca2+ peak. Wang and colleagues found that a BAPTA- or FURA-2 induced [Ca2+]cyt peak evoked a transient 2.5-fold increase in tonoplast ion conductance, whereas slow and small Ca2+ peaks did not elicit this response. The Ca2+ induced increase in tonoplast ion conductance is thought to be due to activation of voltage-independent channels.
TWO-PORE CHANNEL 1 (TPC1), a tonoplast localized depolarization-activated Ca2+ influx channel, was shown to be important for salt stress-induced Ca2+ signal propagation through the root (Choi et al. 2014). TPC1 is activated by high [Ca2+]cyt and is sensitive to both cytosolic and vacuolar Ca2+ levels, which suggests that it might be involved in regulating the Ca2+ balance across the vacuolar membrane (Dadacz-Narloch et al. 2011). It might, however, act indirectly through the generation of a vacuolar membrane potential which in turn would activate other voltage-gated Ca2+ channels (Choi et al. 2014). The role of TPC1 in tip growth remains unexplored, but transcript levels are selectively high in trichoblast cell files in Arabidopsis (Brady et al. 2007). As such, it will be interesting to see if TPC1 might be involved in regulating Ca2+ dynamics in RH cells (Konrad et al. 2011).
Finally, patch-clamp measurement of ion conductance on intact vacuole has revealed the existence of several types of Ca2+-regulated cation channels in the tonoplast (Allen and Sanders 1996; Isayenkov et al. 2010; Hedrich and Marten 2011). At the time of writing, no data exists on their involvement in RH or PT development.
Elements of the endoplasmic reticulum (ER)
are continuously replenished through the clear zone, at the tip of growing PTs and RHs (Lovy-Wheeler et al. 2007). They move along the ‘reverse fountain’ cytoplasmic streaming typical of tip-growing cells. This finding, together with several implications that the ER is able to sequester vast amounts of Ca2+, makes it an ideal candidate organelle for a Ca2+ source/sink in tip-growing cells. The ER has been hypothesized to function as a capacitive Ca2+ store (Trewavas and Malho 1997) and is one of the possible organelles that could contribute to the oscillating Ca2+ dynamics observed in the apical cytoplasm. Following a [Ca2+]cyt peak, Ca2+ sequestration in the ER could bring the Ca2+ level back to the basal level. The ER in Arabidopsis PTs sequesters up to 500 μM of Ca2+ (Iwano et al. 2009) and contains a protein called calreticulin which is able to bind 25 mol of Ca2+ per mol of protein (Michalak et al. 2009). Even more, the dissipation of tip-localized Ca2+ is thought to be regulated by ER-localized Ca2+-ATPases which would allow Ca2+ ions to move against the concentration gradient into the ER lumen (Obermeyer and Weisenseel 1991; Sze et al. 1999; Franklin-Tong 1999). Using an ER-targeted YC3.6, it was shown that cyclopiazonic acid (an inhibitor of ER-type Ca2+-ATPases) decreased the [Ca2+]ER and inhibited the growth of PTs (Iwano et al. 2009). Several Ca2+-transporting proteins such as ACA2 (autoinhibited Ca2+-ATPase) and ECA1 (ER-type Ca2+-ATPase) are expressed in PTs (Sze et al. 2006).
Finally, despite the strong influx of Ca2+ from the cell wall, the ER might also release Ca2+ at the tip. A possibility is that elements in the ER would facilitate IP3-induced Ca2+ release (Malhó 1998; Franklin-Tong 1999). A role for IP3-regulated Ca2+ release is well established in PTs (Malhó 1998; Monteiro et al. 2005). More so, the ER membrane contains inositol triphosphate (IP3) receptors which, in response to low [Ca2+], relay information to the PM ultimately resulting in an influx of extracellular Ca2+ (Putney et al. 2001).
Vesicles
are densely packed in the tip of growing RHs and PTs and occupy the entire clear zone. Vesicle fusion relies strongly on a high [Ca2+]cyt micro-environment (Zorec and Tester 1992). However, despite their obvious role in the exo- and endocytic pathway, they might also function as a Ca2+ store. In neuroendocrine cells, some vesicles were shown to harbor Ca2+ that can be exchanged in a cyclic ADP ribose-dependent manner (Mitchell et al. 2001). In plants, another hint towards a role as Ca2+ stores for vesicles is the fact that a calcium pump (ECA3) was shown to be localized to the post-Golgi endomembranes, which give rise to secretory vesicles (Sze et al. 2006).
Mitochondria
are not found in the clear zone of growing RHs and PTs. The mitochondrial proteome contains several Ca2+-binding, EF-hand-containing proteins and Ca2+-dependent protein kinases (Day et al. 2002; Heazlewood et al. 2004). Mitochondria have been shown to release Ca2+ to the cytosol, however, in a way that is too slow to relate to the rapid Ca2+ spikes observed in tip-growing cells (Loro et al. 2012).
Contrastingly, accumulated evidence implicates that mitochondria might have a pivotal role in Ca2+ sequestration instead. Plant mitochondria were shown to contain a Ca2+ uptake system (Hanson et al. 1965; Dieter and Marmé 1980; Akerman and Moore 1983; Zottini and Zannoni 1993). For Ca2+ to be pumped into the mitochondrial matrix, the Ca2+ acquisition system must be able to function at an inner-membrane potential of approx. 180 mV. Using targeted YC3.6 Ca2+ sensors to simultaneously monitor Ca2+ dynamics in the cytoplasm and mitochondria of Arabidopsis root cells, it was shown that a cytoplasmic Ca2+ increase related directly to mitochondrial Ca2+ accumulation (Loro et al. 2012). Importantly, the observed Ca2+ dynamics were particularly different from those in the cytosol (Logan and Knight 2003; Loro et al. 2012). Ca2+ dynamics also responded to exogenous application of ATP, which has also been implicated in the regulation of RH growth. A hint towards the protein(s) that might regulate mitochondrial Ca2+ dynamics came from the functional characterization of the Arabidopsis MICU protein, an EF-hand mitochondrial Ca2+ uniporter (Wagner et al. 2015). MICU is involved in fine-tuning the Ca2+ influx into the mitochondrial lumen. The micu loss-of-function mutations resulted in a higher than normal mitochondrial Ca2+ resting concentration and a reduced ability to dampen auxin and ATP-triggered Ca2+ influx into the mitochondrial matrix. Most notably, MICU is expressed in in vivo grown PTs and throughout the root (Brady et al. 2007; Qin et al. 2009).
The hereby mentioned Ca2+ sources and sinks do not function separately. It is important to acknowledge that Ca2+ dynamics in tip-growing cells are the result of a complex pathway that connects all involved Ca2+ stores and transport mechanisms. Localized Ca2+ concentrations depend on diffusion through the cell wall; retention in the cell wall; active inward transport; uptake into the vacuole, ER, mitochondria and vesicles; and transport outward towards the apoplast.
4.1.5 Direct Targets of Calcium Signalling
The intrinsic properties of Ca2+ signatures are interpreted by the action of several Ca2+-sensing proteins. The Ca2+ signal is then ‘decoded’, resulting in a specific cellular response (e.g. long-distance Ca2+-mediated signal transduction from root to shoot leads to changes in shoot gene transcription; Choi et al. 2014). In tip growth, Ca2+ signal transduction has been shown to ultimately regulate most of the key components related to the tip growth machinery (Fig. 9.5). It has been found that Ca2+ may regulate membrane trafficking since loss of the Ca2+ gradient disrupts the tip-focused accumulation of RabA4b and affects RH growth (Preuss et al. 2006). In addition, cytosolic Ca2+ can modulate F-actin dynamics by controlling the activity of diverse actin-binding proteins (ABPs) such as profilins, villins and actin-depolymerizing factors (Hussey et al. 2006), thereby indirectly influencing vesicle movement. Moreover, Ca2+ has been implicated as a crucial component of several feedback loops regulating ROP-GTPase activity (Yan et al. 2009) and ROS production at the tip (Takeda et al. 2008).
Multiple Ca2+-sensing/-binding proteins are expressed in PTs and RHs (Fig. 9.5). Upon Ca2+ binding, a conformational change is induced leading to signal transduction. Signal transduction is often the result of consecutive phosphorylation cascades initiated by Ca2+-dependent protein kinases (CDPKs). Such CDPKs containing an enzymatic domain are commonly referred to as Ca2+ responders, whereas proteins that lack direct Ca2+-dependent catalytic activity (calmodulin proteins (CaMs), calmodulin-like proteins (CMLs), calcineurin B-like proteins (CBLs) and CBL-interacting protein kinases, (CIPKs)) are designated sensor relays (Sanders et al. 2002). The latter ‘relay’ the Ca2+ signal by conformation-induced protein-protein interactions. We will shortly discuss these proteins in more detail, in relation to RH and PT development.
Calcium-dependent protein kinases
have both a CaM and kinase domain, allowing them to ‘sense’ Ca2+ and immediately relay the Ca2+ signal through phosphorylation of one or more target proteins. The CDPK family consists of 34 members, most of which contain N-myristoylation and/or N-palmitoylation sites. The latter reflects a probable membrane association, consistent with their role as Ca2+-sensing proteins. Importantly, one fourth of the known Arabidopsis CDPKs is preferentially expressed in pollen (Pina et al. 2005), suggesting a major role in tip growth. Moreover, CDPKs are considered active at Ca2+ concentrations in the physiological range detected at the tip of growing RHs and PTs (100–1000 nM; Myers et al. 2009). Multiple studies have indeed shown that CDPKs are important regulators of tip growth. For instance, Myers et al. (2009) have shown that the Ca2+-dependent protein kinases 17 and 34 (CPK17 and CPK34) are localized at the PM at the tip of growing PTs and that they act redundantly to regulate PT elongation and fertilization. Most interestingly, a recent study found that a CDPK-regulated negative anion gradient exists at the tip of growing RHs (Gutermuth et al. 2013). More specifically, CDPK activated anion efflux at the tip resulted in the occurrence of an anion decrease parallel with each Ca2+ peak. These anion oscillations are due to the interaction of CPK2 and CPK20 and their ability to phosphorylate SLAC1 HOMOLOGUE 3 (SLAH3) in growing PTs. Importantly, CPK2 is transcribed in trichoblast cell files in Arabidopsis roots (Brady et al. 2007). More evidence showing that CDPKs can couple different ion dynamics comes from Zhao et al. (2013a). The PM-localized proteins CPK11 and CPK24 negatively regulate PT growth through Ca2+-mediated control of the SHAKER POLLEN INWARD K+ CHANNEL (SPIK; Zhao et al. 2013a). Interestingly, CPK32 was shown to interact with CNGC18, a crucial Ca2+ channel in PTs (Zhou et al. 2014). Furthermore, several CDPKs were shown to regulate actin cytoskeleton organization, polarity and even self-incompatibility in Zea mays, Nicotiana alata and Petunia hybrid (Estruch et al. 1994; Kunz et al. 1996; Allwood et al. 2001; Yoon et al. 2006).
Clearly, most research about the role of CDPKs in tip growth has focused on PTs. However, in Medicago truncatula CDPK1 was shown to control RH growth and morphology (Ivashuta et al. 2005). MtCDPK1 loss of function leads to dissipation of the tip-focused ROS gradient and disorganization of the actin cytoskeleton. Interestingly, Dubiella et al. (2013) showed that in response to a Ca2+ peak, CPK5 phosphorylates the NADPH oxidase RBOHD, thereby leading to apoplastic ROS production and cell-to-cell Ca2+-ROS signal transduction (Dubiella et al. 2013). Publicly available transcriptomics data shows that CPK5 is also expressed in RH cell files. Could it be involved in trichoblast-to-trichoblast Ca2+ signal transduction? Similarly, CPK32 and its interaction partner CNGC18 in PTs were also found to be expressed in RHs. Could both proteins be working together in RHs to regulate Ca2+ dynamics at the tip? Finally, CPK11 but not CPK24 (which together regulate K+ channel activity in PTs) was found to be highly expressed in RH cells in Arabidopsis. Investigating RH growth and morphology in cpk11 knockout plants could be an interesting avenue in identifying novel players in Ca2+-regulated RH development.
Calmodulin (CaMs), calmodulin-like (CMLs), calcineurin B-like (CBLs) and CBL-interacting protein kinases (CIPKs)
are also likely to have a prominent role in tip growth regulation. However, little is known about these proteins and their involvement in RH and PT development. The Arabidopsis genome contains seven CaM-coding sequences, three of which code for the same protein (CaM2, CaM3 and CaM5). Besides a potential role for CaM2 in pollen development and fertilization efficiency (Landoni et al. 2010), none of the CaM proteins have been functionally characterized in relation to tip growth. Based on their preferential expression in RHs and PTs, CaM3 and potentially CaM7 could be involved in regulating the tip growth process.
The family of CMLs contains 50 members in Arabidopsis. However, most of them remain uncharacterized at the time of writing. Two CML proteins have been shown to be involved in pollen development. CML24/TOUCH2 loss of function leads to delayed pollen germination, slower PT growth and a shorter final PT length (Yang et al. 2014). Cml24/touch2 PTs exhibit a higher [Ca2+]cyt and a disorganized actin cytoskeleton. Interestingly, CML24/TOUCH2 transcription is induced by touch, suggesting it might function in the pathway of mechanosensitive Ca2+ channels. In the root, TCH2 is specifically expressed in atrichoblast cell files. CML25 knockout plants have a similar phenotype to that of cml24 plants (Wang et al. 2015a). In addition, cml25 plants were shown to regulate K+ influx into PTs. Importantly, CML25 is also specifically expressed in RH cell files, implying a general involvement in tip growth. Lin and colleagues showed that cml25 plants grow longer RHs under phosphate starvation (Lin et al. 2011b). However, no additional information is known on the role of this protein in RH development. Public transcriptomics data shows that at least eight CML proteins could be involved in RH development. The transcription of CML4, CML7, CML12, CML18, CML25, CML32, CML37 and CML48 is high and specifically directed towards RH cells (Brady et al. 2007). As such, the current knowledge of CMLs might heavily underestimate their role in RH tip growth.
Ten CBLs are found in the Arabidopsis genome. CBL1 is the only CBL protein with an established role in RH development. Preuss et al. (2006) found that CBL1 interacts in vivo with PI-4Kβ1 (phosphatidyl-inositol 4-OH kinase which generates the membrane-trafficking regulator phosphoinositide PI-4P), which in turn interacts with RabA4b. RabA4b is found on apically localized trans-Golgi-derived vesicles which are thought to transport new cell wall material to the tip. As such, the authors provided a link between CBL1-mediated Ca2+ signalling and cell wall delivery at the tip. Despite the fact that CBL3, CBL4, CBL6 and CBL9 show preferential transcription in RH cell files, none of these have been investigated for a role in RH tip growth. However, interesting results have highlighted an important role for CBL1, CBL2, CBL3 and CBL9 in PT development. Knowing that CBL3 and CBL9 might also be present in RH cells, it could be very interesting to see if these findings also apply for RH development. CBL2 and CBL3 regulate vacuolar dynamics in PTs through interaction with CIPK12 (Steinhorst et al. 2015). Overexpression of CBL2 and CBL3 results in lower pollen germination frequency and slower PT growth, whereas single- or double-knockout mutant exhibits impaired PT growth in vivo and in vitro. Upon interaction of the CBLs with CIPK12, the latter protein relocalized from the cytosol to the vacuole. Overexpression of CIPK12 results in a marked vacuolar phenotype, whereas loss of function results in complete loss of polar PT growth.
Similarly, CBL1 and CBL9 overexpression leads to impaired PT growth (Mähs et al. 2013). This phenotype was shown to be related to overexpression-induced hypersensitivity to high K+ levels. As such, in knockout PTs, low K+ availability resulted in a reduction of PT growth. Most interestingly, Drerup et al. (2013) subsequently showed that CBL1 and CBL9 interact with CIPK26 which in turn phosphorylates and activates the NADPH oxidase RBOHF, leading to induction of ROS production. Notably, CBL9 and RBOHF are also expressed in RHs, implying that a similar mechanism might act during RH growth.
Twenty-six CIPK genes have been identified in the genome of Arabidopsis. Again, little is known about the function of these genes in plant development. However, recent effort has identified CIPKs as important regulators of PT growth. As highlighted before, CIPK12 was shown to be involved in PT growth through interaction with CBL2 and CBL3 (Steinhorst et al. 2015). CIPK19 is likely involved in regulating the Ca2+ influx at the tip of growing PTs (Zhou et al. 2015a). Overexpression of CIPK19 led to higher apical [Ca2+]cyt, the formation of bulged PT tips, loss of PT polarity and decreased fertilization competitiveness. Treatment with La3+ (a calcium channel blocker) rescued the phenotype, showing that CIPK19 affect tip-focused Ca2+ concentration through regulation of the apical Ca2+ influx. In the Arabidopsis root, CIPK19 is specifically, albeit mildly transcribed in RH cell files, implying a common role in RH development. CIPK23, which is expressed in RH cells, was shown to be involved in HIGH-AFFINITY K+ TRANSPORTER 5/K+ TRANSPORTER 1 (HAK5/AKT1)-mediated K+-uptake through interaction with CBL1/CBL9 in roots (Ragel et al. 2015; Wang et al. 2016). A possible role for CIPK26 was also discussed previously. Despite these efforts to characterize the role of CIPKs in tip growth, no studies have focused on RH growth. However, at least 12 out of 25 CIPKs are strongly expressed in RH cell files (CIPK2, CIPK5, CIPK6, CIPK8, CIPK9, CIPK10, CIPK13, CIPK19, CIPK21, CIPK22, CIPK23, CIPK24), suggesting a major role in RH development.
4.2 Proton Oscillations Regulate Tip Growth
4.2.1 Proton Concentration
Intra- and extracellular pH regulation is of crucial importance for several developmental processes. Cytosolic and apoplastic pH homeostasis allows nutrient and sugar transport across the PM, organ development and cell elongation (Gjetting et al. 2012). More so, the existence of local pH gradients controls secondary transport in plant cells (Sze et al. 1999; Felle 2001), enzymatic reactions mostly rely on a pH optimum, differences in pH allow for compartmentalization (e.g. cytosol vs. vacuolar lumen) and pH differences across membranes lay the basis of hyperpolarization-driven signal transduction.
Local pH alterations depend on (1) the buffering capacity of the considered compartment, (2) active transport of protons (H+) across plant membranes and (3) local H+ production or consumption by metabolic processes. Scientific research has led to the understanding that well-coordinated interaction between these processes can lead to the formation of local H+ accumulation or depletion. As a result, intracellular pH gradients are formed, which have been shown to function as secondary messengers in plant development. Much like the characteristics of Ca2+ signatures, pH differences often occur in a highly spatially and temporally organized manner. Quantitative analyses of these pH signatures has been challenging for long. Consecutively, our understanding of pH dynamics is still limited compared to what has been observed for Ca2+. However, the recent development of several genetically encoded ratiometric pH sensors (Choi et al. 2012; Zhang et al. 2012; Gjetting et al. 2012) is promising and will most definitely further contribute to our understanding.
H+ translocation across membranes occurs in two directions, depending on specific transporters. As such, transient acidification or alkalinization has been observed both in the cytosol and the apoplast. With regard to cell growth, H+ translocation between the intra- and extracellular environment is key to the ‘acid growth’ theory which states that cells are able to expand faster following acidification of the cell wall (Rayle and Cleland 1992). This finding is now largely attributed to the acidic pH optimum of cell wall loosening expansins (McQueen-Mason et al. 1992; McQueen-Mason and Cosgrove 1995).
Crucially, the extracellular pH (pHext) has a pivotal role in tip growth, too. For instance, when placed in different pH buffers, the growth of PT can be inhibited (Feijó et al. 1999). Similarly, a sudden increase in the pHext led to cessation of RH growth, whereas a sudden decrease caused RH bursting (Monshausen et al. 2007). Consistent with the acid growth theory, upon RH initiation the cytosolic pH (pHcyt) locally increases, while the cell wall locally acidifies (Bibikova et al. 1998). Until the switch to tip growth is made, this configuration is maintained. Next, during fast tip growth, a tightly controlled mechanism regulates cytosolic and apical apoplastic H+ dynamics (Fig. 9.6). The resulting spatial and temporal pH changes are pivotal for controlling oscillating tip growth.
4.2.2 A Tip-Focused Oscillating H+ Gradient Controls PT and RH Growth
The diffusion coefficient is much higher for H+ compared to that of Ca2+. Moreover, experimental evidence has shown that a change in H+ concentration of 25–90 mM is required for a one unit pHcyt increase (Plieth et al. 1997; Plieth and Hansen 1998; Oja et al. 1999). Despite H+ diffusion and the high passive buffering capacity of the cytosol (Felle 2001), a pHcyt gradient exists at the tip of growing PTs and RHs (Fig. 9.6). In RHs, the tip-localized pH is slightly alkaline (pH 7.4–7.6) compared to the rest of the cytoplasm (Monshausen et al. 2007; Bai et al. 2014a). In PTs on the other hand, the pH at the tip is slightly acidic, followed by the presence of a subapical alkaline band (Feijó et al. 1999; Michard et al. 2008, 2009). As such, the maintained presence of alkaline micro domains suggests that in both RHs and PTs a mechanism must be in place that actively removes H+ from the apical region. Indeed, both in RHs and PTs, scientific evidence points towards polarized H+ efflux in the subapical regions (Fig. 9.6). More specifically, Feijó et al. (1999) reported on a H+ efflux (~0.004–0.01 amol μm−2 s−1) at the base of the clear zone in PTs. Similarly, a H+ efflux (0–0.02 amol μm−2 s−1) was detected starting 20 μm from the tip in tobacco PTs (Certal et al. 2008). Further away from the tip, this pattern would revert to a continuous small influx with a peak close to the pollen grain. At the surface of the pollen grain itself, a strong H+ efflux was again present. Certal et al. (2008) showed that, considering the entire process ranging from early pollen germination (~10 μm) to prolonged PT growth (>500 μm), flux dynamics are much more complex than previously thought. Originally, a strong H+ efflux is present at the pollen grain’s surface. During PT growth, efflux of H+ is observed along the subapical region of the PT. Subsequently, callose plugs are formed in spatially defined regions where no net flux is detected. Upon formation of the primary callose plug, the efflux ranging from the plug to the grain gradually converts to an influx which finally causes this part of the PT to die.
Compared to PTs, current knowledge in RHs suggests that the spatial distribution of H+ fluxes in RHs is far less complex. In contrast with PTs, no subapical alkaline band was observed in growing RHs. However, H+ efflux was found to be the highest at the base of the growing RH (~0.03–0.04 amol μm−2 s−1; Jones et al. 1995).
Like for the tip-localized Ca2+ gradient, the apical pH gradient found in RHs and PTs also occurs in an oscillatory manner (Lovy-Wheeler et al. 2006; Monshausen et al. 2007; Michard et al. 2008). During RH tip growth, the pHcyt oscillates between ~7.4 and ~7.6. These oscillations have the same frequency as the growth rate oscillations (2–4 min−1), but each growth pulse is preceded by an acidification with a lead of 7 s. Similarly, the apical pHcyt in tobacco PTs was found to oscillate with a magnitude of at least 0.3 pH units and a period of 1–4 min (Michard et al. 2008). In Lilium PTs a cytosolic alkalinization preceded a growth pulse by approx. 11 s, and a subsequent acidification followed growth by approx. 8 s (Lovy-Wheeler et al. 2006). These transient acidifications are the result of H+ influx at the extreme apex of growing PTs and RHs. As such H+ are (at least partly) cycled through the growing tip. Hence, they are imported at the tip and subsequently exported back to the apoplast either at the base of the clear zone (PTs) or at the base of the shank (RHs).
4.2.3 Oscillating H+ Influx from the Cell Wall
Each cytosolic acidification event is the result of active H+ transport across the PM at the tip. As such, transmembrane H+ fluxes also oscillate. Vibrating microelectrode analysis indeed revealed a H+ influx at the very tip of growing RHs and PTs. However, the measured fluxes strongly differ between studies. Monshausen et al. (2007) reported inward H+ fluxes up to 0.9 amol μm−2 s−1 at the tip of growing RHs. Jones et al. (1995) reported on a H+ influx at the tips of growing Limnobium stoloniferum RHs in the range of 0.01 amol μm−2 s−1. Feijó et al. (1999) reported on an oscillating H+ influx in the range of 0–0.04 amol μm−2 s−1, whereas Michard et al. (2008) and Messerli et al. (1999) report on a pulsatile influx of 0.1–0.4 and 4.89 ± 0.81 amol μm−2 s−1, respectively, in growing PT tips.
The buffering capacity of the apoplast is generally considered to be much lower than that of the cytosol (in the range of 4 mM H+ per pH unit; Oja et al. 1999). Logically, periodic efflux of H+ from the cell wall to the cytosol thus causes pHext oscillations. Monshausen et al. (2007) found that each cytosolic acidification/H+ influx peak was indeed accompanied by an extracellular alkalinization. The pHext was found to oscillate between 5.8 and 5.4 (double the amplitude of pHcyt oscillations). An extracellular alkalinization coincided with cytosolic acidification and followed each growth pulse by 7 s. The nature of transient extracellular alkalinization/acidification events is considered crucial for regulating cell wall dynamics (see section “Cell Wall Pectin Dynamics”).
4.2.4 H+ Transporter Proteins Regulate H+ Fluxes During Tip Growth
Apical and subapical H+ fluxes are generated by specific H+ pumps and non-specific H+ symporter or antiporter proteins (Fig. 9.6). Several types of H+ pumps have been reported, either specifically dedicated to H+ transport (PM-, tonoplast- or endomembrane-localized H+-ATPases) or relying on H+ symport for active translocation of nutrients across the PM. The former ATPases actively generate H+ electrochemical gradients (Palmgren 2001), which are then exploited for active nutrient transport by H+/nutrient symport or antiporter proteins. Holdaway-Clarke and Hepler (2003) hypothesized that H+ influx at the tip of growing PTs is regulated by non-specific cation channels, whereas H+ efflux relates to the specific activity of H+-ATPases. At the time of writing, little is known about the exact nature of H+ transporting proteins that act in RH tip growth. However, a quick survey of public transcriptomics data shows that many putative RH-specific proteins might be involved in generating H+ fluxes across membranes.
4.2.4.1 H+ Influx Proteins at the Tip
Whereas H+-specific microelectrode experiments revealed inward H+ fluxes across the apical PM, the exact nature of the H+ transporting proteins is still largely unknown. H+ influx is generally facilitated by non-specific H+ symporter or antiporter proteins, which use the transmembrane electrochemical gradient to co-transport nutrients alongside with H+. Several putative H+ symport and antiport proteins were shown to be transcribed in pollen, but functional characterization is generally lacking (Bock et al. 2006). A PM-localized pollen-specific H+/broad-spectrum monosaccharide symporter SUGAR TRANSPORTER 6 (STP6) was identified in Arabidopsis (Scholz-Starke et al. 2003). However, STP6 loss-of-function pollen exhibited no obvious phenotype. Notably, pollen-specific monosaccharide and sucrose transport proteins were also identified in Petunia and tobacco, suggesting that a conserved saccharide-based H+-symport system exists in pollen (Ylstra et al. 1998; Lemoine et al. 1999). More so, in vitro RH and PT tip growth rely on the presence of sucrose. The Arabidopsis genome contains 9 sucrose and 14 monosaccharide transport proteins (Scholz-Starke et al. 2003).
At the tip of growing PTs, a tip-focused K+ influx (6.88 ± 1.44 amol μm−2 s−1) coexists alongside the H+ influx (Messerli et al. 1999). H+ and K+ fluxes oscillate in phase relative to each other, but H+/K+ peaks lag growth pulses by ±11 s. Might this suggest the existence of a H+/K+ symport system? Interestingly, both in RHs and PTs, several K+ influx transporter proteins have been identified and characterized, but none of them exhibit H+ symport activity (Rigas et al. 2001; Ivashikina et al. 2001; Reintanz et al. 2002; Mouline et al. 2002; Desbrosses et al. 2003; Ahn et al. 2004; Lu et al. 2011). Most likely, the coupling of H+ and K+ fluxes is due to the strong pH sensitivity of K+ uptake channels, rather than the existence of a H+/K+ symport system (Mouline et al. 2002; Griessner and Obermeyer 2003; Lu et al. 2011). However, the latter option cannot be ruled out.
The current knowledge on H+ symport proteins in RHs is also quite limited. Patch-clamp analysis revealed the existence of an H+/NO3 − symport system in the PM of Maize roots (Ruiz-Cristin and Briskin 1991). Similar NO3 − transport was observed at the PM of Arabidopsis RHs (Meharg and Blatt 1995). The latter NO3 − transport occurred in a pH-dependent manner and involved the co-transport of two protons per single NO3 − molecule, providing strong evidence for a dedicated H+/NO3 − RH-located symport system. Ion-sensitive microelectrode measurements also revealed a H+/Cl− symporter current in RHs of Sinapis alba (Felle 1994). This current has not been assigned to a specific locus; however, the evidence strongly suggests symport-based coupling of H+ and Cl− transport. Upon lowering the pHext, the [Cl−]cyt increases and the cytoplasm acidifies. Complementary, the same response was observed when increasing the [Cl−]ext. More so, the Cl− fluxes were also shown in PTs to oscillate in phase with growth pulses (Zonia et al. 2001).
Hamam and colleagues described a Na+/H+ exchange protein at the PM (Hamam et al. 2016), and it is expressed specifically in RH cell files. Interestingly, a Li+/H+ exchange protein was characterized at the PM, which is also expressed in RHs (An et al. 2007; Brady et al. 2007).
Finally, a H+/H2PO4 − symporter protein named LePT1 was identified in tomato (Daram et al. 1998). The gene is strongly expressed in RHs and upregulated under phosphate deficiency.
To our knowledge, no other H+ influx proteins have been characterized at the PM of growing PTs and RHs until now. Thus, a major knowledge gap exists regarding the mechanisms controlling H+ influx in tip-growing cells.
4.2.4.2 Subapical H+ Efflux Proteins
H+-ATPases constitute the main family of H+ export proteins. They perform active H+ transport across the PM through the hydrolysis of ATP. H+-ATPases are thought to lie at the basis of plant nutrient uptake. Hence, the H+-ATPase-mediated generation of a PM-localized electrochemical gradient is known to activate nutrient-specific secondary active transporters and membrane channels (Gilroy and Jones 2000; Ashcroft et al. 2009). The Arabidopsis genome codes for 12 H+-ATPase genes (AHA1-12). Seven P-type H+ pumps were found to be expressed during pollen germination and PT growth (Song et al. 2009), and several H+-ATPases were found to be expressed in RHs (Moriau et al. 1999; Palmgren 2001; Santi and Schmidt 2009; Młodzińska et al. 2015). Indeed, public transcriptomics data confirms that the transcription of several AHA genes is restricted to RHs, PTs or both (Table 9.3).
A role for H+-ATPases in controlling tip growth was first confirmed through a series of pharmacological experiments. PTs grew faster in the presence of fusicoccin (a H+-ATPase agonist) but seized to grow when supplemented with the H+-ATPase antagonists vanadate or N-ethylmaleimide (Rodriguez-Rosales et al. 1989; Feijó et al. 1992; Fricker et al. 1997; Pertl et al. 2001; Sun et al. 2009; Lang et al. 2014). More so, treatment of tobacco PTs with orthovanadate inhibited the subapical H+ efflux by 80%, strongly suggesting that H+-ATPases maintain the latter (Certal et al. 2008). Few studies have focused on the functional annotation of H+-ATPases in tip growth. Loss of function of AHA7 was shown to cause a decrease in the number of RHs (Santi and Schmidt 2009). A tobacco pollen-specific AHA with homology to Arabidopsis AHA9, AHA8 and AHA6 was found at the subapical PM of PTs (Certal et al. 2008). The fact that it was excluded from the PT tip is consistent with the subapical H+ effluxes observed in tip-growing cells. Overexpression of NtAHA led to the formation of abnormal callose plugs, aberrant H+ fluxes and overall shorter PTs. Protein-reporter constructs showed that AHA2 is expressed in RHs (Fuglsang et al. 2007; Młodzińska et al. 2015). Santi and Schmidt (2009) found that AHA2 could be involved in controlling iron mobilization through rhizosphere acidification in response to iron deficiency. Most interestingly, both AHA2 and AHA1 were found to interact with CNGC17 (Ladwig et al. 2015). CNGC channels are putative Ca2+ channels with the potential of regulating Ca2+ dynamics in tip-growing cells (see Sect. 9.4.1.3). CNGC17 is also specifically expressed in RH cells. As such this raises the question: ‘might there be a direct link between the H+ efflux machinery and the regulation of Ca2+ import?’.
A recent study by Veshaguri and colleagues added another layer of complexity to the regulation and dynamics of H+-ATPase-mediated H+ fluxes (Veshaguri et al. 2016). Based on single-molecule characterization, they showed that AHA2 switches between three discrete functional states: pumping, inactive and leaky. The intrinsic properties of pH gradients directly determine in which state the pump resides. As such, it is easy to image that also in RHs and PTs, the tip-focused pH signatures regulate the functioning of subapical H+-ATPases. In addition, all P-type H+-ATPases contain an autoregulatory domain, which is subject to phosphorylation, thus adding another layer of control.
4.2.4.3 The Vacuole as H+ Source/Sink
The role of the vacuole is often neglected when it comes to allocation of H+. However, (1) several H+ pumps are thought to localize preferentially to the tonoplast, (2) the vacuolar pH is strongly acidic in comparison to the pHcyt and (3) the vacuole extents until right beneath the clear zone. Several families of putative vacuolar H+-ATPases exist in the Arabidopsis genome, and despite the fact that none of these pumps have been investigated towards their possible involvement in tip growth, transcriptome data leaves no doubt that they might have a pivotal role in controlling RH development. At least 20 vacuolar H+-ATPase subunits are specifically transcribed in RH cell files (Table 9.4; Brady et al. 2007).
More so, the Na+/H+ EXCHANGER 1-4 (NHX1-4) H+ efflux proteins also localize to the tonoplast (Reguera et al. 2015). Transcriptome analysis shows that NHX1 is strongly and preferentially expressed in RH cells. Albeit low, NHX4 is preferentially transcribed in trichoblasts.
4.2.5 Signalling Downstream of pH Oscillations
4.2.5.1 Actin Remodelling
The actin cytoskeleton is a highly spatially organized and dynamic component in tip-growing cells. Experimental evidence derived from studying PTs strongly supports pH-dependent regulation of actin turnover during tip growth. This is based on the facts that (1) an actin fringe of cortical microfilaments co-localizes with the alkaline band in growing PTs, (2) cytosolic acidification disturbs or abolishes this actin fringe and (3) pH-regulated actin depolymerization factor (ADF) proteins co-localize with the actin fringe (Lovy-Wheeler et al. 2006). Lovy-Wheeler and colleagues carefully studied the pH-dependent dynamics of the actin cytoskeleton in growing Lilium PTs. They found that artificially lowering the tip-focused pH caused the actin fringe to move closer to the growing tip and resulted in 80% growth reduction (10 mM sodium acetate) or caused the fringe to dissipate completely and growth to stop entirely (100 mM sodium acetate). In addition, treatment of PTs with latrunculin B (LatB; destabilizes actin filaments) causes the dissipation of the acidic domain at the tip and the allocation of the alkaline band towards the apex (Cárdenas et al. 2008). These findings support a role for a feedback loop between tip pHcyt and apical actin dynamics (Fig. 9.6). Furthermore, they showed that ADF co-localizes strongly with the actin fringe and allocates similarly in response to acidification. ADF proteins are thought to promote actin-polymerization in an alkaline environment (Gungabissoon et al. 1998; Allwood et al. 2002; Chen et al. 2002). Contrary to PTs, and consistent with the RH base-positioned H+ efflux, a subapical alkaline band has not been observed in growing RHs. However, whereas in PTs the apical pH gradient is slightly acidic (located above the alkaline band), in RHs the apical pH gradient is slightly alkaline (Monshausen et al. 2007; Bai et al. 2014a). As such, we suggest that ADF activity could also regulate actin dynamics in RHs. More so, both ADF8 and ADF11 were shown to be transcribed specifically in RH cell files (Brady et al. 2007; Kandasamy et al. 2007; Ruzicka et al. 2007) and were previously found to be part of the transcriptional core RH machinery (Bruex et al. 2012).
Lovy-Wheeler et al. (2006) suggested a self-sustained cycle controlling pH-mediated actin-remodelling at the tip. An alkaline pH would promote ADF-activity, which in turn favours increased actin depolymerization. The latter would result in faster growth and an increase of the H+ influx at the tip, leading to cytoplasmic acidification. Subsequent inactivation of ADF would then lead to a decrease of actin polymerization, growth and H+ influx, allowing for the pH to gradually rise again. Logically, such an autoregulatory loop would result in actin polymerization/depolymerization oscillations at the tip (see Sect. 9.5.1.2).
4.2.5.2 Cell Wall Pectin Dynamics
The cell wall of tip-growing cells is a highly dynamic compartment, strongly relying on pH oscillations to fine-tune the spatial and temporal balance of cell wall rigidification/loosening (Fig. 9.6). This process is now thought to largely rely on the presence of several cell wall-modifying proteins whose action is pH dependent. In general, RH and PT elongation seem to be consistent with the theory of acid growth, where a more acidic environment promotes cell wall loosening (Rayle and Cleland 1992). More H+ would generally increase the activity of expansins while inhibiting the action of pectin methylesterases (Cosgrove 2000; Michelli 2001; see Sects. 9.6.2 and 9.6.3).
5 The Cytoskeleton
5.1 Actin Dynamics Control Apical Cell Growth in RHs
5.1.1 Introduction
RH and PT tip growth rely on highly polarized delivery of secretory vesicles to the growing apex and strict subcellular localization of specific organelles. In RHs, directional vesicle and organelle transport is facilitated by the presence of a dynamic actin cytoskeleton (Fig. 9.7) similar to that observed in growing PTs (see Chap. 3).
When RH growth seizes, thick actin bundles protrude the entire cytoplasm, including the apex (Ketelaar et al. 2003; He et al. 2006). It has been shown that treatment with the actin polymerization inhibitor CytD terminates RH growth (Miller et al. 1999). Moreover, like in PTs, depolymerization of F-actin with LatB inhibits RH growth (Gibbon et al. 1999; Baluška et al. 2000). In Arabidopsis, there are at least eight isovariants of actin. Ectopic expression of individual isoforms resulted in disruption of the actin cytoskeleton and severe developmental defects (An et al. 1996a, b; Huang et al. 1997; Kandasamy et al. 2002, 2007). As such, different actin isoforms seem to relate to different functions. The latter might also imply that they are each associated with different means of regulation. However, at the time of writing, evidence for such isoform-specific control in both RHs and PTs is rather limited. Kandasamy and colleagues did reveal that ectopic expression of ACT1 resulted in strong developmental defects, likely associated with incorrect interaction with endogenous vegetative actin-binding proteins, since coexpression with the native ACT1-specific ABPs partially rescued the phenotypes.
ACT2, ACT7 and ACT8 are expressed in vegetative tissues including RHs. ACT2 and ACT8 are essential for proper tip growth since act2-1 (aka enl2 or der1) and act8-2 mutants exhibit stunted RHs, while the act2-1/act8-2 double mutant is even hairless (Gilliland et al. 2002; Ringli et al. 2002; Nishimura et al. 2003; Kandasamy et al. 2009). Even partial loss of ACT2 functionality results in drastic RH swelling and premature growth arrest (Diet et al. 2004). ACT7 transcription is auxin inducible and found throughout the root epidermis rather than being restricted to trichoblast cell files (McDowell et al. 1996a; An et al. 1996b; Kandasamy et al. 2001). Its role, however, seems to be restricted to early RH establishment, given that the RH density is decreased in act7 knockout plants. Together with ACT2, ACT7 regulates planar polarity establishment in early RH development (reviewed in Balcerowicz et al. 2015; Kiefer et al. 2015).
In PTs, several more actin isoforms are expressed besides ACT2 and ACT8 (Wang et al. 2008). The remaining isoforms are referred to as the class of reproductive actins (ACT1, ACT3, ACT4, ACT11 and ACT12; McDowell et al. 1996b; McKinney and Meagher 1998), and surprisingly, not much is known about their individual functions. ACT11 was shown to regulate actin turnover and subsequent vesicle turnover rates in Arabidopsis PTs (Chang and Huang 2015).
A continuous effort towards the characterization of the actin cytoskeleton and its key regulators has led us to acknowledge its role in PT (see Chap. 3) and RH development. Future research will greatly benefit from novel in vivo labelling and imaging techniques and the availability of a vast number of T-DNA insertional mutants. Here we describe the current state of knowledge regarding the molecular players controlling actin dynamics in growing RHs.
5.1.2 Do Actin Polymerization/Depolymerization Oscillations Exist in RHs?
The regulation of polymerization/depolymerization of AFs has been shown to depend on Ca2+, pH, phosphoinositide and ROP-GTPase dynamics, most of which oscillate during tip growth (see Sects. 9.2 and 9.4). As such, it is easily conceivable that actin turnover at the tip could also exhibit an oscillatory pattern. In RHs, initial data revealed clear fluctuations in labelling intensity of tip-localized F-actin + ends (Vazquez et al. 2014). Quantitative analysis of these fluctuations on a broader timescale might reveal the temporal and spatial dynamics of actin oscillations in growing RH. For now, however, the hypothesis that oscillatory actin turnover might exist during RH development is solely based on what has been observed in PTs. Treatment of growing PTs with low [LatB] (2 nM) resulted in reversible inhibition of growth rate and [Ca2+]cyt oscillations (Cárdenas et al. 2008). Importantly, however, PTs did not seize to grow but instead continued to elongate at a basal growth rate. This finding illustrates that actin polymerization is needed to sustain oscillatory but not linear growth, strongly suggesting that actin turnover itself exhibits oscillatory changes. Indeed, through the development of a G-actin-specific ratiometric dye, the authors were able to show that tip-focused G-actin oscillates with the same period as growth oscillations, but with a phase lag of ±10 s. As such, a low level of G-actin/an increase in F-actin polymerization anticipated an increase in growth rate. Ca2+ oscillations lag growth oscillations by approx. 5 s (Messerli et al. 2000) and thus anticipate G-actin oscillations. It is therefore tempting to propose that Ca2+ dynamics could regulate oscillatory actin turnover through direct control of ABPs (Pei et al. 2012). Moreover, the ABPs VILLINS and ADFs have been shown to regulate RH growth in a Ca2+-dependent manner. For instance, ZmADF3’s actin-severing activity is regulated by a Ca2+-dependent protein kinase (Smertenko et al. 1998; Allwood et al. 2001). VILLIN4 promotes capping and severing of AFs at high (5 μM) but not at low (0.5 μM) [Ca2+] (Zhang et al. 2011a). Considering that these concentrations lie within the physiological range associated with the tip-focused Ca2+ gradient, it is easy to imagine that VILLIN activity oscillates together with Ca2+ oscillations.
In addition to Ca2+-dependent regulation of actin oscillations, pH oscillations might also play an important role. Based on pharmacological and localization studies, there seems to be a feedback loop controlling actin and pH dynamics at the apex of tip-growing cells (Lovy-Wheeler et al. 2006). Moreover, research has shown that certain ADF proteins are preferentially functional in an alkaline environment, consistent with the base of the clear zone.
5.1.3 Actin-Binding Proteins Regulate RH Tip Growth
Emerging evidence shows that the control of actin dynamics by several ABPs is tightly embedded with the core tip growth machinery. This is illustrated by the existence of actin-regulating factors with a specific sensitivity towards Ca2+, pH and phospholipid signalling (Fig. 9.8). Here, we provide an overview of the ABPs shown to be involved in regulating RH tip growth.
5.1.3.1 Control of Actin Nucleation
Formins
are proteins that directly bind to the elongating barbed end of AFs, where they enhance filament elongation while protecting the growing end from capping proteins (Kovar and Pollard 2004; Romero et al. 2004). Their function largely depends on their ability to interact with a variety of proteins, thereby forming large multiprotein complexes generally including profilins (discussed later). Notably, several formin isoforms contain ROP-GTPase-binding domains (Watanabe et al. 1997; Petersen et al. 1998) and were shown to associate with MTs (Deeks et al. 2010; Li et al. 2010; Wang et al. 2013). Formins have a pivotal role in mammals, fungi and plants and were shown to be important for RH and PT development (Deeks et al. 2005; Yi et al. 2005; Ye et al. 2009; Cheung et al. 2010; Huang et al. 2013b). Twenty-one formin-related sequences were identified in the Arabidopsis genome alone (Deeks et al. 2002; Cvrckova et al. 2004). Several formins seem to be preferentially transcribed in RH cells (relatively high transcription, AtFH5, AtFH8 and AtFH1; moderate transcription, AtFH10, AtFH13, AtFH16, AtFH19, AtFH20), and overexpression of AtFH8 lacking its FH2 (actin-binding) domain led to aberrant RH development, with RHs being shorter, seizing growth at the bulge stage or being completely absent from the epidermis (Deeks et al. 2005). The latter suggest that AtFH8 could be involved in both bulge formation (reviewed in Balcerowicz et al. 2015) and tip growth. The authors suggest that in vivo the truncated protein would compete with the interacting proteins of the functional AtFH8, thereby preventing the latter from nucleating the actin cytoskeleton. An additional study revealed that constitutive AtFH8 overexpression resulted in short, waved, bulged and/or branched RHs with an over-accumulation of AFs (Yi et al. 2005). FH8 was shown to nucleate actin barbed ends in vitro and, curiously, to induce actin severing instead of polymerization. Yet it enhances polymerization in the presence of profilin. The latter has not been shown in any other formin isoform.
AtFH5 is also strongly and specifically expressed in RH cell files (Brady et al. 2007). Corresponding functional characterization in RHs is however still lacking. In PTs, AtFH3 and AtFH5 both regulate apical expansion, but they seem to do so in different ways (Ye et al. 2009; Cheung et al. 2010). Interestingly, present data clearly supports a role for FH5 in subapical vesicle targeting.
OsFH1 (FH1 Oryza sativa homologue) knockout plants display very short RHs when no structural support is present (liquid media instead of solid; Huang et al. 2013a, b). When grown on a solid surface, RHs appeared normal. Besides OsFH1 and AtFH8, no other formins have been attributed to regulating RH growth.
Just like formins, the ACTIN-RELATED PROTEIN 2/3 (ARP2/3) complex mediates barbed end actin assembly and thus promotes actin nucleation (Hussey et al. 2006). The seven-protein complex binds to existing AFs and stimulates the formation of new side branches. The complex consists of seven subunits (Arp2, Arp3, ArpC1/p41, ArpC2/p34, ArpC3/p20, ArpC4/p20, ArpC5/p16), which are all expressed in plants (Mathur et al. 2003a). The function of the ARP2/3 complex is considered to be highly conserved between different biological systems, given that Arabidopsis subunits can complement their yeast homologues and mammalian homologues can complement mutations in plant subunits (Le et al. 2003; Mathur et al. 2003b). The currently described plant-specific mutations associated with loss of function of Arp2/3 subunits all resulted in morphogenesis-related phenotypes (Mathur et al. 1999, 2003a; Li et al. 2003) or related to regulation of stomatal aperture (Li et al. 2013, 2014) or salt stress-induced Ca2+ signalling (Zhao et al. 2013b). The evidence regarding involvement in RH and PT tip growth is very scarce. It was shown that AtARP2 is strongly transcribed in pollen grains (Klahre and Chua 1999), and Mathur et al. (2003b) revealed that RHs of the crooked mutants, harbouring a loss-of-function mutation in the ARPC5 subunit, were either short and stunted or curvy and up to double as wide as wild-type RHs. In addition, the occasional presence of two bulges on a single trichoblast cell suggests that the ARP2/3 complex might regulate both RH initiation and elongation. The actin cytoskeleton in crooked RHs consisted of alternating regions with thick actin patches (associated with growth restriction) and fine F-actin bundles (associated with growth). The wurm (ARP2 knockout) and distorted1 (ARP3 knockout) mutations exhibit a similar short and wavy RH phenotype, as a result of F-actin aggregation (Mathur et al. 2003a). Given the fact that loss of function of each of three ARP2/ARP3 single subunits causes the same phenotype, it is conceivable that the observed defect is due to loss of function of the entire complex. As such, it can be hypothesized that the ARP2/3 complex regulates the formation of fine filamentous actin cables in RHs, thereby controlling RH polarity and final RH length.
Profilins
are G-actin-binding nucleotide exchange factors that catalyse the exchange of ADP to ATP, thereby returning actin monomers to the profiling-actin-ATP pool (Valenta et al. 1993; Gibbon et al. 1998; Pollard and Borisy 2003). They can constitute a large part of the total protein pool (up to 127 μM), largely equimolar with the concentration of G-actin, as observed in Maize pollen (Gibbon et al. 1999). In the presence of profilins, plant formins can enhance filament elongation rates by a factor of 10–42 (Zhang et al. 2016). However, profilins can either inhibit spontaneous nucleation of AFs in the absence of formins (at the minus-ends) or promote AF elongation through interaction formation of profilin-G-actin-formin complexes at plus-ends (Kovar et al. 2003; Michelot et al. 2005; Vidali et al. 2009; Zhang et al. 2011b; van Gisbergen and Bezanilla 2013; Ketelaar 2013). Minus-end inhibition of polymerization might be actin isoform specific (Kijima et al. 2016). Five profilin isoforms are transcribed in Arabidopsis (Huang et al. 1996) yet only one is trichoblast specific (PRF1; Brady et al. 2007), whereas at least three profilins are expressed in in vivo grown PTs (PRF1, PRF4 and PRF5). In RHs, profilin specifically localized to the apex of emerging RH bulges and growing RHs (Braun et al. 1999). This pattern is altered when RH growth stops or upon treatment with the microfilament disruptor CytD and the phosphatidylinositol 4,5-biphosphate [PI(4,5)P2] signalling disruptor mastoparan, strongly suggesting that profilin is involved in controlling tip growth in a PI(4,5)P2-dependent manner. Prf1 knockout plants exhibit a variety of RH phenotypes related to increased cell elongation (McKinney et al. 2001). The authors suggest that the absence of PRF1 protein could result in more free G-actin, which could enhance filament polymerization. However, the actual mechanism by which PRF1 controls RH elongation has not been characterized. Surprisingly, Vidali and Hepler (1997) found that in PTs profilin localization differs from that observed in RHs. In PTs, profilins were found to localize to the peripheral cytoplasm of the cell and accumulate mostly in the central region of the shank.
5.1.3.2 Control of Actin Depolymerization
Actin-depolymerizing factors
show affinity for both filamentous actin and actin monomers. They enable severing of ADP-actin filaments and promote ADP-actin filament dissociation at the minus-end (Maciver and Hussey 2002; Pollard and Borisy 2003). The latter means that ADF proteins enhance actin turnover by replenishing the monomer pool, and hence, released minus-end monomers can be recycled for plus-end growth. In addition, ADFs might also promote AF bundling and nucleation (Dong et al. 2001a; Andrianantoandro and Pollard 2006; Tholl et al. 2011). Their action is regulated by cytosolic Ca2+ (through phosphorylation by CDPKs), pH dynamics and phosphoinositide signalling (Gungabissoon et al. 1998; Smertenko et al. 1998; Allwood et al. 2001, 2002; Tholl et al. 2011; Dong and Hong 2013). As such, it is easy to imagine that ADFs perceive related cytosolic signatures and relay them towards fine-tuning of actin dynamics. The Arabidopsis genome encodes at least 11 ADF proteins (Ruzicka et al. 2007). ADF8 and ADF11 are specifically transcribed in trichoblast cell files (Brady et al. 2007; Ruzicka et al. 2007; Bruex et al. 2012). However, both genes have not been functionally described in relation to RH tip growth. Overexpression of AtADF1, which is expressed in the root epidermis but not specifically in trichoblasts, caused shorter and wider RHs with irregular actin distribution, whereas adf1 knockout RHs were longer and contained more actin cables (Dong et al. 2001b). These observations are consistent with the function of ADF proteins and indicate that ADF-mediated actin depolymerization is important for RH development. Not ADF8 and ADF11 but ADF7 and ADF10 are predominantly expressed in growing PTs, and both proteins are associated with the actin fringe and thick actin cables in the PT shank (Ruzicka et al. 2007; Wang et al. 2008; Qin et al. 2009; Bou Daher et al. 2011). ADF7 was shown to regulate AF severing and depolymerization rates in vivo (Zheng et al. 2013).
The actin-interacting protein1 (AIP1)
enhances ADF depolymerization activity and has a crucial role in directing RH tip growth (Allwood et al. 2002; Ketelaar et al. 2007, 2004). It caps barbed ends and disassembles ADF-bound filaments (Ono et al. 2004; Okada et al. 2006). Ethanol-induced RNA interference of AIP1 transcript resulted in drastically shorter RHs and a dramatic decrease of the RH growth rate (Ketelaar et al. 2004). Moreover, consistent with the presumable lack of ADF activity and subsequent absence of actin depolymerization, thick actin bundles reached all the way into the RH apex. Surprising though, the AIP1 loss-of-function phenotype (short RHs) differs considerably from that observed in ADF knockout plants (long RHs; Dong et al. 2001b). This difference might imply an additional role of AIP1 besides stimulation of ADF activity. Ethanol-induced AIP1 overexpression on the other hand also inhibited RH growth, resulting in short and swollen RHs and thick actin cables (Ketelaar et al. 2007). Interestingly, AIP1 and ADF seem to function in a feedback loop, where AIP1 functioning also depends on ADF presence (Augustine et al. 2011). A recent study showed that AIP1 interacts directly with ACT7 (Kiefer et al. 2015), and together they regulate RH initiation through ROP-mediated planar polarity establishment (reviewed in Balcerowicz et al. 2015), downstream of WEREWOLF (WER) in an ethylene-dependent manner.
5.1.3.3 Control of Actin Bundling
The Arabidopsis genome encodes 5 villin-type proteins (Huang et al. 2005; Khurana et al. 2010), shown to be involved in regulating actin bundling, but also severing, nucleation and plus-end capping (e.g. Yokota et al. 2005; Zhang et al. 2010). As such, villins are considered to be important in regulating actin turnover, and some do so in a Ca2+-dependent manner (Yokota et al. 2005; Zhang et al. 2011a), whereas others are Ca2+ insensitive (Khurana et al. 2010). The villin-specific Ca2+-dependency coincides with the presence of at least three Ca2+-binding sites (Huang et al. 2005), and their function regulates tip growth, both in RHs and PTs.
In RHs, double loss of function of VLN2 and VLN3 did not result in a RH phenotype (van der Honing et al. 2012). However, GFP-VLN3 was shown to decorate shank-localized F-actin bundles. Loss of function of the RH-specific Ca2+-sensitive VLN4 that regulates severing and capping, resulted in slowing of RH growth, shorter RHs and alterations of cytoplasmic streaming, due to reduction of actin bundles (Zhang et al. 2011a). Given their apparent redundancy, it would be very interesting to see how RH growth is affected in a triple vln2 vln3 vln5 knockout mutant.
In PTs VLN2 and VLN5 are thought to act redundantly in regulating actin turnover and construction of actin collars at the PT tip (Zhang et al. 2010; Qu et al. 2013). The two Lilium villin homologues P-115-ABP and P-135-ABP regulate Ca2+-dependent AF bundling (Yokota et al. 2005), and P-135-ABP can promote actin turnover. Together, these results identify villins as important regulators of PT and RH growth.
5.1.3.4 Control of Actin-Mediated Trafficking
Myosins are motor proteins that, by means of ATP hydrolysis, transport vesicles and organelles along AFs (e.g. Reisen and Hanson 2007; Sweeney and Houdusse 2010). Seventeen myosin-class genes are transcribed in Arabidopsis, of which 13 belong to the XI-myosin class with an established role in plant development (Hashimoto et al. 2005). Functional characterization of myosin proteins has been challenging due to a high degree of redundancy (Peremyslov et al. 2008, 2010). However, recent advances have provided increasing evidence for their involvement in RH tip growth. The first evidence came from Hashimoto and colleagues, showing that MYOSIN 2 (MYA2) was localized to RHs, appeared as punctate dots (Hashimoto et al. 2005), co-sedimented with F-actin and potentially transported peroxisomes. In addition, MYA2 was suggested to also transport vesicles (Reisen and Hanson 2007; Walter and Holweg 2008). The RH length of mya2 knockout plants was over 50% decreased compared to wild-type, in parallel with a two times reduction in Golgi, peroxisome and mitochondrial trafficking speeds in RHs (Peremyslov et al. 2008; Avisar et al. 2009). XI-K loss of function resulted in the same RH and trafficking defects (Ojangu et al. 2007; Peremyslov et al. 2008; Avisar et al. 2012). Xi-k RHs grew slower and seized to grow earlier (Park and Nebenführ 2013). Together with myosin-binding proteins 1 and 2 (MyoB1/MyoB2), XI-K co-localized with yet uncharacterized non-ER-derived endomembrane vesicles along F-actin cables (Peremyslov et al. 2012). Fluorescently tagged XI-K and MyoB1/2 protein exhibited a highly polarized localization in growing RH, which disappeared when growth seized (Peremyslov et al. 2012, 2013). Together, these findings support a role for myosins in regulating fast RH tip growth.
However, at least six myosins are transcribed specifically in RHs, implying that besides MYA2 and XI-K, XI-B/XI-C/XI-D and XI-H might also regulate RH development (Brady et al. 2007). Peremyslov et al. (2010) generated a number of triple and quadruple knockout mutants of XI-family myosins and illustrated that simultaneous loss of function could result in branched, thick or mislocalized RH morphology and a decrease in RH length of up to a factor 10. The fact that RH morphology strongly differed in different knockout combinations suggests that individual myosins serve distinct roles in RH development. Moreover, their results indicate that myosins might also be involved in planar polarity establishment during RH initiation (Peremyslov et al. 2010; reviewed in Balcerowicz et al. 2015).
Also in PTs, at least six XI myosins are expressed (Madison et al. 2015), and PTs of xi-c xi-e double-knockout plants grew much slower, resulting in a severely decreased fertilization efficiency. Peroxisome movement and AF organization were disturbed in mutant PTs. Interestingly, a similar myosin-dependent effect on F-actin organization was observed in RHs (Peremyslov et al. 2010; Park and Nebenführ 2013). As such, a feedback loop seems to exist in both RHs and PTs, with F-actin organization regulating myosin functioning, and vice versa. The mechanism that controls myosin to actin signalling has not yet been identified.
Finally, cytoplasmic Ca2+ might be involved in regulating myosin activity. Myosin XI motility and actin association strongly depend on the Ca2+ concentration (Tominaga et al. 2012). At concentrations higher than 1 μM Ca2+, the motility and ATPase activity of a myosin isolated from Lilium PTs were strongly decreased (Yokota et al. 1999). Crucially, calmodulin-dependent reversible regulation of myosin motility was observed in the range of 1–10 μM Ca2+, consistent with the [Ca2+]cyt fluctuations observed at the apex of tip-growing cells (Pierson et al. 1996; Wymer et al. 1997; Felle and Hepler 1997). As such, it is tempting to imagine that in tip-growing cells, myosin trafficking could be regulated by the Ca2+ signatures present in the apex.
5.2 The Microtubule Cytoskeleton
5.2.1 Organization of Microtubules in Root Hairs
In RHs, two distinct populations of MTs have been identified. Cortical MTs (CMTs) are present throughout all stages of RH development and, similar to what has been observed in PTs (see Chap. 3), are oriented longitudinally along the shank (Van Bruaene et al. 2004). Studies from several plant species suggest that CMTs, like F-actin, are absent from RH apices (Sieberer et al. 2002; Weerasinghe et al. 2003; Van Bruaene et al. 2004; Vassileva et al. 2005). Endoplasmic MTs (EMTs), which exhibit a more irregular arrangement in comparison to CMTs, form when tip growth begins and accumulate in the subapical region and around the nucleus. EMTs are extremely dynamic and display higher sensitivity to depolymerizing drugs than CMTs (Sieberer et al. 2002; Van Bruaene et al. 2004). As for PTs, the role of MTs in regulating RH development remains poorly understood. It is suggested that EMTs might be involved in positioning of AFs and transport of nucleation complexes from the nucleus; however, their exact role remains unclear (Van Bruaene et al. 2004). Pharmacological analysis revealed that EMTs are required for nuclear positioning within RHs of Medicago (Sieberer et al. 2002) but not of Arabidopsis (Ketelaar et al. 2002).
5.2.2 Disruption of Microtubules Affects Root Hair Morphology
Both pharmacological and genetic studies have shown that MTs play a role in RH development by maintaining the direction of tip growth. Treatment of Arabidopsis roots with the MT stabilizing drug taxol and the MT depolymerizing drug oryzalin results in wavy RH growth and occasionally causes formation of multiple tips (Bibikova et al. 1999; Ketelaar et al. 2002). In addition, manipulations of the Ca2+ gradient and application of a touch stimulus trigger formation of new growth points in taxol-treated RHs, whereas in the control RHs, this only leads to the transient reorientation of growth (Bibikova et al. 1999). Consistent with the effects of MT disturbing drugs, crooked and/or branched RH have also been reported for mutants in α-tubulin (Bao et al. 2001), MICROTUBULE ORGANIZATION 1 (MOR1; Whittington et al. 2001) and ARMADILLO REPEAT-CONTAINING KINESIN 1/MORPHOGENESIS OF ROOT HAIR 2 (ARK1/MRH2; Jones et al. 2006; Sakai et al. 2008). MOR1 encodes a MT-associated protein (MAP) with several HEAT repeats that might serve as MT-binding sites. The point mutation in the N-terminal HEAT motif of MOR1 leads to temperature-dependent disruption of CMTs indicating that MOR1 plays a role in stabilizing MTs (Whittington et al. 2001). In contrast, ARK1/MRH2 has recently been shown to promote MT disassembly through a yet unknown mechanism. Low concentrations of oryzalin were able to partially restore normal RH growth in ark1-1 mutants, whereas taxol caused even more severe RH defects. As such, the role of ARK1/MRH2 in RH tip growth seems to be maintaining the pool of free tubulin which is required for rapid MT polymerization (Eng and Wasteneys 2014). However, it is important to note that a previous study suggested that ARK1/MRH2 acts as a MT-stabilizing factor (Yang et al. 2007). Interestingly, in contrast to RHs, taxol and oryzalin do not have a significant effect on PT growth indicating possible differences in the role of the MT cytoskeleton in these two cell types (Gossot and Geitmann 2007; Poulter et al. 2008; Bou Daher and Geitmann 2011; Zhou et al. 2015b).
5.2.3 The Microtubule/Actin Interface
There is growing evidence that MTs contribute to tip growth through interaction with the actin cytoskeleton. It has been demonstrated that administration of the actin-disrupting agent cytochalasin B (CytB) causes an inhibition of reverse fountain streaming in Hydrocharis RHs and that the effect of the drug is fully reversible (Shimmen et al. 1995). However, simultaneous treatment with CytB and the MT-destabilizing herbicide propyzamide followed by removal of CytB does not lead to recovery of long actin cables and cytoplasmic streaming (Tominaga et al. 1997). It therefore appears that the presence of MTs is essential for re-establishment of AFs. On the other hand, in Medicago, longer treatment with the actin-depolymerizing drug LatB leads to formation of MT bundles in the (sub)apical region of RH cells (Timmers et al. 2007). Consistently, in tobacco PTs, long MTs organized as bundles replace the short and randomly oriented ones in the presence of a low dose of LatB (Idilli et al. 2012). Thus, the actin cytoskeleton has an influence on MT dynamics too. In Arabidopsis RHs, the cross-talk between MTs and AFs might involve the action of ARK1/MRH2 since an ARM domain-containing fragment of this kinesis has the ability to bind polymerized actin in vitro and mrh2–mrh3 mutant displays increased sensitivity to LatB (Yang et al. 2007). Moreover, a mutation in ARK1 enhances the phenotype of CA-ROP2 (Yang et al. 2007), and ROP2 regulates actin organization in RHs (Jones et al. 2002).
6 The Cell Wall as a Dynamic System
Much like in PTs, the protoplasm of RHs is surrounded by a dynamic cell wall that consists of cellulose, hemicellulose, pectin and several types of proteins (Somerville et al. 2004). In addition, the basic mechanisms controlling cell wall deposition in RHs are similar to those found in PTs, as well as the resulting biomechanical properties along the RH axis. More so, several cell wall-related genes are transcribed in both RH and PT cells (Becker et al. 2014). Nevertheless, despite these commonalities, the detailed molecular composition of the RH cell wall seems to differ considerably from that of PTs. Here we review the current knowledge on the RH cell wall.
6.1 Cellulose Deposition in Root Hair Cell Walls
The main load-bearing network of plant cell walls, cellulose microfibrils tethered by hemicelluloses such as xyloglucan, is partly responsible for the restraining feature in the RH’s shank (Cosgrove 2005). Electron microscope experiments revealed that most terrestrial plants have a random and short cellulose microfibril organization in the primary wall deposited at the RH tip (Newcomb 1965; Emons and van Maaren 1987; Akkerman et al. 2012; Rounds and Bezanilla 2013). In the shank of the RH, a second layer of more ordered cellulose microfibrils is deposited at the inside of the random wall, helicoidal or parallel to the RH axis (Akkerman et al. 2012). Addition of the cellulose synthase inhibitor, 2,6-dichlorobenzene (DCB) or cellulose-specific endo-(1→4)-β-glucanase (cellulase) to RHs resulted in rapid cessation of growth and even induced cell rupture at the tip, suggesting that deposition of cellulose or cellulose-like polysaccharides is a necessity for controlled tip growth of RHs (Park et al. 2011).
While most of the cell wall components like pectin, xyloglucan and other hemicelluloses are delivered by secretory vesicles, cellulose is synthesized at the PM by cellulose synthase (CESA) complexes (CSCs; Cosgrove 2005). From the 10 CESA genes present in Arabidopsis (Doblin et al. 2002), only CESA1, CESA3 and CESA6 are involved in primary cellulose synthesis (Arioli et al. 1998; Fagard et al. 2000; Scheible and Pauly 2004). Nevertheless, several lines of evidence suggest that other proteins than these three CESAs are involved in cellulose synthesis at the hair’s tip. When the temperature-sensitive mutant radial swollen 1 (rsw1), mutated in the CESA1 gene, was grown at restrictive temperature, RH morphology was altered, but the tip growth process was not completely abolished (Baskin et al. 1992; Arioli et al. 1998; Williamson et al. 2001), which suggests that at least CESA1 is not essential for tip growth in RHs. Fluorescent fusion proteins of the two other CESAs involved in cellulose synthesis in primary cell walls, CESA3 and CESA6, do not localize to the apical PM of growing RHs, nor to the vesicle-rich zone in the hair apex, which are the sites one expects when these proteins would play an essential role in cellulose deposition at the tip (Park et al. 2011). In addition, isoxaben, interfering with CESA3 and CESA6, was not able to alter RH elongation. All data so far suggest that CESA1, CESA3 and CESA6 are not required for RH tip growth, but it cannot be ruled out that other CESAs take part in cellulose deposition at the tip. Interestingly, mutants of two members of the cellulose-like super family, CSLD2 and CSLD3 (KOJAK), produce RHs with a range of abnormalities, with many RHs rupturing late in development (Bernal et al. 2008), or contain RHs that burst prematurely (Favery et al. 2001; Wang et al. 2001), respectively. Additionally, both YFP-tagged proteins are localized to the PM and in the vesicle-rich zone in the expanding tip. The CSLD family is the closest one of the CSLs to the CESA genes, with 35% identity at the amino acid level (Richmond and Somerville 2001), and even though the (1→4)-β-glucan synthase activity of CESA6 can functionally replace the catalytic activity of the CSLD3 domain, it is not clear at the moment whether the products of CSLD3, (1→4)-β-glucan polysaccharides, assemble into cellulose-like microfibrils (Galway et al. 2011; Park et al. 2011).
Most importantly, unlike in RHs where cellulose is the predominant cell wall component, PTs have a lower amount of cellulose but a very high amount of callose in their cell walls (see Chap. 3). In contrast to RHs, PT cellulose synthesis does seem to rely on CESA6 (Chebli et al. 2012). Yet here also the CSLD family plays a role since mutants of CSLD1 and CSLD4 show reduced pollen germination ability in vitro (Bernal et al. 2008), although it is not sure whether this is a pre- or post-germination effect.
6.2 Xyloglucan
Xyloglucan (XyG), the most abundant form of hemicellulose in dicots, interacts with cellulose microfibrils forming the load-bearing cellulose-xyloglucan network (Carpita and Gibeaut 1993). As it tethers adjacent cellulose microfibrils (Cosgrove 2005), it is expected that alterations in XyG might result in changes in mechanical properties of the cell walls and hence potential growth defects. Pena et al. (2012) reported that a unique acidic XyG is exclusively present in the Arabidopsis RH cell wall and that a loss-of-function mutation in ROOT HAIR SPECIFIC8/XYLOGLUCAN-SPECIFIC GALACTURONOSYLTRANSFERASE1 (RHS8/XUT1), catalysing the synthesis of this galacturonic acid-containing XyG, causes a short RH phenotype, indicating the importance of this form of XyG in polarized expansion. Furthermore, Cavalier et al. (2008) have shown that double mutants in xylosyltransferases (XXTs), xxt1/xxt2, that catalyse the addition of xylosyl to the glucan backbone of XyG lack detectable amounts of XyG and produce short RHs with swollen bases. The single mutant xxt5 and the triple mutant xxt1 xxt2 xxt5 have short and swollen RHs as well (Zabotina et al. 2008, 2012), but do not show rupturing tips. Selective degradation of XyG in growing RHs using xyloglucanase leads to the same conclusion that XyG absence results in reduced RH elongation, but not to rupture as was the case when cellulose was targeted (Park et al. 2011).
Besides altered synthesis, modifications of XyG can also affect cell wall mechanical properties. Xyloglucan endotransglucosylases/hydrolases (XTHs) are cell wall enzymes that cut XyG chains and reform bonds with water (hydrolase activity, XEH) and other xyloglucan acceptor substrates (endotransglycosylase activity, XET), potentially altering the distance between adjacent cellulose microfibrils and hence loosening cell walls (Nishitani and Vissenberg 2007; Van Sandt et al. 2007). High XET activity was indeed found in elongating epidermal cells and RHs at all stages of growth (Vissenberg et al. 2000, 2001, 2003), yet xth mutants with a detectable RH phenotype are still absent. Surprisingly, addition of recombinant XTH proteins leads to RH swelling, reduction and even cessation of RH growth (Maris et al. 2009), although one should take care since the XTH proteins are experimentally added from the outside of the wall, while under normal circumstances, they are secreted at the inside and younger part of the cell wall. Expansins are another class of proteins that interact with XyG and break their hydrogen bonds with cellulose at more acidic pH, thereby weakening the wall (Cosgrove 2005). A reduction of expansin A7 (EXPA7) expression resulted in shorter RHs (Lin et al. 2011a), confirming that expansin A7 likely performs active cell wall modification activities during the elongation of the hair tip.
In PTs, fucosylated XyG epitopes were uniform all along the cell wall of straight growing PT, with a slightly lower abundance at the tip compared with the distal region (Chebli et al. 2012). At the moment, no effects of XyG absence are described on PT and pollen development.
Taken together, XyG plays a role in the growth of RHs, but its absence does not lead to cell rupture, suggesting that cellulose is not only connected to XyG. Indeed, Dick-Pérez et al. (2011) demonstrated interactions between pectin and cellulose microfibrils, and both pectic polysaccharides and xylans seem to have an enhanced role in the walls from the xxt1 xxt2 double mutant that lacks detectable XyG (Park and Cosgrove 2012).
6.3 The Pectin Matrix
The above findings demonstrate that next to the cellulose/XyG load-bearing network, other cell wall components such as pectin, forming a highly hydrated matrix for the cellulose-xyloglucan framework, greatly contribute to RH growth. Enzymatic degradation of pectin using pectate lyase indeed inhibited RH elongation, but did not induce RH rupture (Park et al. 2011). In Arabidopsis, mutations in UDP-4-KETO-6-DEOXY-D-GLUCOSE-3,5-EPIMERASE-4-REDUCTASE 1 (UER1) and UDP-D-GLUCURONATE 4-EPIMERASE 6 (GAE6), both enzymes involved in the synthesis of pectic substrates, cause a short RH phenotype that can be rescued by applying exogenous precursors to the growth media (Pang et al. 2010). Furthermore, plants lacking LRR-extensin1 (LRX1) are defective in RH cell wall formation and produce short, collapsed and branched RHs. A suppressor screen has revealed that the lrx1 phenotype can be reversed by mutation in RHAMNOSE BIOSYNTHESIS1 (RHM1). Since rhamnose is a major component of pectin and the rhm1 mutation changes the expression of other cell wall-related genes, the suppression of the lrx1 phenotype is likely due to changes in cell wall composition (Diet et al. 2006). In addition, the pectin cell wall dynamics in tip-growing cells has been analysed using propidium iodide. In RHs and PT the fluorescence intensity of apical propidium iodide shows an oscillatory pattern in which each peak precedes growth rate oscillations. However, the distribution of fluorescence in both cell types is distinct, with RHs exhibiting predominant labelling along the shanks, whereas in PT this is clearly seen at the apex (Rounds et al. 2011). These results are consistent with previous findings that the tip region of growing PTs is mainly composed of pectins, especially homogalacturonan (HG). HGs are deposited in a highly methylesterified form at the apex through exocytosis and they become demethylated by pectin methylesterase (PME) activity (see Sect. 9.3.5). Spatial and temporal regulation of PME activity depends strongly on PMEIs, the Ca2+ concentration in the cell wall and local pH differences. Inactivation of a pollen-specific PME, PPME1, resulted in curved, irregularly shaped PTs that were dramatically stunted because of reduced elongation rates (Tian et al. 2006). Similar unstable and retarded PT growth with occasional tube bursting was seen in mutants of VANGUARD1 (VGD1), another pollen-expressed PME (Jiang et al. 2005). Surprisingly, at the moment, evidence for the involvement of PMEs in regulating RH growth is largely lacking.
6.4 Control by Second Messengers and Cell Wall Sensing/Modifying Proteins
The presence and correct assembly of extensins (EXTs), cell wall structural proteins, is crucial in the development of RHs. As mentioned before, LRX1 needs to interact with the RH cell wall, and this depends on the oxidative cross-linking of tyrosine (Tyr) residues in its EXT domain (Baumberger et al. 2001; Ringli 2010). Absence of this interaction results in impaired RH development. It is known that during plant defence reactions, EXT cross-linking can be mediated by peroxidases, and they have also been predicted to form the required cross-links with EXTs during RH formation (Almagro et al. 2009). Furthermore, cell wall self-assembly of EXTs requires correct O-glycosylation, and this is needed for normal RH elongation (Velasquez et al. 2011; Boron et al. 2014). Localization and interference with degrading enzymes indicate that EXTs are present in the PT wall and that they are required for normal PT elongation as well (García-Hernández and Cassab López 2005; Zhang et al. 2014).
The abundance and arrangements of apoplastic components determine the cell wall mechanical properties at the RH and PT tip, yet this can be changed by the activity of several other actors. Ca2+ can interact with demethylesterified pectin to stiffen the wall, and local changes in apoplastic pH can change the activity of cell wall remodelling enzymes and proteins (Cosgrove 2005; Maris et al. 2009, 2011). Furthermore, ROS seem to play dual roles, as hydroxyl radicals can cleave cell wall polymers, thereby loosening the wall, whereas hydrogen peroxide can cause the opposite by helping peroxidases to cross-link certain cell wall components. On top of that, the complexity rises as certain cell wall defects in RHs and PT might not be the direct cause of reduced or ceased elongation, since certain RLK family members can serve as cell wall integrity sensors (Guo et al. 2009; Wolf et al. 2012), conferring information from the cell wall to the inside of the cell, regulating, for example, ROS production through ROPs (Duan et al. 2010), which affects the elongation of tip-growing cells.
7 Conclusion and Perspective
The number of identified players in the molecular regulation of RH tip growth is increasing rapidly, but their specific interactions and the mechanisms that integrate internal and environmental signals to fine-tune RH growth remain far from clear. Comparing the more comprehensive knowledge on PTs with that of RH tip growth, we identified many possible targets for future RH research. However, many challenges remain to be addressed in order to better understand the vast complexity and integrated nature that lie at the basis of RH tip growth and tip growth in general. A problem of particular concern regarding the study of RH development lies within the fact that RH cells are an integral part of the total root system. Unlike for PTs, it is currently very challenging to acquire a pure or undiluted RH cell extract without employing harsh techniques such as protoplast isolation. Consecutively, high throughput -omics techniques which cannot be performed on single cells have been left unexploited, despite the fact that they could provide enormous insight and identify several new targets in studying RH tip growth. Similarly, the cell wall has proven to be a very complex, dynamic and difficult structure to probe. Most importantly, however, the outcome of intracellular-extracellular signalling pathways is the targeted secretion, synthesis and modification of new cell wall material. Despite its importance, very little is known about tip-related cell wall dynamics. Plants have been shown to contain a diverse set of putative cell wall sensing proteins (CrRLK1Ls), which likely perceive specific information on cell wall composition and subsequently relay the latter towards the cell wall-controlling tip growth machinery. How do these proteins sense cell wall composition, and is RH growth disturbance/cessation in cell wall mutants a direct consequence of aberrant cell wall structure or is it the result of CrRLK1L-mediated signal transduction?
In addition, we now know that cell wall dynamics largely depend on extracellular changes in ion and ROS concentrations. However, it is most likely that highly localized ion transport and ROS generation lead to the existence of micro domains in which cell wall modification strongly differs from the surrounding environment, much like the regulatory micro domains observed at the surface of membranes. The fluxes leading to these extra- as well as intracellular ion accumulation/depletion dynamics have been experimentally observed in several independent experiments. Based on their characteristics, they are thought to relate to a vast array of ion-transporting transmembrane proteins localized either to the tip or the shank of growing RHs. The identification of the loci corresponding to plasma membrane and endomembrane-localized transporters is however still largely lacking. More so, whereas different ion oscillations have been shown to influence one another, the way in which they are interconnected is poorly understood. For instance, it is unclear how Ca2+, ROS and pH dynamics interact to control RH elongation.
Furthermore, the signals encoded by oscillatory ion signatures are mostly unknown. Why do ion concentrations oscillate, and how do these oscillations translate into oscillatory growth rates? How is the oscillatory nature of ion transport regulated? Recent research efforts are gradually providing insight into these processes. However, the possible involvement of Ca2+ and pH-sensitive proteins, which interpret and relay the ion-specific signal towards downstream targets, has been largely neglected. Feedback loops involving several of these proteins are likely embedded throughout the signalling cascade leading up to successful RH and PT growth. Importantly, ROP GTPases are now thought to function as signalling hubs, ‘sensing’ and integrating the key molecular RH growth machinery mentioned above. But what are the direct and downstream targets of these proteins, and how is their signal relayed to govern tip growth?
ROP GTPases have been shown to regulate cytoskeleton dynamics, but despite the well-established role of the actin cytoskeleton, the role of microtubules in both RH and PT elongation is still dubious. Finally, the cytoskeleton has a pivotal role in the establishment of a highly organized subcellular organization in tip-growing cells. However, the role of individual subcellular compartments and the way in which they might interact to regulate RH elongation are poorly understood.
It is clear that many challenges lie ahead to better understand RH development. Here we have identified many interesting targets for future research. Studying the molecular pathways governing tip growth and integrating them into a network that leads up to successful RH elongation will have to go hand in hand with the development of new techniques which will allow us to probe the complexity of RH cells and their building blocks. Many questions remain open, yet combined efforts on PTs and RHs will lead to exciting discoveries and a better understanding of the tip growth process.
Abbreviations
- ACA:
-
autoinhibited Ca2+-ATPase
- ACT:
-
ACTIN
- ADF:
-
actin-depolymerizing factor
- AFs:
-
actin filaments
- AHA:
-
Arabidopsis H+-ATPase
- AIP1:
-
AKT1 INTERACTING PROTEIN PHOSPHATASE 1
- ANX:
-
ANXUR
- ARK1:
-
ARMADILLO REPEAT-CONTAINING KINESIN 1
- ARP2/3 complex:
-
actin-related protein 2/3 complex
- ATPase:
-
adenosine triphosphatase
- ATSFH1:
-
ARABIDOPSIS THALIANA SHORT ROOT HAIR 1
- AtSTP6:
-
ARABIDOPSIS THALIANA SUGAR TRANSPORTER 6
- BAPTA:
-
1,2-bis(o-aminophenoxy)ethane-N,N,N′,N′-tetraacetic acid
- CA:
-
constitutively active
- [Ca2+ cyt[:
-
cytoplasmic calcium concentration
- [Ca2+ ER[:
-
endoplasmic reticulum calcium concentration
- [Ca2+ ext[:
-
extracellular calcium concentration
- CaM:
-
calmodulin
- cAMP:
-
cyclic adenosine monophosphate
- CAP1:
-
[CA2+]CYT-ASSOCIATED PROTEIN KINASE 1
- CBLs:
-
calcineurin B-like proteins
- CBM3a:
-
carbohydrate-binding module 3a
- CDPK:
-
calcium-dependent protein kinase
- CESA:
-
CELLULOSE SYNTHASE
- CIPKs:
-
CBL-interacting protein kinases
- [Cl− cyt[:
-
chloride concentration cytoplasmic
- CMLs:
-
calmodulin-like proteins
- CMTs:
-
cortical microtubules
- CNGC:
-
cyclic nucleotide-gated channel
- cNMP:
-
cyclic nucleotide
- CNQX:
-
6-cyano-7-nitroquinoxaline-2,3-dione
- CPK3:
-
CALCIUM-DEPENDENT PROTEIN KINASE 3
- CRIB:
-
Cdc42- and Rac-interactive binding
- CrRLK1Ls:
-
Catharanthus roseus RLK1-like kinases
- CSC:
-
cellulose synthase complex
- CSLD:
-
CELLULOSE SYNTHASE-LIKE D
- CytB:
-
cytochalasin B
- DACC:
-
depolarization-activated calcium channel
- DCB:
-
2,6-dichlorobenzonitrile
- DN:
-
dominant negative
- DPI:
-
diphenyleneiodonium
- ECA1:
-
ER-type Ca2+-ATPase
- EGTA:
-
ethylene glycol-bis(β-aminoethyl ether)-N,N,N′,N′-tetraacetic acid
- EMTs:
-
endoplasmic microtubules
- EXP7:
-
EXPANSIN7
- F-actin:
-
filamentous actin
- FER:
-
FERONIA
- FH1 domain:
-
formin homology 1 domain
- FH2 domain:
-
formin homology 2 domain
- FRET:
-
Förster resonance energy transfer
- G-actin:
-
globular actin
- GAE6:
-
UDP-D-GLUCURONATE 4-EPIMERASE 6
- GAP:
-
GTPase-activating protein
- GDI:
-
guanosine nucleotide dissociation inhibitor
- GDP:
-
guanosine diphosphate
- GEF:
-
guanine nucleotide exchange factor
- GFP:
-
green fluorescent protein
- GLR:
-
glutamate receptor
- GTP:
-
guanosine triphosphate
- GTPase:
-
guanosine triphosphatase
- HACC:
-
hyperpolarization-activated calcium channel
- HAK5:
-
HIGH-AFFINITY K+ TRANSPORTER 5
- HEK:
-
human embryonic kidney
- HG:
-
homogalacturonan
- IP3 :
-
inositol trisphosphate
- LatB:
-
latrunculin B
- LePT1:
-
Lycopersicon esculentum phosphate transporter 1
- LRX1:
-
LEUCINE-RICH REPEAT/EXTENSIN 1
- MAPK/MPK:
-
MITOGEN-ACTIVATED PROTEIN KINASE
- MCA1/2:
-
MID1-COMPLEMENTING ACTIVITY 1/2
- MICU:
-
mitochondrial Ca2+ uniporter
- MOR1:
-
MICROTUBULE ORGANIZATION 1
- MRH2:
-
MORPHOGENESIS OF ROOT HAIR 2
- MSL2/3:
-
MSCS-LIKE 2/3
- MT:
-
microtubules
- MyoB1/2:
-
myosin-binding proteins 1/2
- NHX1-4:
-
SODIUM HYDROGEN EXCHANGER 1-4
- NOX:
-
NADPH oxidase
- ORF:
-
open reading frame
- OXI1:
-
OXIDATIVE SIGNAL-INDUCIBLE1
- PH:
-
pleckstrin homology
- pHcyt :
-
cytoplasmic pH
- pHext :
-
extracellular pH
- PIN2:
-
PIN-FORMED 2
- PI-4Kβ1:
-
PHOSPHATIDYLINOSITOL 4-OH KINASE β1
- PI-4P:
-
phosphatidylinositol 4-phosphate
- PI(4,5)P2 :
-
phosphatidylinositol 4,5-biphosphate
- Plus(+) end:
-
barbed actin filament end
- PM:
-
plasma membrane
- PME:
-
pectin methylesterase
- PMEI:
-
pectin methylesterase inhibitor
- prf1 :
-
profilin 1
- PRONE:
-
plant-specific ROP nucleotide exchanger
- PT:
-
pollen tube
- qRT-PCR:
-
quantitative reverse transcriptase polymerase chain reaction
- RabA4b:
-
RAB GTPASE HOMOLOGUE A4B
- RBOH:
-
RESPIRATORY BURST OXIDASE HOMOLOGUE
- RH:
-
root hair
- RHD2:
-
ROOT HAIR DEFECTIVE 2
- RHM1:
-
RHAMNOSE BIOSYNTHESIS 1
- RHS:
-
root hair specific
- RHS8:
-
ROOT HAIR SPECIFIC 8
- RIC:
-
ROP-INTERACTIVE CRIB MOTIF-CONTAINING PROTEIN
- RIP:
-
ROP INTERACTIVE PARTNER
- RLK:
-
receptor-like kinase
- RNAi:
-
RNA interference
- ROPs:
-
Rho-like GTPases from plants
- ROS:
-
reactive oxygen species
- SCN1:
-
SUPERCENTIPEDE1
- SIMK:
-
STRESS-INDUCED MAPK
- SLAH3:
-
SLAC1 HOMOLOGUE 3
- SOD:
-
superoxide dismutase
- TAIR:
-
The Arabidopsis Information Resource
- TCH2:
-
TOUCH2
- T-DNA:
-
transfer-DNA
- TPC1:
-
TWO-PORE CHANNEL 1
- UER1:
-
UDP-4-KETO-6-DEOXY-D-GLUCOSE-3,5-EPIMERASE-4-REDUCTASE 1
- VGD1:
-
VANGUARD1
- VLN:
-
VILLIN
- WER:
-
WEREWOLF
- XEH:
-
XYLOGLUCAN ENDOHYDROLASE
- XTH:
-
XYLOGLUCAN ENDOTRANSGLUCOSYLASE/HYDROLASE
- XUT1:
-
XYLOGLUCAN-SPECIFIC GALACTURONOSYLTRANSFERASE 1
- XXT:
-
XYLOGLUCAN XYLOSYLTRANSFERASE
- XyG:
-
xyloglucan
- YC3.6:
-
Yellow Cameleon 3.6 (cytosolic calcium sensor)
- YFP:
-
yellow fluorescent protein
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Schoenaers, S., Balcerowicz, D., Vissenberg, K. (2017). Molecular Mechanisms Regulating Root Hair Tip Growth: A Comparison with Pollen Tubes. In: Obermeyer, G., Feijó, J. (eds) Pollen Tip Growth. Springer, Cham. https://doi.org/10.1007/978-3-319-56645-0_9
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