A role for pectin-associated arabinans in maintaining the flexibility of the plant cell wall during water deficit stress

One of the main components of pectin, a primary constituent of higher plant cell walls, is rhamnogalacturonan I. This polymer comprised of linked alternating rhamnose and galacturonic acid residues is decorated with side chains composed of arabinose and galactose residues. At present, the function of these side chains is not fully understood. Our research on Southern African resurrection plants, plants that are capable of surviving severe dehydration (desiccation), has revealed that their cell walls are capable of extreme flexibility in response to water loss. One species, Myrothamnus flabellifolia, has evolved a constitutively protected leaf cell wall, composed of an abundance of arabinose polymer side chains, suggested to be arabinans and/or arabinogalactans, associated with the pectin matrix. In this article, we propose a hypothetical model that explains how the arabinan rich pectin found in the leaves of this desiccation-tolerant plant permits almost complete water loss without deleterious consequences, such as irreversible polymer adhesion, from occurring. Recent evidence suggesting a role for pectin-associated arabinose polymers in relation to water dependent processes in other plant species is also discussed.Key words: arabinans, cell wall, desiccation, resurrection, rehydration, rhamnogalacturonan IThe flowering plant cell wall is a composite structure consisting of a skeletal framework of cellulose and hemicellulose embedded within a matrix of pectin polysaccharides and cell wall glycoproteins.^1,2 The pectin matrix, in turn, is composed of three primary types of polysaccharides, these being rhamnogalacturonan I (RGI), rhamnogalacturonan II (RGII) and homogalacturonan (HG).¹ RGII is a complex polysaccharide, consisting of many unusual sugar moieties, and is not present in large amounts in the wall.³ HG is effectively a linear homopolymer of galacturonic acid and is believed to facilitate the formation of tight junctions, ‘egg boxes’, by complexing with calcium ions present in the cell wall.¹ RGI is a polymer composed of a backbone of alternating glycosidically linked rhamnose and galacturonic acid residues.¹ Side chains, consisting of either arabinogalactan polymers or linear chains of arabinans and/or galactans, are then attached to the rhamnose residues of the RGI backbone.¹ The manner with which these polymers are attached or become entangled with each other and cellulosic polymers to form the pectin matrix has been a matter of debate. The classical theory is that the RGI and HG polymers alternate with each other as block polymers and that the side chains interact with neighbouring polysaccharide chains. Recently, this standard theory has been questioned and an argument whereby the HG polymers are actually side chains of a RGI backbone polymer has been advanced.⁴ Nevertheless, the complexity of pectin polysaccharides is such that ascribing definitive functions to this matrix of polysaccharides has proven quite difficult. The physical properties of the pectin matrix suggest a number of possible functions. The water binding properties of the galacturonic acid residues indicate that polymers containing these groups have the capacity to hydrate and swell and so possibly help maintain polymer separation in the wall.⁵ The side chains of RGI include arabinan and galactan polymers which have been shown to be highly mobile^6,7,8 with the potential to interact with each other forming a temporally entangled matrix.⁹ It is also believed that arabinan chains, which have been shown to contain ferulate residues attached to terminal arabinose groups, are able to oxidatively cross-link via the formation of diferulate bridges between arabinan chains that originate on separate RGI polysaccharides.¹⁰ The pectin matrix is now believed to contain sub-domains of RGI, HG and RGII which may interact with different polysaccharide components of the cell wall such as cellulose or xyloglucan.^11,12 Hence, it is possible that the pectin matrix may form these associations with other polysaccharides via covalent⁹ and/or non-covalent¹¹ (e.g., H-bonding) interactions and in so doing ensure the integrity of the wall and its polymer organisation. Although a number of general functions, such as hydration and ion binding, have been proposed for the pectin matrix, in particular the RGI polymer and its neutral side chains, there has been difficulty in elucidating specific functions for these polysaccharides. A number of molecular genetic studies have been performed with the aim of establishing specific functions for the RGI side chains. A recent study showed that genetic removal of the arabinan side chains in the cell walls of Nicotiana plumbaginfolia results in the formation of a non-organogenic callus culture with loosely attached cells.¹³ Furthermore, it has been shown that ‘in muro’ fragmentation of the RG1 backbone in Solanum tuberosum results in abnormal development of the periderm.¹⁴ This suggests that these side chains may play at least some role in normal cell attachment and cell development. However, the real problem is that no obvious phenotypic differences between wild type and mutant plants (in which neutral side chains have been modified) have been observed.^15,16,17 It may be that the conditions under which phenotypic differences between wild type and mutant plants would arise have not yet been investigated. We believe the water binding and attachment properties of the pectin matrix are particularly important. This is especially so given the role pectin plays in the middle lamella ensuring attachment of cells to each other and in the formation of the apoplast where water mediated transport of solutes occurs.¹ Our research has focused on a group of Southern African plants termed ‘Resurrection plants’ because of their unique ability to survive severe dehydration (desiccation) to an almost air-dry state.¹⁸ We have been interested in how the cell walls of angiosperm resurrection plants such as Craterostigma wilmsii^19,20 and Myrothamnus flabellifolia^21,22 may have become adapted to survive this extreme water deficit stress (desiccation). We have shown that in the case of the Myrothamnus flabellifolia leaf cell wall, which becomes considerably folded when dried, does not undergo dramatic changes in composition or polymer location in response to desiccation.²¹ Rather we propose that this plant has evolved a constitutively protected cell wall which is able to undergo repeated cycles of desiccation and rehydration.^21,22 We have observed that the pectin component of the leaf cell wall in this species was unusually rich in arabinose polymers, most likely arabinan and arabinogalactan in nature, which we advanced was the reason that the cell wall of this species was able to tolerate desiccation.²¹ Here we provide a simple model (Fig. 1) whereby the arabinan side chains of the pectin polysaccharides are responsible for possibly buffering/replacing the lost water during desiccation and in so doing prevent the formation of tight junctions (e.g., egg boxes) or strong H-bonding interactions between the normally separate ‘skeletal’ polysaccharides (e.g., cellulose microfibrils and xyloglucan tethers) embedded in the pectin matrix. Our model is supported by the observation that cell wall arabinans play a crucial role in the response of guard cells to turgor pressure.²³ It was shown that removal of arabinans by enzymatic digestion of leaf strips of Commelina communis resulted in locking of the guard cell walls in either the open or closed position.²³ Additional roles for arabinan polymers in cell walls have recently been implied with respect to the salt tolerance of Mesembryanthemum crystallinum,²⁴ ensuring hydration of the seed endosperm of Gleditsia triacanthos during germination²⁵ and the tolerance of tropical legume seeds to dehydration.²⁶ We believe that the arabinan side chains of RGI play a critical role in the ability of cell walls to remain flexible during plant growth and may have important functions in relation to the water content of the cell. Further studies aimed at determining the relationship between wall water content, RGI side chains and cell wall flexibility may reveal hitherto unsuspected functions for these polysaccharides in the life of the plant.Open in a separate windowFigure 1A model proposing the role of arabinose rich pectin polymers in stabilising the cell wall against water loss. (A) Pectin consisting of short arabinan chains in the hydrated state, (B) pectin consisting of short arabinan chains in the dehydrated state; (C) pectin consisting of long arabinan chains in the hydrated state; (D) pectin consisting of long arabinan chains in the dehydrated state. The likelihood of irreversible tight junctions (e.g., egg boxes) forming in arabinan poor cell walls during dehydration is demonstrated in (B) while the reversible buffering effect of arabinan rich cell walls is proposed in (D) as would possibly occur in Myrothamnus flabellifolia. For simplicity arabinan chains not participating in the buffering interactions between the RGI backbone chains have been shortened to two arabinose residues in length. Note in (A) and (B) all arabinan chains are two arabinose residues in length.     

Biochemical and Immunocytological Characterizations of Arabidopsis Pollen Tube Cell Wall

During plant sexual reproduction, pollen germination and tube growth require development under tight spatial and temporal control for the proper delivery of the sperm cells to the ovules. Pollen tubes are fast growing tip-polarized cells able to perceive multiple guiding signals emitted by the female organ. Adhesion of pollen tubes via cell wall molecules may be part of the battery of signals. In order to study these processes, we investigated the cell wall characteristics of in vitro-grown Arabidopsis (Arabidopsis thaliana) pollen tubes using a combination of immunocytochemical and biochemical techniques. Results showed a well-defined localization of cell wall epitopes. Low esterified homogalacturonan epitopes were found mostly in the pollen tube wall back from the tip. Xyloglucan and arabinan from rhamnogalacturonan I epitopes were detected along the entire tube within the two wall layers and the outer wall layer, respectively. In contrast, highly esterified homogalacturonan and arabinogalactan protein epitopes were found associated predominantly with the tip region. Chemical analysis of the pollen tube cell wall revealed an important content of arabinosyl residues (43%) originating mostly from (1→5)-α-l-arabinan, the side chains of rhamnogalacturonan I. Finally, matrix-assisted laser desorption ionization time-of-flight mass spectrometry analysis of endo-glucanase-sensitive xyloglucan showed mass spectra with two dominant oligosaccharides (XLXG/XXLG and XXFG), both being mono O-acetylated, and accounting for over 68% of the total ion signals. These findings demonstrate that the Arabidopsis pollen tube wall has its own characteristics compared with other cell types in the Arabidopsis sporophyte. These structural features are discussed in terms of pollen tube cell wall biosynthesis and growth dynamics.Fertilization of flowering plants requires the delivery of the two sperm cells, carried by a fast growing tip-polarized pollen tube, to the egg cell. In plants with dry stigma and solid style such as Arabidopsis (Arabidopsis thaliana), this process begins with the deposition and specific adhesion of the pollen grains on the stigmatic tissue, subsequent hydration of the pollen grains, and germination of pollen tubes (Palanivelu and Preuss, 2000). Pollen tubes invade the papillae cell wall of the stigma, enter the short style, and grow through the apoplast of the specialized transmitting tract (TT) that is filled with a nutrient-rich extracellular matrix (Kandasamy et al., 1994; Lennon et al., 1998). During this invasive growth, pollen tubes are guided to the ovules via signals that need to pass through the cell wall to reach their membrane-associated or intracellular targets (Lord and Russell, 2002; Kim et al., 2003; Boavida et al., 2005; McCormick and Yang, 2005; Johnson and Lord, 2006). In plant species with wet stigma and hollow style such as lily (Lilium longiflorum), adhesion between the pollen tube wall and the TT epidermis extracellular matrix is important for the growth of the pollen tubes toward the ovules (Mollet et al., 2000, 2007; Park et al., 2000; Chae et al., 2007). In addition to being the interface between the tube cells and the surroundings (female sporophyte or culture medium), the pollen tube wall also controls the cell shape, protects the generative cells, and allows resistance against turgor pressure (Geitmann and Steer, 2006; Geitmann, 2010).Most of our knowledge on cell wall polymers of higher plants comes from investigations on vegetative organs in which cells have diffuse growth. The cell wall is mainly composed of polysaccharides (cellulose, hemicellulose, pectin, and occasionally callose, depending on the tissue) and proteoglycans (e.g. extensin and arabinogalactan proteins [AGPs]) forming a complex network with processing enzymes.Pectins are complex wall macromolecules with uncertain supramolecular organization (Vincken et al., 2003) consisting of homogalacturonan (HG) that can be methylesterified and acetylesterified, rhamnogalacturonan I (RG-I), rhamnogalacturonan II (RG-II), and xylogalacturonan (Carpita and McCann, 2000). HG is a polymer of repeated units of (1→4)-α-d-GalUA that can be cross-linked with calcium upon block-wise action of pectin methylesterases (PMEs) on methylesterified HG (Micheli, 2001). RG-II has the same homopolymer backbone as HG but is substituted with four different oligosaccharides composed of unusual sugars, such as apiose, aceric acid, and 3-deoxy-d-manno-2-octulosonic acid, of unknown function (for review, see Caffall and Mohnen, 2009). RG-I consists of the repeating disaccharide (1→4)-α-d-GalUA-(1→2)-α-l-Rha, with a wide variety of side chains attached to the rhamnosyl residues, ranging from monomers to large oligosaccharides such as (1→4)-β-d-galactan, (1→5)-α-l-arabinan, and/or type I arabinogalactan (Caffall and Mohnen, 2009).Xyloglucan (XyG) is the major hemicellulosic polysaccharide of the primary wall of flowering plants. Classic XyG consists of a (1→4)-β-d-glucan backbone substituted with Xyl, Gal-Xyl, or Fuc-Gal-Xyl motifs, which correspond, according to the one-letter code proposed by Fry et al. (1993), to X, L, and F, respectively, G being the unsubstituted glucosyl residue of the glucan backbone. The main XyG fragments released after endo-glucanase treatment of the cell wall from wild-type Arabidopsis vegetative organs are generally XXXG, XXLG/XLXG, XXFG, and XLFG (Zablackis et al., 1995; Lerouxel et al., 2002; Nguema-Ona et al., 2006; Obel et al., 2009). In addition, O-acetylation of XyG can occur, most generally on the galactosyl residues, but its biological function is unknown (Cavalier et al., 2008). In the primary wall, XyG interacts with cellulose microfibrils via hydrogen bonds and participates in the control of cell expansion (Cosgrove, 1999).AGPs and extensin belong to the Hyp-rich glycoproteins superfamily with very high levels of type II arabinogalactan glycosylation (Nothnagel, 1997; Showalter, 2001). These proteoglycans have been implicated in many aspects of plant development, including cell expansion, cell signaling and communication, embryogenesis, wound response, and pollen tube guidance (Wu et al., 1995; Nothnagel, 1997; Seifert and Roberts, 2007; Driouich and Baskin, 2008).Despite the importance of pollen tubes for the delivery of the sperm cells to the egg, little is known about the underlying molecular mechanisms that regulate the mechanical interaction of pollen tubes with female floral tissues. There are very scarce data concerning the different components of the pollen tube cell wall. Past approaches to characterize the pollen tube cell wall are limited to a few plant genera, including Camellia (Nakamura and Suzuki, 1981), Lilium (Jauh and Lord, 1996; Mollet et al., 2002), Nicotiana (Rae et al.,1985; Li et al., 1995; Ferguson et al., 1998; Qin et al., 2007), Pinus (Derksen et al., 1999), and Zea (Rubinstein et al., 1995), and are mostly based on immunocytochemistry. These studies revealed that, depending on the species, the pollen tube cell wall contains epitopes that are found in the polymers described above, including HGs with varying levels of methylesterification, AGPs, extensin-like proteins, and low amounts of cellulose. Unlike most other plant cells, callose, a (1→3)-β-glucan, is predominant and is deposited in the wall back from the tip. Moreover, it is deposited at regular intervals to form callose plugs that maintain the tube cell in the apical expanding region of the tube and separate the viable from the degenerating region of the tube (for review, see Geitmann and Steer, 2006). Only a few reports have investigated the pollen tube of the model plant Arabidopsis. They have focused either on in vivo-grown or on in vitro-grown pollen tubes using monoclonal antibodies (MAbs) directed against a subset of cell wall epitopes present in HG, XyG, and AGPs (Lennon and Lord, 2000; Freshour et al., 2003; Pereira et al., 2006), but quantitative chemical analyses are lacking. This lack of information is most likely due to the fact that substantial amounts of pollen tube material are needed for chemical analysis, and a reproducible and efficient method for liquid culture of Arabidopsis pollen tubes had not been established until recently (Boavida and McCormick, 2007; Bou Daher et al., 2009).Here, we report the composition and localization of different cell wall polymers of in vitro-grown wild-type Arabidopsis pollen tubes based on biochemical analyses coupled to immunocytochemical investigations both at light and transmission electron microscopy (TEM) levels using recently developed MAbs. Our results show distinct patterns of labeling (tip, whole tube, and shank of the tube) depending on the recognized epitope. The most striking observations are (1) the abundance of (1→5)-α-l-arabinan in the tube wall (greater than 40 mol % of Ara), mostly localized, with LM6 and LM13, in the outer wall layer of the tube and (2) an atypical XyG matrix-assisted laser desorption ionization time-of-flight mass spectrometry (MALDI-TOF MS) profile with over 68% of the oligosaccharide fragments being O-acetylated.     

How does timing,duration and severity of heat stress influence pollen-pistil interactions in angiosperms?

Reproductive development in sexual plants is substantially more sensitive to high temperature stress than vegetative development, resulting in negative implications for food and fiber production under the moderate temperature increases projected to result from global climate change. High temperature exposure either during early pollen development or during the progamic phase of pollen development will negatively impact pollen performance and reproductive output; both phases of pollen development are considered exceptionally sensitive to moderate heat stress. However, moderately elevated temperatures either before or during the progamic phase can limit fertilization by negatively impacting important pollen pistil interactions required for successful pollen tube growth toward the ovules. This mini-review identifies the impacts of heat stress on pollen-pistil interactions and sexual reproduction in angiosperms. A special emphasis is placed on the biochemical response of the pistil to moderately high temperature and the resultant influence on in vivo pollen performance and fertilization.Key words: pollen-pistil interaction, carbohydrates, heat stress, fertilization, pollen tube growth, climate changeSexual reproduction is substantially more sensitive to moderately high temperature stress than vegetative processes.¹ Consequently, the yield of crops with valuable reproductive structures used for food (i.e., grain crops and horticultural crops) and fiber (i.e., cotton) would be especially sensitive to moderately elevated temperatures projected to result from global climate change. Sexual reproduction in angiosperms occurs in essentially three stages: gametophyte development (from meiosis to pollination), the progamic phase (from pollination to zygote formation) and embryo development (from zygote to seed).² During the pro-gamic phase, a number of reproductive processes must occur in a highly concerted fashion for successful fertilization to occur. (1) Anther dehiscence allows mature pollen grains to be transferred to a receptive stigmatic surface; (2) pollen grains germinate and pollen tubes penetrate the stigmatic surface of the pistil; (3) pollen tubes grow through the transmitting tissue of the style and towards a sexually competent ovule; finally, (4) double fertilization produces a zygote and its associated endosperm. Inhibition of any one of the aforementioned processes during the progamic phase, will necessarily limit seed development.³Although the timing and precise coordination of events during the progamic phase are strongly determined by genotype and occur in a unique and well-defined manner for a given species,⁴ the environment encountered either before or during the pro-gamic phase also exerts considerable control over the fertilization process, and can strongly influence reproductive success.⁵ Consequently, high temperature has been shown to substantially limit fertilization in vivo.⁵ Depending upon the timing, duration and severity, heat stress can limit fertilization⁵ by (1) inhibiting male⁶ and female^5,7 gametophyte development, (2) inhibiting pollen germination,^6,8,9 (3) limiting pollen tube growth,^8–11 or (4) by altering the development of tissues required to carry out reproductive processes (i.e., anther and pistil tissues).¹ Although the existing literature concerning heat stress and reproductive development in sexual plants is exhaustive (reviewed in ref. ¹ and ²), the approaches used by various investigators to elucidate plant reproductive responses to high temperature vary substantially from study to study. Consequently, it is the aim of this review to characterize the impact of timing, duration and severity of heat stress on sexual processes occurring during the progamic phase. A special emphasis is placed on the biochemical response of the pistil to moderately high temperature and the resultant influence on in vivo pollen performance.     

Analysis of LuPME3, a pectin methylesterase from Linum usitatissimum,revealed a variability in PME proteolytic maturation

Pectin methylesterase (PME) catalyzes the de-methylesterification of pectin in plant cell walls during cell elongation.¹ Pectins are mainly composed of α(1, 4)-D-galacturonosyl acid units that are synthesized in a methylesterified form in the Golgi apparatus to prevent any interaction with Ca²⁺ ions during their intracellular transport.² The highly methylesterified pectins are then secreted into the apoplasm³ and subsequently de-methylesterified in muro by PMEs. This can either induce the formation of pectin gels through the Ca²⁺ crosslinking of neighboring non-methylesterified chains or create substrates for pectin-degrading enzymes such as polygalacturonases and pectate lyases for the initiation of cell wall loosening.⁴ PMEs belong to a large multigene family. Sixty­six PME-related genes are predicted in the Arabidopsis genome.¹ Among them, we have recently shown that AtPME3 (At3g14310), a major basic PME isoform in A. thaliana, is ubiquitously expressed in vascular tissues and play a role in adventitious rooting.⁵ In flax (Linum usitatissimum), three genes encoding PMEs have been sequenced so far, including LuPME3, the ortholog of AtPME3. Analysis of the LuPME3 isoform brings new insights into the processing of these proteins.     

Membrane trafficking mediated by OsDRP2B is specific for cellulose biosynthesis

Increasing evidence has revealed that membrane trafficking is highly associated with cell wall metabolism. Factors involved in vesicle delivery, e.g., cytoskeleton and motor proteins, have showed regulatory effects on cell wall structure and components. However, little is known about the involvement of other trafficking components in distribution of cell wall-related compartments. Dynamins are important proteins functioning in membrane tubulation and vesiculation. Recently, we have reported characterization of the rice dynamin-related protein 2B (OsDRP2B). Mutation in OsDRP2B causes a significant reduction in cellulose content. Its association with the trans-Golgi network (TGN) and clathrin-coated vesicles and the reduced CESA4 abundance at the bc3 plasma membrane suggest that BC3/OsDRP2B is involved in the transport of essential elements for cellulose synthesis. Here, we provide additional evidence for BC3 subcellular localization via observing OsDRP2B-GFP in living root hairs of transgenic plants. Uronic acid and fractional composition analyses further confirm that the amount of arabinoxylan and other noncellulosic polysaccharides is increased in bc3. However, three putative xylan synthesis genes are downregulated in mutant plant revealed by real-time PCR analysis. These results imply that compartments delivered by OsDRP2B are specifically responsible for cellulose biosynthesis.Key words: OsDRP2B, cellulose biosynthesis, membrane trafficking, brittleness, ricePlant cell wall is an extracellular matrix enriched in polysaccharides. Except for cellulose that is produced at the plasma membrane by cellulose synthase (CESA) complexes, most of the cell wall products are assumed being synthesized inside cells, e.g., in the Golgi apparatus and secreted outside through complex membrane trafficking. Besides the cell wall-localized products, some proteins essential for cellulose biosynthesis need to be translocated onto the plasma membrane to facilitate cellulose formation.^1,2 Intracellular trafficking is therefore a key level for regulating cell wall composition and architecture, which are highly dynamic during cellular development.³ This notion is substantiated by the fact that wall architecture within the same cell is heterogeneity, indicating the presence of cell wall specific deposition domains.^4,5 For example, pectins are often located at the cell corners.³ Different de-esterified homogalacturonan (HG) are present along the growing pollen tubes or root hairs: tips have highly esterified HG; the de-esterified degree is increased after tips.⁶ Although it is believed that these specific patterns could be the result of the targeted secretion of polysaccharides,³ our knowledge about the polysaccharide secretion is still very few. Currently, in vivo viewing CESA-containing compartments and the movement inside living cells have provided direct evidence for the trafficking action of CESA compartments.^2,7,8 The delivery and removal of CESA complexes to/from the plasma membrane are very complicated, which require the involvement of many components, such as cytoskeleton and syntaxins.^7,9,10 Syntaxins, part of SNARE complexes, function as docking factor of cell wall-related compartments during cell plate formation.¹⁰ Dynamin and dynamin-related proteins (DRPs) are involved in diverse events of cellular membrane remodeling.¹¹ It remains unknown about whether DRPs are responsible for CESA trafficking. Recently, we have reported that BC3, the rice DRP2B protein, plays a role in complex membrane trafficking and affects the biosynthesis of secondary walls. Here, we provide additional cellular and wall chemical data to confirm that BC3/OsDRP2B is specifically involved in the secondary cell wall cellulose synthesis.     

Potassium flux in the pollen tubes was essential in plant sexual reproduction

Potassium channels are controlling K⁺ transport across plasma membrane and thus playing a central role in all aspects of osmolarity as well as numerous other functions in plants, including in sexual reproduction. We have used whole-cell and single-channel patch-clamp recording techniques investigated the regulation of intracellular free Ca²⁺-activated outward K⁺ channels in Pyrus pyrifolia pollen tube protoplasts. We have also showed the channels could be inhibited by heme and activated carbon monoxide (CO). In the presence of oxygen and NADPH, hemoxygenases catalyzes heme degradation, producing biliverdin, iron and CO. Considered the oxygen concentration approaching zero in the ovary, the heme will inhibit the K⁺ outward flux from the intracellular of pollen tube, increasing the pollen tubes osmolarity, inducing pollen tube burst. Here we discuss the putative role of K⁺ channels in plant sexual reproduction.Key words: pear, pollen, K⁺ channels, heme, carbon monoxideIon channels in the pollen tube play critical roles in mediation pollen germination and pollen tube growth.^1–3 Early studies were focus on the plasma membrane calcium channel regulation and cytosolic free calcium concentration variation in the pollen tube reason by which was one of the most important second messengers in plants.^3–7 However, reports have also showed that the potassium channels in the pollen tubes were also involved in several important steps of plant sexual reproduction.^8–19 Recently, more reports further demonstrated this phenomena.^20–24 In the report by Lu et al. they demonstrated that two cation/proton exchangers (CHX), CHX21 and CHX23, are essential for pollen tube growth guidance in Arabidopsis.²² chx21 chx23 double mutant induces the fertility impaired, but which is unchanged in both single chx21 or chx23 mutants. They have also found that the double mutant pollen grains germination and pollen tube growth in the transmitting tract were not difference with the wild-type, however, the double mutant pollen tubes fail to turn toward ovules.²² Protein localization experiments show CHX23 is expressed in the endoplasmic reticulum of pollen tubes; functional analysis results showed that CHX23 as a K⁺ transporter mediates K⁺ uptake in a pH-dependent manner. So, these protein affect the signal transduction pathway of pollen tube growth toward to the ovule by controlling the cation balance and pH in the pollen tube.²² Amien et al. identified a signaling ligand of defensin-like (DEFL) protein, ZmES4, which expressed in maize synergid. ZmES4 activates the maize pollen tube tip plasma membrane K⁺ Shaker channel KZM1.²⁰ This finding is also very interesting. Pollen tube bursting suggested to be based on the osmotic stress; the influx of K⁺ mediated by ZmES4-activated KZM1 will trigger rapid plasma membrane depolarization, which induced the pollen tube tip burst.²⁰ Furthermore, the osmotic increasing induced by too much K⁺ in the cytosolic of pollen tube was not only resulted by inward K⁺ channel activation, but also resulted by outward K⁺ channel inhibition in the pollen tube plasma membrane. In our report, we find a intracellular Ca²⁺-sensitive outward K⁺ channel in pear pollen tube plasma membrane, which could be inhibited by heme and activated by heme oxidative production, carbon monoxide (CO), may play a functional role in the pollen tube brusting.²³In the presence of oxygen and NADPH, hemoxygenases catalyzes heme degradation, producing biliverdin, iron and CO.²⁵ Early reports showed that oxygen plays an important role in plant sexual reproduction. Pollen tubes grow through the style toward the ovary with high speed, a process that consumes tremendous amounts of energy and requires rapid oxygen uptake by pollen tubes.²⁶ Pollen grains have roughly 20 times the level of mitochondria and respire 10 times faster than vegetative tissue.^12,27–29 Furthermore, oxygen has been proposed as a possible cue for pollen-tube guidance.³⁰ Indeed, the existence of an oxygen gradient in the unpollinated style has been shown in some species such as Hipeastrum hybridum. Oxygen pressure is high in the stigma and style but suddenly decreases at the base of the style, approaching zero in the ovary. Moreover, pollen-tube growth itself creates hypoxic regions within the style.³¹ Therefore, we suggest that the outward K⁺ channel inhibited by heme is dominant compared with which activated by CO when pollen tubes reach the ovary, based on where the hypoxic condition (Fig. 1). However, the gene encode the outward K⁺ channel in the pear pollen tube remains to be determined in the further study.Open in a separate windowFigure 1Reciprocal regulation of heme and carbon monoxide in putative Ca²⁺-activated outward K⁺ channel. Under normal condition, in the presence of NADPH, heme is metabolized by hemeoxygenase to generate carbon monoxide (CO), which activates outward K⁺ channel. However, without the oxygen, heme cannot be metabolized. The accumulated heme acts as an inhibitor of outward K⁺ channel, even in the presence of NADPH. The accumulated K⁺ in the cytosolic of pollen will induced the pollen tube depolarized, then burst.     

A new callose function: Involvement in differentiation and function of fern stomatal complexes

Callose in polypodiaceous ferns performs multiple roles during stomatal development and function. This highly dynamic (1→3)-β-D-glucan, in cooperation with the cytoskeleton, is involved in: (a) stomatal pore formation, (b) deposition of local GC wall thickenings and (c) the mechanism of stomatal pore opening and closure. This behavior of callose, among others, probably relies on the particular mechanical properties as well as on the ability to form and degrade rapidly, to create a scaffold or to serve as a matrix for deposition of other cell wall materials and to produce fibrillar deposits in the periclinal GC walls, radially arranged around the stomatal pore. The local callose deposition in closing stomata is an immediate response of the external periclinal GC walls experiencing strong mechanical forces induced by the neighboring cells. The radial callose fibrils transiently co-exist with radial cellulose microfibrils and, like the latter, seem to be oriented via cortical MTs.Key words: callose, cytoskeleton, fern stomata, guard cell wall thickening, stomatal function, stomatal pore formationCallose represents a hemicellulosic matrix cell wall component, usually of temporal appearance, which is synthesized by callose synthases, enzymes localized in the plasmalemma and degraded by (1→3)-β-glucanases.^1–4 It consists of triple helices of a linear homopolymer of (1→3)-β-glucose residues.^5–7 The plant cell is able to form and degrade callose in a short time. On the surface of the plasmolyzed protoplast a thin callose surface film may arise within seconds.⁸ Callose is the only cell wall component that is implicated in a great variety of developmental plant processes, like cell plate formation,^9–11 microspore development,^12–14 trafficking through plasmodesmata,^15,16 formation and closure of sieve pores,¹⁶ response of the plant cells to multiple biotic and abiotic stresses,^4,5 establishment of distinct “cell cortex domains”,¹⁷ etc.Despite the widespread occurrence of callose, its general function(s) is (are) not well understood (reviewed in refs. ⁴ and ⁵). It may serve as: a matrix for deposition of other cell wall materials, as in developing cell plates;⁹ a cell wall-strengthening material, as in cotton seed hairs and growing pollen tubes;¹⁸ a sealing or plugging material at the plasma membrane of pit fields, plasmodesmata and sieve plate pores;¹⁶ a mechanical obstruction to growth of fungal hyphae or a special permeability barrier, as in pollen mother cell walls and muskmelon endosperm envelopes.^4,19,20 The degree of polymerization, age and thickness of callose deposits may cause variation in its physical properties.⁵Evidence accumulated so far showed that a significant number of ferns belonging to Polypodiales and some other fern classes forms intense callose deposits in the developing GC wall thickenings.^21–28 This phenomenon has not been observed in angiosperm stomata, although callose is deposited along the whole surface of the young VW and in the VW ends of differentiating and mature stomata (our unpublished data; reviewed in refs ²⁹ and ³⁰).Stomata are specialized epidermal bicellular structures (Fig. 1A) regulating gas exchange between the aerial plant organs and the external environment. Their appearance in the first land plants was crucial for their adaptation and survival in the terrestrial environment. The constituent GCs have the ability to undergo reversible changes in shape, leading to opening and closure of the stomatal pore (stomatal movement). The mechanism by which GCs change shape is based on: (a) the particular mechanical properties of GC walls owed to their particular shape, thickening, fine structure and chemical composition and (b) the reversible changes in vacuole volume, in response to environmental factors, through fairly complicated biochemical pathways.^30–33Open in a separate windowFigure 1(A) Diagrammatic representation of an elliptical stoma. (B–E) Diagram to show the process of stomatal pore formation in angiosperms (B and C) and Polypodiales ferns (D and E). The arrows in (B) indicate the forming stomatal pore. DW, dorsal wall; EPW, external periclinal wall; GC, guard cell; IPW, internal periclinal wall; ISP, internal stomatal pore; PE polar ventral wall end; VW, ventral wall.The present review is focused on the multiple-role of callose in differentiating and functioning fern stomata, as they are substantiated by the available information, including some unpublished data, and in particular in: stomatal pore formation, deposition of GC wall thickenings and opening and closure of the stomatal pore. The mode of deposition of fibrillar callose deposits in GC walls and the mechanism of their alignment are also considered.     

Self-Incompatibility Involved in the Level of Acetylcholine and cAMP

Elongation of pollen tubes in pistils after self-pollination of Lilium longiflorum cv. Hinomoto exhibiting strong gametophytic self-incompatibility was promoted by cAMP and also promoted by some metabolic modulators, namely, activators (forskolin and cholera toxin) of adenylate cyclase and inhibitors (3-isobutyl-1-methylxanthine and pertussis) of cyclic nucleotide phosphodiesterase. Moreover, the elongation was promoted by acetylcholine (ACh) and other choline derivatives, such as acetylthiocholine, L-α-phosphatidylcholine and chlorocholinechloride [CCC; (2-chloroethyl) trimethyl ammonium chloride]. A potent inhibitor (neostigmine) of acetylcholinesterase (AChE) as well as acetylcholine also promoted the elongation. cAMP enhanced choline acetyltransferase (ChAT) activity and suppressed AChE activity in the pistils, suggesting that the results are closely correlated with self-incompatibility in L. longiflorum. In short, it came to light that cAMP modulates ChAT (acetylcholine-forming enzyme) and AChE (acetylchoine-decomposing enzyme) activities to enhance the level of ACh in the pistils of L. logiflorum after self-incompatible pollination. These results indicate that the self-incompatibility on self-pollination is caused by low levels of ACh and/or cAMP.Key Words: pollen tubes, self-incompatibility, Lilium longiflorum, cAMP, acetylcholie, AChE, ChATCyclic AMP (cAMP) is an essential signaling molecule in both prokaryotes and eukaryotes.¹ The existence of cAMP in higher plants was questioned by some reviewers^2–4 in the mid 1970''s, so that many workers were discouraged from studying roles in plant biology. However, its presence was confirmed by mass spectrometry⁵ and infrared spectrometry⁶ in the early 1980''s and increasing evidence^7–12 now suggests that cAMP makes important contributions in plant cells, as in animals.Lily (Lilium longiflorum) exhibits strong gametophytic self-incompatibility.^13,14 Thus, elongation of pollen tubes in the pistil after self-incompatible pollination in L. longiflorum cv. Hinomoto stops halfway, in contrast to the case after cross-compatible pollination (cross with cv. Georgia).¹⁴ This self-incompatibility appears to be associated with the stress and self-incompatible pollination on stigmas of lilies results in activation and/or induction of enzymes such as NADH- and NADPH-dependent oxidases, xanthine oxidase, superoxide dismutase (SOD), catalase and ascorbate peroxidase in the pistils.¹⁵ The activities of NADH- and NADPH-dependent oxidases (O₂⁻-forming enzymes), however, are known to be suppressed by cAMP¹⁶ and increase in the level of cAMP in guinea pig neutrophils results in their decreased expression.¹⁷ The level of O₂⁻ reactions with SOD is also decreased by cAMP.¹⁸ In the case of the lily, inhibition of NADH- and NADPH-dependent oxidases by cAMP was found to be noncompetitive with NAD(P)H.¹⁶ We hypothesized that decrease in active oxygen species such as O₂⁻ and suppression of stress enzyme activities in self-pollinated pistils of lily by cAMP might cause elongation of pollen tubes after self-pollination and this proved to be the case. Namely, elongation of pollen tubes after self-incompatible pollination in lily was promoted by exogenous cAMP at a concentration as low as 10 nM, a conceivable physiological level.¹³ Moreover, similar elongation could be achieved with adenylate cyclase activators [forskolin(FK) and cholera toxin] and cAMP phosphodiesterase inhibitors [3-isobutyl-1-methylxanthine (IBMX) and pertussis toxin].^14,19 These phenomena led us to examine the involvement of endogenous cAMP in pistils after self-incompatible or cross-compatible pollination. As expected, the level of endogenous cAMP in pistils after self-pollination was approximately one half of that after cross-pollination. Furthermore, this was associated with a concomitant decrease in adenylate cyclase and increase in cAMP phosphodiesterase.¹⁹Many researchers in the field of plant biology have been unsuccessful in attempts to estimate the quantity of cAMP and to detect activities of adenylate cyclase and cAMP phosphodiesterase. On major difficulty is the presence of proteases and we have overcome this problem by using protease inhibitors, such as aprotinin and leupeptin.¹⁹In 1947, acetylcholine (ACh) of higher plants was first reported in a nettle (Urtica urens) found in the Himalaya mountain range.²⁰ In 1983, its existence in plants was confirmed by mass spectrometry of preparations from Vigna seedlings.²¹ In our preliminary studies, CCC (chlorocholinechloride), a plant growth retardant (specifically an anti-gibberellin), enhanced the elongation of the pollen tubes in pistils after self-incompatible pollination in lilies. This led us to investigate whether other choline derivatives cause similar effects and positive findings were obtained with ACh, acetylthiocholine and L-α-phosphatidlylcholine.²² Moreover, the elongation was also promoted by neostigmine, an inhibitor of acetylcholine esterase (AChE) activity. In line with these results, choline acetyltransferase (ChAT) demonstrated low and AChE high activity in pistils after self-incompatible pollination.The positive influence of cAMP^14,19 and ACh²² in pistils of L. longiflorum after self-incompatible pollination encouraged us to examine the involvement of these two molecules in regulation of pollen tube elongation of lily after self-incompatible and cross-compatible pollination. As a result, it was revealed that cAMP promotes ChAT and suppresses AChE activity in pistils after both self- and cross-pollination. In other words, the self-incompatibilty in pistils of L. longiflorum appears to be due to levels of ACh and/or cAMP below certain threshold values.Hitherto, these substances have not been recognized to play important roles in the metabolic systems of higher plants. However, given their conservation through evolution, it is natural that such central metabolic substances make essential contributions, regardless of the organism. We have succeeded in establishing physiological functions of cAMP and ACh in pistils of lily^14,19,22 and this points to use of plant reproductive organs such as research materials. The exact responsibilities of the two molecules may depend on differences in tissues or organs of plants and further molecular biological studies in this area are clearly warranted. This issue is currently being investigated.     

A Distinct Pathway for Polar Exocytosis in Plant Cell Wall Formation

Post-Golgi protein sorting and trafficking to the plasma membrane (PM) is generally believed to occur via the trans-Golgi network (TGN). In this study using Nicotiana tabacum pectin methylesterase (NtPPME1) as a marker, we have identified a TGN-independent polar exocytosis pathway that mediates cell wall formation during cell expansion and cytokinesis. Confocal immunofluorescence and immunogold electron microscopy studies demonstrated that Golgi-derived secretory vesicles (GDSVs) labeled by NtPPME1-GFP are distinct from those organelles belonging to the conventional post-Golgi exocytosis pathway. In addition, pharmaceutical treatments, superresolution imaging, and dynamic studies suggest that NtPPME1 follows a polar exocytic process from Golgi-GDSV-PM/cell plate (CP), which is distinct from the conventional Golgi-TGN-PM/CP secretion pathway. Further studies show that ROP1 regulates this specific polar exocytic pathway. Taken together, we have demonstrated an alternative TGN-independent Golgi-to-PM polar exocytic route, which mediates secretion of NtPPME1 for cell wall formation during cell expansion and cytokinesis and is ROP1-dependent.Plant development and growth require coordinated tissue and cell polarization. Two of the most essential cellular processes involved in polarization are cell expansion and cytokinesis, which determines cell morphology and functions (Jaillais and Gaude, 2008; Dettmer and Friml, 2011; Li et al., 2012). Pollen tube and root hair growth require highly polarized membrane trafficking (Libault et al., 2010; Kroeger and Geitmann, 2012). Cytokinesis, by which new cells are formed, separates daughter cells by forming a new structure within the cytoplasm termed the cell plate (CP). Made up of a cell wall (CW), surrounded by new plasma membrane (PM), the cell plate is generally considered to be an example of internal cell polarity in a nonpolarized plant cell (Bednarek and Falbel, 2002; Baluska et al., 2006).The conventional view of pollen tube tip growth and cell plate formation is supported by polar exocytic secretion of numerous vesicles (diameter of 60–100 nm) to the pollen tube tip and phragmoplast areas during cytokinesis. These polar exocytic vesicles, which are generally believed to originate from the Golgi apparatus, are delivered to the site of secretion via the cytoskeleton and fuse with the target membrane with the aid of fusion factors (Jurgens, 2005; Backues et al., 2007). However, whether these polar exocytic vesicles undergoing post-Golgi trafficking are part of the conventional Golgi-trans-Golgi network (TGN)-PM/CP exocytosis or are derived from some other unidentified exocytic secretion pathway remain unclear.Polar exocytosis is regulated and controlled by a conserved Rho GTPase signaling network in fungi, animals, and plants (Burkel et al., 2012; Ridley, 2013). Rho of plant (ROP), the sole subfamily of Rho GTPases in plant, participate in signaling pathways that regulate cytoskeleton organization and endomembrane trafficking, consequently determining cell polarization, polar growth and cell morphogenesis (Gu et al., 2005; Lee et al., 2008). In growing pollen tubes, ROP1 participates in regulating polar exocytosis in the tip region via two downstream pathways to regulate apical F-actin dynamics: RIC4-mediated F-actin polymerization and RIC3-mediated apical actin depolymerization. A constitutively active mutant of ROP1 (CA-rop1) prevents fusion of these vesicles with the PM and enhances the accumulation of exocytic vesicles in the apical cortex of pollen tubes (Lee et al., 2008). Although ROP GTPases have been extensively researched, their roles in polar membrane expansion in pollen tubes and epidermal pavement cells remains unclear (Xu et al., 2010; Yang and Lavagi, 2012), and there have been insufficient studies on the functions of ROPs in controlling cell plate formation during cytokinesis. Cell division requires precise regulation and spatial organization of the cytoskeleton for delivery of secretion vesicles to the expanding cell plate (Molendijk et al., 2001).In addition, newly made cell walls during cell expansion and cell plate formation require sufficient plasticity in order to integrate new membrane materials to support the polarized membrane extension. They also should be strong enough to withstand the internal turgor pressure and thereby maintain the shape of the cell (Zonia and Munnik, 2011; Hepler et al., 2013). Recent studies have demonstrated that pectins are important for both cytokinesis and cell expansion (Moore and Staehelin, 1988; Bosch et al., 2005; Chebli et al., 2012; Altartouri and Geitmann, 2015; Bidhendi and Geitmann, 2016). Pectins are one of the major cell wall components of the middle lamella and primary cell wall. They are polymerized and methylesterified in the Golgi and subsequently released into the apoplastic space as “soft” methylesterified polymers. The homogalacturonan components of pectin are later de-methylesterified by pectin methylesterases (PMEs). The demethylesterified pectins can be cross-linked, interact with Ca²⁺, and finally form the “hard” pectin matrix of the cell wall. Therefore, the enzymatic activity of PMEs determines the rigidity of the cell wall (Micheli, 2001; Peaucelle et al., 2011).In Arabidopsis (Arabidopsis thaliana) and tobacco (Nicotiana tabacum) pollen tubes, PMEs are found predominantly polar localized in the tip region and determine the rigidity of the apical cell wall (Bosch et al., 2005; Jiang et al., 2005; Fayant et al., 2010; Chebli et al., 2012; Wang et al., 2013). PME isoform knockout mutants in Arabidopsis (AtPPME1 or vanguard1) produce unstable pollen tubes which burst when germinated in vitro and have reduced fertilization abilities (Jiang et al., 2005; Rockel et al., 2008). Recent studies have shown that in growing tobacco pollen tubes, polar targeting of NtPPME1 to the pollen tube apex depends on an apical F-actin mesh network (Wang et al., 2013). Although the functions of PME in cell wall constriction are well documented, the intracellular secretion and regulation mechanism of the exocytic process of PME still remain largely unexplored. In addition, pectins are also found to be abundant in the forming cell plate, raising the possibility that PMEs may also function during cell plate formation (Moore and Staehelin, 1988; Dhonukshe et al., 2006).In our study, we have used NtPPME1 as a marker to identify a polar exocytic process which is distinct from the conventional Golgi-TGN-PM exocytosis pathway in both pollen tube tip growth and cell plate formation. We have identified a Golgi-derived secretory vesicle (GDSV) for the polar secretion and targeting of NtPPME1 to the cell wall that bypasses the TGN during cell polarization. Further investigations using ROP1 mutants have shown that this polar exocytosis is ROP1 dependent.     

New insights into the functional roles of CrRLKs in the control of plant cell growth and development

Receptor-like kinases (RLKs) are a family of transmembrane proteins with a variable ligand-binding extracellular domain and a cytoplasmic kinase domain. In Arabidopsis, there are ∼600 RLKs believed to have diverse functions during plant growth, development and interactions with the environment. Based on the variable extracellular domain, RLKs can be classified into different subfamilies. The CrRLK subfamily contains 17 members in Arabidopsis and characterization of some of its members suggests a role for these proteins in the regulation of growth and reproduction. This review focuses on the roles of CrRLKs in the regulation of polarized growth with emphasis on the newly identified signal transduction pathways activated downstream of CrRLKs. A picture is emerging where CrRLKs are part of a conserved signal transduction cascade important for growth maintenance in different cell types.Key words: CrRLKs, FERONIA, RAC/ROP, ROS, polar growthThe ability of plants to perceive and process environmental and internal information into coordinated responses is crucial to their adaptability and survival in constantly changing environments. Most of signal perception occurs at the plasma membrane of cells where membrane-associated receptors receive signals to activate downstream signaling cascades that regulate growth and development. In plants and animals alike, receptor-like kinases (RLKs) mediate many of the signaling events at the cell surface and in the model plant Arabidopsis they comprise a monophyletic family with more than 600 members.¹ RLKs are transmembrane proteins with a variable N-terminal extracellular domain and a Ser/Thr intracellular kinase domain. The diversity of their extracellular domains suggests involvement in the transduction of a wide range of signals and allows them to be classified into different sub-families.² The CrRLK1L subfamily (from here on referred to as CrRLK) is named after the first member characterized in Catharanthus roseus cell cultures³ and contains 17 members in Arabidopsis.⁴ Several members of this family have now been implicated in growth regulatory processes.THESEUS1 (THE1) was identified through a suppressor screen of a cellulose-deficient mutant (prc1-1) which has a short hypocotyl phenotype.⁵ Loss of THE1 function resulted in reduced growth inhibition in the prc1-1 the1 double mutant. Interestingly, the the1 mutation itself has no effect in wild type background, thus leading to the suggestion that THE1 functions as a sensor of cell wall integrity in situations where the cell wall is weakened and organ elongation would be detrimental for the plant.^4,5A second CrRLK, FERONIA (FER), was first implicated in the regulation of female control of fertility. In the female gametophyte FER is involved in sensing pollen tube arrival and promoting its rupture which is necessary for double fertilization to occur.^6,7 FER is in fact involved in several processes depending on the tissue where it is expressed. In hypocotyls, FER is involved in the integration of ethylene and brassinosteroid (BR) signals to regulate hypocotyl elongation in the dark.⁸ Moreover, FER, THE1 and the closely related HERCULES1 (HERK1), were found to regulate cell elongation by interacting with BR signaling.⁹ More recently, roles for FER in the regulation of root hair development and fungal invasion have been established.^10,11 The pollen-specific ANXUR1 (ANX1) and ANXUR2 (ANX2) are closely related to FER and act redundantly to maintain pollen tube growth integrity during its journey through the style and ensure against precocious pollen tube rupture before reaching the ovule.^12,13Apparently with different biological roles, all the CrRLK members analyzed thus far have an effect on the growth of plant cells. The present review focuses on their role during cell growth with emphasis on polar cell growth and the downstream pathways activated by CrRLKs.     

The Cell Wall of the Arabidopsis Pollen Tube��Spatial Distribution, Recycling, and Network Formation of Polysaccharides

The pollen tube is a cellular protuberance formed by the pollen grain, or male gametophyte, in flowering plants. Its principal metabolic activity is the synthesis and assembly of cell wall material, which must be precisely coordinated to sustain the characteristic rapid growth rate and to ensure geometrically correct and efficient cellular morphogenesis. Unlike other model species, the cell wall of the Arabidopsis (Arabidopsis thaliana) pollen tube has not been described in detail. We used immunohistochemistry and quantitative image analysis to provide a detailed profile of the spatial distribution of the major cell wall polymers composing the Arabidopsis pollen tube cell wall. Comparison with predictions made by a mechanical model for pollen tube growth revealed the importance of pectin deesterification in determining the cell diameter. Scanning electron microscopy demonstrated that cellulose microfibrils are oriented in near longitudinal orientation in the Arabidopsis pollen tube cell wall, consistent with a linear arrangement of cellulose synthase CESA6 in the plasma membrane. The cellulose label was also found inside cytoplasmic vesicles and might originate from an early activation of cellulose synthases prior to their insertion into the plasma membrane or from recycling of short cellulose polymers by endocytosis. A series of strategic enzymatic treatments also suggests that pectins, cellulose, and callose are highly cross linked to each other.Upon contact with the stigma, the pollen grain swells through water uptake and develops a cellular protrusion, the pollen tube. During its growth in planta, the pollen tube invades the transmitting tissue of the pistil and finds its way to the ovary to deliver the male gametes for double fertilization to happen (Heslop-Harrison, 1987). Depending on the species, pollen tubes can grow extremely rapidly both in planta and in in vitro conditions. To fulfill its biological function, the pollen tube has to (1) adhere to and invade transmitting tissues (Hill and Lord, 1987; Lennon et al., 1998), (2) provide physical protection to the sperm cells, and (3) control its own shape and invasive behavior (Parre and Geitmann, 2005b; Geitmann and Steer, 2006). For all of these functions, the pollen tube cell wall plays an important regulatory and structural role. Although the pollen tube does not form a conventional secondary cell wall layer, its wall is assembled in two phases. The “primary layer” is mainly formed of pectins and other matrix components secreted at the apical end of the cell. The “secondary layer” is assembled by the deposition of callose in more distal regions of the cell (Heslop-Harrison, 1987). Depending on the species, cellulose microfibrils have been found to be associated either with the outer pectic or with the inner callosic layer. Unlike most other plant cells, cellulose is not very abundant representing only 10% of total neutral polysaccharides in Nicotiana alata pollen tubes, whereas callose accounts for more than 80% in this species (Schlüpmann et al., 1994).The biochemical composition of the pollen tube cell wall has been well characterized in many species such as Lilium longiflorum (Lancelle and Hepler, 1992; Jauh and Lord, 1996), tobacco (Nicotiana tabacum; Kroh and Knuiman, 1982; Geitmann et al., 1995; Ferguson et al., 1998; Derksen et al., 2011), Petunia hybrida (Derksen et al., 1999), Pinus sylvestris (Derksen et al., 1999), and Solanum chacoense (Parre and Geitmann, 2005a). But for Arabidopsis (Arabidopsis thaliana), the model for plant molecular biology studies (Arabidopsis Genome Initiative, 2000), there is a striking lack of quantitative information concerning the composition of the pollen tube cell wall as well as the spatial distribution of its components. This is all the more surprising because numerous mutants defective in enzymes involved in cell wall synthesis exhibit a pollen tube phenotype (for example, Jiang et al., 2005; Nishikawa et al., 2005; Wang et al., 2011). Two studies have characterized the Arabidopsis pollen germinating in vitro (Derksen et al., 2002) and in vivo (Lennon and Lord, 2000), but both are qualitative rather than quantitative. A biochemical study by Dardelle and coworkers investigated the cell wall sugar composition in a more quantitative way but does not provide any detailed spatial information (Dardelle et al., 2010; Lehner et al., 2010). This lack of information is not surprising given that until recently Arabidopsis pollen was known to be rather challenging to germinate reproducibly in vitro and more difficult to manipulate than the pollen of many other plant species (Bou Daher et al., 2009). With the publication of optimized methods for in vitro germination (Boavida and McCormick, 2007; Bou Daher et al., 2009), it has become much more feasible to germinate healthy-looking Arabidopsis pollen tubes in vitro in a highly reproducible way.The precisely controlled spatial distribution of biochemical components in the pollen tube cell wall is crucial for shape generation and maintenance of this perfectly cylindrical cell (Geitmann and Parre, 2004; Aouar et al., 2010; Fayant et al., 2010; Geitmann, 2010). The pollen tube, therefore, represents an ideal model system to study the link between intracellular signaling, biochemistry, cell mechanical properties, and morphogenesis in plant cells. Because of its typically fast growth rates, it responds quickly to any environmental triggers such as pharmacological, hormone, or enzymatic treatments. Adding Arabidopsis to the group of commonly studied pollen tube species is particularly timely, because one-third of the approximately 800 cell wall synthesis genes identified in this species are expressed in or are specific to its pollen (Pina et al., 2005). Therefore, the Arabidopsis pollen tube has become a valuable system for cell wall studies, especially with the increasing availability of cell wall mutant lines (Liepman et al., 2010).Here we describe the biochemical composition of the Arabidopsis pollen tube cell wall grown in in vitro conditions using immunocytochemical labeling coupled with epifluorescence and electron microscopic techniques. Rather than relying on imaging alone, we developed a quantitative strategy to assess the precise spatial distribution of cell wall components. This quantitative approach will provide an important tool and baseline dataset for the investigation of mutant phenotypes and for the interpretation of pharmacological studies. Furthermore, we used selective and strategically combined enzymatic digestions to determine the degree of connectivity between the individual types of cell wall polysaccharide networks.     

The Wurst protein: A novel endocytosis regulator involved in airway clearance and respiratory tube size control

The mammalian lung and the Drosophila airways are composed of an intricate network of epithelial tubes that transports fluids or gases and converts during late embryogenesis from liquid- to air-filling. Conserved growth factor pathways have been characterized in model organisms such as Drosophila or the mouse that control patterning and branching of tubular networks. In contrast, knowledge of the coordination of respiratory tube size and physiology is still limited. Latest studies have shown that endocytosis plays a major role in size determination and liquid clearance of the respiratory tubes and a new key regulator of these processes was identified, the Drosophila Wurst protein. wurst encodes a J-domain transmembrane protein which is essential for Clathrin-mediated endocytosis. It is evolutionary conserved and single Wurst orthologs are found in mammals (termed DNAJC22). In this commentary, we discuss the role of Wurst/DNA°C22 and address whether these proteins may be general regulators of Clathrin-mediated endocytosis.Key words: wurst, clathrin, endocytosis, liquid clearance, tube size, airways, drosophilaMany organs of the body, including the lung, the cardiovascular system, the liver and the kidney, consist of ramified networks of epithelial tubes. The proper size and shape of these tubes are crucial for their transport function since they affect flow rates of transported materials and are therefore important determinants of organ function. Genetic pathways controlling some of the early steps in development of branched tubular networks, including branch budding and tube formation, have been identified in the fruit fly Drosophila melanogaster. In the last decade it has turned out that many of the key growth regulators and signaling cascades bear an evolutionary conserved function in tubular network formation.¹ In contrast, knowledge of molecular processes that regulate and maintain distinct sizes and shapes of epithelial tubes is still scarce. During development of the airways, morphological and physiological processes, such as tube size determination and the transition from liquid-to air-filled tubes, occur in later stages of embryogenesis in Drosophila^2,3 or fetal development in mammals.⁴ In a clinical context, residual lung liquid at birth impairs oxygenation of the blood and severe fluid retention is an important feature of the neonatal respiratory distress syndrome, the most common cause of death among premature and newborn infants.⁴ Nevertheless, respiratory tube regulators that coordinate both tube morphology and physiology are mostly unknown.Using the Drosophila tracheal (respiratory) system as a model system, several genes that influence tube diameter and length have been identified. These include genes involved in the synthesis of a cylindrical chitin matrix secreted by tracheal cells and genes that encode chitin modifying enzymes.^5–10 Furthermore, regulators of septate junctions, the insect cognate of vertebrate tight junctions, are involved in determining tube morphogenesis.^11–15 Latest findings have now shown that endocytosis is crucial for both size determination and liquid clearance of respiratory tubes. By genetic screening, a new evolutionary conserved key regulator has been identified, the Drosophila wurst gene.     

Arabinogalactan proteins (AGPs) related to pollen tube guidance into the embryo sac in Arabidopsis

Some AGP molecules or their sugar moieties are probably related to the guidance of the pollen tube into the embryo sac, in the final part of its pathway, when arriving at the ovules. The specific labelling of the synergid cells and its filiform apparatus, which are the cells responsible for pollen tube attraction, and also the specific labelling of the micropyle and micropylar nucellus, which constitutes the pollen tube entryway into the embryo sac, are quite indicative of this role. We also discuss the possibility that AGPs in the sperm cells are probably involved in the double fertilization process.Key words: Arabidopsis, arabinogalactan proteins, AGP 6, gametic cells, pollen tube guidanceThe selective labelling obtained by us with monoclonal antibodies directed to the glycosidic parts of AGPs, in Arabidopsis and in other plant species, namely Amaranthus hypochondriacus,¹ Actinidia deliciosa² and Catharanthus roseus, shows that some AGP molecules or their sugar moieties are probably related to the guidance of the pollen tube into the embryo sac, in the final part of its pathway, when arriving at the ovules. The evaluation of the selective labelling obtained with AGP-specific monoclonal antibodies (Mabs) JIM 8, JIM 13, MAC 207 and LM 2, during Arabidopsis pollen development, led us to postulate that some AGPs, in particular those with sugar epitopes identified by JIM 8 and JIM 13, can be classified as molecular markers for generative cell differentiation and development into male gametes.Likewise, we also postulated that the AGP epitopes recognized by Mabs JIM 8 and JIM 13 are also molecular markers for the development of the embryo sac in Arabidopsis thaliana. Moreover, these AGP epitopes are also present along the pollen tube pathway, predominantly in its last stage, the micropyle, which constitutes the region of the ovule in the immediate vicinity of the pollen tube target, the embryo sac.³We have recently shown the expression of AGP genes in Arabidopsis pollen grains and pollen tubes and also the presence of AGPs along Arabidopsis pollen tube cell surface and tip region, as opposed to what had been reported earlier. We have also shown that only a subset of AGP genes is expressed in pollen grain and pollen tubes, with prevalence for Agp6 and Agp11, suggesting a specific and defined role for some AGPs in Arabidopsis sexual reproduction (Pereira et al., 2006).⁴Therefore we continued by using an Arabidopsis line expressing GFP under the command of the Agp6 gene promoter sequence. These plants were studied under a low-power binocular fluorescence microscope. GFP labelling was only observed in haploid cells, pollen grains (Fig. 1) and pollen tubes (Fig. 2); all other tissues clearly showed no labelling. These observations confirmed the specific expression of Agp6 in pollen grains and pollen tubes. As shown in the Figures 1 and ​and2,2, the labelling with GFP is present in all pollen tube extension, so probably, AGP 6 is not one of the AGPs identified by JIM 8 and JIM 13, otherwise GFP light emission would localize more specifically in the sperm cells.⁵ So we think that MAC 207 which labels the entire pollen tube wall (Fig. 3) may indeed be recognizing AGP6, which seems to be expressed in the vegetative cell. In other words, the specific labelling obtained for the generative cell and for the two male gametes, is probably given by AGPs that are present in very low quantities, apparently not the case for AGP 6 or AGP 11.Open in a separate windowFigure 1Low-power binocular fluorescence microscope image of an Arabidopsis flower with the AGP 6 promoter:GFP construct. The labelling is evident in pollen grains that are being released and in others that are already in the stigma papillae.Open in a separate windowFigure 2Low-power binocular fluorescence microscope image of an Arabidopsis ovary with the AGP6 promoter:GFP construct. The ovary was partially opened to show the pollen tubes growing in the septum, and into the ovules. The pollen tubes are also labelled by GFP.Open in a separate windowFigure 3Imunofluorescence image of a pollen tube growing in vitro, and labeled by MAC 207 monoclonal antibody. The labelling is evident all over the pollen tube wall.After targeting an ovule, the pollen tube growth arrests inside a synergid cell and bursts, releasing the two sperm cells. It has recently been shown that sperm cells, for long considered to be passive cargo, are involved in directing the pollen tube to its target. In Arabidopsis, HAP2 is expressed only in the haploid sperm and is required for efficient pollen tube guidance to the ovules.⁶ The same could be happening with the AGPs identified in the sperm cells by JIM 8 and JIM 13. We are now working on tagging these AGPs and using transgenic plants aiming to answer to such questions.Pollen tube guidance in the ovary has been shown to be in the control of signals produced by the embryo sac. When pollen tubes enter ovules bearing feronia or sirene mutations (the embryo sac is mutated), they do not stop growing and do not burst. In Zea mays a pollen tube attractant was recently identified in the egg apparatus and synergids.⁷ Chimeric ZmEA1 fused to green fluorescent protein (ZmEA1:GFP) was first visible within the filiform apparatus and later was localized to nucellar cell walls below the micropylar opening of the ovule. This is the same type of labelling that we have shown in Arabidopsis ovules, using Mabs JIM 8 and JIM 13. We are now involved in the identification of the specific AGPs associated with the labellings that we have been showing.     

Loss of LORELEI function in the pistil delays initiation but does not affect embryo development in Arabidopsis thaliana

Double fertilization, uniquely observed in plants, requires successful sperm cell delivery by the pollen tube to the female gametophyte, followed by migration, recognition and fusion of the two sperm cells with two female gametic cells. The female gametophyte not only regulates these steps but also controls the subsequent initiation of seed development. Previously, we reported that loss of LORELEI, which encodes a putative glycosylphosphatidylinositol (GPI)-anchored protein, in the female reproductive tissues causes a delay in initiation of seed development. From these studies, however, it was unclear if embryos derived from fertilization of lre-5 gametophytes continued to lag behind wild-type during seed development. Additionally, it was not determined if the delay in initiation of seed development had any lingering effects during seed germination. Finally, it was not known if loss of LORELEI function affects seedling development given that LORELEI is expressed in eight-day-old seedlings. Here, we showed that despite a delay in initiation, lre-5/lre-5 embryos recover, becoming equivalent to the developing wild-type embryos beginning at 72 hours after pollination. Additionally, lre-5/lre-5 seed germination, and seedling and root development are indistinguishable from wild-type indicating that loss of LORELEI is tolerated, at least under standard growth conditions, in vegetative tissues.Key words: LORELEI, glycosylphosphatidylinositol (GPI)-anchored protein, embryogenesis, DD45, seed germination, primary and lateral root growth, seedling developmentDouble fertilization is unique to flowering plants. Upon female gametophyte reception of a pollen tube, the egg and central cells of the female gametophyte fuse with the two released sperm cells to form zygote and endosperm, respectively and initiate seed development.¹ The female gametophyte controls seed development by (1) repressing premature central cell or egg cell proliferation until double fertilization is completed,^1–3 (2) supplying factors that mediate early stages of embryo and endosperm development^1,4,5 and (3) regulating imprinting of genes required for seed development.^1,6The molecular mechanisms underlying female gametophyte control of early seed development are poorly understood. Although much progress has been made in identifying genes and mechanisms by which the female gametophyte represses premature central cell or egg cell proliferation until double fertilization is completed and regulates imprinting of genes required for seed development,^1,6 only a handful of female gametophyte-expressed genes that affect early embryo^7,8 and endosperm⁹ development after fertilization have been characterized. This is particularly important given that a large number of female gametophyte-expressed genes likely regulate early seed development.⁵We recently reported on a mutant screen for plants with reduced fertility and identification of a mutant that contained a large number of undeveloped ovules and very few viable seeds.¹⁰ TAIL-PCR revealed that this mutant is a new allele of LORELEI(LRE) [At4g26466].^10,11 Four lre alleles have been reported;¹¹ so, this mutant was designated lre-5.¹⁰ The Arabidopsis LORELEI protein contains 165 amino acids and possesses sequence features indicative of a glycosylphosphatidylinositol (GPI)-anchor containing cell surface protein. GPI-anchors serve as an alternative to transmembrane domains for anchoring proteins in cell membranes and GPI-anchored proteins participate in many functions including cell-cell signaling.¹²     

Golgi-localized UDP-glucose transporter is required for cell wall integrity in rice

Cell wall-related nucleotide sugar transporters (NSTs) theoretically supply the cytosolic nucleotide sugars for glycosyltransferases (GTs) to carry out ploysaccharide synthesis and modification in the Golgi apparatus. However, the regulation of cell wall synthesis by NSTs remains undescribed. Recently, we have reported the functional characterization of Oryza sativa nucleotide sugar transport (Osnst1) mutant and its corresponding gene. OsNST1/BC14 is localized in the Golgi apparatus and transports UDP-glucose. This mutant provides us with a unique opportunity for evaluation of its broad impacts on cell wall structure and components. We previously examined cell wall composition of bc14 and wild type plants. Here, the spatial distribution of these cell wall alterations was analyzed by immunolabeling approach. Analysis of the sugar yield in different cell wall fractions indicated that this mutation improves the extractability of cell wall components. Field emission scanning electron microscopy further showed that the orientation of microfibrils in bc14 is irregular when compared to that in wild type. Therefore, this UDP-glucose transporter, making substrates available for polysaccharide biosynthesis, plays a critical role in maintaining cell wall integrity.Key words: UDP-glucose transporter, Golgi apparatus, cell wall polysaccharides, xylan, riceNucleotide sugars mainly generated in cytosol are the substrates for the synthesis of cell wall polysaccharides. Supply of nucleotide sugars is thus a key level for regulation of cell wall components and structure. Mutation in MUR1, an isoform of GDP-D-mannose-4,6-dehydratase, causes reduced amount of GDP-fucose and abnormal xyloglucan structure.^1,2 Disturbance of UDP-rhamnose synthesis via the mutation in RHM2/MUM4 decreases the rhamnogalacturonan I contents in Arabidopsis seeds. Cellulose synthase catalytic subunits (CESAs) generally use cytosolic UDP-glucoses to synthesize cellulose on the plasma membrane. UDP-glucose can be produced either via the catalysis of sucrose by sucrose synthase (SuSy) or through the phosphorylation of glucose-1-phosphate by UDP-glucose pyrophosphorylase (UGPase).³ Suppression of SuSy function in cotton inhibited fiber initiation and elongation.⁴ For the synthesis of noncellulosic polysaccharides occurring inside the Golgi lumen, the cytosolic nucleotide sugars should be translocated inwards by Golgi nucleotide sugar transporters (NSTs).⁵ However, this hypothesis remains to be confirmed, although transport activities have been identified in some plant NSTs.^6–10 Altering the precursor supply may also affect the overall carbon allocation in plants. It is reasonable that substrate regulation often causes pleiotropic effects on cell wall biosynthesis and plant growth. Without genetic resources or mutants on cell wall related NST, the exact evaluation of NSTs'' impacts on cell wall structure and composition is largely delayed. Until recently, we identified a Golgi-localized transporter OsNST1 mutant in rice. This transporter has been found to supply UDP-glucose for the formation of matrix polysaccharides, thereby modulating cellulose biosynthesis.¹¹ Here, we examine these alterations of cell wall polymers at the cellular level. The orientation of cellulose microfibrils and extractability of wall polysaccharides were also compared between the mutant and wild type. All those further our understandings of the functions of NSTs and the synergetic synthesis of different polymers.     

Nitric oxide and nitrite are likely mediators of pollen interactions

The ability of plants to produce nitric oxide (NO) is now well recognised. In plants, NO is involved in the control of organ development and in regulating some of their physiological functions. We have recently shown that pollen generates NO in a constitutive manner and have measured both intra- and extracellular production of this radical. Furthermore, we have shown that nitrite accumulates in the media surrounding the pollen and have suggested that the generation of these signaling molecules may be important for the normal interaction between the pollen grain and the stigma on which it alights. However, pollen grains inevitably come into contact with other tissues, including those of animals and it is likely that the NO produced will influence the behavior of the cells associated with these tissues. Such non-animal-derived, NO-mediated effects on mammalian cells may not be restricted to pollen and plant debris and fungal spore-derived NO may elicit similar effects.Key words: allergy, fungal spores, nitric oxide, nitrite, pollenNitric oxide (NO) has been recognised as a signaling molecule for 20+ years, but its roles in controlling cellular activity are far from fully understood. In plants, NO is involved in numerous biological processes¹ including seed germination,² floral development,³ the control of stomatal closure⁴ and root gravitropism⁵ and is also known to affect gene expression.⁶ Recently, we showed that pollen of Arabidopsis, Senecio and Tradescantia produces NO,⁷ and speculated that its role in this specific context is to help orchestrate early signaling events of the pollen-stigma interaction.^7,8 We subsequently showed that NO generation by pollen is more widespread among angiosperms and not just restricted to the species that were first investigated.⁹ Obviously, this intracellular generation of NO could influence the internal biochemistry of the pollen grain and pollen tube. However, for it to impact on other tissues, such as the stigma, on which the pollen grains alight during pollination, the NO generated would have to be released into the extracellular matrix.To demonstrate that pollen grains do indeed release NO to their surroundings we employed a water soluble derivative of the fluorescent NO probe, diaminofluorescein (DAF), to show that the 525 nm emission of the surrounding solution increased with time and that this fluorescence could be removed by scavenging the NO released from the pollen with compounds such as 2-phenyl-4,4,5,5,-tetramethylimidazoline-1-oxyl 3-oxide (PTIO). Thus, it is quite conceivable that, in vivo, NO produced by pollen moves into the extracellular matrix where it exerts an influence on the activity of cells in the adjacent tissues. Interestingly, in vitro rehydration of the pollen (analagous to the regulated hydration of pollen on the stigma) was needed before NO evolution could be measured. Normally, some form of specific stimulation, such as that which occurs either during pathogenesis¹⁰ or which results from the increased hormone levels observed during stomatal closure,¹¹ is required to initiate NO production by plant tissues. Thus, it is interesting here, that water appears to be the signaling cue to initiate constitutive NO release by the pollen.As a result of its free radical nature, NO is notoriously difficult to measure. As the chemistry involved in their reactivity has become better understood, doubts have been raised concerning the specificity of many of the fluorescent probes that have been used for its detection.¹² Commonly the fluorescent NO probe, DAF, is used, but similar alternative probes such as diamino-rhodamine (DAR) have recently also been described.¹³ Here, Figure 1 shows the NO-dependent fluorescence of DAR4M-AM-infused Brassica napus pollen and the associated temporal increase in the fluorescence of the extracellular medium containing a cell impermeable form of the dye. Despite the use of these different dye-based probes, it has still proved important to use other approaches to detect pollen NO production to refute the possibility that similarly reactive free radicals other than NO are responsible for the increased fluorescence observed. We have, therefore, confirmed our fluorescence measurements using electron paramagnetic resonance (EPR) techniques⁹ which have also indicated the presence of NO. Thus, the use of both fluorescent probe and EPR approaches point to the generation and release of NO from the pollen of all the plant species studied.Open in a separate windowFigure 1The diamino-rhodamine dyes, DAR4M-AM (cell permeable) and DAR4M (cell impermeable), can be used to detect intra- and extracellular pollen-derived nitric oxide (NO) respectively. Aqueous suspensions of Brassica napus sp. pollen were incubated for 15 min at room temp in 10 µM DAR4M-AM either without (A) or with (B) 200 µM of the NO scavenger, 2-(4-carboxyphenyl)-4,4,5,5-tetramethylimidazoline-1-oxyl-3-oxide (cPTIO). In each case, after removal of the excess dye and resuspension of the pollen in 10% (v/v) glycerol, the accumulated DAR4M-AM fluorescence signals within the pollen grains were detected by spinning disc, laser scanning, confocal microscopy with excitation at 560 nm and emission detection at 575 nm. The extracellular accumulation with time of the NO-associated fluorescence signal of the dye, DAR4M, in the media was also followed spectrophotometrically (C). Using the same excitation and emission detection wavelengths, the fluorescence of aqueous suspensions of the pollen in 10 µM DAR4M either without (Ci) or with (Cii) 200 “M cPTIO was monitored over a 10 min. period at room temp. The output fluorescence signal with time is presented in relative units.An additional NO detection technique based on ozone chemiluminescence was also used to confirm the data obtained.⁹ Unlike the fluorescence and EPR approaches which measure the accumulated production of NO, this method detects the steady-state levels of NO at any given time. However, as these levels proved to be very low and not readily detectable by this approach, we altered the assay conditions so as to measure the nitrite that accumulated as a result of NO oxidation in the extracellular media. While the nitrite that accumulated in the media could have done so as a result of being directly excreted by the pollen, the results obtained were in accordance with the earlier observations that pollen evolves NO.⁹ Neither should nitrite be dismissed as a mere downstream by-product. Not only is it the substrate for the production of NO by enzymes such as nitrate reductase,¹⁴ it can also act as a cell signaling molecule in its own right¹⁵ effecting increased cGMP production, increases in different cytochrome P450 activities and the induction of specific gene expression.Having established that pollen produces NO and nitrite, the mechanisms underlying their generation and subsequent signaling require determination. In mammalian cells the production of NO by a family of nitric oxide synthase enzymes is well understood.¹⁶ However, attempts to find plant homologues have so far proved unsuccessful, with the sole proposed candidate¹⁷ having now been shown to be a G protein.^18–20 Nitrate reductase is clearly one source of NO in plants,^11,14 but whether other enzymes exist which are similarly involved remains a matter for debate and discovery. Obviously, as plant NO synthesising enzymes are identified their function in the generation of NO and nitrite in pollen will need to be established.Originally,⁷ we suggested that pollen-derived NO is integral to the pollen-stigma interaction and this now needs to be determined. Nevertheless, the NO and nitrite released externally by pollen may also affect the cells of any moist tissues on which pollen grains land. Such cells may include, for example, those lining mammalian nasal passages. It is well established that NO helps orchestrate the activity of cells involved in human immune responses¹⁶ and this begs the question as to whether or not pollen-produced NO alters these responses during, for example, the onset of the symptoms of hayfever? Many plant cells produce NO, particular during stress and after wounding²¹ and damaged plant tissues that come into contact with human cells in environments that create such debris also have the potential to elicit similar responses. The reaction of mammalian cells to fungi, which are known to possess NOS enzymes²² and whose spores are a main contributor to asthma,²³ may also be similarly mediated.To conclude, pollen grains appear to generate both NO and nitrite constitutively. Determining the functional significance and ramifications of this production in terms of both endogenous and exogenous cell signaling is an important focus for future research.