The Actin Cytoskeleton and Signaling Network during Pollen Tube Tip Growth

The organization and dynamics of the actin cytoskeleton play key roles in many aspects of plant cell development. The actin cytoskeleton responds to internal developmental cues and en-vironmental signals and is involved in cell division, subcellular organelle movement, cell polarity and polar cell growth. The tip-growing pollen tubes provide an ideal model system to investigate fundamental mechanisms of underlying polarized cell growth. In this system, most signaling cascades required for tip growth, such as Ca~(2+)-, small GTPases- and lipid-mediated signaling have been found to be involved in transmitting signals to a large group of actin-binding proteins. These actin-binding proteins subsequently regulate the structure of the actin network, as well as the rapid turnover of actin filaments (F-actin), thereby eventually controlling tip growth. The actin cytoskeleton acts as an integrator in which multiple signaling pathways converge, providing a general growth and regulatory mechanism that applies not only for tip growth but also for polarized diffuse growth in plants.     

肌动蛋白在丝瓜花粉管顶端生长中的作用

用非固定荧光标记的鬼笔环肽作为肌动蛋白探针观察并证明了丝瓜未萌发的花粉粒和不同生长时期花粉管中肌动蛋白纤丝的分布及其形态变化。又用细胞松弛素B（CB）、氯两嗪（CPZ）及N-乙酰马来酰胺（NEM）证明了丝瓜花粉管伸长与肌动蛋白既有密切的关系,也受Ca2 的调节。     

花粉管钙信号特性及其调控研究进展

花粉管在花柱中生长受多个信号分子的协同调控,钙离子在其中发挥着重要作用.钙是一种重要的第二信使,它将外界的多种生物或非生物信息转化为对细胞内基因表达以及细胞生理反应的调控.钙信号表达方式是胞内自由钙浓度的特异性变化.该文对国内外近年来有关花粉管生长中钙信号特性及其调控的研究进展,如花粉管尖端自由钙离子浓度梯度与胞内钙振荡、花粉管质膜钙转运体的鉴定及其调控特性、花粉管钙信号与微丝和ROP蛋白的关系以及花粉管钙信号与植物自交不亲和性反应的关系等进行综述,为深入开展相关研究提供参考.     

Pollen Tube Cytoskeleton: Structure and Function

   apd: 3 July 2001     

Germination of Monocolpate Angiosperm Pollen: Evolution of the Actin Cytoskeleton and Wall during Hydration, Activation and Tube Emergence

The monocolpate pollen grain of Narcissus pseudonarcissus L.has two preferred sites for tube emergence, one at each endof the colpus. While the cellulosic microfibnls of the innerlayer of the intine are disposed circumferentially in the centreof the grain, the microfibrils in these terminal sites are shorterand randomly oriented Soon after the beginning of hydration,inclusions of the vegetative cell begin movement, firstly ina rotatory manner, and then in a pattern focused on one or bothgermination sites, where the intine bulges as hydration progresses.These changes are associated with the evolution of the actincytoskeleton. Actin is present in the unactivated grain in theform of fusiform bodies. During hydration these dissociate toform finer fibrils, initially randomly disposed. Then, correlatedwith the change of the pattern of movement in the vegetativecell, the actin fibril system becomes polarized towards thegermination sites, where shorter fibrils accumulate. Callose,absent from the ungerminated grain, is deposited within thecellulosic wall in these locations, forming a shallow dome whicheventually develops into an annulus subtending the inner calloselining of the emerging tube. The transition to cylindrical growthis associated firstly with the development of zonation in thecytoplasm of the vegetative cell, with the tip occupied by apopulation of wall precursor bodies (P-particles) and a denseaggregate of short actin fibrils; and then with the establishmentof the ‘inverse fountain’ pattern of movement characteristicof the apical part of the extending tube. Narcissus pseudonarcissus L, pollen activation, pollen germination, actin cytoskeleton, tip-growth system, pollen-tube wall development     

花粉管细胞结构与生长机制研究进展

花粉管的极性顶端生长是一个复杂的动力学过程, 在高等植物有性生殖过程中起着重要的作用。花粉管的生长过程包括许多方面, 其中最为重要的是花粉管细胞骨架动态和胞质运动。本文较全面地综述了花粉管的结构、细胞骨架、胞质运动、囊泡转运及循环、线粒体运动以及内质网和高尔基体之间囊泡运动等。     

花粉管细胞结构与生长机制研究进展

花粉管的极性顶端生长是一个复杂的动力学过程,在高等植物有性生殖过程中起着重要的作用。花粉管的生长过程包括许多方面,其中最为重要的是花粉管细胞骨架动态和胞质运动。本文较全面地综述了花粉管的结构、细胞骨架、胞质运动、囊泡转运及循环、线粒体运动以及内质网和高尔基体之间囊泡运动等。     

PLC—IP3信号途径参与花粉管伸长调控的显微注射实验

以百合（Ｌｉｌｉｕｍ ｄａｖｉｄｉｉ Ｄｕｃｈ．）花粉为材料,通过显微注射肌醇磷脂信使系统中重要组成成分或其抗体,研究该信使系统牟花粉管伸长的影响。发现显微注射动物来源磷脂酶Ｃ（ＰＬＣ）β１－３抗体显著抑制花粉管的伸长生长,而注射ＰＬＣβ４抗体对花粉管伸长无影响;显微注射三磷酸肌醇（ＩＰ３）,可显著促进花粉管伸长生长;显微注射动物来源的ＩＰ３Ｒ２、ＩＰ３Ｒ３抗体可显著抑制花粉管伸长生长,而注射ＩＰ     

The Involvement of PLC-IP3 Signaling Pathway in Pollen Tube Growth

The effect of phospholipase C (PLC) signaling pathway on lily (Lilium davidii Duch.) pollen tube elongation was examined by means of microinjection. Pollen tube elongation was inhibited by microinjecting antibodies against animal PLCβ1-3 or inositol-1,4,5-triphosphate receptor （IP3R2, 3）, but was not affected by antibodies against animal PLCβ4 or IP3R1. Pollen tube elongation was also stimulated significantly by microinjecting IP3. The results suggest that PLC-IP3 signaling pathway might present in pollen system and be involved in pollen tube growth.     

mTORC2调节细胞骨架的信号通路

近几年来,关于哺乳动物雷帕霉素靶（mammalian target of rapamycin,mTOR）在各种哺乳动物细胞中调节肌动蛋白微丝极化及肌球蛋白微丝网形成的研究一直在不断地取得新的进展。尽管到目前为止,包括mTORC2上游和下游在内的相关的调控路径还未明确,但是因为mTORC6,的物学多样性,使其成为了当今生物学研究的焦点之一。基于长久以来特别是近五年对mTORC2的研究,在涉及细胞运动迁移、增殖分化、蛋白质合成、凋亡及自噬等生物学功能的研究中,一些重要的下游相关调控分子和蛋白相继被发现,比如P—Rexl／2、Rho家族GTPases、PKC、cAMP、p27kip1等。该综述着重总结了mTORC2实现这些生物学功能所可能通过的四条路径。当然,仍然需要大量的实验数据和研究证据进一步地证实和完善这些已经发现的可能存在的路径。     

肌醇磷脂信号组分调节花粉发育和花粉管生长的研究进展

肌醇磷脂信号系统以肌醇磷脂代谢循环为基础, 由多种磷酸磷脂酰肌醇分子和多磷酸肌醇分子及催化代谢的磷脂酶、激酶组成。该信号系统参与调节动、植物细胞生长发育及应答环境刺激等多种生理过程。花粉发育和花粉管的生长是植物有性生殖的基础, 肌醇磷脂信号系统中多种组分参与其生理过程的调节。该文综述了植物肌醇磷脂信号系统中各组分的相互关系, 以及相关组分调节花粉发育和花粉管生长生理过程的研究进展。     

Confocal Microscopy Observations on Actin Cytoskeleton in the Pollen and Pollen Protoplast of Narcissus

Actin cytoskeleton was localized in the pollen and pollen protoplast of Narcissus cyclamineus using fluorescence labelled phalloidin andconfocal microscopy. In the hydrated pollen (before germination) actin filamem bundles were arranged in a parallel array and at right angles to the long axis of the pollen grain in the cortex. But at the germination pore region(or fur row) the actin filament bundles formed a reticulate network. In the centre of the grain there was also an actin filament network which was more open and had less bundles associated with it than the network underneath the furrow. When the pollen grain started to produce pollen tube, most(if not all) of the actin filament bundles in the pollen grain rearranged into a parallel array pointing towards the tube. The bundles in the array later elongated and extended into the pollen tube. In the pollen protoplast a very tightly-packed actin bundle network was present. Numerous branches and jonts of actin filament bundles could be seen in the network. If the protoplasts were fixed before staining, the bundles aggregated and the branches and joints became less obvious indicating that fixation had affected the nature and arrangement of the actin filament bundles. If the pollen protoplasts were bursted (using the osmotic shock technique) or extracted (using Triton X-100), fragments of actin filament bundles could still be found associated with the membrane ghost indicating that some of the actin filament bundles in the cortex were tightly attached to the membrane. Using a double staining technique, actin filaments and microtubules were co-localized in the pollen protoplast. The co-alignment of some of the actin filament bundles with the microtubule bundles suggested that the actin cytoskeleton and the microtubule cytoskeleton were not distributed at random but in a well organized and orchestrated manner [possibly under the control of a yet undiscovered structure(s). The actin filament cytoskeleton in the generative cells failed to stain either in pollen or pollen tube, but they became stained in the pollen protoplast. The actin cytoskeleton in the generative cell appeared as a loosely organized network made up of short and long actin filament bundles.     

Actin Cytoskeleton: A Team Effort during Actin Assembly

Two recent studies highlight how tandems of previously described actin nucleators collaborate to produce new actin filaments. One key player in these collaborations is formin, which appears to function as a modulator of filament elongation.     

Arabidopsis ACTIN-DEPOLYMERIZING FACTOR7 Severs Actin Filaments and Regulates Actin Cable Turnover to Promote Normal Pollen Tube Growth

Actin filaments are often arranged into higher-order structures, such as the longitudinal actin cables that generate the reverse fountain cytoplasmic streaming pattern present in pollen tubes. While several actin binding proteins have been implicated in the generation of these cables, the mechanisms that regulate their dynamic turnover remain largely unknown. Here, we show that Arabidopsis thaliana ACTIN-DEPOLYMERIZING FACTOR7 (ADF7) is required for turnover of longitudinal actin cables. In vitro biochemical analyses revealed that ADF7 is a typical ADF that prefers ADP-G-actin over ATP-G-actin. ADF7 inhibits nucleotide exchange on actin and severs filaments, but its filament severing and depolymerizing activities are less potent than those of the vegetative ADF1. ADF7 primarily decorates longitudinal actin cables in the shanks of pollen tubes. Consistent with this localization pattern, the severing frequency and depolymerization rate of filaments significantly decreased, while their maximum lifetime significantly increased, in adf7 pollen tube shanks. Furthermore, an ADF7–enhanced green fluorescent protein fusion with defective severing activity but normal G-actin binding activity could not complement adf7, providing compelling evidence that the severing activity of ADF7 is vital for its in vivo functions. These observations suggest that ADF7 evolved to promote turnover of longitudinal actin cables by severing actin filaments in pollen tubes.     

Arabidopsis Microtubule-Destabilizing Protein 25 Functions in Pollen Tube Growth by Severing Actin Filaments

The formation of distinct actin filament arrays in the subapical region of pollen tubes is crucial for pollen tube growth. However, the molecular mechanisms underlying the organization and dynamics of the actin filaments in this region remain to be determined. This study shows that Arabidopsis thaliana MICROTUBULE-DESTABILIZING PROTEIN25 (MDP25) has the actin filament–severing activity of an actin binding protein. This protein negatively regulated pollen tube growth by modulating the organization and dynamics of actin filaments in the subapical region of pollen tubes. MDP25 loss of function resulted in enhanced pollen tube elongation and inefficient fertilization. MDP25 bound directly to actin filaments and severed individual actin filaments, in a manner that was dramatically enhanced by Ca²⁺, in vitro. Analysis of a mutant that bears a point mutation at the Ca²⁺ binding sites demonstrated that the subcellular localization of MDP25 was determined by cytosolic Ca²⁺ level in the subapical region of pollen tubes, where MDP25 was disassociated from the plasma membrane and moved into the cytosol. Time-lapse analysis showed that the F-actin-severing frequency significantly decreased and a high density of actin filaments was observed in the subapical region of mdp25-1 pollen tubes. This study reveals a mechanism whereby calcium enhances the actin filament–severing activity of MDP25 in the subapical region of pollen tubes to modulate pollen tube growth.     

Calcium Channel Activity during Pollen Tube Growth and Reorientation

We have shown previously that the inhibition of pollen tube growth and its subsequent reorientation in Agapanthus umbellatus are preceded by an increase in cytosolic free calcium ([Ca2+]c), suggesting a role for Ca2+ in signaling these processes. In this study, a novel procedure was used to measure Ca2+ channel activity in living pollen tubes subjected to various growth reorienting treatments (electrical fields and ionophoretic microinjection). The method involves adding extracellular Mn2+ to quench the fluorescence of intracellular Indo-1 at its ca2+-insensitive wavelength (isosbestic point). The spatial and temporal kinetics of Ca2+ channel activity correlated well with measurements of [Ca2+]c dynamics obtained by fluorescence ratio imaging of Indo-1. Tip-focused gradients in Ca2+ channel activity and [Ca2+]c were observed and quantified in growing pollen tubes and in swollen pollen tubes before reoriented growth. In nongrowing pollen tubes, Ca2+ channel activity was very low and [Ca2+]c gradients were absent. Measurements of membrane potential indicated that the growth reorienting treatments induced a depolarization of the plasma membrane, suggesting that voltage-gated Ca2+ channels might be activated.     

Arabidopsis RIC1 Severs Actin Filaments at the Apex to Regulate Pollen Tube Growth

Pollen tubes deliver sperms to the ovule for fertilization via tip growth. The rapid turnover of F-actin in pollen tube tips plays an important role in this process. In this study, we demonstrate that Arabidopsis thaliana RIC1, a member of the ROP-interactive CRIB motif-containing protein family, regulates pollen tube growth via its F-actin severing activity. Knockout of RIC1 enhanced pollen tube elongation, while overexpression of RIC1 dramatically reduced tube growth. Pharmacological analysis indicated that RIC1 affected F-actin dynamics in pollen tubes. In vitro biochemical assays revealed that RIC1 directly bound and severed F-actin in the presence of Ca²⁺ in addition to interfering with F-actin turnover by capping F-actin at the barbed ends. In vivo, RIC1 localized primarily to the apical plasma membrane (PM) of pollen tubes. The level of RIC1 at the apical PM oscillated during pollen tube growth. The frequency of F-actin severing at the apex was notably decreased in ric1-1 pollen tubes but was increased in pollen tubes overexpressing RIC1. We propose that RIC1 regulates F-actin dynamics at the apical PM as well as the cytosol by severing F-actin and capping the barbed ends in the cytoplasm, establishing a novel mechanism that underlies the regulation of pollen tube growth.     

FIMBRIN1 Is Involved in Lily Pollen Tube Growth by Stabilizing the Actin Fringe

An actin fringe structure in the subapex plays an important role in pollen tube tip growth. However, the precise mechanism by which the actin fringe is generated and maintained remains largely unknown. Here, we cloned a 2606-bp full-length cDNA encoding a deduced 77-kD fimbrin-like protein from lily (Lilium longiflorum), named FIMBRIN1 (FIM1). Ll-FIM1 was preferentially expressed in pollen and concentrated at actin fringe in the subapical region, as well as in longitudinal actin-filament bundles in the shank of pollen tubes. Microinjection of Ll-FIM1 antibody into lily pollen tubes inhibited tip growth and disrupted the actin fringe. Furthermore, we verified the function of Ll-FIM1 in the fim5 mutant of its closest relative, Arabidopsis thaliana. Pollen tubes of fim5 mutants grew with a larger diameter in early stages but could recover into normal forms in later stages, despite significantly slower growth rates. The actin fringe of the fim5 mutants, however, was impaired during both early and late stages. Impressively, stable expression of fim5pro:GFP:Ll-FIM1 rescued the actin fringe and the growth rate of Arabidopsis fim5 pollen tubes. In vitro biochemical analysis showed that Ll-FIM1 could bundle actin filaments. Thus, our study has identified a fimbrin that may stabilize the actin fringe by cross-linking actin filaments into bundles, which is important for proper tip growth of lily pollen tubes.     

The Apical Actin Fringe Contributes to Localized Cell Wall Deposition and Polarized Growth in the Lily Pollen Tube

In lily (Lilium formosanum) pollen tubes, pectin, a major component of the cell wall, is delivered through regulated exocytosis. The targeted transport and secretion of the pectin-containing vesicles may be controlled by the cortical actin fringe at the pollen tube apex. Here, we address the role of the actin fringe using three different inhibitors of growth: brefeldin A, latrunculin B, and potassium cyanide. Brefeldin A blocks membrane trafficking and inhibits exocytosis in pollen tubes; it also leads to the degradation of the actin fringe and the formation of an aggregate of filamentous actin at the base of the clear zone. Latrunculin B, which depolymerizes filamentous actin, markedly slows growth but allows focused pectin deposition to continue. Of note, the locus of deposition shifts frequently and correlates with changes in the direction of growth. Finally, potassium cyanide, an electron transport chain inhibitor, briefly stops growth while causing the actin fringe to completely disappear. Pectin deposition continues but lacks focus, instead being delivered in a wide arc across the pollen tube tip. These data support a model in which the actin fringe contributes to the focused secretion of pectin to the apical cell wall and, thus, to the polarized growth of the pollen tube.Pollen tubes provide an excellent model for studying the molecular and physiological processes that lead to polarized cell growth. Because all plant cell growth results from the regulated yielding of the cell wall in response to uniform turgor pressure (Winship et al., 2010; Rojas et al., 2011), the cell wall of the pollen tube must yield only at a particular spot: the cell apex, or tip. To accomplish the extraordinary growth rates seen in many species, and to balance the thinning of the apical wall due to rapid expansion, the pollen tube delivers prodigious amounts of wall material, largely methoxylated pectins, to the tip in a coordinated manner. Recent studies suggest that the targeted exocytosis increases the extensibility of the cell wall matrix at the tip, which then yields to the existing turgor pressure, permitting the tip to extend or grow (McKenna et al., 2009; Hepler et al., 2013). There are many factors that influence exocytosis in growing pollen tubes; in this study, we investigate the role of the apical actin fringe.For many years, it has been known that an actin structure exists near the pollen tube tip, yet its exact form has been a matter of some contention (Kost et al., 1998; Lovy-Wheeler et al., 2005; Wilsen et al., 2006; Cheung et al., 2008; Vidali et al., 2009; Qu et al., 2013). The apical actin structure has been variously described as a fringe, a basket, a collar, or a mesh. Using rapid freeze fixation of lily (Lilium formosanum) pollen tubes followed by staining with anti-actin antibodies, the structure appears as a dense fringe of longitudinally oriented microfilaments, beginning 1 to 5 µm behind the apex and extending 5 to 10 µm basally. The actin filaments are positioned in the cortical cytoplasm close to the plasma membrane (Lovy-Wheeler et al., 2005). More recently, we used Lifeact-mEGFP, a probe that consistently labels this palisade of longitudinally oriented microfilaments in living cells (Vidali et al., 2009; Fig. 1A, left column). For the purposes of this study, we will refer to this apical organization of actin as a fringe.Open in a separate windowFigure 1.The actin fringe and the thickened pollen tube tip wall are stable, although dynamic, structures during pollen tube growth. A, The left column shows a pollen tube transformed with Lifeact-mEGFP imaged with a spinning-disc confocal microscope. Maximal projections from every 15 s are shown. The right column shows epifluorescence images of a pollen tube stained with PI. Again, images captured every 15 s are shown. Bars = 10 μm. B, The data from the pollen tube in A expressing Lifeact-mEGFP were subjected to kymograph analysis using an 11-pixel strip along the image’s midline. C, The first three frames from the pollen tube in A and B were assigned the colors red, blue, and green, respectively, and then overlaid. Areas with white show the overlap of all three. The fringe is stable, but most of its constituent actin is not shared between frames.Many lines of evidence demonstrate that actin is required for pollen tube growth. Latrunculin B (LatB), which blocks actin polymerization, inhibits pollen tube growth and disrupts the cortical fringe at concentrations as low as 2 nm. Higher concentrations are needed to block pollen grain germination and cytoplasmic streaming (Gibbon et al., 1999; Vidali et al., 2001). Actin-binding proteins, including actin depolymerizing factor-cofilin, formin, profilin, and villin, and signaling proteins, such as Rho-of-Plants (ROP) GTPases and their effectors (ROP interacting crib-containing proteins [RICs]), also have been shown to play critical roles in growth and actin dynamics (Fu et al., 2001; Vidali et al., 2001; Allwood et al., 2002; Chen et al., 2002; Cheung and Wu, 2004; McKenna et al., 2004; Gu et al., 2005; Ye et al., 2009; Cheung et al., 2010; Staiger et al., 2010; Zhang et al., 2010a; Qu et al., 2013; van Gisbergen and Bezanilla, 2013).Our understanding of the process of exocytosis and pollen tube elongation has been influenced by ultrastructural images of pollen tube tips, which reveal an apical zone dense with vesicles (Cresti et al., 1987; Heslop-Harrison, 1987; Lancelle et al., 1987; Steer and Steer, 1989; Lancelle and Hepler, 1992; Derksen et al., 1995). It has long been assumed that these represent exocytotic vesicles destined to deliver new cell wall material. This model of polarized secretion has been challenged in recent years in studies using FM dyes. Two groups have suggested that exocytosis occurs in a circumpolar annular zone (Bove et al., 2008; Zonia and Munnik, 2008). However, other studies, using fluorescent beads attached to the cell surface, indicate that the maximal rate of expansion, and of necessity the greatest deposition of cell wall material, occurs at the apex along the polar axis of the tube (Dumais et al., 2006; Rojas et al., 2011). Similarly, our experiments with propidium iodide (PI; McKenna et al., 2009; Rounds et al., 2011a) and pectin methyl esterase fused to GFP (McKenna et al., 2009) show that the wall is thickest at the very tip and suggest that wall materials are deposited at the polar axis, consistent with the initial model of exocytosis (Lancelle and Hepler, 1992). Experiments using tobacco (Nicotiana tabacum) pollen and a receptor-like kinase fused to GFP also indicate that exocytosis occurs largely at the apical polar axis (Lee et al., 2008).Many researchers argue that apical actin is critical for exocytosis (Lee et al., 2008; Cheung et al., 2010; Qin and Yang, 2011; Yan and Yang, 2012). More specifically, recent work suggests that the fringe participates in targeting vesicles and thereby contributes to changes in growth direction (Kroeger et al., 2009; Bou Daher and Geitmann, 2011; Dong et al., 2012). In this article, using three different inhibitors, namely brefeldin A (BFA), LatB, and potassium cyanide (KCN), we test the hypothesis that polarized pectin deposition in pollen tubes requires the actin fringe. Our data show that during normal growth, pectin deposition is focused to the apex along the polar axis of the tube. However, when growth is modulated, different end points arise, depending on the inhibitor. With BFA, exocytosis stops completely, and the fringe disappears, with the appearance of an actin aggregate at the base of the clear zone. LatB, as shown previously (Vidali et al., 2009), incompletely degrades the actin fringe and leaves a rim of F-actin around the apical dome. Here, we show that, in the presence of LatB, pectin deposition continues, with the focus of this activity shifting in position frequently as the slowly elongating pollen tube changes direction. With KCN, the actin fringe degrades completely, but exocytosis continues and becomes depolarized, with pectin deposits now occurring across a wide arc of the apical dome. This dome often swells as deposition continues, only stopping once normal growth resumes. Taken together, these results support a role for the actin fringe in controlling the polarity of growth in the lily pollen tube.