Rop GTPase-dependent dynamics of tip-localized F-actin controls tip growth in pollen tubes

Tip-growing pollen tubes provide a useful model system to study polar growth. Although roles for tip-focused calcium gradient and tip-localized Rho-family GTPase in pollen tube growth is established, the existence and function of tip-localized F-actin have been controversial. Using the green fluorescent protein-tagged actin-binding domain of mouse talin, we found a dynamic form of tip-localized F-actin in tobacco pollen tubes, termed short actin bundles (SABs). The dynamics of SABs during polar growth in pollen tubes is regulated by Rop1At, a Rop GTPase belonging to the Rho family. When overexpressed, Rop1At transformed SAB into a network of fine filaments and induced a transverse actin band behind the tip, leading to depolarized growth. These changes were due to ectopic Rop1At localization to the apical region of the plasma membrane and were suppressed by guanine dissociation inhibitor overexpression, which removed ectopically localized Rop1At. Rop GTPase-activating protein (RopGAP1) overexpression, or Latrunculin B treatments, also recovered normal actin organization and tip growth in Rop1At-overexpressing tubes. Moreover, overexpression of RopGAP1 alone disrupted SABs and inhibited growth. Finally, SAB oscillates and appears at the tip before growth. Together, these results indicate that the dynamics of tip actin are essential for tip growth and provide the first direct evidence to link Rho GTPase to actin organization in controlling cell polarity and polar growth in plants.     

Actin-depolymerizing factor mediates Rac/Rop GTPase-regulated pollen tube growth

Pollen tube elongation is a rapid tip growth process that is driven by a dynamic actin cytoskeleton. A ubiquitous family of actin binding proteins, actin-depolymerizing factors (ADFs)/cofilins, bind to actin filaments, induce severing, enhance depolymerization from their slow-growing end, and are important for maintaining actin dynamics in vivo. ADFs/cofilins are regulated by multiple mechanisms, among which Rho small GTPase-activated phosphorylation at a terminal region Ser residue plays an important role in regulating their actin binding and depolymerizing activity, affecting actin reorganization. We have shown previously that a tobacco pollen-specific ADF, NtADF1, is important for maintaining normal pollen tube actin cytoskeleton organization and growth. Here, we show that tobacco pollen grains accumulate phosphorylated and nonphosphorylated forms of ADFs, suggesting that phosphorylation could be a regulatory mechanism for their activity. In plants, Rho-related Rac/Rop GTPases have been shown to be important regulators for pollen tube growth. Overexpression of Rac/Rop GTPases converts polar growth into isotropic growth, resulting in pollen tubes with ballooned tips and a disrupted actin cytoskeleton. Using the Rac/Rop GTPase-induced defective pollen tube phenotype as a functional assay, we show that overexpression of NtADF1 suppresses the ability of NtRac1, a tobacco Rac/Rop GTPase, to convert pollen tube tip growth to isotropic growth. This finding suggests that NtADF1 acts in a common pathway with NtRac1 to regulate pollen tube growth. A mutant form of NtADF1 with a nonphosphorylatable Ala substitution at its Ser-6 position [NtADF1(S6A)] shows increased activity, whereas the mutant NtADF1(S6D), which has a phospho-mimicking Asp substitution at the same position, shows reduced ability to counteract the effect of NtRac1. These observations suggest that phosphorylation at Ser-6 of NtADF1 could be important for its integration into the NtRac1 signaling pathway. Moreover, overexpression of NtRac1 diminishes the actin binding activity of green fluorescent protein (GFP)-NtADF1 but has little effect on the association of GFP-NtADF1(S6A) with actin cables in pollen tubes. Together, these observations suggest that NtRac1-activated activity regulates the actin binding and depolymerizing activity of NtADF1, probably via phosphorylation at Ser-6. This notion is further supported by the observation that overexpressing a constitutively active NtRac1 in transformed pollen grains significantly increases the ratio of phosphorylated to nonphosphorylated ADFs. Together, the observations reported here strongly support the idea that NtRac1 modulates NtADF1 activity through phosphorylation at Ser-6 to regulate actin dynamics.     

Imaging the actin cytoskeleton in growing pollen tubes

Given the importance of the actin cytoskeleton to pollen tube growth, we have attempted to decipher its structure, organization and dynamic changes in living, growing pollen tubes of Nicotiana tabacum and Lilium formosanum, using three different GFP-labeled actin-binding domains. Because the intricate structure of the actin cytoskeleton in rapidly frozen pollen tubes was recently resolved, we now have a clear standard against which to compare the quality of labeling produced by these GFP-labeled probes. While GFP-talin, GFP-ADF and GFP-fimbrin show various aspects of the actin cytoskeleton structure, each marker produces a characteristic pattern of labeling, and none reveals the entire spectrum of actin. Whereas GFP-ADF, and to a lesser extent GFP-talin, label the fringe of actin in the apex, no similar structure is observed with GFP-fimbrin. Further, GFP-ADF only occasionally labels actin cables in the shank of the pollen tube, whereas GFP-fimbrin labels an abundance of fine filaments in this region, and GFP-talin bundles actin into a central cable in the core of the pollen tube surrounded by a few finer elements. High levels of expression of GFP-talin and GFP-fimbrin frequently cause structural rearrangements of the actin cytoskeleton of pollen tubes, and inhibit tip growth in a dose dependent manner. Most notably, GFP-talin results in thick cortical hoops of actin, transverse to the axis of growth, and GFP-fimbrin causes actin filaments to aggregate. Aberrations are seldom seen in pollen tubes expressing GFP-ADF. Although these markers are valuable tools to study the structure of the actin cytoskeleton of growing pollen tubes, given their ability to cause aberrations and to block pollen tube growth, we urge caution in their use. Electronic Supplementary Material Supplementary material is available for this article at and is accessible for authorized users. Financial Source: National Science Foundation grant Nos. MCB-0077599 and MCB-0516852 to PKH EU Research Training Network TIPNET (project HPRN-CT-2002-00265), Brussels, Belgium, to BV     

Arabidopsis LIM proteins PLIM2a and PLIM2b regulate actin configuration during pollen tube growth

The pollen tube grows rapidly, exclusively at its tip, to deliver its sperm for fertilization. The polarized tip growth of pollen tubes is dependent on the highly dynamic actin cytoskeleton. Plant LIM proteins (named after initials of containing proteins Lin11, Isl-1, and Mec-3) have been shown to regulate actin bundling in different cells, however, their roles in pollen tube growth have remained obscure. Here, we report the function of Arabidopsis LIM proteins PLIM2a and PLIM2b in pollen tube growth. The PLIM2a mutation resulted in short and swollen Arabidopsis pollen tube with defective actin bundles. The expression of the construct green fluorescent protein (GFP)-PLIM2b led to fluorescence of the actin bundles in germinating pollen and also the long actin bundles along the growing pollen tubes in Arabidopsis, but not of the short and sparse actin bundles that characterize the tip regions of the pollen tubes. There is a partially redundant function between PLIM2a and PLIM2b in the shank actin bundle organization during Arabidopsis pollen tube growth, as PLIM2b could rescue for the defective shank actin bundles in PLIM2a mutation pollen tubes. This report suggests critical roles of PLIM2a/PLIM2b in actin configuration during Arabidopsis pollen germination and tube growth.     

Microinjection of Guanine NucleotideAnalogues into Lily Pollen Tubes Results in Isodiametric TipExpansion

Abstract: Heterotrimeric and small G-proteins aresupposed to participate in tip growth of plant cells. Quantitative changes intip growth rate after introduction of non-hydrolysable guanine nucleotideanalogues (NA) into lily pollen tubes have been interpreted as support for thehypothesis that heterotrimeric G-proteins regulate tube elongation (Ma et al.,1999 IDREF="R243-11">11). Here, we report that microinjection of guanineNA into lily pollen tubes causes loss of growth polarity, resulting inisodiametric tip swelling. Our results are compatible with current modelssuggesting an involvement of plant Rho-related small G-proteins (Rop) in themaintenance of pollen tube polarity and in tip morphogenesis.     

Control of pollen tube tip growth by a Rop GTPase-dependent pathway that leads to tip-localized calcium influx.

We have shown that Rop1At, a pollen-specific Rop GTPase that is a member of the Rho family of small GTP binding proteins, acts as a key molecular switch controlling tip growth in Arabidopsis pollen tubes. Pollen-specific expression of constitutively active rop1at mutants induced isotropic growth of pollen tubes. Overexpression of wild-type Arabidopsis Rop1At led to ectopic accumulation of Rop1At in the plasma membrane at the tip and caused depolarization of pollen tube growth, which was less severe than that induced by the constitutively active rop1at. These results indicate that both Rop1At signaling and polar localization are critical for controlling the site of tip growth. Dominant negative rop1at mutants or antisense rop1at RNA inhibited tube growth at 0.5 mM extracellular Ca(2+), but growth inhibition was reversed by higher extracellular Ca(2+). Injection of anti-Rop antibodies disrupted the tip-focused intracellular Ca(2+) gradient known to be crucial for tip growth. These studies provide strong evidence for a Rop GTPase-dependent tip growth pathway that couples the control of growth sites with the rate of tip growth through the regulation of tip-localized extracellular Ca(2+) influxes and formation of the tip-high intracellular Ca(2+) gradient in pollen tubes.     

Inhibition of Pollen Tube Elongation by Microinjected Anti-Rop1Ps Antibodies Suggests a Crucial Role for Rho-Type GTPases in the Control of Tip Growth

Microinjection of anti-Rop1Ps antibodies was used to assess the function of a tip-localized Rho-type GTPase, Rop, in controlling pollen tube growth. Injected antibodies induced sustained growth arrest within 1 to 2 min after injection but did not affect cytoplasmic streaming. Coinjection with Rop rescued antibody-induced growth inhibition, indicating that injected antibodies specifically block the activity of Rop GTPases. Antibody-induced inhibition was significantly enhanced in the presence of a lower threshold of extracellular [Ca2+] or a subinhibitory dosage of caffeine. In contrast, injection of the C3 toxin, which inactivates a different Rho-type GTPase, arrested tube elongation 10 to 20 min after injection. C3-induced growth arrest was accompanied by the cessation of cytoplasmic streaming. These data suggest that Rho-type GTPases play a pivotal role in the control of pollen tube elongation. We propose that Rop may regulate a Ca2+-dependent pathway involved in vesicle docking/fusion, whereas a C3-sensitive Rho GTPase may mediate cytoplasmic streaming.     

Microtubules and microfilaments are both responsible for pollen tube elongation in the coniferPicea abies (Norway spruce)

Summary InPicea abies (Norway spruce), microtubules and actin microfllaments both form a dense matrix throughout the tube mainly parallel to the direction of elongation. In these conifer pollen tubes the organization of this matrix is different from that in angiosperms. This study tests our hypothesis that differences in cytoskeletal organization are responsible for differences in tube growth and physiology. Pollen grains were germinated in media containing cytoskeletal disrupters and analyzed for germination, tube length, tube branching, and tip swelling. Disruption of microtubules significantly inhibits tube elongation and induces tube branching and tip swelling. Tip swelling is probably caused by disruption of the microtubules in the tip that are perpendicular to the direction of elongation. Confocal microscopy indicates that colchicine and propyzamide cause fragmentation of microtubules throughout the tube. Oryzalin and amiprophosmethyl cause a complete loss of microtubules from the tip back toward the tube midpoint but leave microtubules intact from the midpoint back to the grain. Disruption of microfilaments by cytochalasins B and D and inhibition of myosin by N-ethylmaleimide or 2,3-butanedione monoxime stops tube growth and inhibits germination. Microfilament disruption induces short branches in tubes, probably originating from defective microfilament organization behind the tip. In addition, confocal microscopy coupled with microinjection of fluorescein-labeled phalloidin into actively growing pollen tubes indicates that microfllament bundles extend into the plastid-free zone at the tip but are specifically excluded from the growing tip. We conclude that microtubules and microfilaments coordinate to drive tip extension in conifer pollen tubes in a model that differs from angiosperms.     

Actin filament organization and polarity in pollen tubes revealed by myosin II subfragment 1 decoration

The actin cytoskeleton plays a crucial role in pollen tube growth. In elongating pollen tubes the organization and arrangement of actin filaments (AFs) differs between the shank and apical region. However, the orientation of AFs in pollen tubes has not yet been successfully demonstrated. In the present work we have used myosin II subfragment 1 (S1) decoration to determine the polarity of AFs in pollen tubes. Electron microscopy studies revealed that in the shank of the tube bundles of AFs exhibit uniform polarity with those close to the cell cortex having their barbed ends oriented towards the tip of the pollen tube while those in the cell center have their barbed ends oriented toward the base of the tube. At the subapex, some AFs are organized in closely packed and longitudinally oriented bundles and some form curved bundles adjacent to the cell membrane. In contrast, few AFs are dispersed with random orientation in the extreme apex of the pollen tube. Our results confirm that the direction of cytoplasmic streaming within pollen tubes is determined by the polarity of AFs in the bundles.     

Regulation of pollen tube polarity: Feedback loops rule

Targeted delivery of immotile sperm through growing pollen tubes is a crucial step in achieving sexual reproduction in angiosperms. Unlike diffuse-growing cells, the growth of a pollen tube is restricted to the very apical region where targeted exocytosis and regulated endocytosis occur. The plant-specific Rho GTPases, Rops, are central organizers for pollen tube polarity. Through effector binding, Rops regulate the tip-focused Ca²⁺ gradient and the actin cytoskeleton during pollen tube growth. Therefore, understanding the spatiotemporal regulation of Rop activity would reveal how establishment and maintenance of tube polarity as well as re-orientation of the growth axis are accomplished. Recent findings indicated that two feedback loops may be fundamental in maintaining a fine-tuned and dynamic Rop activity. The concerted activities of RopGAP and RopGDI prevent lateral diffusion of activated Rop, restricting Rop activity to the apical plasma membrane. Conversely, pollen receptor kinases (PRKs) and RopGEFs positively feedback regulate Rop activity through protein binding and membrane recruitment. Feedback loops would also be essential for pollen tube re-orientation. Shallow extracellular cues amplified by concerted activities of feedback loops would lead to asymmetric activation of Rop and result in tube re-orientation.Key words: Rho GTPases, Rop, GEF, GAP, GDI, receptor kinase, feedback loop     

Cytochalasin B Treatment of Apple (<Emphasis Type="Italic">Malus pumila</Emphasis> Mill.) Pollen Tubes Alters the Cytoplasmic Calcium Gradient and Causes Major Changes in the Cell Wall Components

It is well established that the actin cytoskeleton is absolutely essential to pollen germination and tube growth. In this study we investigated the effects of cytochalasin B (CB), which affects actin polymerization by binding to the barbed end of actin filaments, on apple (Malus pumila Mill.) pollen tube growth. Results showed that CB altered the morphology of pollen tubes, which had a larger diameter than control tubes beside inhibiting pollen germination and tube growth. Meantime CB also caused an abnormal distribution of actin filaments in the shank of the treated pollen tubes. Fluo-3/AM labeling indicated that the gradient of cytosolic calcium ([Ca²⁺]c) in the pollen tube tip was abolished by exposure to CB, which induced a much stronger signal in the cytoplasm. Cellulose and callose distribution in the tube apex changed due to the CB treatment. Immunolabeling with different pectin and arabinogalactan protein (AGP) antibodies illustrated that CB induced an accumulation of pectins and AGPs in the tube cytoplasm and apex wall. The above results were further supported by Fourier-transform infrared (FTIR) analysis. The results suggest the disruption of actin can result in abnormal growth by disturbing the [Ca²⁺]c gradient and the distribution of cell wall components at the pollen tube apex.     

Pyrus pyrifolia stylar S-RNase induces alterations in the actin cytoskeleton in self-pollen and tubes in vitro

Summary. Pears (Pyrus pyrifolia L.) have an S-RNase-based gametophytic self-incompatibility system, and S-RNases have also been implicated in self-pollen or genetically identical pollen rejection. Tip growth of the pollen tube is dependent on a functioning actin cytoskeleton. In this study, configurations of the actin cytoskeleton in P. pyrifolia pollen and effects of stylar S-RNases on its dynamics were investigated by fluorescence and confocal microscopy. Results show that actin filaments in normal pollen grains exist in fusiform or circular structures. When the pollen germinates, actin filaments assembled around one of the germination pores, and then actin bundles oriented axially throughout the shank of the growing tube. There was a lack of actin filaments 5–15 μm from the tube tip. When self-stylar S-RNase was added to the basal medium, pollen germination and tube growth were inhibited. The configuration of the actin cytoskeleton changed throughout the culturing time: during the first 20 min, the actin configurations in the self-pollen and tube were similar to the control; after 20 min of treatment, the actin filaments in the pollen tube gradually moved into a network running from the shank to the tip; finally, there was punctate actin present throughout the whole tube. Although the actin filaments of the self-pollen grain also disintegrated into punctate foci, the change was slower than in the tube. Furthermore, the alterations to the actin cytoskeleton occurred prior to the arrest of pollen tube growth. These results suggest that P. pyrifolia stylar S-RNase induces alterations in the actin cytoskeleton in self-pollen grains and tubes. Correspondence: Shao-ling Zhang, College of Horticulture, Nanjing Agricultural University, Nanjing, Jiangsu 210095, People’s Republic of China.     

Circular F-actin bundles and a G-actin gradient in pollen and pollen tubes of Lilium davidii

The distribution of and relationship between F-actin and G-actin were investigated in pollen grains and pollen tubes of Lilium davidii Duch. using a confocal laser scanning microscope after fluorescence and immunofluorescence labeling. Circular F-actin bundles were found to be the main form of microfilament cytoskeleton in pollen grains and pollen tubes. Consistent with cytoplasmic streaming in pollen tubes, there were no obvious F-actin bundles in the 10- to 20-microm tip region of long pollen tubes, only a few short F-actin fragments. Labeling with fluorescein isothiocyanate (FITC)-DNase I at first established the presence of a tip-focused gradient of intracellular G-actin concentration at the extreme apex of the tube, the concentration of G-actin being about twice as high in the 10- to 20-microm region of the tip as in other regions of the pollen tube. We also found that the distribution of G-actin was related negatively to that of the F-actin in pollen tubes of L. davidii. Caffeine treatment caused the G-actin tip-focused gradient to disappear, and F-actin to extend into the pollen tube tip. Based on these results, we speculate that the circular F-actin bundles may be the track for bidirectional cytoplasmic streaming in pollen tubes, and that in the pollen tube tip most of the F-actin is depolymerized into G-actin, leading to the absence of F-actin bundles in this region.     

ROP GTPase regulation of pollen tube growth through the dynamics of tip-localized F-actin

Pollen tubes expand by tip growth and extend directionally toward the ovule to deliver sperms during pollination. They provide an excellent model system for the study of cell polarity control and tip growth, because they grow into uniformly shaped cylindrical cells in culture. Mechanisms underlying tip growth are poorly understood in pollen tubes. It has been demonstrated that ROP1, a pollen-specific member of the plant-specific Rop subfamily of Rho GTPases, is a central regulator of pollen tube tip growth. Recent studies in pollen from Arabidopsis and other species have revealed a ROP-mediated signalling network that is localized to the apical PM region of pollen tubes. The results provide evidence that the localization of this signalling network establishes the site for tip growth and the localized activation of this signalling network regulates the dynamics of tip F-actin. These results have shown that the ROP1-mediated dynamics of tip F-actin is a key cellular mechanism behind tip growth in pollen tubes. Current understanding of the molecular basis for the regulation of the tip actin dynamics will be discussed.     

Localization of a Rho GTPase Implies a Role in Tip Growth and Movement of the Generative Cell in Pollen Tubes

The Rho family GTPases function as key molecular switches, controlling a variety of actin-dependent cellular processes, such as the establishment of cell polarity, cell morphogenesis, and movement in diverse eukaryotic organisms. A novel subfamily of Rho GTPases, Rop, has been identified in plants. Protein gel blot and RNA gel blot hybridization analyses indicated that one of these plant Rho GTPases, Rop1, is expressed predominantly in the male gametophyte (pollen and pollen tubes). Cell fractionation analysis of pollen tubes showed that Rop is partitioned into soluble and particulate fractions. The particulate Rop could be solubilized with detergents but not with salts, indicating that it is tightly bound to membranes. The membrane association appears to result from membrane anchoring via a geranylgeranyl group because an in vitro isoprenylation assay demonstrated that Rop1Ps is geranylgeranylated. Subcellular localization, using indirect immunofluorescence and confocal microscopy, showed that Rop is highly concentrated in the cortical region of the tube apex and in the periphery of the generative cell. The cortical Rop protein at the apex forms a gradient with decreasing concentration from tip to base and appears to be associated with the plasma membrane. These results suggest that the apical Rop GTPase may be involved in the signaling mechanism that controls the actin-dependent tip growth of pollen tubes. Localization of the Rop GTPase to the periphery of the generative cell is analogous to that of myosin, suggesting that the Rop GTPase plays an important role in the modulation of an actomyosin motor system involved in the movement of the generative cell.     

The function of actin-binding proteins in pollen tube growth

Pollen tube growth is a key step in sexual reproduction of higher plants. The pollen tube is a typical example of tip-growing cells and shows a polarized cytoplasm. To develop and maintain polarized growth, pollen tubes need a carefully regulated actin cytoskeleton. It is well known that actin-binding proteins are responsible for the direct control of dynamic actin filaments and serve as a link between signal transduction pathways and dynamic actin changes in determining cellular architecture. Several of these classes have been identified in pollen tubes and their detailed characterisation is progressing rapidly. Here, we aim to survey what is known about the major actin-binding proteins that affect actin assembly and dynamics, and their higher-order organisation in pollen tube growth.     

Actin bundler PLIM2s are involved in the regulation of pollen development and tube growth in Arabidopsis

Microspores develop inside the anther, where they are surrounded by nourishing tapetal cells. However, many cellular processes occurring during microspore development in the locule are poorly characterized. The actin cytoskeleton is known to play a crucial role in various aspects of the plant developmental process. During pollen tube tip growth, actin cytoskeleton serves as an efficient molecular transportation track, although how it functions in pollen development is unknown. The plant actin bundler PLIM2s have been shown to regulate actin bundling in different cells. Here, we investigate the biological function of three Arabidopsis pollen-specific LIM proteins, PLIM2a, PLIM2b, and PLIM2c (collectively, PLIM2s), in pollen development and tube growth. Variable degrees of suppressed expression of the PLIM2s by RNA interference resulted in aberrant phenotypes. Complete suppression of the PLIM2s totally disrupted pollen development, producing abortive pollen grains and rendering the transgenic plants sterile. Partial suppression of the PLIM2s arrested pollen tube growth to a lesser extent, resulting in short and swollen pollen tubes. Finally, the PLIM2c promoter initiated expression in pollen during stamen filament elongation, and the PLIM2c protein was located on particle structures in the developing pollen grains in Arabidopsis. These suggest that the actin bundler, PLIM2s, are an important factor for Arabidopsis pollen development and tube growth.     

2, 6-dichlorobenzonitrile Causes Multiple Effects on Pollen Tube Growth beyond Altering Cellulose Synthesis in Pinus bungeana Zucc

Cellulose is an important component of cell wall, yet its location and function in pollen tubes remain speculative. In this paper, we studied the role of cellulose synthesis in pollen tube elongation in Pinus bungeana Zucc. by using the specific inhibitor, 2, 6-dichlorobenzonitrile (DCB). In the presence of DCB, the growth rate and morphology of pollen tubes were distinctly changed. The organization of cytoskeleton and vesicle trafficking were also disturbed. Ultrastructure of pollen tubes treated with DCB was characterized by the loose tube wall and damaged organelles. DCB treatment induced distinct changes in tube wall components. Fluorescence labeling results showed that callose, and acidic pectin accumulated in the tip regions, whereas there was less cellulose when treated with DCB. These results were confirmed by FTIR microspectroscopic analysis. In summary, our findings showed that inhibition of cellulose synthesis by DCB affected the organization of cytoskeleton and vesicle trafficking in pollen tubes, and induced changes in the tube wall chemical composition in a dose-dependent manner. These results confirm that cellulose is involved in the establishment of growth direction of pollen tubes, and plays important role in the cell wall construction during pollen tube development despite its lower quantity.