The role of plant villin in the organization of the actin cytoskeleton, cytoplasmic streaming and the architecture of the transvacuolar strand in root hair cells of Hydrocharis

In many types of plant cell, bundles of actin filaments (AFs) are generally involved in cytoplasmic streaming and the organization of transvacuolar strands. Actin cross-linking proteins are believed to arrange AFs into the bundles. In root hair cells of Hydrocharis dubia (Blume) Baker, a 135-kDa polypeptide cross-reacted with an antiserum against a 135-kDa actin-bundling protein (135-ABP), a villin homologue, isolated from lily pollen tubes. Immunofluorescence microscopy revealed that the 135-kDa polypeptide co-localized with AF bundles in the transvacuolar strand and in the sub-cortical region of the cells. Microinjection of antiserum against 135-ABP into living root hair cells induced the disappearance of the transvacuolar strand. Concomitantly, thick AF bundles in the transvacuolar strand dispersed into thin bundles. In the root hair cells, AFs showed uniform polarity in the bundles, which is consistent with the in-vitro activity of 135-ABP. These results suggest that villin is a factor responsible for bundling AFs in root hair cells as well as in pollen tubes, and that it plays a key role in determining the direction of cytoplasmic streaming in these cells. Received: 16 September 1999 / Accepted: 3 December 1999     

Calcium-calmodulin suppresses the filamentous actin-binding activity of a 135-kilodalton actin-bundling protein isolated from lily pollen tubes

We have isolated a 135-kD actin-bundling protein (P-135-ABP) from lily (Lilium longiflorum) pollen tubes and have shown that this protein is responsible for bundling actin filaments in lily pollen tubes (E. Yokota, K. Takahara, T. Shimmen [1998] Plant Physiol 116: 1421-1429). However, only a few thin actin-filament bundles are present in random orientation in the tip region of pollen tubes, where high concentrations of Ca(2+) have also been found. To elucidate the molecular mechanism for the temporal and spatial regulation of actin-filament organization in the tip region of pollen tubes, we explored the possible presence of factors modulating the filamentous actin (F-actin)-binding activity of P-135-ABP. The F-actin-binding activity of P-135-ABP in vitro was appreciably reduced by Ca(2+) and calmodulin (CaM), although neither Ca(2+) alone nor CaM in the presence of low concentrations of Ca(2+) affects the activity of P-135-ABP. A micromolar order of Ca(2+) and CaM were needed to induce the inhibition of the binding activity of P-135-ABP to F-actin. An antagonist for CaM, W-7, cancelled this inhibition. W-5 also alleviated the inhibition effect of Ca(2+)-CaM, however, more weakly than W-7. These results suggest the specific interaction of P-135-ABP with Ca(2+)-CaM. In the presence of both Ca(2+) and CaM, P-135-ABP organized F-actin into thin bundles, instead of the thick bundles observed in the absence of CaM. These results suggest that the inhibition of the P-135-ABP activity by Ca(2+)-CaM is an important regulatory mechanism for organizing actin filaments in the tip region of lily pollen tubes.     

The 135 kDa actin-bundling protein fromLilium longiflorum pollen is the plant homologue of villin

Summary Actin microfilaments, which are essential for cell growth and cytoplasmic streaming in pollen tubes, are closely dependent on actin-binding proteins for their organization and regulation. We have purified the plant 135 kDa actin-bundling protein (P-135-ABP) fromLilium longiflorum pollen and determined that its amino acid composition is highly similar to members of the villin-gelsolin family of proteins. We used antibodies against P-135-ABP to probe an expression cDNA library ofL. longiflorum pollen and isolated a full-length clone (ABP135) that corresponds to a 106 kDa polypeptide. The deduced amino acid sequence ofABP135 shows homology with members of the villin-gelsolin family of proteins and contains the characteristic six repeats of this family, as well as an extended carboxy-terminal domain that includes the villin headpiece preceded by a highly variable region. Using two-dimensional polyacrylamide gel electrophoresis we detected at least 5 isoforms of P-135-ABP, with isoelectric points (pI) ranging between 5.6 to 5.9. The most abundant P-135-ABP isoform has a pI of 5.8, closely approximating the pI predicted from the deducedABP135 amino acid sequence. These data, together with the partial amino acid sequence from a proteolytic peptide of the protein, indicate that P-135-ABP is a plant villin. Immuno-detection of Lilium villin in rapidly frozen pollen tubes localized it to actin bundles. Lilium villin is also ubiquitously expressed in all tissues tested. Since villins, like gelsolins, are also Ca²⁺-dependent severing, capping, and nucleating proteins, Lilium villin may participate in F-actin fragmentation and nucleation in the apex of the pollen tube where there is steep Ca²⁺ gradient.Abbreviations BMM butyl methyl-methacrylate - PPI polyphos-phoinositides - SDS-PAGE sodium dodecyl sulfate-polyacrylamide gel electrophoresis     

Plant 115-kDa actin-filament bundling protein, P-115-ABP, is a homologue of plant villin and is widely distributed in cells

In many cases, actin filaments are arranged into bundles and serve as tracks for cytoplasmic streaming in plant cells. We have isolated an actin-filament bundling protein, which is composed of 115-kDa polypeptide (P-115-ABP), from the germinating pollen of lily, Lilium longiflorum [Nakayasu et al. (1998) BIOCHEM: Biophys. Res. Commun. 249: 61]. P-115-ABP shared similar antigenicity with a plant 135-kDa actin-filament bundling protein (P-135-ABP), a plant homologue of villin. A full-length cDNA clone (ABP115; accession no. AB097407) was isolated from an expression cDNA library of lily pollen by immuno-screening using antisera against P-115-ABP and P-135-ABP. The amino acid sequence of P-115-ABP deduced from this clone showed high homology with those of P-135-ABP and four villin isoforms of Arabidopsis thaliana (AtVLN1, AtVLN2, AtVLN3 and AtVLN4), especially AtVLN4, indicating that P-115-ABP can also be classified as a plant villin. The P-115-ABP isolated biochemically from the germinating lily pollen was able to arrange F-actin filaments with uniform polarity into bundles and this bundling activity was suppressed by Ca2+-calmodulin (CaM), similar to the actin-filament bundling properties of P-135-ABP. The P-115-ABP type of plant villin was widely distributed in plant cells, from algae to land plants. In root hair cells of Hydrocharis dubia, this type of plant villin was co-localized with actin-filament bundles in the transvacuolar strands and the sub-cortical regions. Microinjection of the antiserum against P-115-ABP into living root hair cells caused the disappearance of transvaculor strands and alteration of the route of cytoplasmic streaming. In internodal cells of Chara corallina in which the P-135-ABP type of plant villin is lacking, the P-115-ABP type showed co-localization with actin-filament cables anchored on the intracellular surface of chloroplasts. These results indicated that plant villins are widely distributed and involved in the organization of actin filaments into bundles throughout the plant kingdom.     

Plant villin, lily P-135-ABP, possesses G-actin binding activity and accelerates the polymerization and depolymerization of actin in a Ca2+-sensitive manner

From germinating pollen of lily, two types of villins, P-115-ABP and P-135-ABP, have been identified biochemically. Ca(2+)-CaM-dependent actin-filament binding and bundling activities have been demonstrated for both villins previously. Here, we examined the effects of lily villins on the polymerization and depolymerization of actin. P-115-ABP and P-135-ABP present in a crude protein extract prepared from germinating pollen bound to a DNase I affinity column in a Ca(2+)-dependent manner. Purified P-135-ABP reduced the lag period that precedes actin filament polymerization from monomers in the presence of either Ca(2+) or Ca(2+)-CaM. These results indicated that P-135-ABP can form a complex with G-actin in the presence of Ca(2+) and this complex acts as a nucleus for polymerization of actin filaments. However, the nucleation activity of P-135-ABP is probably not relevant in vivo because the assembly of G-actin saturated with profilin, a situation that mimics conditions found in pollen, was not accelerated in the presence of P-135-ABP. P-135-ABP also enhanced the depolymerization of actin filaments during dilution-mediated disassembly. Growth from filament barbed ends in the presence of Ca(2+)-CaM was also prevented, consistent with filament capping activity. These results suggested that lily villin is involved not only in the arrangement of actin filaments into bundles in the basal and shank region of the pollen tube, but also in regulating and modulating actin dynamics through its capping and depolymerization (or fragmentation) activities in the apical region of the pollen tube, where there is a relatively high concentration of Ca(2+).     

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.     

Localization of pectins in the pollen tube wall of Ornithogalum virens L. Does the pattern of pectin distribution depend on the growth rate of the pollen tube?

Monoclonal antibodies that recognize pectins were used for the localization of esterified (JIM7) and acidic, unesterified (JIM5) forms of pectin in pollen tube walls of Ornithogalum virens L. (x = n = 3). The results indicated that the distribution of the two forms of pectin in the pollen tube wall depended on the medium (liquid or solid) used for pollen germination. In pollen tubes grown in the liquid medium, the localization of JIM7 was limited to the very tip of the pollen tube, whereas the localization of JIM5 indicated a uniform distribution of unesterified pectins in the very tip of the tube and along the subapical parts of the tube wall. In tubes germinated on the medium stabilized with agar (1–2%) the localization of JIM7 and JIM5 indicated the presence of both forms of pectin in the tube tip and along the whole length of the pollen tube wall in a ring-like pattern. Thus, the localization of esterified pectins in the sub-apical part of the pollen tube wall, below the apex of the tube, is described for the first time. Measurements of the growth rates of pollen tubes growing on the two types of medium indicated that oscillations in tube growth rate occur but these do not coincide with the pattern of pectin distribution in the tube wall. Our results complement the previous data obtained for the localization of JIM5 and JIM7 in pollen tube walls of other plant species. (Y.-Q. Li et al. 1994, Sex Plant Reprod 7: 145–150) and provide new insight into an understanding of the construction of the pollen tube wall and the physiology of pollen grain germination. Received: 25 January 1999 / Accepted: 23 June 1999     

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.     

Cytoskeleton in Pollen and Pollen Tubes of Ginkgo biloba L.

The distribution of F-actin and microtubules was investigated in pollen and pollen tubes of Ginkgo biloba L. using a confocal laser scanning microscope after fluorescence and immunofluorescence labeling. A dense F-actin network was found in hydrated Ginkgo pollen. When Ginkgo pollen was germinating,F-actin mesh was found under the plasma membrane from which the pollen tube would emerge. After pollen germination, F-actin bundles were distributed axially in long pollen tubes of G. biloba. Thick F-actin bundles and network were found in the tip of the Ginkgo pollen tube, which is opposite to the results reported for the pollen tubes of some angiosperms and conifers. In addition, a few circular F-actin bundles were found in Ginkgo pollen tubes. Using immunofluorescence labeling, a dense microtubule network was found in hydrated Ginkgo pollen under confocal microscope. In the Ginkgo pollen tube, the microtubules were distributed along the longitudinal axis and extended to the tip. These results suggest that the cytoskeleton may have an essential role in the germination of Ginkgo pollen and tube growth.     

Organization of the actin cytoskeleton during pollen development inGasteria verrucosa (Mill.) H. Duval visualized with rhodamine-phalloidin

The three-dimensional organization of the microfilamental cytoskeleton of developingGasteria pollen was investigated by light microscopy using whole cells and fluorescently labelled phalloidin. Cells were not fixed chemically but their walls were permeabilized with dimethylsulphoxide and Nonidet P-40 at premicrospore stages or with dimethylsulphoxide, Nonidet P-40 and 4-methylmorpholinoxide-monohydrate at free-microspore and pollen stages to dissolve the intine.Four strikingly different microfilamentous configurations were distinguished. (i) Actin filaments were observed in the central cytoplasm throughout the successive stages of pollen development. The network was commonly composed of thin bundles ramifying throughout the cytoplasm at interphase stages but as thick bundles encaging the nucleus prior to the first and second meiotic division. (ii) In released microspores and pollen, F-actin filaments formed remarkably parallel arrays in the peripheral cytoplasm. (iii) In the first and second meiotic spindles there was an apparent localization of massive arrays of phalloidin-reactive material. Fluorescently labelled F-actin was present in kinetochore fibers and pole-to-pole fibers during metaphase and anaphase. (iv) At telophase, microfilaments radiated from the nuclear envelopes and after karyokinesis in the second meiotic division, F-actin was observed in phragmoplasts.We did not observe rhodamine-phalloidin-labelled filaments in the cytoplasm after cytochalasin-B treatment whereas F-actin persisted in the spindle. Incubation at 4° C did not influence the existence of cytoplasmic microfilaments whereas spindle filaments disappeared. This points to a close interdependence of spindle microfilaments and spindle tubules.Based on present data and earlier observations on the configuration of microtubules during pollen development in the same species (Van Lammeren et al., 1985, Planta165, 1-11) there appear to be apparent codistributions of F-actin and microtubules during various stages of male meiosis inGasteria verrucosa.Abbreviation DMSO dimethylsulfoxide     

Role of a callose synthase zymogen in regulating wall deposition in pollen tubes of Nicotiana alata Link et Otto

The callose synthase (CalS) activity of membrane preparations from cultured Nicotiana alata Link & Otto pollen tubes is increased several-fold by treatment with trypsin in the presence of digitonin, possibly due to activation of an inactive (zymogen) form of the enzyme. Active and inactive forms of CalS are also present in stylar-grown tubes. Callose deposition was first detected immediately after germination of pollen grains in liquid medium, at the rim of the germination aperture. During tube growth the 3-linked glucan backbone of callose was deposited at an increasing rate, reaching a maximum of 65 mg h⁻¹ in tubes grown from 1 g pollen. Callose synthase activity was first detected immediately after germination, and then also increased substantially during tube growth. Trypsin caused activation of CalS throughout a 30-h time course of tube growth, but the degree of activation was higher for younger pollen tubes. Over a 10-fold range of callose deposition rates, the assayed CalS activity was sufficient to account for the rate of callose deposition without trypsin activation, implying that the form of CalS active in isolated membranes is responsible for callose deposition in intact pollen tubes. Sucrose-density-gradient centrifugation separated a lighter, intracellular membrane fraction containing only inactive CalS from a heavier, plasma-membrane fraction containing both active and inactive CalS, with younger pollen tubes containing relatively more of the inactive intracellular enzyme. The increasing rate of callose deposition during pollen-tube growth may thus be caused by the transport of inactive forms of CalS from intracellular membranes to the plasma membrane, followed by the regulated activation of these inactive forms in this final location. Received: 1 December 1998 / Accepted: 21 January 1999     

Rop1Ps promote actin cytoskeleton dynamics and control the tip growth of lily pollen tube

Rop, the small GTPase of the Rho family in plants, is believed to exert molecular control over dynamic changes in the actin cytoskeleton that affect pollen tube elongation characteristics. In the present study, microinjection of Rop1Ps was used to investigate its effects on tip growth and evidence of interaction with the actin cytoskeleton in lily pollen tubes. Microinjected wild type WT-Rop1Ps accelerated pollen tube elongation and induced actin bundles to form in the very tip region. In contrast, microinjected dominant negative DN-rop1Ps had no apparent effect on pollen tube growth or microfilament organization, whereas microinjection of constitutively active CA-rop1Ps induced depolarized growth and abnormal pollen tubes in which long actin bundles in the shank of the tube were distorted. Injection of phalloidin, a potent F-actin stabilizer that inhibits dynamic changes in the actin cytoskeleton, prevented abnormal growth of the tubes and suppressed formation of distorted actin bundles. These results indicate that Rop1Ps exert control over important aspects of tip morphology involving dynamics of the actin cytoskeleton that affect pollen tube elongation. Electronic Supplementary Material Supplementary material is available for this article at and is accessible for authorized users.     

Differential roles of microtubule and actin-myosin cytoskeleton in the growth of Pinus pollen tubes

The behavior and role of the microtubule (MT) and actin-myosin components of the cytoskeleton during pollen tube growth in two species of Pinus were studied using anti--tubulin, rhodamine-phalloidin, anti-myosin, and the appropriate inhibitors. Within germinated pollen tubes MTs were arranged obliquely or transversely, but in elongated tubes they were arranged along the tube's long axis. MTs were localized in the tube tip region, excluding the basal part. Altered growth was found in pollen tubes treated with colchicine; the tips of many pollen tubes incubated in the liquid medium were branched and/or rounded, and those in the agar medium were divided into many branches. Both the branching and the rounding were considered to be caused by the disturbance of polarizing growth of the tube due to MT disorganization with colchicine treatment. Actin filaments (F-actin) were found in the major parts of many pollen tubes along their long axis, excluding the tip region. In a few tubes, however, F-actin was distributed throughout the tube. The areas in the pollen tube containing F-actin were filled with abundant cytoplasmic granules, but the areas without F-actin had very few granules. The tube nucleus, which migrated from the grain area into the tube, was closely associated with F-actin. Germination of pollen grains treated with cytochalasin B was little affected, but further tube elongation was inhibited. Myosin was identified on cytoplasmic granules and to a lesser extent on the tube nucleus in the pollen tubes. Several granules were attached to the nuclear envelope. Tube growth was completely inhibited by N-ethylmaleimide treatment. In generative cells that were retained in the pollen grain, both MT and F-actin networks were observed. Myosin was localized on the cytoplasmic granules but not on the cell surface. In conclusion, it was shown that actin-myosin and MTs were present in gymnospermous Pinus pollen tubes and it is suggested that the former contributed to outgrowth of the tubes and the latter contributed to polarized growth. Several differences in the behavior of cytoskeletal elements in generative cells compared to angiosperms were revealed and are discussed.     

Comparison of F-actin fluorescent labeling methods in pollen tubes of Lilium davidii

Fluorescence labeling of F-actin in pollen tubes by various methods has produced inconsistent results in the literature. Here, we report that EGTA, which was always used in fixative buffers in the past and thought to help cytoskeleton stabilization, can significantly affect F-actin distribution and lead to the formation of thick F-actin bundles at the tip of the pollen tube. We also found that vacuum-infiltration for the first 5 min during pollen tube fixation can better preserve normal cytoplasm structure and F-actin distribution. In contrast, m-maleimidobenzoic acid N-hydroxysuccinimide ester (MBS) treatment before chemical fixation resulted in a shortening of the free zone of thick F-actin bundles in the pollen tube tip. Taken together, our results suggest that exclusion of EGTA and MBS from the fixative buffer, in combination with vacuum-infiltration in the first 5 min of fixation, can improve F-actin fluorescence labeling in pollen tubes of Lilium davidii.Li Wang and Yi-Min Liu are considered joint first authors     

Simulation of the packing of idealized transmembrane α-helix bundles

The aim of this study is to investigate if the packing motifs of native transmembrane helices can be produced by simulations with simple potentials and to develop a method for the rapid generation of initial candidate models for integral membrane proteins composed of bundles of transmembrane helices. Constituent residues are mapped along the helix axis in order to maintain the amino acid sequence-dependent properties of the helix. Helix packing is optimized according to a semi-empirical potential mainly composed of four components: a bilayer potential, a crossing angle potential, a helix dipole potential and a helix-helix distance potential. A Monte Carlo simulated annealing protocol is employed to optimize the helix bundle system. Necessary parameters are derived from theoretical studies and statistical analysis of experimentally determined protein structures. Preliminary testing of the method has been conducted with idealized seven Ala₂₀ helix bundles. The structures generated show a high degree of compactness. It was observed that both bacteriorhodopsin-like and δ-endotoxin-like structures are generated in seven-helix bundle simulations, within which the composition varies dependent upon the cooling rate. The simulation method has also been employed to explore the packing of N = 4 and N = 12 transmembrane helix bundles. The results suggest that seven and 12 transmembrane helix bundles resembling those observed experimentally (e.g., bacteriorhodopsin, rhodopsin and cytochrome c oxidase subunit I) may be generated by simulations using simple potentials. Received: 16 November 1998 / Revised version: 26 March 1999 / Accepted: 8 April 1999     

Actin-Bundling Protein Isolated from Pollen Tubes of Lily : Biochemical and Immunocytochemical Characterization

A 135-kD actin-bundling protein was purified from pollen tubes of lily (Lilium longiflorum) using its affinity to F-actin. From a crude extract of the pollen tubes, this protein was coprecipitated with exogenously added F-actin and then dissociated from F-actin by treating it with high-ionic-strength solution. The protein was further purified sequentially by chromatography on a hydroxylapatite column, a gel-filtration column, and a diethylaminoethyl-cellulose ion-exchange column. In the present study, this protein is tentatively referred to as P-135-ABP (Plant 135-kD Actin-Bundling Protein). By the elution position from a gel-filtration column, we estimated the native molecular mass of purified P-135-ABP to be 260 kD, indicating that it existed in a dimeric form under physiological conditions. This protein bound to and bundled F-actin prepared from chicken breast muscle in a Ca²⁺-independent manner. The binding of 135-P-ABP to actin was saturated at an approximate stoichiometry of 26 actin monomers to 1 dimer of P-135-ABP. By transmission electron microscopy of thin sections, we observed cross-bridges between F-actins with a longitudinal periodicity of 31 nm. Immunofluorescence microscopy using rhodamine-phalloidin and antibodies against the 135-kD polypeptide showed that P-135-ABP was colocalized with bundles of actin filaments in lily pollen tubes, leading us to conclude that it is the factor responsible for bundling the filaments.Actin filaments, one of the major components of the cytoskeleton, are organized into a highly ordered architecture and are involved in various kinds of cell motility. Their architecture is regulated by several kinds of actin-binding proteins, including cross-linking proteins, severing proteins, end-capping proteins, and monomer-sequestering proteins in animal, protozoan, and yeast cells (Stossel et al., 1985; Pollard and Cooper, 1986; Vandekerckhove and Vancompernolle, 1992). In plant cells the organization of the actin cytoskeleton also changes remarkably during the cell cycle or during developmental processes, and it is suggested that actin-binding proteins are involved in their dynamic change. However, little is known about actin-binding proteins in plant cells.Only a low-M_r actin-binding and -depolymerizing protein, profilin, in white birch (Betula verrucosa; Valenta et al., 1991), maize (Zea mays; Staiger et al., 1993; Ruhlandt et al., 1994), bean (Phaseolus vulgaris; Vidali et al., 1995), tobacco (Nicotiana tabacum; Mittermann et al., 1995), tomato (Lycopersicon esculentum; Darnowski et al., 1996), Arabidopsis (Arabidopsis thaliana; Huang et al., 1996), and lily (Lilium longiflorum; Vidali and Hepler, 1997), and an ADF in lily (Kim et al., 1993), rapeseed (Brassica napus; Kim et al., 1993), and maize (Rozycka et al., 1995; Lopez et al., 1996), have been identified by biochemical or molecular biological means.The native and recombinant forms of these proteins are capable of binding to animal or plant actin (Valenta et al., 1993; Giehl et al., 1994; Ruhlandt et al., 1994; Lopez et al., 1996; Perelroizen et al., 1996; Carlier et al., 1997). Plant profilin expressed in mammalian BHK-21 cells (Rothkegel et al., 1996) or profilin-deficient Dictyostelium discoideum cells (Karakesisoglou et al., 1996) was able to functionally substitute for endogenous profilin in these cells. The introduction of plant profilin into living stamen hair cells by microinjection caused the rapid reduction of the number of actin filaments (Staiger et al., 1994; Karakesisoglou et al., 1996; Ren et al., 1997). These results indicate that plant profilin and ADF share many functional similarities with other eukaryote profilins and ADFs.It is well known that the actin cytoskeleton undergoes dynamic changes in organization during hydration and activation of the vegetative cells of pollen grains (Pierson and Cresti, 1992). Before hydration actin filaments exist as fusiform or spiculate structures (a storage form), but they are rearranged to form a network upon hydration (Heslop-Harrison et al., 1986; Tiwari and Polito, 1988). In the growing pollen tube there are strands or bundles of actin filaments parallel to the long axis (Perdue et al., 1985; Pierson et al., 1986; Miller et al., 1996) that are involved in cytoplasmic streaming (Franke et al., 1972; Mascarenhas and Lafountain, 1972) and transport of vegetative nuclei and generative cells to the growing tip (Heslop-Harrison et al., 1988; Heslop-Harrison and Heslop-Harrison, 1989). Characterization of the function of actin-binding proteins is essential to understanding the regulation of actin organization during the developmental process of pollen. Since only a small number of vacuoles containing proteases develop in pollen grains and pollen tubes at a younger stage, pollen tubes are suitable materials for isolating and biochemically studying actin-binding proteins responsible for organizing actin filaments into various forms.In a previous paper we reported that several components in a crude extract prepared from lily pollen tubes, including a 170-kD myosin heavy chain and 175-, 135-, and 110-kD polypeptides, could be coprecipitated with exogenously added F-actin (Yokota and Shimmen, 1994). We also found that rhodamine-labeled F-actin was tightly bound to the glass surface treated with the fraction containing the 135- and 110-kD polypeptides (Yokota and Shimmen, 1994). These results suggested that either one or both of the 135- and 110-kD polypeptides possesses an F-actin-binding activity. In the present study, we purified the 135-kD polypeptide from lily pollen tubes by biochemical procedures and then characterized its F-actin-binding properties and distribution in the pollen tubes. This protein was able to bundle F-actin isolated from chicken breast muscle and colocalized with actin-filament bundles in pollen tubes. We refer to this protein as P-135-ABP (Plant 135-kD Actin-Bundling Protein).     

Microtubules at wound sites of Nitella internodal cells passively co-align with actin bundles when exposed to hydrodynamic forces generated by cytoplasmic streaming

The organization of cortical microtubules at wound sites in Nitella pseudoflabellata(A. Br. & Nordst.) em. R.D.W. and N. flexilis(L.) Ag. internodal cells was examined in relation to the regeneration of actin filament bundles in order to identify the mechanisms by which microtubules are oriented. Actin bundle regrowth occurs prior to that of microtubules, so it was considered possible that microtubule alignment is actin-dependent, perhaps mediated by cross-linking proteins. In all types of wounds investigated, subcortical actin bundles regenerated parallel to the direction of cytoplasmic streaming. Microtubule orientation patterns, however, varied according to the nature of wound formation and the type of wound wall eventually produced. In chloroplast-free windows induced by blue light irradiation, microtubule orientation varied according to the size of the window. Microtubules were randomized in 10- to 30-μm-wide windows where exposure to cytoplasmic flow is minimal, but were aligned more or less parallel to regenerated actin bundles in 80- to 100-μm-wide windows. Where co-alignment between microtubules and actin bundles was obvious after fluorescence labelling, electron micrographs revealed that microtubules and actin bundles were too widely spaced to account for any cross-linkages. Furthermore, treatments that inhibited or reduced cytoplasmic streaming without altering the direction of actin bundles caused randomization of microtubules previously oriented in the streaming direction, even in the presence of taxol. When evenly flat wound walls were induced by 10⁻⁴ M chlortetracycline, microtubules were co-aligned with nearby actin bundles at the surface of the wound wall. At wounds induced by treatment with 5 × 10⁻² M CaCl₂, however, microtubules were randomly oriented and preferentially located in the narrow clefts between the wound-wall protuberances, up to several micrometers away from the actin bundles near the wound-wall tips. These results indicate that microtubules regenerated in wounds are merely co-aligned with actin filament bundles because they are passively aligned by the hydrodynamic forces created by cytoplasmic flow. Received: 4 August 1998 / Accepted: 30 January 1999     

Heavy meromyosin induces sliding movements between antiparallel actin filaments

Suzuki et al. [Biochemistry 28, 6513-6518 (1989)] have shown that, when F-actin is mixed with inert high polymer, a large number of actin filaments closely align in parallel with overlaps to form a long and thick bundle. The bundle may be designated non-polar, as the constituent filaments are random in polarity (Suzuki et al. 1989). I prepared non-polar bundles of F-actin using methylcellulose (MC) as the high polymer, exposed them to heavy meromyosin (HMM) in the presence of ATP under a light microscope, and followed their morphological changes in the continuous presence of MC. It was found that bundles several tens of micrometers long contracted to about one-third the initial length, while becoming thicker, in half a minute after exposure to HMM. Subsequently, each bundle was split longitudinally into several bundles in a stepwise manner, while the newly formed ones remained associated together at one of the two ends. The product, an aster-like assembly of actin bundles, was morphologically quiescent; that is, individual bundles never contracted upon second exposure to HMM and ATP, although they were still longer than the F-actin used. Bundles in this state consisted of filaments with parallel polarity as examined by electron microscopy. This implies that non-polar bundles were transformed into assemblies of polar bundles with ATP hydrolysis by HMM. Importantly, myosin subfragment-1 caused neither contraction nor transformation. These results are interpreted as follows. In the presence of ATP, the two-headed HMM molecule was able to cross-bridge antiparallel actin filaments, as well as parallel ones.(ABSTRACT TRUNCATED AT 250 WORDS)     

Microtubule disassembly enhances reversible cytochalasin-dependent disruption of actin bundles in characean internodes

Summary Parallel bundles of actin filaments at the cortex-endoplasm interface provide tracks for myosin-generated cytoplasmic streaming in characean internodes. These bundles resist disassembly or structural modification when exposed to 10 μM cytochalasin D (CD) even though this concentration of CD rapidly (within minutes) but reversibly arrests streaming. Unexpectedly, we discovered that prolonged treatment with lower concentrations of CD could partially disassemble the subcortical actin bundles. Actin bundles became discontinuous following one- to several-day treatment with concentrations (6 μM) that reduced but did not arrest streaming, and the residual fragments mostly remained parallel to the chloroplast files. When microtubules were concurrently disassembled with tubulin-specific drugs, however, low CD concentrations (2.5–3 μM) completely arrested bulk streaming, disrupted the largely 2-dimensional actin bundle array and caused the formation of a coarse, thick-meshed actin network that extended from the cortex to the endoplasm. Despite such massive reconstruction, drug removal enabled cells to recover continuous parallel bundles and streaming. Recovery was possible if both or just one of the drugs were removed. In recovered cells, the streaming pattern frequently redeveloped in new directions that did not follow the chloroplast files, and later, chloroplast files readjusted to the new polarity established by the actin bundles. This first report on the complete and reversible disassembly of characean actin bundles provides new insights into the mechanism of actin bundle assembly and organization and supports the idea of indirect interactions between actin filaments and microtubules.     

Transient gene expression in pine pollen tubes following particle bombardment

 A biolistic particle delivery system was used to genetically transform pollen tubes of three species of white pine (Pinus aristata, P. griffithii and P. monticola). The introduced plasmid DNA contained the GUS coding sequence flanked by the 35S CaMV promoter and NOS terminator sequences. Successful gene delivery was demonstrated by transient GUS expression as evaluated by standard histochemical assay. Distance of target specimens significantly influenced transient GUS expression in all three species of white pine. A target distance of 6 cm resulted in a significant number of transformed pollen tubes in P. aristata and P. griffithii, while distances of 6 and 9 cm resulted in a significant number of transformed pollen tubes in P. monticola. Generally, the number of pollen tubes expressing GUS activity was higher in P. aristata than in P. griffithii and P. monticola. The possibility of using GUS-transformed pollen tubes in conjunction with in vitro fertilization in conifers was examined. Gene expression in pollen tubes was also examined under electron microscopy where the X-glu reaction product occurred as large crystalline electron-dense precipitates in the cytoplasm. Received: 17 December 1998 / Revision received: 17 March 1999 / Accepted: 14 April 1999