Behavior of mitochondria, microtubules, and actin in the triangular yeastTrigonopsis variabilis

Summary Dimorphic yeastTrigonopsis variabilis is a unique species that can form either an ellipsoidal or a triangular cell depending upon nutritional conditions. This fluorescence microscopic study was intended to correlate morphological changes of mitochondria in the triangular cells with the distribution of the cytoskeleton. In addition, unique features in the behavior of the cytoskeleton were also examined during triangular cell formation. In log-phase cells stained with 4,6-diamidino-2-phenylindole, mitochondrial nucleoids appeared as a string of beads throughout the vegetative growth. The profile of mitochondria stained by 3,3-dihexyloxacarbocyanine iodide showed a network corresponding to the fluorescence images of mitochondrial nucleoids in both mother and daughter cells. Cell-cycle-dependent fragmentation of mitochondria was not discerned. As the culture reached stationary phase, a network of mitochondria gradually changed to form unique rings that were located near the angles of triangular cells. When examined by immunofluorescence microscopy with anti-tubulin antibody, microtubules were found to be well developed along the sides of cells in the cytoplasm ofT. variabilis interphase cells. Although distributions of microtubules and mitochondria are different during cell cycle as a whole, cytoplasmic microtubules frequently extended along a part of the mitochondria in budded cells, suggesting correlation of microtubules and mitochondria. Rhodamine-phalloidin staining revealed both actin patches and cables. Actin cables elongated from mother cells into the buds and showed close proximity to mitochondria, although complete overlapping of both structures was rare. Moreover, actin patches localized on the mitochondrial network at a frequency of 65%. These results suggested that actin cables and patches, as well as microtubules, participated in the distribution of mitochondria. The localization of actin patches separated towards opposite ends at a bud tip when the bud grew to medium size. The unique localization of actin patches is responsible for bi-directional growth of the bud, forming triangular cells.     

Probing the Plant Actin Cytoskeleton during Cytokinesis and Interphase by Profilin Microinjection

We have examined the cytological effects of microinjecting recombinant birch profilin in dividing and interphase stamen hair cells of Tradescantia virginiana. Microinjection of profilin at anaphase and telophase led to a marked effect on cytokinesis; cell plate formation was often delayed, blocked, or completely inhibited. In addition, the initial appearance of the cell plate was wrinkled, thin, and sometimes fragmented. Injection of profilin at interphase caused a thinning or the collapse of cytoplasmic strands and a retardation or inhibition of cytoplasmic streaming in a dose-dependent manner. Confocal laser scanning microscopy of rhodamine-phalloidin staining in vivo revealed that high levels of microinjected profilin induced a degradation of the actin cytoskeleton in the phragmoplast, the perinuclear zone, and the cytoplasmic strands. However, some cortical actin filaments remained intact. The data demonstrate that profilin has the ability to act as a regulator of actin-dependent events and that centrally located actin filaments are more sensitive to microinjected profilin than are cortical actin filaments. These results add new evidence supporting the hypothesis that actin filaments play a crucial role in the formation of the cell plate and provide mechanical support for the cytoplasmic strands in interphase cells.     

Profilin inhibits pollen tube growth through actin-binding,but not poly-<Emphasis Type="SmallCaps">l</Emphasis>-proline-binding

Previously, we have shown that excess profilin inhibits pollen tube growth at significantly lower concentrations than it blocks cytoplasmic streaming. To elucidate the mechanism by which profilin achieves this function, we have employed mutant profilins from Schizosaccharomyces pombe [J. Lu and T.D. Pollard (2001) Mol Biol Cell 12:1161–1175], which have defects in actin-binding, ability to inhibit polymerization, and poly-l-proline (PLP)-binding. Using Lilium longiflorum L. pollen and S. pombe profilins as wild-type (wt) standards, mutant profilins have been injected into pollen tubes of Lilium, and examined for their effects on growth rate and cell morphology. Our results show that mutant Y5D (68% actin-binding; 1.1% PLP-binding) is indistinguishable from wt-standard profilins. However mutant K81F (2.7% actin-binding; 77% PLP-binding) and especially mutant K67E (<1% actin-binding; 100% PLP-binding) are significantly less effective than wt-standard profilins in their ability to inhibit pollen tube growth. PLP also inhibits pollen tube growth. However, PLP is not different from K67E/PLP combined, which has no actin-binding, suggesting that PLP does not function by binding to profilin. In addition, there are differences in the morphology and F-actin organization in cells injected with PLP versus wt-profilin. Whereas wt-profilin causes a fragmentation and marked reduction in the amount of F-actin [L. Vidali et al. (2001) Mol Biol Cell 12:2534–2545], PLP generates an extensive disorganization without any apparent reduction in the amount of F-actin. We conclude that along with actin-binding activity of profilin, PLP-containing proteins also participate in the growth control process, and can do so independently of binding to profilin.Abbreviations 3D Three-dimensional - PLP Poly-l-proline - RMS Root mean square - wt Wild type     

Cytoplasmic actin A3 gene promoter injected as supercoiled plasmid is transiently active inBombyx mori embryonic vitellophages

Summary Freshly deposited eggs ofBombyx mori were microinjected with supercoiled plasmid DNA which carried the -galactosidase coding sequence ofEscherichia coli inserted in place of the coding sequence of theB. mori cytoplasmic actin A3 gene. Transient expression of this fusion gene in the embryo was determined by in situ histochemical detection of enzyme activity. After injection of the plasmid at different stages of embryonic development, -galactosidase activity depending on the injected DNA was only detected in the vitellophages. This indicates the presence of active transactivators of the actin A3 gene promoter in this cell type. Tissue specificity of the fusion gene expression could be related to the early polyploidization of vitellophages, a process which would favour the stability of the nuclear pool of injected plasmids. The activity of the transgene in vitellophages was detectable at 24–33 h of egg development, the stage presumed for the onset of zygotic gene expression, up to the end of embryogenesis. This gene transfer system is thus promising to analyse thecis regulatory sequences of the actin A3 gene and could be utilized for other ubiquitous genes. Correspondence to: M. Coulon-Bublex     

Changes of the actin filament system in the green algaMicrasterias denticulata induced by different cytoskeleton inhibitors

Summary Two different techniques have been adapted forMicrasterias denticulata to depict the actin cytoskeleton of both untreated and inhibitor-treated developing cells: the quickstaining method, where the cells are fixed in a mixture of glutaraldehyde and formaldehyde followed by staining with phalloidin without embedding, and the methacrylate method, where the cells are also fixed by aldehydes and where the embedding medium is removed prior to incubation with an actin antibody. Both methods produce sufficient preservation and visualization of actin microfilaments (MFs) and confirm earlier observations on the presence of a cortical actin MF network in both the growing and the nongrowing semicell as well as of a basketlike MF arrangement around the migrating nucleus. The results show that a network of actin MFs is essential for the proper development of the young lobes ofM. denticulata. Early developmental stages expanding uniformly at the beginning of growth lack any netlike actin MF arrangement. The actin cytoskeleton in developing cells treated with the actin-targeting agents cytochalasin D and latrunculin B is markedly influenced. Cytochalasin D, which produces the most pronounced effects, causes a breakdown of the network of actin MFs, resulting in bright actin clusters as well as in short and abnormally thick actin fragments particularly in cortical cell regions. In latrunculin B-treated cells remnants of the former actin MF network are still visible, yet most of the actin cytoskeleton appears collapsed and is reduced to short filament pieces. The disturbance of the actin MF system visualized in the present study correlates with the severe morphological and ultrastructural changes occurring in desmid cells as a consequence of both drugs. The dinitroanilin herbicide oryzalin, known to deploymerize cytoplasmic microtubules, causes also an impairment of the actin cytoskeleton inM. denticulata though not sufficient to influence normal cell growth and differentiation.Abbreviations CB cytochalasin B - CD cytochalasin D - DMSO dimethyl sulfoxide - FA formaldehyde - GA glutaraldehyde - LAT-A latrunculin A - LAT-B latrunculin B - MFs microfilaments - MT microtubule Dedicated to Professor Walter Gustav Url on the occasion of his 70th birthday     

Nuclear localization of profilin during the cell cycle in Tradescantia virginiana stamen hair cells

Summary. The localization of the actin-monomer-binding protein profilin during the cell cycle of living Tradescantia virginiana stamen hair cells has been studied by microinjection of a fluorescently labeled analog of the protein. In contrast to previously published studies performed on chemically fixed animal cells, we do not find a specific colocalization of profilin with actin filament arrays. Our results show that, besides a general cytoplasmic distribution, profilin specifically accumulates in the nucleus in interphase and prophase cells. This nuclear localization was confirmed by means of electron microscopic immunolocalization of endogenous profilin (in Gibasis scheldiana stamen hair cells). During mitosis, as the nuclear envelope and nuclear matrix break down at the onset of prometaphase, the nuclear profilin redistributes equally into the accessible volume (cytosol) of the cell. During metaphase and anaphase no specific localization of profilin can be observed associated with the mitotic apparatus. However, during telophase, as nuclear envelopes and nuclear matrices re-form and the sister chromatids start to decondense, a subset of the microinjected profilin again localizes to the nucleus. No accumulation of profilin could be observed in the phragmoplast, where a distinct array of actin filaments exists. The function of profilin in the nucleus remains unclear.Correspondence and reprints: Department of Biology, 221 Morrill Science Center II, University of Massachusetts, Amherst, MA 01003, U.S.A.Received September 30, 2002; accepted February 12, 2003 Published online September 23, 2003     

Effect of cytochalasin A on actin distribution in the fission yeastSchizosaccharomyces pombe studied by fluorescent and electron microscopy

Summary Actin distribution and ultrastructure of the fission yeastSchizosaccharomyces pombe treated with cytochalasin A (CA) were investigated by fluorescence microscopy using rhodamine-conjugated phalloidin (rh-ph) and freeze substitution electron microscopy. Among the cytochalasins tested, CA was most effective and at 5 g/ ml inhibited the appearance of the actin ring at the cell equator at the stage prior to septum formation and the accumulation of actin dots at the septum-forming site both in wild-type cells and the mutantcdc 11, which is defective in septum formation at restrictive temperature. Freeze substitution electron microscopy of CA-treated cells revealed the displacement and morphological alteration of cytoplasmic vesicles and dictyosomes within 30 min and the appearance of dense bodies in the cytoplasm. A sub-population of cytoplasmic vesicles and dictyosomes were insensitive to CA and maintained their original structure. An electron less dense layer containing filamentous material was noted beneath the plasma membrane and thought to be the area of heavy actin patches stained with rh-ph at the cells ends. These results suggest that CA disrupted an actin network that normally maintains the organization of the secretory pathway involving dictyosomes and vesicles.     

Characterization of Ricinus communis phloem profilin,RcPRO1

The mature, functional sieve tube, which forms the conduit for assimilate distribution in higher plants, is dependent upon protein import from the companion cells for maintenance of the phloem long-distance translocation system. Using antibodies raised against proteins present in the sieve-tube exudate of Ricinus communis (castor bean) seedlings, a cDNA was cloned which encoded a putative profilin, termed RcPRO1. Expression and localization studies indicated that RcPRO1 mRNA encodes a phloem profilin, with some expression occurring in epidermal, cortex, pith and xylem tissue. Purified, recombinant RcPRO1 was functionally equivalent to recombinant maize profilin ZmPRO4 in a live cell nuclear displacement assay. The apparent equilibrium dissociation constant for RcPRO1 binding to plant monomeric (G-)actin was lower than the previously characterized maize profilins. Moreover, the affinity of RcPRO1 for poly-L-proline (PLP) was significantly higher than that for recombinant maize profilins. Within the sieve-tube exudate, profilin was present in 15-fold molar excess to actin. The data suggest that actin filament formation is prevented within the assimilate stream. These results are discussed in terms of the unique physiology of the phloem.     

Evidence that actin filaments are involved in controlling the permeability of plasmodesmata in tobacco mesophyll

The role of actin filaments in regulating plasmodesmal transport has been studied by microinjection experiments in mesophyll cells of tobacco (Nicotiana tabacum L. cv. Samsun). When fluorescent dextrans of various molecular sizes were each co-injected with specific actin filament perturbants cytochalasin D (CD) or profilin into these cells, dextrans up to 20 kilodalton (kDa) moved from the injected cell into surrounding cells within 3–5 min. In contrast, when such dextrans were injected alone or co-injected with phalloidin into the mesophyll cells, they remained in the injected cells. Phalloidin co-injection slowed down or even inhibited CD- or profilin-elicited dextran cell-to-cell movement. Dextrans of 40 kDa or larger were unable to move out of the injected cell in the presence of CD or profilin. These data suggest that actin filaments may participate in the regulation of plasmodesmal transport by controlling the permeability of plasmodesmata.     

Effects of cross-linked profilin:beta/gamma-actin on the dynamics of the microfilament system in cultured cells

There is evidence that the profilin:actin complex is the immediate precursor in the formation of actin filaments in cells. This paper describes the cell morphology and microfilament distribution after microinjection of covalently cross-linked profilin:beta/gamma-actin (PxA) in two different cell lines. Injected cells were either kept unstimulated or stimulated with platelet-derived growth factor (PDGF) before fixation and visualization of filamentous actin. After injection of low doses of PxA, the cells displayed an actin organization characterized by a clearance of diffuse fluorescence from a region immediately interior of ruffling edges and the appearance of small dots of fluorescence in the same region. At higher concentrations, PxA effectively inhibited outgrowth of lamellae and microspikes, and there was a drastic reduction of actin staining in the zone behind the advancing edge. This effect is reminiscent of the effect of cytochalasin B on fibroblasts and the growth cone of neuronal cells. As in these cases, there remained a rim of actin-dependent fluorescence on the very edge of the membrane lamella, particularly in the PxA-treated fibroblasts. The interference of PxA with the formation of surface structures was pronounced after PDGF stimulation. Here, PxA effectively eliminated the enhancement of the ruffling activity in the cell edges and on the dorsal surface of the cells. In contrast to PxA, injection of non-cross-linked profilin:beta/gamma-actin had no apparent effect on cell morphology and microfilament distribution except for an increased concentration of filamentous actin in one of the cell lines.     

Regulation of myosin sliding alongChara actin bundles by native skeletal muscle tropomyosin

Summary Native tropomyosin from rabbit skeletal muscle introduced by intracellular perfusion intoChara cells inhibited the cytoplasmic streaming irrespective of the Ca²⁺ concentration. To find the action site of native tropomyosin inChara, the cytoplasmic streaming was reconstituted by introducing isolated endoplasm into actin donorChara cells from which native endoplasm had been removed. The reconstituted streaming was inhibited by pretreatment of the actin donor cells with native tropomyosin but not by that of the endoplasm, suggesting that the native tropomyosin inhibited the cytoplasmic streaming by binding toChara actin bundles. Staining of the actin bundles with FITC-labeled native tropomyosin also showed that the native tropomyosin could bind to the actin bundles. Streaming reconstituted fromChara actin bundles and skeletal muscle myosin was insensitive to Ca²⁺, but became sensitive on application of the native tropomyosin.Abbrevations APW artificial pond water - ATP adenosine 5-triphosphoric acid - BSA bovine serum albumin - EDTA ethylene diamine tetraacetic acid - EGTA ethyleneglycol-bis-(-aminoethylether) N,N,N,N-tetraacetic acid - FITC fluorescein isothiocyanate - FITC-NTM fluorescein isothiocyanate-labeled native tropomyosin - NTM native tropomyosin     

Tip-localized actin polymerization and remodeling,reflected by the localization of ADF,profilin and villin,are fundamental for gravity-sensing and polar growth in characean rhizoids

Polar organization and gravity-oriented, polarized growth of characean rhizoids are dependent on the actin cytoskeleton. In this report, we demonstrate that the prominent center of the Spitzenkörper serves as the apical actin polymerization site in the extending tip. After cytochalasin D-induced disruption of the actin cytoskeleton, the regeneration of actin microfilaments (MFs) starts with the reappearance of a flat, brightly fluorescing actin array in the outermost tip. The actin array rounds up, produces actin MFs that radiate in all directions and is then relocated into its original central position in the center of the Spitzenkörper. The emerging actin MFs rearrange and cross-link to form the delicate, subapical meshwork, which then controls the statolith positioning, re-establishes the tip-high calcium gradient and mediates the reorganization of the Spitzenkörper with its central ER aggregate and the accumulation of secretory vesicles. Tip growth and gravitropic sensing, which includes control of statolith positioning and gravity-induced sedimentation, are not resumed until the original polar actin organization is completely restored. Immunolocalization of the actin-binding proteins, actin-depolymerizing factor (ADF) and profilin, which both accumulate in the center of the Spitzenkörper, indicates high actin turnover and gives additional support for the actin-polymerizing function of this central, apical area. Association of villin immunofluorescence with two populations of thick undulating actin cables with uniform polarity underlying rotational cytoplasmic streaming in the basal region suggests that villin is the major actin-bundling protein in rhizoids. Our results provide evidence that the precise coordination of apical actin polymerization and dynamic remodeling of actin MFs by actin-binding proteins play a fundamental role in cell polarization, gravity sensing and gravity-oriented polarized growth of characean rhizoids.Abbreviations ADF Actin-depolymerizing factor - CD Cytochalasin D - MF Microfilament     

Evolutionarily conserved modules in actin nucleation: lessons from Dictyostelium discoideum and plants

Summary. The actin cytoskeleton plays a central part in the dynamic organization of eukaryotic cell structure. Nucleation of actin filaments is a crucial step in the establishment of new cytoskeletal structures or modification of existing ones, providing abundant targets for regulatory processes. A substantial part of our understanding of actin nucleation derives from studies on yeast and metazoan cells. However, recent advances in structural and functional genome analysis in less traditional models, such as plants or Dictyostelium discoideum, provide an emerging picture of an evolutionarily conserved core of at least two actin nucleation mechanisms, one mediated by the Arp2/3 complex and the other one by the formin-based module. A considerable degree of conservation is found also in the systems controlling the balance between filamentous and globular actin (profilin, actin-depolymerizing factor/cofilin) and even in certain regulatory aspects, such as the involvement of Rho-related small GTPases. Identification of such conserved elements provides a prerequisite for the characterization of evolutionarily variable aspects of actin regulation which may be responsible for the rich morphological diversity of eukaryotic cells.Correspondence and reprints: Department of Plant Physiology, Faculty of Sciences, Charles University, Vininá 5, 128 44 Praha 2, Czech Republic.     

Profilin-Dependent Nucleation and Assembly of Actin Filaments Controls Cell Elongation in Arabidopsis

Actin filaments in plant cells are incredibly dynamic; they undergo incessant remodeling and assembly or disassembly within seconds. These dynamic events are choreographed by a plethora of actin-binding proteins, but the exact mechanisms are poorly understood. Here, we dissect the contribution of Arabidopsis (Arabidopsis thaliana) PROFILIN1 (PRF1), a conserved actin monomer-binding protein, to actin organization and single filament dynamics during axial cell expansion of living epidermal cells. We found that reduced PRF1 levels enhanced cell and organ growth. Surprisingly, we observed that the overall frequency of nucleation events in prf1 mutants was dramatically decreased and that a subpopulation of actin filaments that assemble at high rates was reduced. To test whether profilin cooperates with plant formin proteins to execute actin nucleation and rapid filament elongation in cells, we used a pharmacological approach. Here, we used Small Molecule Inhibitor of Formin FH2 (SMIFH2), after validating its mode of action on a plant formin in vitro, and observed a reduced nucleation frequency of actin filaments in live cells. Treatment of wild-type epidermal cells with SMIFH2 mimicked the phenotype of prf1 mutants, and the nucleation frequency in prf1-2 mutant was completely insensitive to these treatments. Our data provide compelling evidence that PRF1 coordinates the stochastic dynamic properties of actin filaments by modulating formin-mediated actin nucleation and assembly during plant cell expansion.The actin cytoskeleton provides tracks for the deposition of cell wall materials and plays important roles during many cellular processes, such as cell expansion and morphogenesis, vesicle trafficking, and the response to biotic and abiotic signals (Baskin, 2005; Smith and Oppenheimer, 2005; Szymanski and Cosgrove, 2009; Ehrhardt and Bezanilla, 2013; Rounds and Bezanilla, 2013). Plant cells respond to diverse internal and external stimuli by regulating the turnover and rearrangement of actin cytoskeleton networks in the cytoplasm (Staiger, 2000; Pleskot et al., 2013). How these actin rearrangements sense the cellular environment and what accessory proteins modulate specific aspects of remodeling remain an area of active investigation (Henty-Ridilla et al., 2013; Li et al., 2014a, 2015).Using high spatial and temporal resolution imaging afforded by variable-angle epifluorescence microscopy (VAEM; Konopka and Bednarek, 2008), we quantified the behavior of actin filaments in Arabidopsis (Arabidopsis thaliana) hypocotyl epidermal cells (Staiger et al., 2009). There are two types of actin filament arrays in the cortical cytoplasm of epidermal cells: bundles and single filaments. Generally, actin bundles are stable with higher pixel intensity values, whereas individual actin filaments are fainter, more ephemeral, and constantly undergo rapid assembly and disassembly through a mechanism that has been defined as “stochastic dynamics” (Staiger et al., 2009; Henty et al., 2011; Li et al., 2012, 2015). Elongating actin filaments in the cortical cytoskeleton originate from three distinct locations: the ends of preexisting actin filaments, the side of filaments or bundles, and de novo in the cytoplasm. Plant actin filaments elongate at rates of 1.6 to 3.4 μm/s, which is the fastest assembly reported in eukaryotic cells. Distinct from the mechanism of treadmilling and fast depolymerization in vitro, however, the disassembly of single actin filaments occurs predominately through prolific severing activity (Staiger et al., 2009; Smertenko et al., 2010; Henty et al., 2011). A commonly held view is that the dynamic actin network in plant cells is regulated by the activities of conserved and novel actin-binding proteins (ABPs). Through reverse-genetic approaches and state-of-the-art imaging modalities, we and others have demonstrated that several key ABPs are involved in the regulation of stochastic actin dynamic properties in a wide variety of plants and cell types (Thomas, 2012; Henty-Ridilla et al., 2013; Li et al., 2014a, 2015). Through these efforts, the field has developed a working model for the molecular mechanisms that underpin actin organization and dynamics in plant cells (Li et al., 2015).Profilin is a small (12–15 kD), conserved actin-monomer binding protein present in all eukaryotic cells (dos Remedios et al., 2003). Profilin binds to actin by forming a 1:1 complex with globular (G-)actin, suppresses spontaneous actin nucleation, and inhibits monomer addition at filament pointed ends (Blanchoin et al., 2014). The consequences of profilin activity on actin filament turnover differ based on cellular conditions and the presence of other ABPs. In vitro studies show that the profilin-actin complex associates with the barbed ends of filaments and promotes actin polymerization by lowering the critical concentration and increasing nucleotide exchange on G-actin (Pollard and Cooper, 1984; Pantaloni and Carlier, 1993). When barbed ends are occupied by capping protein, profilin acts as an actin-monomer sequestering protein. These opposing effects of profilin might be a regulatory mechanism for profilin modulation of actin dynamics in cells. In addition to actin, profilin interacts with Pro-rich proteins, as well as polyphosphoinositide lipids in vitro (Machesky et al., 1994). Formin is an ABP that mediates both actin nucleation and processive elongation using the pool of profilin-actin complexes (Blanchoin et al., 2010). The primary sequence of formin includes a Pro-rich domain, named Formin Homology1 (FH1). Evidence from fission and budding yeast shows that profilin can increase filament elongation rates by binding to the FH1 domain (Kovar et al., 2003; Moseley and Goode, 2005; Kovar, 2006). The FH1 domain of Arabidopsis FORMIN1 (AtFH1) is also reported to modulate actin nucleation and polymerization in vitro (Michelot et al., 2005). Recently, two groups reported that profilin functions as a gatekeeper during the construction of different actin networks generated by formin or ARP2/3 complex in yeast and mammalian cells (Rotty et al., 2015; Suarez et al., 2015). These studies highlight the importance of profilin regulation in coordinating the different actin arrays present in the same cytoplasm of eukaryotic cells. However, direct evidence for how profilin facilitates formin-mediated actin nucleation or barbed end elongation in cells remains to be established.Genomic sequencing and isolation of PROFILIN (PRF) cDNAs from plants reveal that profilin is encoded by a multigene family. For example, moss (Physcomitrella patens) has three isovariants (Vidali et al., 2007) and maize (Zea mays) has five (Staiger et al., 1993; Kovar et al., 2001). In Arabidopsis, at least five PRF genes have been identified (Christensen et al., 1996; Huang et al., 1996; Kandasamy et al., 2002). Studies in maize show that the biochemical properties of profilin isoforms differ in vitro (Kovar et al., 2000). Moreover, the localization of profilin isoforms reveals organ-specific expression patterns. Detection of protein levels in vivo with isovariant-specific profilin antibodies demonstrate that Arabidopsis PRF1, PRF2, and PRF3 are constitutively expressed in vegetative tissues, whereas PRF4 and PRF5 are expressed mainly in flower and pollen tissues (Christensen et al., 1996; Huang et al., 1996; Ma et al., 2005).Several genetic studies on the functions of profilin in plants have been conducted. Reduction of profilin levels in P. patens results in the inhibition of tip growth, disorganization of F-actin, and formation of actin patches (Vidali et al., 2007). Moreover, it was shown that the interaction between profilin and actin or Pro-rich ligands is critical for tip growth in moss. Arabidopsis PRF1 has been demonstrated to be involved in cell elongation, cell shape maintenance, and control of flowering time through overexpression and antisense PRF1 transgenic plants, and further, the reduction of PRF1 inhibits the growth of hypocotyls (Ramachandran et al., 2000). However, investigation of a prf1-1 mutant, which contains a T-DNA insertion in the promoter region of the PRF1 gene, indicates that cell expansion of seedlings is promoted and that protein levels of PRF1 are regulated by light (McKinney et al., 2001). Recently, Müssar et al. (2015) reported a new Arabidopsis T-DNA insertion allele, prf1-4, that shows an obvious dwarf seedling phenotype. To date, however, there has not been a critical examination of the impact of the loss of profilin on the organization and dynamics of bona-fide single actin filaments in vivo.Here, we use a combination of genetics and live-cell imaging to investigate the role of PRF1 in the control of actin dynamics and its effect on axial cell expansion. We observed a significant decrease in the overall filament nucleation frequency in prf1 mutants, which is opposite to expectations if profilin suppresses spontaneous nucleation. Through a pharmacological approach, we found that nucleation frequency in wild-type cells treated with a formin inhibitor, SMIFH2, phenocopied prf1 mutants. We also analyzed the dynamic turnover of individual filaments in prf1 mutants and observed a significant decrease in the rate of actin filament elongation and maximum length of actin filaments. Specifically, we found that PRF1 favors the growth of a subpopulation of actin filaments that elongate at rates greater than 2 μm/s and similar results were obtained in cells after SMIFH2 treatment. Our results provide compelling evidence that Arabidopsis PRF1 contributes to stochastic actin dynamics by modulating formin-mediated actin nucleation and filament elongation during axial cell expansion.     

Functional characterization of <Emphasis Type="Italic">Gossypium hirsutum</Emphasis> profilin 1 gene (<Emphasis Type="Italic">GhPFN1</Emphasis>) in tobacco suspension cells

Cotton fiber is an extremely long plant cell. Fiber elongation is a complex process and the genes that are crucial for elongation are largely unknown. We previously cloned a cDNA encoding an isoform of cotton profilin and found that the gene (designated GhPFN1) was preferentially expressed in cotton fibers. In the present study, we have further analyzed the expression pattern of GhPFN1 during fiber development and studied its cellular function using tobacco suspension cells as an experimental system. We report that expression of GhPFN1 is tightly associated with fast elongation of cotton fibers whose growth requires an intact actin cytoskeleton. Overexpression of GhPFN1 in the transgenic tobacco cells was correlated with the formation of elongated cells that contained thicker and longer microfilament cables. Quantitative analyses revealed a 2.5–3.6 fold increase in total profilin levels and a 1.6–2.6 fold increase in the F-actin levels in six independent transgenic lines. In addition to the effect on cell elongation, we also observed delayed cell cycle progression and a slightly lower mitotic index in the transgenic cells. Based on these data, we propose that GhPFN1 may play a critical role in the rapid elongation of cotton fibers by promoting actin polymerization. Hai-Yun Wang and Yi Yu contributed equally to this work.     

Evidence for actin transformation during the contraction-relaxation cycle of cytoplasmic actomyosin: Cycle blockade by Phalloidin injection

1) The injection of a mushroom drug, Phalloidin (750 microgram -1 mg/ml), into the endoplasmic channel of Physarum veins induces an irreversible blockade of the intrinsic contraction-relaxation automaticity of the ectoplasmic tube wall, as measured by tensiometrical methods. 2) The morphological responses to Phalloidin injection include an increase and condensation of cytoplasmic actomyosin sheets bordering the plasmalemma invaginations within the ectoplasmic tube and a more pronounced dense layer of "groundplasm" in the cell cortex. This is in accordance with experiments with other cells as well as with Physarum. 3) The addition of marker particles to the injection solution revealed that the injected substances can be brought into direct contact with the contractile substrate, before newly formed membranes separate off the injection fluid. 4) Since Phalloidin irreversibly transforms oligomeric actin into a filamentous "Phalloidin-actin complex" and because this transformation does not hinder the actin in activating myosin ATPase, it is concluded that the contraction-relaxation cycle of cytoplasmic actomyosin in Physarum involves actin transformations. If these transformations are hindered, e.g. by Phalloidin, one stage and thereby the whole cycle is sustained which results in a blockade of the intrinsic contraction automaticity. 5) The functional importance of actin transformations in the congraction physiology of cytoplasmic actomyosins and cell motility phenomena is discussed.     

Cortical actin filaments fragment and aggregate to form chloroplast-associated and free F-actin rings in mechanically isolatedZinnia mesophyll cells

Summary Changes in F-actin organization following mechanical isolation ofZinnia mesophyll cells were documented by rhodamine-phalloidin staining. Immediately after isolation, most cells contained irregular cortical actin fragments of varying lengths, and less than 5% of cells contained intact cortical filaments. During the first 8 h of culture, filament fragments were replaced by actin rings, stellate actin aggregates, and bundled filament fragments. Some of these aggregates had no association with organelles (free actin aggregates). Other aggregates were associated with chloroplasts, which changed in shape and location at the same time actin aggregates appeared. F-actin was concentrated within or around the nucleus in a small percentage of cells. After 12 h in culture, the percentage of cells with free actin rings and chloroplast-associated actin aggregates began to decline and the percentage of cells having intact cortical actin filaments increased greatly. Intermediate images were recorded that strongly indicate that free actin rings, chloroplast-associated actin rings, and other actin aggregates self-assemble by successive bundling of actin filament fragments. The fragmentation and bundling of F-actin observed in mechanically isolatedZinnia cells resembles changes in F-actin distribution reported after diverse forms of cell disturbance and appears to be an example of a generalized response of the actin cytoskeleton to cell stress.Abbreviations FITC fluorescein isothiocyanate - MBS m-maleimidobenzoic acid N-hydroxysuccinimide ester - RhPh tetramethylrhodamine isothiocyanate-phalloidin     

An immunofluorescence study of mitosis in a mite-pathogen,Neozygites sp. (Zygomycetes: Entomophthorales)

Summary Mitosis in a mite-pathogenic species ofNeozygites (Zygomycetes: Entomophthorales) was investigated by indirect immunofluorescence microscopy using an antibody against -tubulin for visualization of microtubules (MTs). DAPI and rhodamine-conjugated phalloidin were used to stain chromatin and actin, respectively. Salient features of mitosis inNeozygites sp. are (1) a strong tendency for mitotic synchrony in any given cell, (2) conical protrusions at the poles of metaphase and anaphase nuclei revealed by actin staining, (3) absence of astral and other cytoplasmic MTs, (4) a spindle that occupies most of the nuclear volume at metaphase, (5) a spindle that remains symmetrical throughout most of mitosis, (6) kinetochore MTs that shorten during anaphase A, (7) a central spindle that elongates during anaphase B, pushing the daughter nuclei into the cell apices, and (8) interpolar MTs that continue to elongate even after separation of the daughter nuclei. Cortical cytoplasmic MTs are present in a few interphasic and post-cytokinetic cells. The data presented show thatNeozygites possesses features unique to this genus and support the erection of theNeozygitaceae as a separate family in theEntomophthorales.Abbreviations DAPI 4,6-diamidino-2-phenylindole - MT microtubule - SPB spindle pole body     

Incompatibility with Formin Cdc12p Prevents Human Profilin from Substituting for Fission Yeast Profilin: INSIGHTS FROM CRYSTAL STRUCTURES OF FISSION YEAST PROFILIN*S?

Expression of human profilin-I does not complement the temperature-sensitive cdc3-124 mutation of the single profilin gene in fission yeast Schizosaccharomyces pombe, resulting in death from cytokinesis defects. Human profilin-I and S. pombe profilin have similar affinities for actin monomers, the FH1 domain of fission yeast formin Cdc12p and poly-l-proline (Lu, J., and Pollard, T. D. (2001) Mol. Biol. Cell 12, 1161–1175), but human profilin-I does not stimulate actin filament elongation by formin Cdc12p like S. pombe profilin. Two crystal structures of S. pombe profilin and homology models of S. pombe profilin bound to actin show how the two profilins bind to identical surfaces on animal and yeast actins even though 75% of the residues on the profilin side of the interaction differ in the two profilins. Overexpression of human profilin-I in fission yeast expressing native profilin also causes cytokinesis defects incompatible with viability. Human profilin-I with the R88E mutation has no detectable affinity for actin and does not have this dominant overexpression phenotype. The Y6D mutation reduces the affinity of human profilin-I for poly-l-proline by 1000-fold, but overexpression of Y6D profilin in fission yeast is lethal. The most likely hypotheses to explain the incompatibility of human profilin-I with Cdc12p are differences in interactions with the proline-rich sequences in the FH1 domain of Cdc12p and wider “wings” that interact with actin.The small protein profilin not only helps to maintain a cytoplasmic pool of actin monomers ready to elongate actin filament barbed ends (2), but it also binds to type II poly-l-proline helices (3, 4). The actin (5) and poly-l-proline (6–8) binding sites are on opposite sides of the profilin molecule, so profilin can link actin to proline-rich targets. Viability of fission yeast depends independently on profilin binding to both actin and poly-l-proline, although cells survive >10-fold reductions in affinity for either ligand (1).Fission yeast Schizosaccharomyces pombe depend on formin Cdc12p (9, 10) and profilin (11) to assemble actin filaments for the cytokinetic contractile ring. Formins are multidomain proteins that nucleate and assemble unbranched actin filaments (12). Formin FH2 domains form homodimers that can associate processively with the barbed ends of growing actin filaments (13, 14). FH2 dimers slow the elongation of barbed ends (15). Most formin proteins have an FH1 domain linked to the FH2 domain. Binding profilin-actin to multiple polyproline sites in an FH1 domain concentrates actin near the barbed end of an actin filament associated with a formin FH2 homodimer. Actin transfers very rapidly from the FH1 domains onto the filament end (16) allowing profilin to stimulate elongation of the filament (15, 17).We tested the ability of human (Homo sapiens, Hs)⁷ profilin-I to complement the temperature-sensitive cdc3-124 mutation (11) in the single fission yeast profilin gene with the aim of using yeast to characterize human profilin mutations. The failure of expression of Hs profilin-I to complement the cdc3-124 mutation prompted us to compare human and fission yeast profilins more carefully. We report here a surprising incompatibility of Hs profilin-I with fission yeast formin Cdc12p, a crystal structure of fission yeast profilin, which allowed a detailed comparison with Hs profilin, and mutations that revealed how overexpression of Hs profilin-I compromises the viability of wild-type fission yeast.     

Profilin connects actin assembly with microtubule dynamics

Profilin controls actin nucleation and assembly processes in eukaryotic cells. Actin nucleation and elongation promoting factors (NEPFs) such as Ena/VASP, formins, and WASP-family proteins recruit profilin:actin for filament formation. Some of these are found to be microtubule associated, making actin polymerization from microtubule-associated platforms possible. Microtubules are implicated in focal adhesion turnover, cell polarity establishment, and migration, illustrating the coupling between actin and microtubule systems. Here we demonstrate that profilin is functionally linked to microtubules with formins and point to formins as major mediators of this association. To reach this conclusion, we combined different fluorescence microscopy techniques, including superresolution microscopy, with siRNA modulation of profilin expression and drug treatments to interfere with actin dynamics. Our studies show that profilin dynamically associates with microtubules and this fraction of profilin contributes to balance actin assembly during homeostatic cell growth and affects micro­tubule dynamics. Hence profilin functions as a regulator of microtubule (+)-end turnover in addition to being an actin control element.