Differential cytoplasm-plasma membrane-cell wall adhesion patterns and their relationships to hyphal tip growth and organelle motility

Summary Plasmolysis of hyphae of the oomycetesSaprolegnia ferax andAchlya ambisexualis and the ascomyceteNeurospora crassa produced abundant cytoplasmic strands between the retracted cytoplasm and punctate adhesions of the plasma membrane to the cell wall. These strands formed throughout the length of mature hyphae and are the first demonstration of Hechtian strands in hyphae. In contrast to similar strands in various plant cells, the strands inSaprolegnia lacked endoplasmic reticulum but contained F-actin, suggesting similarity between their adhesion sites and focal contacts in animal cells. However, strand adhesion to the wall was insensitive to RGD-containing peptides, suggesting that the trans-membrane adhesion molecules differ from animal integrins. The pattern of plasma membrane-cell wall adhesion varied in different zones along hyphae, with broad, irregular connections in the extreme apex, uniform and continuous connection in a transition zone, and small, punctate adhesions in the mature subapical zone, suggesting differential functions in these different regions. The apical adhesions are important in tip growth, as diverse inhibitors induced concomitant changes in hyphal growth and the adhesions in the apical and transition zones. Plasmolysis also induced cytoplasmic migrations throughout hyphae. Such migrations were dominated by the central cytoplasm, and produced distorted organelles which spanned central and peripheral cytoplasm, thus supporting the idea that the adhesions in mature zones of hyphae anchor the peripheral cytoplasm and facilitate cytoplasmic and organelle migrations.Abbreviations OM organic medium - RP rhodamine phalloidin - DIC differential interference contrast - PIPES piperazine-N,N-bis-2-ethanosulphonic acid     

Visualization of actin arrays in growing hyphae of the fungusSaprolegnia ferax

Summary We have observed the distribution of filamentous actin in growing hyphae of the oomyceteSaprolegnia ferax. The actin was stained by electroporating intact hyphae in the presence of 4×10^–8 M rhodamine phalloidin. Hyphae quickly recovered from electroporation and showed an apical cap of densely packed actin filaments. The pores created by the electric shock resealed in 8–10min and within 1/2 h hyphae resumed growth and appeared normal. This technique allows us to observe actin arrays during growth and may prove to be a useful tool in determining the complex roles of actin in apical growth.Abbreviations RP rhodamine phalloidin - F-actin filamentous actin     

Involvement of the cytoskeleton in the intracellular distribution of mannoproteins in hyphal cells ofCandida albicans

Cylindrical growth of fungal hyphae requires spatial organization of secretion to the growing tip. In order to better understand the involvement of the cytoskeleton in the spatial control of the secretion, we examined the effects of two anti-cytoskeletal drugs, benomyl and cytochalasin A, on the intracellular distribution of mannoproteins, a major secreted component of the cell wall, in hyphal cells of the dimorphic yeastCandida albicans. The distribution of the mannoproteins was assessed by epifluorescence microscopy with a fluorescence-labelled lentil lectin (FITC-LCA). Brefeldin A, an inhibitor of secretory transport, induced a localized accumulation of the mannopolysaccharides near the tip as previously reported (Akashiet al. 1997). Benomyl, an inhibitor of microtubules, disrupted the localized accumulation of the polysaccharides. Cytochalasin A, an inhibitor of actin, caused a localized accumulation of the polysaccharides near the tip, where Golgi-like cisternae were also accumulated. Both cytochalasin A and brefeldin A caused some modifications of the actinnnetwork, but neither disturbed the polarization of actin and neither affected the microtubule network. Our results suggested that the microtubules are involved in membrane trafficking in hyphal growth as well as the cell polarity of the hyphae.     

How hyphae grow: Morphogenesis explained?

Summary Apical growth of fungal hyphae represents a relatively simple instance of cellular morphogenesis. Thanks to the polarized transport and exocytosis of precursor vesicles, new cell wall and plasma membrane are continuously deposited at the hyphal apex; the question is how the characteristic shape of tube and tapered tip comes about. Recent experiments lend support to a model whose central feature is a mobile vesicle supply center corresponding to the Spitzenkörper (apical body) visible in growing hyphae. Shapes predicted by the model agree remarkably well with those of actual hyphae. Nevertheless, critical examination of the model's premises suggests that it requires extension so as to incorporate both a driving force for expansion and a gradient of cell wall plasticity. I propose that a mobile vesicle supply center may be one, but only one, of a range of physiological devices employed by tip-growing organisms to localize the exocytosis of precursor vesicles. Apical growth should ensue whenever the loci of exocytosis advance vectorially, and nascent cell wall expands in a graded manner.Abbrevations VSC vesicle supply center - SPK Spitzenkörper     

UV microirradiation implicates F-actin in reinforcing growing hyphal tips

Summary The cell walls of plants and fungi are thought to provide the strength required to resist turgor and thus maintain the integrity and morphology of these cells. However, during growth, walls must undergo rapid expansion which requires them to be plastic and therefore weak. In most tip-growing cells there is an apical concentration of F-actin associated with the rapidly expanding cell wall. Disruption of F-actin in the growing tips of hyphae ofSaprolegnia ferax by a localized irradiation, beginning 2–6 m behind the apex, with actin-selective 270 nm uv light caused the hyphae to burst, suggesting that actin supports the weak apical wall against turgor pressure. Bursting was pH dependent and Ca²⁺ independent at neutral pH. Hyphae burst in the very tip, where the cell wall is expected to be weakest and actin is most concentrated, as opposed to the lower part of the apical taper where osmotic shock induces bursting when actin is intact. When hyphae were irradiated with a wavelength of light that is less effective at disrupting actin, growth was slowed but they failed to burst, demonstrating that bursting was most likely due to F-actin damage. We conclude that F-actin reinforces the expanding apical wall in growing hyphae and may be the prime stress bearing structure resisting turgor pressure in tip growing cells.Abbreviations RP rhodamine phalloidin - F-actin filamentous actin - EGTA ethylene-glycol-bis-(-amino-ethyl ether) N,N-tetra-acetic acid - PIPES piperazine-N,N-bis-(2-ethanesulfonic acid) - uv ultraviolet     

Distribution and dynamics of the cytoskeleton in graviresponding protonemata and rhizoids of characean algae: exclusion of microtubules and a convergence of actin filaments in the apex suggest an actin-mediated gravitropism

The organization of the microtubule (MT) and actin microfilament (MF) cytoskeleton of tip-growing rhizoids and protonemata of characean green algae was examined by confocal laser scanning microscopy. This analysis included microinjection of fluorescent tubulin and phallotoxins into living cells, as well as immunofluorescence labeling of fixed material and fluorescent phallotoxin labeling of unfixed material. Although the morphologically very similar positively gravitropic (downward growing) rhizoids and negatively gravitropic (upward growing) protonemata show opposite gravitropic responses, no differences were detected in the extensive three-dimensional distribution of actin MFs and MTs in both cell types. Tubulin microinjection revealed that in contrast to internodal cells, fluorescent tubulin incorporated very slowly into the MT arrays of rhizoids, suggesting that MT dynamics are very different in tip-growing and diffusely expanding cells. Microtubules assembled from multiple sites at the plasma membrane in the basal zone, and a dense subapical array emerged from a diffuse nucleation centre on the basal side of the nuclear envelope. Immunofluorescence confirmed these distribution patterns but revealed more extensive MT arrays. In the basal zone, short branching clusters of MTs form two cortical hemicylinders. Subapical, axially oriented MTs are distributed in equal density throughout the peripheral and inner cytoplasm and are closely associated with subapical organelles. Microtubules, however, are completely absent from the apical zones of rhizoids and protonemata. Actin MFs were found in all zones of rhizoids and protonemata including the apex. Two files of axially oriented bundles of subcortical actin MFs and ring-like actin structures in the streaming endoplasm of rhizoids were detected in the basal zones by microinjection or rhodamine-phalloidin labeling. The subapical zone contains a dense array of mainly axially oriented actin MFs that co-distribute with the subapical MT array. In the apex, actin MFs form thicker bundles that converge into a remarkably distinct actin patch in the apical dome, whose position coincides with the position of the endoplasmic reticulum aggregate in the centre of the Spitzenk?rper. Actin MFs radiate from the actin patch towards the apical membrane. Together with results from previous inhibitor studies (Braun and Sievers, 1994, Eur J Cell Biol 63: 289–298), these results suggest that MTs have a stabilizing function in maintaining the polar cytoplasmic and cytoskeletal organization. The motile processes, however, are mediated by actin. In particular, the actin cytoskeleton appears to be involved in the structural and functional organization of the Spitzenk?rper and thus is responsible for controlling cell shape and growth direction. Despite the similar structural arrangements of the actin cytoskeleton, major differences in the function of actin MFs have been observed in rhizoids and protonemata. Since actin MFs are more directly involved in the gravitropic response of protonemata than of rhizoids, the opposite gravitropism in the two cell types seems to be based mainly on different properties and activities of the actin cytoskeleton. Received: 14 September 1997 / Accepted: 16 October 1997     

Biomechanical models of hyphal growth in actinomycetes

The tip growth of filamentary actinomycetes is investigated within the framework of large deformation membrane theory in which the cell wall is represented as a growing elastic membrane with geometry-dependent elastic properties. The model exhibits realistic hyphal shapes and indicates a self-similar tip growth mechanism consistent with that observed in experiments. It also demonstrates a simple mechanism for hyphal swelling and beading that is observed in the presence of a lysing agent.     

Effects of fixatives and permeabilisation buffers on pollen tubes: implications for localisation of actin microfilaments using phalloidin staining

Summary Standard methods for visualising microfilament (MF) arrays in pollen tubes using rhodamine phalloidin (RP) involve treatment of living tubes with a variety of stabilising, permeabilising, and fixation agents. Video differential interference contrast (DIC) microscopy has been used to investigate the effect of these agents on normalNicotiana pollen tube structure and activity. Most of these agents were found to induce extensive axial translocations generally starting with tipward contractions. These movements were less extensive in the apex compared to more distal regions, however, tips often suffered swelling damage. RP staining patterns of the actin cytoskeleton were highly variable within fixation treatments. In addition to investigating agents used by other authors on pollen tubes, we investigated the efficacy of pretreatment withm-maleimido-benzyol N-hydroxysuccinimide ester (MBS). This resulted in less disruption to the pollen tubes, especially when used alone in growth medium. It also gave better HP-labelling than that achieved in standard aldehyde-fixed specimens. We conclude that standard preparation methods do not faithfully preserve in vivo cytoplasmic integrity in pollen tubes so that subsequent images of MF distribution may be misleading.Abbreviations GM growth medium - RP rhodamine phalloidin - MBS m-maleimidobenzoyl N-hydroxysuccinimide ester - DIC differential interference contrast - MF microfilament - PIPES piperazine-N, N-bis-2-ethanesulphonic acid - PME 50 mM PIPES buffer, pH 6.8, amended with 2.0 mM EGTA and 1 mM MgSO₄ - EB extraction buffer Dedicated to Professor Eldon H. Newcomb in recognition of his contributions to cell biology     

Redistribution of actin, profilin and phosphatidylinositol-4,5-bisphosphate in growing and maturing root hairs

The continuously changing polar cytoplasmic organization during initiation and tip growth of root hairs is reflected by a dynamic redistribution of cytoskeletal elements. The small G-actin binding protein, profilin, which is known to be a widely expressed, potent regulator of actin dynamics, was specifically localized at the tip of root hairs and co-distributed with a diffusely fluorescing apical cap of actin, but not with subapical actin microfilament (MF) bundles. Profilin and actin caps were present exclusively in the bulge of outgrowing root hairs and at the apex of elongating root hairs; both disappeared when tip growth terminated, indicating a tip-growth mechanism that involves profilin-actin interactions for the delivery and localized exocytosis of secretory vesicles. Phosphatidylinositol-4,5-bisphosphate (PIP₂), a ligand of profilin, was localized almost exclusively in the bulge and, subsequently, formed a weak tip-to-base gradient in the elongating root hairs. When tip growth was eliminated by the MF-disrupting inhibitor cytochalasin D, the apical profilin and the actin fluorescence were lost. Mastoparan, which is known to affect the PIP₂ cycle, probably by stimulating phospholipases, caused the formation of a meshwork of distinct actin MFs replacing the diffuse apical actin cap and, concomittantly, tip growth stopped. This suggests that mastoparan interferes with the PIP₂-regulated profilin-actin interactions and hence disturbs conditions indispensable for the maintenance of tip growth in root hairs. Received: 11 March 1999 / Accepted: 27 May 1999     

The dynamic behavior of cytoplasmic F-actin in growing hyphae

Summary A dynamic population of cytoplasmic F-actin was observed with electroporated rhodamine phalloidin (RP) staining in growing hyphae ofSaprolegnia ferax. This central actin population was distinct from the fibrillar peripheral network previously described in chemically fixed hyphae in that it was diffuse, pervaded the entire cytoplasm and was most concentrated in the central cytoplasm 8.4 m from the tip. The peripheral network did not stain with electroporated RP. The apical concentration of central cytoplasmic actin was only present in growing hyphae and developed prior to tip extension. It co-localized with the polarized distribution of mitochondria and endoplasmic reticulum in the tip, suggesting that it functions in positioning these organelles during tip growth. Within the central actin there was a consistent apical cleft which only occurred in growing hyphae and whose position predicted the direction of tip growth. This cleft was coincident with the known accumulation of apical wall vesicles, suggesting that it is either established by vesicle exclusion of the central actin network or is permeated by a portion of the in vivo unstained peripheral network. Photobleaching studies showed that in both growing and non-growing hyphae, cytoplasmic actin continually and rapidly moved from subapical regions to the tip where it accumulated. It mostly moved forward at the rate of tip growth, while some also left the tip, presumably to populate subapical regions.Abbreviations RP rhodamine phalloidin - F-actin filamentous actin - DIC Nomarski differential interference contrast - FITC fluorescein isothiocyanate     

Pollen tube growth: coping with mechanical obstacles involves the cytoskeleton

Cellular growth and movement require both the control of direction and the physical capacity to generate forces. In animal cells directional control and growth forces are generated by the polymerization of and traction between the elements of the cytoskeleton. Whether actual forces generated by the cytoskeleton play a role in plant cell growth is largely unknown as the interplay between turgor and cell wall is considered to be the predominant structural feature in plant cell morphogenesis. We investigated the mechano-structural role of the cytoskeleton in the invasive growth of pollen tubes. These cells elongate rapidly by tip growth and have the ability to penetrate the stigmatic and stylar tissues in order to drill their way to the ovule. We used agents interfering with cytoskeletal functioning, latrunculin B and oryzalin, in combination with mechanical in vitro assays. While microtubule degradation had no significant effect on the pollen tubes’ capacity to invade a mechanical obstacle, latrunculin B decreased the pollen tubes’ ability to elongate in stiffened growth medium and to penetrate an obstacle. On the other hand, the ability to maintain a certain growth direction in vitro was affected by the degradation of microtubules but not actin filaments. To find out whether both cytoskeletal elements share functions or interact we used both drugs in combination resulting in a dramatic synergistic response. Fluorescent labeling revealed that the integrity of the microtubule cytoskeleton depends on the presence of actin filaments. In contrast, actin filaments seemed independent of the configuration of microtubules.     

Rapid wound responses ofSaprolegnia ferax hyphae depend upon actin and Ca2+-involving deposition of callose plugs

Summary Growing hyphae of the oomyceteSaprolegnia ferax wounded by impalement with a ca. 0.2 m diameter glass microelectrode normally respond within seconds with an apically directed cytoplasmic contraction followed by production of a plug which encases the electrode and occludes its recording of transmembrane potentials. This plug contains callose and Ca²⁺-associated membranes. To characterize the rapid wounding response, we disrupted specific filamentous (F) actin populations and Ca²⁺ regulation. Plug formation is inhibited by disruption of F-actin populations and low exogenous Ca²⁺ but not by inhibition of stretch-activated Ca²⁺ channels with Gd³⁺. Therefore, stretch-activated channels are not the immediate sensor. Instead, sensing may involve strain on the actin cytoskeleton which triggers the occlusion response. This wound response is qualitatively similar to the production of septa which isolate developing sporangia and seal severed hyphae, indicating the use of a normal basic cellular developmental system as a protective mechanism against environmental damage. The wound response is essential, since an inability to seal sites of mechanical damage is potentially catastrophic in acellular coenocytic organisms.Abbreviations APW artificial pond water - BAPTA 1,2-bis(orthzo-aminophenoxy)ethane-N,N,N,N-tetrapotassium acetate - CTC chlortetracycline - DIC Nomarski differential interference contrast microscopy - F-actin filamentous actin - LatB latrunculin B - PM plasma membrane - RP rhodamine-labeled phalloidin - SA channels stretch-activated channels     

Non-polymerizing long-pitch actin dimers that interact with myosin

The production of a soluble actomyosin complex would be a significant step toward elucidating molecular interactions responsible for biological movement. We took a systematic approach to producing soluble long-pitch actin dimers that are polymerization-deficient yet retain biological protein-protein interactions, including myosin binding. Actin mutant proteins and chemical crosslinking were combined with different polymerization inhibition strategies, including ADP-ribosylation, or the use of a polymerization-deficient actin mutant protein. While all of the long-pitch actin dimers retained interactions reflective of F-actin activity, each displayed different interactions with myosin. Myosin did not interact productively with long-pitch actin dimers capped with DNase-I, and led to filament formation of unmodified long-pitch actin dimers or dimers possessing a polymerization-deficient actin subunit. However, ADP-ribosylated long-pitch actin dimers interacted with myosin, giving this dimer great potential for producing a soluble actomyosin complex, which could greatly improve our understanding of the molecular basis of movement in cells, tissues, and organisms.     

Force and compliance: rethinking morphogenesis in walled cells

In the turgid cells of plants, protists, fungi, and bacteria, walls resist swelling; they also confer shape on the cell. These two functions are not unrelated: cell physiologists have generally agreed that morphogenesis turns on the deformation of existing wall and the deposition of new wall, while turgor pressure produces the work of expansion. In 1990, I summed up consensus in a phrase: "localized compliance with the global force of turgor pressure." My purpose here is to survey the impact of recent discoveries on the traditional conceptual framework. Topics include the recognition of a cytoskeleton in bacteria; the tide of information and insight about budding in yeast; the role of the Spitzenk?rper in hyphal extension; calcium ions and actin dynamics in shaping a tip; and the interplay of protons, expansins and cellulose fibrils in cells of higher plants.     

Disturbance of endomembrane trafficking by brefeldin A and calyculin A reorganizes the actin cytoskeleton of <Emphasis Type="Italic">Lilium longiflorum</Emphasis> pollen tubes

We investigated the effect of brefeldin A on membrane trafficking and the actin cytoskeleton of pollen tubes of Lilium longiflorum with fluorescent dyes, inhibitor experiments, and confocal laser scanning microscopy. The formation of a subapical brefeldin A-induced membrane aggregation (BIA) was associated with the formation of an actin basket from which filaments extended towards the tip. The orientation of these actin filaments correlated with the trajectories of membrane material stained by FM dyes, suggesting that the BIA-associated actin filaments are used as tracks for retrograde transport. Analysis of time series indicated that these tracks (actin filaments) were either stationary or glided along the plasma membrane towards the BIA together with the attached membranes or organelles. Disturbance of the actin cytoskeleton by cytochalasin D or latrunculin B caused immediate arrest of membrane trafficking, dissipation of the BIA and the BIA-associated actin basket, and reorganization into randomly oriented actin rods. Our observations suggest that brefeldin A causes ectopic activation of actin-nucleating proteins at the BIA, resulting in retrograde movement of membranes not only along but also together with actin filaments. We show further that subapical membrane aggregations and actin baskets supporting retrograde membrane flow can also be induced by calyculin A, indicating that dephosphorylation by type 2 protein phosphatases is required for proper formation of membrane coats and polar membrane trafficking.     

CYFIP dependent actin remodeling controls specific aspects of Drosophila eye morphogenesis

Cell rearrangements shape organs and organisms using molecular pathways and cellular processes that are still poorly understood. Here we investigate the role of the Actin cytoskeleton in the formation of the Drosophila compound eye, which requires extensive remodeling and coordination between different cell types. We show that CYFIP/Sra-1, a member of the WAVE/SCAR complex and regulator of Actin remodeling, controls specific aspects of eye architecture: rhabdomere extension, rhabdomere terminal web organization, adherens junctions, retina depth and basement membrane integrity. We demonstrate that some phenotypes manifest independently, due to defects in different cell types. Mutations in WAVE/SCAR and in ARP2/3 complex subunits but not in WASP, another major regulator of Actin nucleation, phenocopy CYFIP defects. Thus, the CYFIP-SCAR-ARP2/3 pathway orchestrates specific tissue remodeling processes.     

不同培养基对冬虫夏草菌丝生长的影响

不同培养基对3个来源不同的冬虫夏草菌菌丝生长影响的研究结果表明,在不同培养基上,各菌株之间在菌丝萌发时间、40d菌落直径和菌落形态上表现出一定的差异。同时筛选到的最优培养基比已报道培养基的菌落生长速度快2～3倍,且菌丝为白色、粗壮,菌丝质量较优。     

An F-actin-depleted zone is present at the hyphal tip of invasive hyphae of Neurospora crassa

The distribution of filamentous actin (F-actin) in invasive and noninvasive hyphae of the ascomycete Neurospora crassa was investigated. Eighty six percent of noninvasive hyphae had F-actin in the tip region compared to only 9% of invasive hyphae. The remaining 91% of the invasive hyphae had no obvious tip high concentration of F-actin staining; instead they had an F-actin-depleted zone in this region, although some F-actin, possibly associated with the Spitzenk?rper, remained at the tip. The size of the F-actin-depleted zone in invasive hyphae increased with an increase in agar concentration. The membrane stain FM 4-64 reveals a slightly larger accumulation of vesicles at the tips of invasive hyphae relative to noninvasive hyphae, although this difference is unlikely to be sufficient to account for the exclusion of F-actin from the depleted zone. Antibodies raised against the actin filament-severing protein cofilin from both yeast and human cells localize to the tips of invasive hyphae. The human cofilin antibody shows a more random distribution in noninvasive hyphae locating primarily at the hyphal periphery but with some diffuse cytoplasmic staining. This antibody also identifies a single band at 21 kDa in immunoblots of whole hyphal fractions. These data suggest that a protein with epitopic similarity to cofilin may function in F-actin dynamics that underlie invasive growth. The F-actin-depleted zone may play a role in the regulation of tip yielding to turgor pressure, thus increasing the protrusive force necessary for invasive growth.     

Mythical origins of the actin cytoskeleton

The origin of the eukaryotic cell is one of the greatest mysteries in modern biology. Eukaryotic-wide specific biological processes arose in the lost ancestors of eukaryotes. These distinctive features, such as the actin cytoskeleton, define what it is to be a eukaryote. Recent sequencing, characterization, and isolation of Asgard archaea have opened an intriguing window into the pre-eukaryotic cell. Firstly, sequencing of anaerobic sediments identified a group of uncultured organisms, Asgard archaea, which contain genes with homology to eukaryotic signature genes. Secondly, characterization of the products of these genes at the protein level demonstrated that Asgard archaea have related biological processes to eukaryotes. Finally, the isolation of an Asgard archaeon has produced a model organism in which the morphological consequences of the eukaryotic-like processes can be studied. Here, we consider the consequences for the Asgard actin cytoskeleton and for the evolution of a regulated actin system in the archaea-to-eukaryotic transition.