Gadolinium effects on gigaseal formation and the adhesive properties of a fungal amoeboid cell, the slime mutant of Neurospora crassa.

Low gadolinium concentrations induce rapid gigaseal formation and cell adhesion to glass and plastic (polystyrene) substrates in the slime mutant of Neurospora crassa. Cellular adhesion is independent of an integrin-mediated mechanism, because pretreatment with the oligopeptide ARG-GLY-ASP-SER (RGDS) did not inhibit it, and there was no spatial correlation between integrin and adhesions. In contrast, concanavalin A and beta-galactosidase both inhibit adhesion, suggesting that adhesion is mediated by sugar moeities at the cell surface. The adhesion sites are motile in the plasma membrane, as shown by the movement of polystyrene microspheres on the cell surface. In addition to an integrin-based adhesive system, which has already been characterized in walled hyphal cells, hyphae have evolved at least two different plasma membrane-based adhesion mechanisms. The relatively non-specific sugar-mediated adhesion caused by gadolinium may be part of the mechanism of gigaseal formation in other cells. In the absence of sugar-mediated adhesion, gadolinium increases the magnitude of the gigaseal in giant unilamellar liposomes composed of phosphatidylcholine, phosphatidylethanolamine, and cholesterol, with or without the negatively charged phosphatidylserine. Thus, gigaseal formation involves at least two different mechanisms.

Ca(2+) shuttling in vesicles during tip growth in Neurospora crassa.

Tip-growing organisms maintain an apparently essential tip-high gradient of cytoplasmic Ca(2+). In the oomycete Saprolegnia ferax, in pollen tubes and root hairs, the gradient is produced by a tip-localized Ca(2+) influx from the external medium. Such a gradient is normally dispensable for Neurospora crassa hyphae, which may maintain their Ca(2+) gradient by some form of internal recycling. We localized Ca(2+) in N. crassa hyphae at the ultrastructural level using two techniques (a) electron spectroscopic imaging of freeze-dried hyphae and (b) pyroantimoniate precipitation. The results of both methods support the presence of Ca(2+) in the wall vesicles and Golgi body equivalents, providing a plausible mechanism for the generation and maintenance of the gradient by Ca(2+) shuttling in vesicles to the apex, without exogenous Ca(2+) influx. Ca(2+) sequestration into the vesicles seems to be dependent on Ca(2+)-ATPases since cyclopiazonic acid, a specific inhibitor of Ca(2+) pumps, eliminated all Ca(2+) deposits from the vesicles of N. crassa.

Cytoskeletal and Ca2+ regulation of hyphal tip growth and initiation.

Hyphal tip growth is a complex process involving finely regulated interactions between the synthesis and expansion of cell wall and plasma membrane, diverse intracellular movements, and turgor regulation. F-actin is a major regulator and integrator of these processes. It directly contributes to (a) tip morphogenesis, most likely by participation in an apical membrane skeleton that reinforces the apical plasma membrane, (b) the transport and exocytosis of vesicles that contribute plasma membrane and cell wall material to the hyphal tips, (c) the localization of plasma membrane proteins in the tips, and (d) cytoplasmic and organelle migration and positioning. The pattern of reorganization of F-actin prior to formation of new tips during branch initiation also indicates a critical role in early stages of assembly of the tip apparatus. One of the universal characteristics of all critically examined tip-growing cells, including fungal hyphae, is the obligatory presence of a tip-high gradient of cytoplasmic Ca2+ that probably regulates both actin and nonactin components of the apparatus, and the formation of which may also initiate new tips. This review discusses the diversity of evidence behind these concepts.

A putative spectrin-containing membrane skeleton in hyphal tips of Neurospora crassa.

The apical plasma membrane (PM) is important in hyphal tip growth, where it may regulate tip extensibility via its association with an appropriate membrane skeleton (MS). By cell fractionation and immunocytochemistry we show that proteins with characteristics of actin, spectrin, and integrin are associated in a MS-like manner with the PM of Neurospora crassa hyphae. The spectrin-like protein in particular is highly concentrated at the PM in the region of maximum apical expansion. This protein shares with other spectrins immunoreactivity, molecular weight, PM association, and actin binding capacity. Its distribution in hyphae suggests that it is a dominant component of the MS in true fungi and is critical to hyphal tip growth.

Plasma membrane-adjacent actin filaments, but not microtubules, are essential for both polarization and hyphal tip morphogenesis in Saprolegnia ferax and Neurospora crassa.

The organization and roles of F-actin and microtubules in the maintenance and initiation of hyphal tip growth have been analyzed in Saprolegnia ferax and Neurospora crassa. In hyphae of both species, the apex is depleted of microtubules relative to subapical regions and near-normal morphogenesis occurs in concentrations of nocodazole or MBC which remove microtubules, slow growth, and disrupt nuclear positioning. In contrast, each species contains characteristic tip-high arrays of plasma membrane-adjacent F-actin, whose organization is largely unaltered by the loss of microtubules but disruption of which by latrunculin B disrupts tip morphology. Hyphal initiation and subsequent normal morphogenesis from protoplasts of both species and spores of S. ferax are independent of microtubules, but at least in S. ferax obligatorily involve the formation of F-actin caps adjacent to the hyphal tip plasma membrane. These observations indicate an obligatory role for F-actin in hyphal polarization and tip morphogenesis and only an indirect role for microtubules.

A tip-high gradient of a putative plasma membrane SNARE approximates the exocytotic gradient in hyphal apices of the fungus Neurospora crassa.

Antibodies to the Saccharomyces cereviseae plasma membrane t-SNARE Sso2p identify a putative 39-kDa homologue in Neurospora crassa. The 39-kDa protein is enriched in plasma membrane (PM) and occurred with other membranes. It is extractable by detergent, but not chaotropic or alkali agents, suggesting membrane insertion. Immunoprecipitation with anti-Sso2p coprecipitated a approximately 100-kDa, Mg(+)-ATP-sensitive band with the 39-kDa protein, suggesting a ternary SNARE complex. Affinity-purified anti-Sso2p gave hyphal staining patterns most consistent with protein localization on both the PM and intracellular exocytotic apical wall vesicles. The PM staining in hyphal apices formed a tip-high gradient, not as steep as that predicted by the "hyphoid equation," but closer to published gradients of cell wall matrix deposition. We conclude that the t-SNAREs are transported to the PM on the apical vesicles, but their tip-high gradient alone is insufficient to explain the vesicle fusion gradient in growing tips.

Mechanisms of hyphal tip growth: tube dwelling amebae revisited.

Over 100 years ago, Reinhardt suggested that hyphal tip growth is comparable to ameboid movement inside a tube; the apical cytoplasm being protruded like a pseudopodium with the wall assembled on its surface. There are increasing data from hyphae which are explicable by this model. Fungi produce pseudopodia-like structures and their cytoplasm contains all of the major components implicated in pseudopodium production in animal cells. Most of these components are concentrated in hyphal tips and tip growth involves actin, a major component of pseudopodia. Together these data indicate that the essence of the ameboid model is still tenable. However, detailed mechanisms of tip growth remain too poorly known to provide definitive proof of the model and the behavior of the trailing cytoplasm indicates differences which are probably a response to the walled lifestyle.

Neither compatible nor self-incompatible pollinations of Brassica napus involve reorganization of the papillar cytoskeleton.

Compatible pollination of Brassica napus necessitates pollen hydration, pollen germination and growth of the pollen tube through the loosened walls of stigmatic papillar cells, whereas self-incompatible (SI) pollinations fail at one of these stages. Analyses of the early stages of pollination show that at high (but not low) relative humidities, both compatible and SI pollen hydrates, but SI germination is reduced and the rare pollen tubes generally fail to penetrate the papillar walls, although there is some wall loosening. Inside the papillae, both compatible and SI interactions may induce the formation of callose, but there is no evidence for a major accumulation of cytoplasm or secretory vesicles in the vicinity of the pollen tubes and neither microtubule nor F-actin patterns re-arrange in this zone. These observations indicate that the source of the wall-loosening enzymes is probably the pollen tube or pollen coat, and that the common cellular responses of plants to attempted invasions have become suppressed in the papilla-pollen tube interaction.

Radial F-actin arrays precede new hypha formation in Saprolegnia: implications for establishing polar growth and regulating tip morphogenesis.

The roles of cortical F-actin in initiating and regulating polarized cell expansion in the form of hyphal tip morphogenesis were investigated by analyzing long term effects of F-actin disruption by latrunculin B in the oomycete Saprolegnia ferax, and detecting localized changes in the cortical F-actin organization preceding hyphal formation. Tubular hyphal morphology was dependent on proper F-actin organization, since latrunculin induced dose-dependent actin disruption and corresponding changes in hyphal morphology and wall deposition. With long incubation times (1 to 3 hours), abundant subapical expansion occurred, the polar form of which was increasingly lost with increasing actin disruption, culminating in diffuse subapical expansion. These extreme effects were accompanied by disorganized cytoplasm, and novel reorganization of microtubules, characterized by star-burst asters. Upon removing latrunculin, hyperbranching produced abundant polar branches with normal F-actin organization throughout the colony. The results are consistent with F-actin regulating polar vesicle delivery and controlling vesicle fusion at the plasma membrane, and suggest that F-actin participates in establishing polar growth. To test this idea further, we utilized the hyperbranching growth form of Saprolegnia. Early during the recovery time, prior to multiple branch formation, radial arrays of filamentous F-actin were observed in regions with no detectable surface protrusion. Their locations were consistent with those of the numerous branches that formed with longer recovery times. Similar radial arrays preceded germ tube formation in asexual spores. The arrays were important for initiating polar growth since the spores lost their ability to polarize when the F-actin was disrupted with latrunculin, and increased isometrically in size rather than producing germ tubes. Therefore, F-actin participates in initiating tip formation in addition to its previously demonstrated participation in maintenance of hyphal tip growth. The cortical location and radial organization of the arrays suggest that they recruit and stabilize membrane-bound and cytosolic factors required to build a new tip.

Interrelationships between cytoplasmic Ca2+ peaks, pollen hydration and plasma membrane conductances during compatible and incompatible pollinations of Brassica napus papillae.

We have investigated Ca(2+)-involving cell signaling, plasma membrane potentials and conductances and callose formation during early stages of pollination of papillae of Brassica napus. Using fluorescence imaging of calcium green-1, we found that application of a range of pollen types and controls all rapidly produced small localized peaks in papillar cytoplasmic [Ca2+]. This response was more frequent in compatible than incompatible interactions and was correlated with subsequent hydration of the applied pollen grains, indicating that it may be a differential prerequisite of the compatible signaling pathway leading to successful pollinations. In contrast, a slight trend to increased plasma membrane conductance (but with no indications of action potential-like responses) and also callose deposition in papillae adjacent to pollen grains followed pollination in both SC and SI interactions, indicating that alterations in plasma membrane permeability and callose deposition during early phases of pollination are not primary determinants of the fate of attempted pollinations.

The roles of Ca2+ and plasma membrane ion channels in hyphal tip growth of Neurospora crassa.

Growing hyphae of the ascomycete fungus Neurospora crassa contained a tip-high gradient of cytoplasmic Ca2+, which was absent in non-growing hyphae and was insensitive to Gd3+ in the medium. Patch clamp recordings in the cell-attached mode, from the plasma membrane of these hyphae, showed two types of channel activities; spontaneous and stretch activated. The spontaneous channels were identified as inward K+ channels based on inhibition by tetraethylammonium. The stretch activated channels had increased amplitudes in response to elevated Ca2+ in the pipette solution, and thus are permeable to Ca2+ and mediate inward Ca2+ movement. Gd3+, which is an inhibitor of some stretch activated channels, incompletely inhibited stretch activated channel activity. Both tetraethylammonium and Gd3+ only transiently reduced the rates of tip growth without changing tip morphology, thus indicating that the channels are not absolutely essential for tip growth. Furthermore, in contrast to the hyphae of another tip growing organism, Saprolegnia ferax, tip-high gradients of neither spontaneous nor stretch activated channels were found. Voltage clamping of the apical plasma membrane potential in the range from -300 to +150 mV did not affect the rates of hyphal elongation. Collectively, these data suggest that ion transport across the plasma membrane at the growing tip in Neurospora is not obligatory for the maintenance of tip growth, but that a gradient of Ca2+, possibly generated from internal stores in an unknown way, is required.

Ca(2+)-dependent polarization of axis establishment in the tip-growing organism, Saprolegnia ferax, by gradients of the ionophore A23187.

A gradient of the divalent cation ionophore A23187 polarized axis establishment in regenerating hyphal protoplasts and germinating cysts of the tip-growing oomycete Saprolegnia ferax. An average of sixty-three percent of new hyphae emerging from initially spherical protoplasts were oriented towards the ionophore source. This polarization was dependent on the presence of Ca2+ and could not be elicited by the presence of either 1 mM Mn2+ or Mg2+. A similar but less marked (56%) orientation was shown by germinating cysts, either with or without pretreatment with the anti-microtubule drug, nocodazole. Further, cyst-derived hyphae which did not originally emerge facing the ionophore source later showed a tendency to reorient their growth towards it. Since A23187 is known to facilitate the entry of Ca2+ into cells, and since, in protoplasts at least, the response is Ca2+ dependent, these results imply that an ionophore-generated Ca2+ gradient within the cells may be responsible for the observed polarizing influence on protoplasts and cysts. It is likely that the role of Ca2+ is essentially the same in both systems: a primary common factor in the establishment of the growth axis. The results provide evidence that Ca2+ polarizes hyphal growth and support the idea that Ca2+ has a ubiquitous, primary role in the initiation of polarity in tip-growing cells.

Integrin and spectrin homologues, and cytoplasm-wall adhesion in tip growth.

Saprolegnia ferax contains an integrin homologue, identified by crossreactivity with antiserum to the consensus sequence of human/chick/Xenopus cytoplasmic domain beta 1-integrin, which is highly conserved. In non-reduced samples, this integrin was larger than the reported size range for beta 1-integrins, at 178 kDa. In reduced samples, there was a reducing agent-concentration-dependent conversion from 178 kDa to 120 kDa, well within the reported size range for beta 1-integrins in other organisms. The integrin antiserum stained plasma membrane-associated patches, which had a shallow tip-high gradient. This population was reduced and its distribution perturbed in hyphae whose growth rate was reduced by half with tetrapentyl ammonium chloride. The expected integrin function in cytoplasm-cell wall attachment was shown by differential resistance to plasmolysis-induced separation, which positively correlated with integrin abundance. However, when there was separation, remnants of cytoplasm stayed attached to the wall. These were enriched in actin and integrin. Saprolegnia also has a spectrin homologue identified by crossreactivity with an erythrocyte spectin antibody, which has a size (246 kDa) similar to other organisms. This spectrin had a superficially similar distribution to that of integrin, but it did not participate in cytoplasm-wall anchoring. These data suggest that Saprolegnia hyphae have a plasma membrane which is strengthened by spectrin, and cytoplasm which is attached to the cell wall by integrin.

Morphological effects of lipopeptides against Aspergillus fumigatus correlate with activities against (1,3)-beta-D-glucan synthase.

The lipopeptide antifungal agents, echinocandins, papulacandins, and pneumocandins, kill Candida albicans by inhibiting glucan synthesis. For this fungus, there is a good correlation of in vitro enzyme inhibition with in vitro assays of MICs. Semisynthetic lipopeptides such as cilofungin, LY303366, L-693,989, and L-733,560 have activity in vivo against Aspergillus infections but appear to be inactive in broth dilution in vitro tests (MICs, > 128 micrograms/ml). To understand how compounds which lack activity in vitro can have good in vivo activity, we monitored the effect of pneumocandins on the morphology of Aspergillus fumigatus and A, flavus strains by light microscopy and electron microscopy and related the changes in growth to inhibition of glucan synthesis. Pneumocandin B0 caused profound changes in hyphal growth; light micrographs showed abnormally swollen germ tubes, highly branched hyphal tips, and many cells with distended balloon shapes. Aspergillus electron micrographs confirmed that lipopeptides produce changes in cell walls; drug-treated germlings showed very stubby growth with thick walls and a conspicuous dark outer layer which was much thicker in the subapical regions. The rest of the hyphal tip ultrastructure was unaffected by the drug, indicating considerable specificity for the primary target. The drug-induced growth alteration produced very compact clumps in broth dilution wells, making it possible to score the morphological effect macroscopically. The morphological changes could be assayed quantitatively by using conventional broth microdilution susceptibility assay conditions. We defined the endpoint as the lowest concentration required to produce the morphological effect and called it the minimum effective concentration to distinguish it from the no-growth endpoints used in MIC determinations. The minimum effective concentration assay was related to inhibition of glucan synthase activity in vitro and may provide a starting point for development of susceptibility testing methods for lipopeptides.

A comparison of techniques for localizing actin and tubulin in hyphae of Saprolegnia ferax.

We have evaluated protocols for immunofluorescence (IF) staining of the potentially interacting actin filaments (F-actin) and microtubules in hyphae of Saprolegnia ferax, using rhodamine-phalloidin (RP) and freeze-substitution electron microscopy (FSEM), respectively, as standards for their distribution. Saprolegnia has four distinguishable cortical F-actin populations with characteristic organizations and RP- and actin-IF-staining affinities, all of which could be labeled with both probes after some protocols. Other protocols stained only some of the populations. Cortical F-actin was always more reproducibly and sharply stained with RP than IF, indicating that the former is the probe of choice for F-actin in these cells. Although no single IF protocol revealed all of the F-actin and microtubule populations, showing the potential need to optimize protocols for specific antibodies, simultaneous localization was readily achieved by dual labeling with RP and tubulin IF. Tubulin IF patterns differed from FSEM: mitotic spindles were revealed but not the more abundant prophase microtubule arrays, and the cytoplasmic microtubules were subapically displaced and bundled into long cables. These cables, which apparently linked nuclei, indicate a previously undetected involvement in nuclear spacing. The tubulin antibody successfully used for IF failed to recognize any proteins in immunoblots, indicating that immunoblots may not always be a useful indicator of success with IF.

Cytoskeletal regulation of ion channel distribution in the tip-growing organism Saprolegnia ferax.

Growing hyphal tips of the oomycete Saprolegnia ferax possess a tip-high gradient of stretch-activated ion channels permeable to calcium. These mechanosensitive channels appear to play a direct role in the polarized tip growth process. Treatment of S. ferax hyphae with cytochalasin E leads to the disruption of plasmalemma-associated, peripheral cytoplasmic actin populations and altered morphology of apical protoplasts, and eliminates the tip-high gradient of stretch-activated channels. Cytochalasin E did not alter the normal aggregation of stretch-activated channels. The density of spontaneous K+ channels was decreased in all regions of the hyphae after treatment with cytochalasin E. These results suggest that the peripheral F-actin network in the growing tip of S. ferax hyphae establishes or maintains the tip-high gradient of SA channels, either by the delivery of channel-bearing vesicles to the apex or by the interactions between the channels and the peripheral actin network.

Roles of calcium ions in hyphal tip growth.

A role for Ca2+ in the tip growth process of fungal hyphae and other eukaryotic walled cells has been widely explored, following the earlier indications of their importance by Jaffe, Steer, and their colleagues. Analysis of the literature on fungi, with selected comparison with other tip-growing plant cells, shows that the growth rate and morphology of hyphae are sensitive to factors which influence intracellular Ca2+. These factors include variations in extracellular Ca2+ concentrations, Ca2+ ionophores, inhibitors of Ca2+ transport, and calmodulin- and Ca(2+)-binding dyes and buffers introduced into the cytoplasm. The effects of these agents appear to be mediated by a tip-high gradient of cytoplasmic free Ca2+ which is obligatorily present in all critically examined growing tips. Most recent observations agree that the gradient is very steep, declining rapidly within 10 to 20 microns of the tip. This gradient seems to be generated by the combined effects of an influx of Ca2+, via plasma membrane, possibly stretch-activated, channels localized in the hyphal tip, and subapical expulsion or sequestration of these ions. Expulsion probably involves a plasma membrane Ca(2+)-ATPase, but it is not yet possible to differentiate among mitochondria, endoplasmic reticulum, or vacuoles as the dominant sites of sequestration. It is suggested that regulation of the Ca2+ gradient in turn modulates the properties of the actin-based component of the cytoskeleton, which then controls the extensibility, and, possibly, the synthesis of the hyphal apex. Regulatory feedback mechanisms intrinsic to this model of tip growth regulation are briefly discussed, together with suggestions for future experiments which are crucial to its further elucidation and establishment.