Transcellular ion currents in the water mold Achlya. Amino acid proton symport as a mechanism of current entry

Achlya, like other tip-growing organisms, generates an endogenous electrical current such that positive charge flows into the hyphal apex and exits from the trunk. The present study is concerned with the mechanism of current generation by hyphae growing in a defined, complete medium. The intensity of the current, measured in the extracellular medium with a vibrating probe, was unaffected by the removal of all the inorganic constituents of the growth medium. However, an increase in the external pH or the deletion of amino acids abolished the current. Removal of methionine alone diminished the current by two thirds. Hyphae also generated a longitudinal pH gradient in the extracellular medium; the region surrounding the tip was more alkaline than the bulk medium, whereas the region around the trunk was relatively acidic. These findings suggest that a flux of protons, dependent upon amino acids in the medium, carries current into the tip and creates the surrounding alkaline zone. The proton current appears to result from the transport of amino acids rather than their metabolism. Conditions that abolished the current also inhibited methionine uptake but had little effect on the respiratory rate. The findings imply a connection between the proton current and chemiosmotic energy transduction. We propose that protons flow into the hyphal tip through amino acid/proton symporters that are preferentially localized there. The proton flux energizes the uptake of amino acids into the growing zone and may also contribute to the polarization of hyphal growth.     

Turgor regulation in hyphal organisms

Turgor regulation in two saprophytic hyphal organisms was examined directly with the pressure probe technique. The ascomycete Neurospora crassa, a terrestrial fungi, regulates turgor after hyperosmotic treatments when growing in a minimal medium containing K(+), Mg(2+), Ca(2+), Cl(-), and sucrose. Turgor recovery by N. crassa after hyperosmotic treatment is concurrent with changes in ion transport: hyperpolarization of the plasma membrane potential and a decline in transmembrane ion conductance. In contrast the oomycete Achlya bisexualis, a freshwater hyphal organism, does not regulate turgor after hyperosmotic treatment, although small transient increases in turgor were occasionally observed. We also monitored turgor in both organisms during hypoosmotic treatment and did not observe a turgor increase, possibly due to turgor regulation. Both hyphal organisms grow with similar morphologies, cellular expansion rates and turgor (0.4-0.7 MPa), yet respond differently to osmotic stress. The results do not support the assumption of a universal mechanism of tip growth driven by cell turgor.     

MEMBRANE POTENTIAL AND ENDOGENOUS ION CURRENT OF PHYCOMYCES SPORANGIOPHORES

Glass microelectrodes were inserted into the growing zone of sporangiophores of Phycomyces blakesleeanus that had been submersed in artificial pond water. The membrane potential (inside negative) increased with increasing pH of the bathing solution from an average of ?98 mV at pH 5 up to ?131 mV at pH 7. Removal of Ca²⁺ from the medium hyperpolarized the membrane potential in the wild type, but caused a significant depolarization in the blue-light-insensitive madC mutant. KCN, diethylstilbestrol, and N,N′-dicyclohexylcarbodiimide depolarized the membrane potential in both the wild type and the madC mutant, while fusicoccin had no effect. Endogenous ion current of up to 2 μA cm^?2 was measured in the growing zone of sporangiophores with an extracellular vibrating electrode. The current density and current pattern varied with the pH of the medium. At pH 5 most sporangiophores had weak inward current along the growing zone, whereas at pH 7 most sporangiophores had strong outward current. The response of the membrane potential to specific inhibitors and the presence of an endogenous ion current indicate an electrogenic H⁺-ATPase in the plasma membrane. The results show a negative correlation between growth rate of sporangiophores growing in buffered aqueous medium and magnitude of membrane potential, as well as density of outward current. They also indicate an important role of protons in controlling the growth of Phycomyces sporangiophores.     

Measurement of hyphal turgor

Cellular turgor pressure is thought to provide the driving force for hyphal extension and for a variety of other fungal processes. This study was conducted to evaluate three different approaches to the measurement of hyphal turgor in the aquatic fungus Achlya bisexualis. Turgor was determined indirectly from measurements of the osmotic potential of hyphal extracts using an osmometer and by a refined incipient plasmolysis technique. Turgor was also measured directly from individual growing hyphae using a micropipet-based pressure probe. Osmometry provided an estimate of the mean turgor of hyphae grown in liquid culture of 0.74 MPa, while the incipient plasmolysis technique indicated turgor pressures of between 1.0 and 1.2 MPa (10 to 12 bars). With the pressure probe, turgors ranging from 0.8 to 1.2 MPa were measured from 49 hyphae in the same difined medium. The low turgor estimates from the osmometric approach probably reflected dilution of the cell contents by cell wall and extracellular fluid during sample extraction. Recordings with the pressure probe showed that turgor did not vary along the length of the coenocytic hyphae and was independent of hyphal diameter. This paper presents the first report of the direct measurement of hyphal turgor pressure.     

Polarized Growth of Fungal Hyphae Is Defined by an Alkaline pH Gradient

Robson, G. D., Prebble, E., Rickers, A., Hosking, S., Denning, D. W., Trinci, A. P. J., and Robertson, W. 1996. Polarized growth of fungal hyphae is defined by an alkaline pH gradient. Fungal Genetics and Biology 20, 289-298. Polarized cell growth is exhibited by a diverse range of eukaryotic and prokaryotic cells. The events which are responsible for this growth are poorly understood. However, the existence of ion gradients may play an important role in establishing and driving cell polarity. Using a pH-sensitive, ratiometric fluorescent dye to monitor intracellular pH in growing fungal hyphae, we report a gradient at the extending hyphal tip that is up to 1.4 pH units more alkaline than more distal regions. Both the magnitude and the length of the pH gradient were strongly correlated with the rate of hyphal extension and eradication of the gradient-arrested growth. These results suggest that alkaline pH gradients may be integral to hyphal extension in fungi.     

Modifications of extracellular electric and ionic gradients preceding the transition from tip growth to isodiametric expansion in the apical cell of the fern gametophyte

Fern (Onoclea sensibilis L.) gametophytes exposed to blue light are induced to undergo a morphological transition from a tip-growing filament to a planar prothallus. Extracellular measurements of electric currents and localized ion activities around the apical cell of 8 to 10 day-old gametophytes were made with a vibrating probe and ion selective electrodes. In darkness, we observed exit current densities of an average of 75 nanoamperes per square centimeter near the tip and 2 to 15 nanoamperes per square centimeter along the lateral walls of this cell. Measurements with ion selective electrodes for H⁺, K⁺, and Ca²⁺ showed that this cell was bounded by a thin layer of medium that was depleted in K⁺ and Ca²⁺ and exhibited a lower pH than the bulk solution. Both the K⁺ and Ca²⁺ depletion zones and the zone of higher acidity were particularly pronounced at the tip end of the cell; the pH at 2 micrometers from the tip was nearly 0.5 units more acid than the bulk medium at pH 6. Disruption of steady state, external gradients with media that contained lower concentrations of H⁺, K⁺, Ca²⁺, or Cl⁻ produced certain differences in the rates of restoration of particular ion zones, raising the possibility that some of the ion migrations are interdependent. Within 15 minutes after irradiation with blue light, current leaving the tip declined to levels which were indistinguishable from those leaving the lateral walls and there was a rapid lowering in the rates of tip acidification and K⁺ depletion near the tip. The rapid dissipation of both the longitudinally aligned electrical field and the tip-localized asymmetries in external cation distribution in blue light suggest that loss of electrical polarity in this tip growing cell may be an initial step in the chain of events which govern changes in cell shape.     

Hyphal tip growth in Achlya bisexualis. II. Distribution of cellulose in elongating and non-elongating regions of the wall

Cellulose has been localized in the hyphal wall of elongating and non-elongating hyphae of Achlya bisexualis using a direct enzyme-colloidal-gold method. A number of controls, including several different types of fixation, support the idea that this labeling is specific for cellulose. Both TEM and SEM were used and they gave similar results. The apical area of an elongating hypha lacks cellulose, but the same area of a non-elongating hypha contains cellulose. We have used specific culture media and light microscopic measurements to ensure that we could distinguish between elongating and non-elongating hyphae. The lack of cellulose at the apex of elongating hyphae seems to require a reevaluation of the current concepts of hyphal tip growth in Achlya and related genera. A major question now is to determine whether or not the lack of a microfibrillar component is a universal pattern among all organisms having tip growth.     

Dynamics of mitochondria during the <Emphasis Type="Italic">Neurospora crassa</Emphasis> tip growth

Tip growth of the mycelial fungus N. crassa vegetative hyphae is realized owing to the combined activities of tens of the cells and diverse intracellular structures, such as microvesicles, microtubules, microfilaments, mitochondria, etc. Using a vital mitochondrial probe Mitotracker Red (10 μM, 10 min) we have found that the same mitochondria can move hundreds of microns along the hyphae within several hours. Analysis of the mitochondria distribution along 100 μm of the tips in intact hyphae as well as in the isolated apical fragments has shown that the congregation of mitochondria in the growing tips can correlate with the rate of elongation. These data together with the earlier electrophysiological estimations of the membrane potential gradients along the hyphal tips suggest that the electrical gradients along the hyphal apical part can be involved in the regulation of the energy supply of the tip growth.     

Band structure of surface electric potential in growing roots

For growing roots of azuki bean (Phaseolus chrysanthos), an electric potential is measured minutely along the surface of the root, together with the surface pH. It was found that the root begins to display a band-type pattern of potential with a spatial period of about 2 cm in a mature region as soon as it grows to about 10 cm in root length, while the surface potential shows only one convex peak around a position 5-20 mm behind a root tip and a succeeding concave peak around 20-35 mm, providing the length of root is shorter than about 10 cm. Since the surface potential takes a relatively positive value on average at the side of the root base compared with that in an elongation zone near the tip, electric current is supposed to flow into the elongation zone, accompanied by some local current loops in the mature region. The present band-type pattern observed first in multi-cell systems seems to be a kind of dissipative structure appearing far from equilibrium, and hence its relationship to growth is discussed.     

Polarized Growth of Fungal Hyphae Is Defined by an Alkaline pH Gradient

Robson, G. D., Prebble, E., Rickers, A., Hosking, S., Denning, D. W., Trinci, A. P. J., and Robertson, W. 1996. Polarized growth of fungal hyphae is defined by an alkaline pH gradient.Fungal Genetics and Biology20,289–298. Polarized cell growth is exhibited by a diverse range of eukaryotic and prokaryotic cells. The events which are responsible for this growth are poorly understood. However, the existence of ion gradients may play an important role in establishing and driving cell polarity. Using a pH-sensitive, ratiometric fluorescent dye to monitor intracellular pH in growing fungal hyphae, we report a gradient at the extending hyphal tip that is up to 1.4 pH units more alkaline than more distal regions. Both the magnitude and the length of the pH gradient were strongly correlated with the rate of hyphal extension and eradication of the gradient-arrested growth. These results suggest that alkaline pH gradients may be integral to hyphal extension in fungi.     

Hyphal tip growth in Achlya bisexualis. I. Distribution of 1,3-{beta}-glucans in elongating and non-elongating regions of the wall

We have approached the problem of hyphal tip growth by comparing the cell wall composition of elongating and non-elongating regions of the hyphae of Achlya bisexualis. To ensure that we could distinguish between elongating and non-elongating hyphae, light microscopic observations were used to determine the rates of elongation under growing and non-growing conditions. When elongation was measured in 10 min intervals it was found to consist of fluctuating periods of fast and slow growth rates, in the form of cycles. Even under our growing conditions, however, a very small number of hyphae in a colony are not elongating. SEM analysis revealed that elongating hyphae have tapered apices, whereas non-elongating hyphae have a rounded apex. The major matrix wall components, 1,3-β-glucans, were localized with an indirect immunogold technique specific for these polymers. This method resulted in their localization to all regions of both elongating and non-elongating hyphae, including the apex.     

Relationships between phosphatidylcholine content, chitin synthesis, growth, and morphology of Aspergillus nidulans choC

The phosphatidylcholine (PC) content of Aspergillus nidulans choC was varied by growing the auxotroph in medium containing various concentrations of choline chloride. Direct linear correlations were observed between PC content and in vivo chitin synthase activity, between in vivo chitin synthase activity and mean hyphal extension rate, and between mean hyphal extension rate and hyphal growth unit length; hyphal growth unit length is a measure of hyphal branching. Further, there was a correlation between PC content and colony radial growth rate. Thus, membrane composition is an important determinant of both hyphal (and colony) extension rate and mycelial morphology.     

Critical evaluation of the VSC model for tip growth

The vesicle supply centre (VSC) model (Bartnicki-Garcia et al., 1989) for hyphal tip growth is powerful because it can model diverse developmental morphologies and predicts cellular organization based in current cell biology. It predicts that tip growth results from the random distribution of cell surface synthesizing vesicles from a point in the tip, the VSC, which determines their pattern of impact and fusion at the plasma membrane. We derive equations for tip-high gradients of vesicle fusions, generated by mechanisms not related to a supply centre, which create typical hyphal morphologies. These equations direct the conceptual basis for tip growth to vesicle fusion gradients, presumably mediated by a putative membrane skeleton associated with the plasma membrane. We also show that the organization and behaviour of motile organelles in growing hyphal tips of the oomycete,Saprolegnia ferax, argue against the presence of an apparatus capable of generating the distribution of vesicles postulated by the VSC model. We conclude that the VSC model is unlikely to describe the mechanistic basis of tip growth inS. ferax, and therefore, at best, it is not universally applicable.     

培养介质pH和EGTA对水霉(Saprolegnia ferax)菌丝细胞肌动蛋白的分布与结构的影响

菌丝在pH 5.0—8.0介质中维持顶端生长,Rhodamin-phalloidin荧光探针显示在菌丝顶端都存在F-actin的“帽子”结构;加入EGTA到培养介质中不影响菌丝的顶端生长和actin的“帽子”结构。值得注意的是:菌丝的Rhodamin-phalloidin荧光强度大小与菌丝顶端生长速率成正比;在含有或不含有EGTA的pH5.0培养条件下,菌丝的生长速率均很低,且后部颗粒状的荧光斑点消失;在pH 3.0-4.0培养介质中菌丝生长停止,不但F-actin“帽子”结构消失,整个菌丝荧光也变得非常微弱无法观察,提示酸性pH可引起F-actin的解聚,从而导致生长速率下降甚至生长停止。     

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     

How does a hypha grow? The biophysics of pressurized growth in fungi

The mechanisms underlying the growth of fungal hyphae are rooted in the physical property of cell pressure. Internal hydrostatic pressure (turgor) is one of the major forces driving the localized expansion at the hyphal tip which causes the characteristic filamentous shape of the hypha. Calcium gradients regulate tip growth, and secretory vesicles that contribute to this process are actively transported to the growing tip by molecular motors that move along cytoskeletal structures. Turgor is controlled by an osmotic mitogen-activated protein kinase cascade that causes de novo synthesis of osmolytes and uptake of ions from the external medium. However, as discussed in this Review, turgor and pressure have additional roles in hyphal growth, such as causing the mass flow of cytoplasm from the basal mycelial network towards the expanding hyphal tips at the colony edge.     

The Organization of mitochondria in growing hyphae of Neurospora crassa

Details of mitochondrial system organization and behavior in the tip of growing N. crassa hyphae and hyphal fragments were studied by means of cell-permeable mitochondria-selective probes in glucose- and sorbitol-containing media. It was shown that filamentous mitochondria concentrate in the 30-μm apical zone of growing hyphae and hyphal fragments independently of the carbon source. The mitochondrial assemblies propagate forward with elongation of hypha, split upon apical branching, and are formed de novo when branches are formed away from the growing tip. These activities resemble microtubule behavior. Co-staining with Mitotracker Red and Mitotracker Green revealed possible functional heterogeneity in subpopulations of mitochondria. It was proposed that the observed features are governed by the microtubular network, while the primary function of mitochondria was to sustain the growth rate. The organizing role of electrical gradients on the growing tip and their influence on mitochondrial and microtubular networks are discussed.     

On‐site secretory vesicle delivery drives filamentous growth in the fungal pathogen Candida albicans

Candida albicans is an opportunistic fungal pathogen that colonises the skin as well as genital and intestinal mucosa of most healthy individuals. The ability of C. albicans to switch between different morphological states, for example, from an ellipsoid yeast form to a highly polarised, hyphal form, contributes to its success as a pathogen. In highly polarised tip‐growing cells such as neurons, pollen tubes, and filamentous fungi, delivery of membrane and cargo to the filament apex is achieved by long‐range delivery of secretory vesicles tethered to motors moving along cytoskeletal cables that extend towards the growing tip. To investigate whether such a mechanism is also critical for C. albicans filamentous growth, we studied the dynamics and organisation of the C. albicans secretory pathway using live cell imaging and three‐dimensional electron microscopy. We demonstrate that the secretory pathway is organised in distinct domains, including endoplasmic reticulum membrane sheets that extend along the length of the hyphal filament, a sub‐apical zone exhibiting distinct membrane structures and dynamics and a Spitzenkörper comprised of uniformly sized secretory vesicles. Our results indicate that the organisation of the secretory pathway in C. albicans likely facilitates short‐range “on‐site” secretory vesicle delivery, in contrast to filamentous fungi and many highly polarised cells.     

Effect of electrical fields on polar growth of Phycomyces blakesleeanus

Abstract When Phycomyces blakesleeanus spores germinated in an electrical field of 10–20 V · cm⁻¹, the hyphal tips showed a strong tendency to grow towards the cathode in a medium with pH 7. A similar response was found during growth at pH 5 but a maximal response was only obtained at higher field strength. Also the emergence of the germ tubes from the spores could be polarized by such fields but the degree of polarization was much smaller at pH 7 and almost nonexistent at pH 5. Ionic strength of the medium did not play an important role since only minor differences were found in media with 0, 1 or 10 mM KH₂ PO₄ as the only salts. The results suggest that a voltage-dependent rearrangement of (membrane) proteins affects the polar growth of the fungus.     

Image analysis of hyphal morphogenesis in Saprolegniaceae (Oomycetes)

Because of their wide range of apical morphology, several members of saprolegniaceous fungi (Oomycetes) were chosen to examine concordance with the vesicle supply center (VSC) model of hyphal morphogenesis. Two computer routines were devised to measure diameter changes over long stretches of hyphae and to test compatibility with the theoretical hyphoid shape, y = xcot(xV/N). In all four genera examined, the apex followed closely the contour described by the hyphoid equation; divergences became evident in the subapex. The hyphae of Saprolegnia parasitica showed maximum concordance with the VSC model, i.e., their profile matched a hyphoid curve from the apex to the entire length of the mature hyphal tube. In Aphanomyces and Leptolegnia, growth in the subapical region subsided becoming less than that specified by the hyphoid equation. In Achlya bisexualis, the reverse was true, the subapical region expanded beyond that specified by the hyphoid equation. The two divergent subapical tendencies gave the hyphal tips a cylindroid or conoid appearance, respectively. Since the hyphal apex of all four species conformed to the curvature dictated by the hyphoid equation, we concluded that a basic VSC mechanism operates in all of these oomycetous fungi. Accordingly, we suggest that the shape of an oomycetous hypha is generated by a VSC-driven gradient of wall formation, which is subject to additional modification in the subapex to produce a range of hyphal tip morphologies. The mathematical basis for generating a conoid hyphal tip by elongating the VSC is described in Appendix A.