Electron tomographic characterization of a vacuolar reticulum and of six vesicle types that occupy different cytoplasmic domains in the apex of tip-growing <Emphasis Type="Italic">Chara</Emphasis> rhizoids

We provide a 3D ultrastructural analysis of the membrane systems involved in tip growth of rhizoids of the green alga Chara. Electron tomography of cells preserved by high-pressure freeze fixation has enabled us to distinguish six different types of vesicles in the apical cytoplasm where the tip growth machinery is accommodated. The vesicle types are: dark and light secretory vesicles, plasma membrane-associated clathrin-coated vesicles (PM-CCVs), Spitzenkoerper-associated clathrin-coated vesicles (Sp-CCVs) and coated vesicles (Sp-CVs), and microvesicles. Each of these vesicle types exhibits a distinct distribution pattern, which provides insights into their possible function for tip growth. The PM-CCVs are confined to the cytoplasm adjacent to the apical plasma membrane. Within this space they are arranged in clusters often surrounding tubular plasma membrane invaginations from which CCVs bud. This suggests that endocytosis and membrane recycling are locally confined to specialized apical endocytosis sites. In contrast, exocytosis of secretory vesicles occurs over the entire membrane area of the apical dome. The Sp-CCVs and the Sp-CVs are associated with the aggregate of endoplasmic reticulum membranes in the center of the growth-organizing Spitzenkoerper complex. Here, Sp-CCVs are seen to bud from undefined tubular membranes. The subapical region of rhizoids contains a vacuolar reticulum that extends along the longitudinal cell axis and consists of large, vesicle-like segments interconnected by thin tubular domains. The tubular domains are encompassed by thin filamentous structures resembling dynamin spirals which could drive peristaltic movements of the vacuolar reticulum similar to those observed in fungal hyphae. The vacuolar reticulum appears to serve as a lytic compartment into which multivesicular bodies deliver their internal vesicles for molecular recycling and degradation. Electronic supplementary material The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Protoplasmic Organization of Hyphal Tips Among Fungi: Vesicles and Spitzenkörper

Hyphal tips of fungi representing Oömycetes, Zygomycetes, Ascomycetes, Basidiomycetes, and Deuteromycetes were examined by light and electron microscopy and compared with respect to their protoplasmic organization. In all fungi studied, there is a zone at the hyphal apex which is rich in cytoplasmic vesicles but nearly devoid of other cell components. Some vesicle profiles are continuous with the plasma membrane at the apices of these tip-growing cells. The subapical zones of hyphae contain an endomembrane system which includes smooth-surfaced cisternae associated with small clusters of vesicles. The findings are consistent with the hypothesis that vesicles produced by the endomembrane system in the subapical region become concentrated in the apex where they are incorporated at the expanding surface. Septate fungi (Ascomycetes, Basidiomycetes, and Deuteromycetes) have an apical body (Spitzenkörper) which is associated with growing hyphal tips. In electron micrographs of these fungi, an additional specialized region within the accumulation of apical vesicles is shown for the first time. This region corresponds on the bases of distribution among fungi, location in hyphae, size, shape and boundary characteristics to the Spitzenkörper seen by light microscopy. This structure is not universally associated with tip growth, whereas apical vesicles are widespread among tip-growing systems.     

Ultrastructural aspects of the hyphal tip ofSclerotium rolfsii preserved by freeze substitution

Summary The hyphal tip ofSclerotium rolfsii was examined after fixation by freeze substitution. The Spitzenkörper consisted of a dense mass of apical vesicles and microvesicles surrounding a vesicle-free zone. Linear arrangements of microvesicles were occasionally observed within the Spitzenkörper. Abundant microfilaments were seen within the Spitzenkörper region, often in close association with apical vesicles and microvesicles. Microtubules passed through the Spitzenkörper and terminated at the plasmalemma at the extreme hyphal apex. Filasomes were mostly observed within the apical region and were in close proximity to the plasmalemma. Rough ER, mitochondria, microtubules, and vacuoles were abundant in the subapical region and were usually oriented parallel to the long axis of the hypha. Ribosomes were aligned on the outer surfaces of mitochondria. Golgi body equivalents were observed throughout the subapical region and appeared as inflated cisternae of varying shapes and electron opacities. Relationships to other basidiomycetous hyphal tip cells are discussed.Abbreviations AV apical vesicle - C Celsius - diam diameter - f filasome - G Golgi body equivalent - h hour - nm nanometer - M mitochondria - ME membranous elements; min minute - MV microvesicle - MVB multivesicular body - N nucleus - OsO₄ osmium tetroxide - R ribosome - ER endoplasmic reticulum - S Spitzenkörper - Va vacuole - m micrometer     

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.     

Hyphal tip organization inAllomyces arbuscula

Summary Light and electron microscopic observations on vegetative hyphae ofAllomyces arbuscula revealed the specialized organization of the tip. There were some minor differences related to culture conditions, but the main ultrastructural features common to all hyphal tips disclosed a special type of organization distinct from that of other fungi. A crescent-shaped apical zone consisted of vesicles and membrane cisternae embedded in a granular matrix. Vesicles fused with the apical plasmalemma and presumably contributed to its expansion and to wall growth. The apical zone contained few ribosomes and generally no other organelles. Mitochondria were concentrated in the immediate subapical zone and scattered through the remainder of the hyphae, as were microbodies. Microtubules formed an asterlike structure with its center in the apical zone. Proximally of the apex, microtubules were axially oriented. Nuclei occurred only a certain distance from the tip. The elements of the apex may maintain the polarity of the hyphae via a gradient and hold it in a state of vegetative growth.     

ULTRASTRUCTURE OF GLANDULAR OVARIAN TRICHOMES OF CYPRIPEDIUM CALCEOLUS AND C. REGINAE (ORCHIDACEAE)

Trichomes on the orchid ovary are a possible site of synthesis and secretion of the floral scent. Scanning electron microscopy of these trichomes shows a bulbous cell on a two-celled stalk. Thin sections of the tip cell revealed the morphology of an active, secretory cell with unusual coated vesicles in the extra-cellular deposition. Abundant smooth endoplasmic reticulum (ER) aggregated beneath the plasma membrane in the apical region of the cell and the limited dictyosomes in the cell suggest direct secretion by ER. Numerous lipid droplets are present in the apical area. Plastids, found only in the basal region of this cell, are more round in profile than typical chloroplasts and contain only a few unstacked thylakoids and a limited membranous reticulum. In addition to the normal plastid envelope, a double layer of membrane (probably ER) is tightly appressed to each dense, starch-free plastid. Highly specialized morphology and subcellular localization of organelles suggest the secretory nature of these trichomes.     

The Neurospora crassa exocyst complex tethers Spitzenk?rper vesicles to the apical plasma membrane during polarized growth

Fungal hyphae are among the most highly polarized cells. Hyphal polarized growth is supported by tip-directed transport of secretory vesicles, which accumulate temporarily in a stratified manner in an apical vesicle cluster, the Spitzenkörper. The exocyst complex is required for tethering of secretory vesicles to the apical plasma membrane. We determined that the presence of an octameric exocyst complex is required for the formation of a functional Spitzenkörper and maintenance of regular hyphal growth in Neurospora crassa. Two distinct localization patterns of exocyst subunits at the hyphal tip suggest the dynamic formation of two assemblies. The EXO-70/EXO-84 subunits are found at the peripheral part of the Spitzenkörper, which partially coincides with the outer macrovesicular layer, whereas exocyst components SEC-5, -6, -8, and -15 form a delimited crescent at the apical plasma membrane. Localization of SEC-6 and EXO-70 to the plasma membrane and the Spitzenkörper, respectively, depends on actin and microtubule cytoskeletons. The apical region of exocyst-mediated vesicle fusion, elucidated by the plasma membrane–associated exocyst subunits, indicates the presence of an exocytotic gradient with a tip-high maximum that dissipates gradually toward the subapex, confirming the earlier predictions of the vesicle supply center model for hyphal morphogenesis.     

The Plasma Membrane Proton Pump PMA-1 Is Incorporated into Distal Parts of the Hyphae Independently of the Spitzenk?rper in Neurospora crassa

Most models for fungal growth have proposed a directional traffic of secretory vesicles to the hyphal apex, where they temporarily aggregate at the Spitzenkörper before they fuse with the plasma membrane (PM). The PM H⁺-translocating ATPase (PMA-1) is delivered via the classical secretory pathway (endoplasmic reticulum [ER] to Golgi) to the cell surface, where it pumps H⁺ out of the cell, generating a large electrochemical gradient that supplies energy to H⁺-coupled nutrient uptake systems. To characterize the traffic and delivery of PMA-1 during hyphal elongation, we have analyzed by laser scanning confocal microscopy (LSCM) strains of Neurospora crassa expressing green fluorescent protein (GFP)-tagged versions of the protein. In conidia, PMA-1-GFP was evenly distributed at the PM. During germination and germ tube elongation, PMA-1-GFP was found all around the conidial PM and extended to the germ tube PM, but fluorescence was less intense or almost absent at the tip. Together, the data indicate that the electrochemical gradient driving apical nutrient uptake is generated from early developmental stages. In mature hyphae, PMA-1-GFP localized at the PM at distal regions (>120 μm) and in completely developed septa, but not at the tip, indicative of a distinct secretory route independent of the Spitzenkörper occurring behind the apex.     

The pollen tube clear zone:Clues to the mechanism of polarized growth

Pollen tubes usually exhibit a prominent region at their apex called the “clear zone” because it lacks light refracting amyloplasts. A robust, long clear zone often associates with fast growing pollen ...     

Vesicle trafficking dynamics and visualization of zones of exocytosis and endocytosis in tobacco pollen tubes

Pollen tubes are one of the fastest growing eukaryotic cells.Rapid anisotropic growth is supported by highly active exocytosisand endocytosis at the plasma membrane, but the subcellularlocalization of these sites is unknown. To understand molecularprocesses involved in pollen tube growth, it is crucial to identifythe sites of vesicle localization and trafficking. This reportpresents novel strategies to identify exocytic and endocyticvesicles and to visualize vesicle trafficking dynamics, usingpulse-chase labelling with styryl FM dyes and refraction-freehigh-resolution time-lapse differential interference contrastmicroscopy. These experiments reveal that the apex is the siteof endocytosis and membrane retrieval, while exocytosis occursin the zone adjacent to the apical dome. Larger vesicles areinternalized along the distal pollen tube. Discretely sizedvesicles that differentially incorporate FM dyes accumulatein the apical, subapical, and distal regions. Previous workestablished that pollen tube growth is strongly correlated withhydrodynamic flux and cell volume status. In this report, itis shown that hydrodynamic flux can selectively increase exocytosisor endocytosis. Hypotonic treatment and cell swelling stimulatedexocytosis and attenuated endocytosis, while hypertonic treatmentand cell shrinking stimulated endocytosis and inhibited exocytosis.Manipulation of pollen tube apical volume and membrane remodellingenabled fine-mapping of plasma membrane dynamics and definedthe boundary of the growth zone, which results from the orchestratedaction of endocytosis at the apex and along the distal tubeand exocytosis in the subapical region. This report providescrucial spatial and temporal details of vesicle traffickingand anisotropic growth. Key words: Endocytosis; exocytosis, hydrodynamics, lipophilic FM dyes, pollen tube growth, vesicle trafficking Received 14 September 2007; Revised 23 November 2007 Accepted 7 January 2008     

Cytoplasmic microtubules and fungal morphogenesis: ultrastructural effects of methyl benzimidazole-2-ylcarbamate determined by freeze- substitution of hyphal tip cells

The effects of methyl benzimidazole-2-ylcarbamate (MBC), one of only a few agents that are active against microtubules of fungi, were analyzed at the ultrastructural level in freeze-substituted hyphal tip cells of Fusarium acuminatum. Nontreated and control cells had numerous microtubules throughout. After just 10 min of exposure to MBC, almost no cytoplasmic microtubules were present, except near spindle pole bodies. After 45 min of exposure to MBC, no microtubules were present in hyphal tip cells, but they were present in the relatively quiescent subapical cells. These observations suggested that there are different rates of turnover for cytoplasmic microtubules in apical and subapical cells and for microtubules near spindle pole bodies and that MBC acts by inhibiting microtubules assembly. A statistical analysis of the distribution of intracytoplasmic vesicles in thick sections of cells treated with MBC, D2O or MBC + D2O was obtained by use of a high- voltage electron microscope. More than 50% of the vesicles in the apical 30 micrometers of control cells were found to lie within 2 micrometers of the tip cell apex. MBC treatment caused this vesicle distribution to become uniform, resulting in a substantial increase in the number of vesicles in subapical regions. The reduction in the number of cytoplasmic microtubules, induced by MBC, apparently inhibited intracellular transport of these vesicles and rendered random the longitudinal orientation of mitochondria. In most cases, D2O appeared capable of preventing these MBC-effects through stabilization of microtubules. These observations support the "vesicle hypothesis" of tip growth and establish a transport role for cytoplasmic microtubules in fungal morphogenesis.     

Rab27b regulates exocytosis of secretory vesicles in acinar epithelial cells from the lacrimal gland

Tear proteins are supplied by the regulated fusion of secretory vesicles at the apical surface of lacrimal gland acinar cells, utilizing trafficking mechanisms largely yet uncharacterized. We investigated the role of Rab27b in the terminal release of these secretory vesicles. Confocal fluorescence microscopy analysis of primary cultured rabbit lacrimal gland acinar cells revealed that Rab27b was enriched on the membrane of large subapical vesicles that were significantly colocalized with Rab3D and Myosin 5C. Stimulation of cultured acinar cells with the secretagogue carbachol resulted in apical fusion of these secretory vesicles with the plasma membrane. Evaluation of morphological changes by transmission electron microscopy of lacrimal glands from Rab27b(-/-) and Rab27(ash/ash)/Rab27b(-/-) mice, but not ashen mice deficient in Rab27a, showed changes in abundance and organization of secretory vesicles, further confirming a role for this protein in secretory vesicle exocytosis. Glands lacking Rab27b also showed increased lysosomes, damaged mitochondria, and autophagosome-like organelles. In vitro, expression of constitutively active Rab27b increased the average size but retained the subapical distribution of Rab27b-enriched secretory vesicles, whereas dominant-negative Rab27b redistributed this protein from membrane to the cytoplasm. Functional studies measuring release of a cotransduced secretory protein, syncollin-GFP, showed that constitutively active Rab27b enhanced, whereas dominant-negative Rab27b suppressed, stimulated release. Disruption of actin filaments inhibited vesicle fusion to the apical membrane but did not disrupt homotypic fusion. These data show that Rab27b participates in aspects of lacrimal gland acinar cell secretory vesicle formation and release.     

Regulation of the tip-high [Ca2+] gradient in growing hyphae of the fungus Neurospora crassa

Previous work has shown that hyphal elongation in the fungus Neurospora crassa requires a tip-high cytosolic Ca2+ gradient. The source of the Ca2+ appears to be intracellular stores as there is no net transplasma membrane Ca2+ flux at the elongating hyphal tip and modification of ion fluxes across the plasma membrane using voltage clamp is without effect on tip growth. To decode the internal mechanisms which generate and maintain the tip-high Ca2+ gradient we first identified calcium regulators which affect hyphal growth and morphology, then determined how they modify cytosolic [Ca2+] and the actin cytoskeleton using fluorescent dyes and confocal microscopy. Cyclopiazonic acid (a known inhibitor of the endoplasmic reticulum calcium ATPase) inhibits growth and increases cytoplasmic [Ca2+] in the basal region 10-25 microm behind the hyphal tip. 2-APB (2-aminoethoxydiphenyl borate, an inhibitor of IP3-induced Ca2+ release) inhibits hyphal elongation and dissipates the tip-high Ca2 gradient 0-10 microm from the tip. Microinjections of the IP3 receptor agonists adenophostin A and IP3 (but not control microinjections of the biologically inactive L-IP3) transiently inhibited growth and induced subapical branches. IP3 microinjections, but not L-IP3, lowered tip-localized [Ca2+] and increased basal [Ca2+]. Even though their effect on [Ca2+] gradients was different, both cyclopiazonic acid and 2-APB disrupted similarly the normal actin pattern at the hyphal apex. Conversely, disruption of actin with latrunculin B dissipated tip-localized Ca2+. We conclude that the tip-high Ca2+ gradient is generated internally by Ca2+ sequestration into endoplasmic reticulum behind the tip and Ca2+ release via an IP3 receptor from tip-localized vesicles whose location is maintained by the actin cytoskeleton.     

Developmental and comparative ultrastructure of glandular hairs in the two Urticaceae. I. Urtica dioica

Secretion produced by glandular hairs is deposited mainly in the periplasmic space of the head cells. It stains intensely for both proteins and polysaccharides. The ultrastructure of meristematic, differentiating, mature and senescent head cells as well as the stalk and basal cells has been described in comparison to that in other cell types of the leaf. The specific features of the head cells are the proliferation of the granular endoplasmic reticulum as well as the multiplication of the dictyosomes and mitochondria during transition to the secretion stage. However, the frequency of dictyosomes varies among secreting hairs. The ER produces neither secretory nor transition vesicles and does not anastomose with the plasmalemma. In the absence of transition vesicles, the transport of secretory proteins and enzymes of polysaccharide synthesis from the ER to dictyosomes apparently includes the cytosolic step. Dictyosomes, though not appearing hypersecretory, produce two types of smooth secretory vesicles generated by the trans Golgi reticulum. The vectorial transfer of prosecretion and membranes across the dictyosome stack proceeds via the transport (shuttle) vesicles. It is, therefore, concluded that exocytosis of smooth secretory Golgi vesicles is the sole mechanism of release of both proteins and polysaccharides. Coated vesicles occasionally seen near the plasmalemma are likely to be involved in the endocytotic membrane retrieval. The secretion product disappears during senescence of the hairs and the secretory cells undergo vacuolation by means of local autophagy.     

Regulation of polarised growth in fungi

Polarised growth in fungi occurs through the delivery of secretory vesicles along tracks formed by cytoskeletal elements to specific sites on the cell surface where they dock with a multiprotein structure called the exocyst before fusing with the plasma membrane. The budding yeast, Saccharomyces cerevisiae has provided a useful model to investigate the mechanisms involved and their control. Cortical markers, provided by bud site selection pathways during budding, the septin ring during cytokinesis or the stimulation of the pheromone response receptors during mating, act through upstream signalling pathways to localise Cdc24p, the GEF for the rho family GTPase, Cdc42p. In its GTP-bound form, Cdc42p activates a multiprotein complex called the polarisome which nucleates actin cables along which the secretory vesicles are transported to the cell surface. Hyphae can elongate at a rate orders of magnitude faster than the extension of a yeast bud, so understanding hyphal growth will require substantial modification of the yeast paradigm. The rapid rate of hyphal growth is driven by a structure called the Spitzenkörper, located just behind the growing tip and which is rich in secretory vesicles. It is thought that secretory vesicles are delivered to the apical region where they accumulate in the Spitzenkörper. The Spitzenkörper then acts as vesicle supply centre, and it has been postulated that vesicles exit the Spitzenkörper in all directions, but because of its proximity, the tip receives a greater concentration of vesicles per unit area than subapical regions. There are no obvious equivalents to the bud site selection pathway to provide a spatial landmark for polarised growth in hyphae. However, an emerging model is the way that the site of polarised growth in the fission yeast, Schizosaccharomyces pombe, is marked by delivery of the kelch repeat protein, Tea1, along microtubules. The relationship of the Spitzenkörper to the polarisome and the mechanisms that promote its formation are key questions that form the focus of current research.     

The cytoplasmic organization of hyphal tip cells in the fungusAllomyces macrogynus

Summary Light and transmission electron microscopy were used to examine hyphal tip cells of the fungusAllomyces macrogynus (Chytridiomycetes). A well defined apical body, i.e., Spitzenkörper, was observed at the extreme apex of hyphal cells. This distinctive, spherical cytoplasmic region consisted of a granular matrix devoid of ribosomes and most organelles. To our knowledge this is the first report describing such a structure in hyphae of an aseptate fungus. Vesicles (45–65 nm diameter) were concentrated in the peripheral cytoplasm of the apex, while relatively few were observed within the Spitzenkörper. Filasomes, spherical patches of dense fibrillar material containing a microvesicle core, were abundant in the apical regions near the plasma membrane. Microtubules traversed the Spitzenkörper at various angles and were in close association with the plasma membrane. Microfilaments were observed as individual elements in the cytoplasm or were organized into bundles. Individual microfilaments were frequently in close association with the plasma membrane, vesicles and microtubules. In the immediate subapical region mitochondria, multivesicular bodies, microbodies, Golgi equivalents and nuclei were abundant.Abbreviations CW cell wall - F filasome - M mitochondria - N nucleus - PM plasma membrane - TEM transmission electron microscopy     

Ultrastructure and cytochemistry of the pearl gland in Piper regnellii (Piperaceae)

Pearl glands are scattered throughout the lamina of developing leaves and rarely found on adult leaves of Piper regnellii (Piperaceae). The pearl gland is a bicellular secretory trichome composed of a short broad basal cell and a spatula-like, semiglobular apical cell. Four different stages of the pearl gland were determined during its ontogenesis: origin, pre-secretory, secretory and post-secretory. During the pre-secretory stage, mitochondria, ribosomes, dictyosomes, rough endoplasmic reticulum, and plastids with electron dense inclusions were present in the cytoplasm of the apical cell. During the secretory stage, the most remarkable characteristics of the apical cell are the proliferation of dictyosomes and their vesicles, rough endoplasmic reticulum, and modified plastids. At this stage, electron-dense oil drops occur in the plastids as well as scattered within the cytoplasm, proteins and polysaccharides are seen in the plastids, vesicles, and vacuoles. Only polysaccharides are present in the periplasmic space, wall cavities, and on the surface of the apical cell. The polysaccharides are one of the main components of the mucilagenous exudate that covers the developing leaf structures. The apical cell of the senescing trichomes undergoes a progressive degeneration of its cellular components, the plastids being the first organelles to undergo lysis.     

Spatially segregated SNARE protein interactions in living fungal cells

The machinery for trafficking proteins through the secretory pathway is well conserved in eukaryotes, from fungi to mammals. We describe the isolation of the snc1, sso1, and sso2 genes encoding exocytic SNARE proteins from the filamentous fungus Trichoderma reesei. The localization and interactions of the T. reesei SNARE proteins were studied with advanced fluorescence imaging methods. The SSOI and SNCI proteins co-localized in sterol-independent clusters on the plasma membrane in subapical but not apical hyphal regions. The vesicle SNARE SNCI also localized to the apical vesicle cluster within the Spitzenk?rper of the growing hyphal tips. Using fluorescence lifetime imaging microscopy and Foerster resonance energy transfer analysis, we quantified the interactions between these proteins with high spatial resolution in living cells. Our data showed that the site of ternary SNARE complex formation between SNCI and SSOI or SSOII, respectively, is spatially segregated. SNARE complex formation could be detected between SNCI and SSOI in subapical hyphal compartments along the plasma membrane, but surprisingly, not in growing hyphal tips, previously thought to be the main site of exocytosis. In contrast, SNCI.SSOII complexes were found exclusively in growing apical hyphal compartments. These findings demonstrate spatially distinct sites of plasma membrane SNARE complex formation in fungi and the existence of multiple exocytic SNAREs, which are functionally and spatially segregated. This is the first demonstration of spatially regulated SNARE interactions within the same membrane.     

Endocytosis and membrane turnover in the germ tube of uromyces fabae

We have used the fluorescent dye FM4-64 as a tracer to demonstrate bulk membrane internalization (endocytosis) and redistribution of the dye within the cytoplasm of the germ tube of the rust fungus Uromyces fabae. Staining of the hyphal membrane was detected 4 s after application of FM4-64 and reached a maximum after 1 min. The highest fluorescence intensity occurred in the apex. Subsequently, staining of the plasma membrane decreased and a subapical region of the fungal protoplast (5-20 &mgr;m from the tip) displayed increasing fluorescence with a maximum after 5 min. Fluorescence in the subapical region was redistributed to an area in the hyphal tip, which corresponds to the accumulation of apical vesicles, after 10-15 min and subsequently to a cytoplasmic region in front of the two nuclei (35-45 &mgr;m from the tip). We conclude from our measurements of membrane fluorescence that the turnover time from endocytosis to secretion of the dye amounts to 15 min. The uptake of the dye into the cytoplasm, but not membrane loading, could be inhibited completely with 5 mM NaN3 or by a temperature shift to 4 degreesC. This is the first evidence for endocytosis in a fungal germ tube. Copyright 1998 Academic Press.     

Development of the discharge apparatus in the fungus Entophlyctis

Correlative light and electron microscopic observations were used to reconstruct the morphological events involved in the development of the discharge apparatus of Entophlyctis zoosporangia. A discharge plug formed as vesicles containing fibrillar material fused with the plasma membrane and deposited their matrices between the plasma membrane and zoosporangial wall. At the apex of the enlarging plug, the zoosporangial wall lost its microfibrillar appearance, became diffuse, and left an inoperculate discharge pore. The discharge plug exuded through this pore and then expanded into a sphere which rested at the tip of the discharge papilla or tube. After the release of the discharge plug, the number of fibrilla containing vesicles decreased and abundant endoplasmic reticulum appeared in the cytoplasm below the plug. Granular material then accumulated at the interface of the discharge plug and the plasma membrane. This was the endo-operculum. A single layer of endoplasmic reticulum subtended the area of plasma membrane which the endo-operculum covered. Later, dictyosomes appeared in the cytoplasm below the endo-operculum. Fusion of Golgi vesicles with the plasma membrane below the endo-operculum coincided with the initiation of cytoplasmic cleavage. This sequence of events indicates that, unlike the discharge plug, the endo-operculum does not originate by vesicular addition of preformed material.