Apical Branching in a Temperature Sensitive Mutant ofAspergillus niger

An apical branching, temperature-sensitive, mutant ofAspergillus niger(ramosa-1) was isolated by UV mutagenesis.Ramosa-1has a wild type morphology at 23°C, but branches apically when shifted to 34°C. The cytological events leading to apical branching were recorded by video-enhanced phase contrast microscopy. The first event was a momentary, localized, cytoplasmic contraction lasting approximately 1 s. This contraction was seen as a sudden unidirectional movement of visible organelles (mitochondria, spheroid bodies) toward the hyphal apex. During the contraction, there was a transitory sharp increase in refractive index in a localized area of cytoplasm in the apex or subapex of the cell. Within 5 s, the Spitzenkörper retracted from its normal position next to the apical pole and disappeared from view 20 to 50 s later. Hyphal elongation rate diminished sharply, and the typical distribution of organelles at the hyphal tip was disturbed. After 210–240 s, organelle distribution returned to normal, polarized growth resumed, but instead of one Spitzenkörper two new Spitzenkörper appeared, each giving rise to an apical branch. The second branch Spitzenkörper appeared with a 60- to 100-s delay. We did not observe the original Spitzenkörper dividing in two; instead, the new Spitzenkörper arosede novofrom vesicle clouds that formed in the apical region next to the future site of branch emergence. In all instances that we examined, the dislocation and disappearance of the Spitzenkörper was preceded by cytoplasmic contractions. We therefore suspect the existence of an intimate connection between the cytoskeletal network and the Spitzenkörper. Accordingly, we propose that the apical branching phenotype inramosa-1is triggered by a molecular event that induces a transient alteration in cytoskeleton organization.     

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     

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     

Diversity and dynamics of the Spitzenkörper in growing hyphal tips of higher fungi

Summary The Spitzenkörper, located in the apex of growing hyphae of septate fungi, has been portrayed previously as a spheroid complex containing a cluster of apical (secretory) vesicles which sometimes encloses a differentiated core area. With the aid of computer-enhanced video microscopy and phase-contrast optics, we studied 32 fungi in the Ascomycetes, Deuteromycetes, Hyphomycetes, Basidiomycetes, and Agonomycetes. The Spitzenkörper appeared as a highly dynamic and pleomorphic multicomponent complex capable of changing shape, size, and position within the hyphal apex during growth. The main theme of this study is to demonstrate two kinds of morphological diversity/variation in Spitzenkörper from diverse fungi: (a) inherent diversity — Spitzenkörper features characteristic of particular fungi, and (b) dynamic pleomorphism — gradual or rapid changes in size, shape, and position of the Spitzenkörper within a single hyphal tip. Several components associated with the Spitzenkörper were identified: (a) vesicle cluster, (b) vesicle cloud, (c) differentiated core region(s) within the Spitzenkörper, (d) apical granules, (e) cytoplasmic filaments. Eight morphological patterns of Spitzenkörper organization are described in the higher fungi based on the shape and distribution of their components. An additional (ninth) pattern was recognized in the chytridiomyceteAllomyces macrogynous from recent work by others. All these patterns appeared to be conserved at the genus level. In all patterns but one, a core region was observed by light microscopy. The Spitzenkörper not only exhibited spontaneous dynamic pleomorphism but also reacted to stress conditions (light, mechanical, and electrical fields). These reactions include migration of the Spitzenkörper back into the subapical zone and/or disassembly of its components. The understanding and conceptualization of this dynamic complex is problematic and should remain flexible enough to encompass the diversity of Spitzenkörper patterns and the dynamic pleomorphism of this specialized apical apparatus which appears to drive hyphal tip growth in the higher fungi.Dedicated to Professor Eldon H. Newcomb in recognition of his contributions to cell biology     

Confocal microscopy of Spitzenkörper dynamics during growth and differentiation of rust fungi

Summary. The membrane-selective fluorescent dye FM4-64, N-(3-triethylammoniumpropyl)-4-(6-(4-(diethylamino)phenyl)hexatrienyl)pyridium dibromide, was used to stain the apical vesicle cluster within the specialized Spitzenkörper of the germ tube of the rust fungi Uromyces vignae and Puccinia graminis f. sp. tritici grown on glass surfaces. The Spitzenkörper stained within 15 min following addition of the dye. Optical sectioning by confocal microscopy of stained hyphal tips showed that the Spitzenkörper was asymmetrically positioned close to the cell–substratum interface during germ tube growth. The Spitzenkörper showed variations in shape and positioning over short (5 s) time intervals. The movement to a new location in the hyphal dome was followed by new growth in that region, consistent with the view that the Spitzenkörper supplies secretory vesicles for germ tube growth. A pronounced Spitzenkörper disappeared at the onset of appressorium differentiation during swelling of the germ tube. However, a stained structure, similar in appearance to a Spitzenkörper, was again observed during the formation of the highly polarized penetration peg.Correspondence and reprints: Centraalbureau voor Schimmelcultures, Uppsalalaan 8, 3584 CT Utrecht, the Netherlands.Received October 25, 2002; accepted February 26, 2003; published online August 26, 2003     

Rhizoids and protonemata of characean algae: model cells for research on polarized growth and plant gravity sensing

Gravitropically tip-growing rhizoids and protonemata of characean algae are well-established unicellular plant model systems for research on gravitropism. In recent years, considerable progress has been made in the understanding of the cellular and molecular mechanisms underlying gravity sensing and gravity-oriented growth. While in higher-plant statocytes the role of cytoskeletal elements, especially the actin cytoskeleton, in the mechanisms of gravity sensing is still enigmatic, there is clear evidence that in the characean cells actin is intimately involved in polarized growth, gravity sensing, and the gravitropic response mechanisms. The multiple functions of actin are orchestrated by a variety of actin-binding proteins which control actin polymerisation, regulate the dynamic remodelling of the actin filament architecture, and mediate the transport of vesicles and organelles. Actin and a steep gradient of cytoplasmic free calcium are crucial components of a feedback mechanism that controls polarized growth. Experiments performed in microgravity provided evidence that actomyosin is a key player for gravity sensing: it coordinates the position of statoliths and, upon a change in the cell's orientation, directs sedimenting statoliths to specific areas of the plasma membrane, where contact with membrane-bound gravisensor molecules elicits short gravitropic pathways. In rhizoids, gravitropic signalling leads to a local reduction of cytoplasmic free calcium and results in differential growth of the opposite subapical cell flanks. The negative gravitropic response of protonemata involves actin-dependent relocation of the calcium gradient and displacement of the centre of maximal growth towards the upper flank. On the basis of the results obtained from the gravitropic model cells, a similar fine-tuning function of the actomyosin system is discussed for the early steps of gravity sensing in higher-plant statocytes.     

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.     

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     

Association of spectrin-like proteins with the actin-organized aggregate of endoplasmic reticulum in the Spitzenkörper of gravitropically tip-growing plant cells

Spectrin-like epitopes were immunochemically detected and immunofluorescently localized in gravitropically tip-growing rhizoids and protonemata of characean algae. Antiserum against spectrin from chicken erythrocytes showed cross-reactivity with rhizoid proteins at molecular masses of about 170 and 195 kD. Confocal microscopy revealed a distinct spherical labeling of spectrin-like proteins in the apices of both cell types tightly associated with an apical actin array and a specific subdomain of endoplasmic reticulum (ER), the ER aggregate. The presence of spectrin-like epitopes, the ER aggregate, and the actin cytoskeleton are strictly correlated with active tip growth. Application of cytochalasin D and A23187 has shown that interfering with actin or with the calcium gradient, which cause the disintegration of the ER aggregate and abolish tip growth, inhibits labeling of spectrin-like proteins. At the beginning of the graviresponse in rhizoids the labeling of spectrin-like proteins remained in its symmetrical position at the cell tip, but was clearly displaced to the upper flank in gravistimulated protonemata. These findings support the hypothesis that a displacement of the Spitzenk?rper is required for the negative gravitropic response in protonemata, but not for the positive gravitropic response in rhizoids. It is evident that the actin/spectrin system plays a role in maintaining the organization of the ER aggregate and represents an essential part in the mechanism of gravitropic tip growth.     

Gravity perception requires statoliths settled on specific plasma membrane areas in characean rhizoids and protonemata

Summary. The noninvasive infrared laser micromanipulation technique (optical tweezers, optical trapping) and centrifugation were used to study susception and perception, the early events in the gravitropic pathway of tip-growing characean rhizoids and protonemata. Reorientation of the growth direction in both cell types was only initiated when at least 2–3 statoliths settled on specific areas of the plasma membrane. This statolith-sensitive plasma membrane area is confined to the statolith region (10–35 μm behind the tip) in positively gravitropic rhizoids, whereas in negatively gravitropic protonemata, this area is limited to the apical plasma membrane (0–10 μm). Statolith sedimentation towards the sensitive plasma membrane areas is mediated by the concerted action of actin and gravity. The process of sedimentation, the pure physical movement, of statoliths is not sufficient to initiate graviresponses in both cell types. It is concluded that specific statolith-sensitive plasma membrane areas play a crucial role in the signal transduction pathway of gravitropism. These areas may represent the primary sites for gravity perception and may transform the information derived from the gravity-induced statolith sedimentation into physiological signals which trigger the molecular mechanisms of the opposite graviresponses in characean rhizoids and protonemata. Received September 10, 2001 Accepted November 16, 2001     

Satellite Spitzenkörper in growing hyphal tips

Summary Growing hyphal tips of higher fungi contain an organized assemblage of secretory vesicles and other cell components collectively known as the Spitzenkörper. Until now, the Spitzenkörper has been portrayed as a single spheroid complex located near the apical cell wall. This study demonstrates the occurrence of multiple Spitzenkörper in growing hyphal apices imaged by video-enhanced phase-contrast microscopy. In addition to the main Spitzenkörper, smaller satellite Spitzenkörper arise a few micrometers behind the apical pole. Four developmental stages were identified: (a) the satellites first appeared as faint phase-dark plaques next to the plasma membrane, (b) gradually increased in size and assumed an ovoid profile, (c) they migrated to the hyphal apex, and (d) finally they merged with the main Spitzenkörper. After the merger, the main Spitzenkörper temporarily increased in size. Satellites were observed in 14 fungi, most of which had relatively large (5–10 m diam.), fast-growing hyphae (2–33 m/min elongation rate). The average frequency of in-focus satellites was 7+/min forFusarium culmorum and 11+/min forTrichoderma viride. As with the main Spitzenkörper, satellites were present only in growing cells. They were transient and remained visible for 3–8 s before merging with the main Spitzenkörper. Within the hyphae, satellites travelled up to six times faster than the average cell elongation rate. Multiple satellites sometimes occurred simultaneously; up to three were seen within a hyphal apex at the same time. Localized cell enlargement occurred next to stationary satellites, suggesting that satellite Spitzenkörper are functional as sources of new cell surface before they reach the main Spitzenkörper; therefore, they account for some variations in the profiles of the growing hyphae. By electron microscopy, satellites consisted of small clusters of apical vesicles surrounding a group of microvesicles located next to the plasma membrane. The identification and behavior of the satellites represent clear evidence of directional mass transport of vesicles toward the hyphal apex. Our observations indicate that satellites are a common phenomenon in growing hyphal apices of septate fungi and that they contribute to growth of the hyphal apex.Abbreviations VSC vesicle supply center     

Immunolocalization of myosin in rhizoids ofChara globularis Thuill

Summary Myosin-related proteins have been localized immunocytochemically in gravity-sensing rhizoids of the green algaChara globularis using a monoclonal antibody against the heavy chain of myosin from mouse 3T3 cells and a polyclonal antibody to bovine skeletal and smooth muscle myosin. In the basal zone of the rhizoids which contain a large vacuole, streaming endoplasm and stationary cortical cytoplasm, the monoclonal antibody stained myosin-related proteins as diffusely fluorescing endoplasmic strands. This pattern is similar to the arrangement of subcortical actin filament bundles. In the apical zone which contains an aggregation of ER membranes and secretory vesicles for tip growth, diffuse immunofluorescence was detected; the intensity of the signal increasing towards the apical cell wall. The most prominent myosin-staining was associated with the surface of statoliths in the apical zone. The polyclonal antibody produced a punctate staining pattern in the basal zone, caused by myosin-related proteins associated with the surface of drganelles in the streaming endoplasm and the periphery of the nucleus. In the apical zone, this antibody revealed myosin-immunofluorescence on the surface of statoliths in methacrylate-embedded rhizoids. Neither antibody revealed myosin-immunofluorescence on the surface of organelles and vesicles in the relatively stationary cytoplasm of the subapical zone. These results indicate (i) that different classes of myosin are involved in the various transport processes inChara rhizoids; (ii) that cytoplasmic streaming in rhizoids is driven by actomyosin, corresponding to the findings onChara internodal cells; (iii) that actindependent control of statolith position and active movement is mediated by myosin-related proteins associated with the statolith surfaces; and (iv) that myosin-related proteins are involved in the process of tip growth.     

Aggregation and collapse of fungal wall vesicles in hyphal tips: a model for the origin of the Spitzenk?rper

The intracellular origins of polarity and branch initiation in fungi centre upon a localization in the supply of fungal wall constituents to specific regions on the hyphal wall. Polarity is achieved and maintained by accumulating secretory vesicles, prior to incorporation into the wall, in the form of an apical body or Spitzenkörper. However, neither the mechanisms leading to this accumulation nor the initiation of branching, are as yet understood. We propose a mechanism, based on experimental evidence, which considers the mechanical properties of the cytoskeleton in order to explain these phenomena. Cytoskeletal viscoelastic forces are hypothesized to be responsible for biasing vesicles in their motion, and a mathematical model is derived to take these considerations into account. We find that, as a natural consequence of the assumed interactions between vesicles and cytoskeleton, wall vesicles aggregate in a localized region close to the tip apex. These results are used to interpret the origin of the Spitzenkörper. The model also shows that an aggregation peak can collapse and give rise to two new centres of aggregation coexisting near the tip. We interpret this as a mechanism for apical branching, in agreement with published observations. We also investigate the consequences and presumptive role of vesicle–cytoskeleton interactions in the migration of satellite Spitzenkörper. The results of this work strongly suggest that the formation of the Spitzenkörper and the series of dynamical events leading to hyphal branching arise as a consequence of the bias in vesicle motion resulting from interactions with the cytoskeleton.     

Hypergravity can reduce but not enhance the gravitropic response ofChara globularis protonemata

Summary The relationship between the position of the statoliths and the direction and rate of tip growth in negatively gravitropic protonemata ofChara globularis was studied with a centrifuge video microscope. Cells placed perpendicularly to the acceleration vector (stimulation angle 90 °) showed a gradual reduction of the gravitropic curvature with increasing accelerations from 1g to 8g despite complete sedimentation of all statoliths on the centrifugal cell flank. It is argued that the increased weight of the statoliths in hypergravity impairs their acropetal transport which is induced when the cell axis deviates from the normal upright orientation. When the statoliths were centrifuged deep into the apical dome at 6g and a stimulation angle of 170 ° the gravitropic curvature after 1 h was identical to that determined for the same cells at 1g and the same stimulation angle. This indicates that gravitropism in Chara protonemata is either independent of the pressure exerted by the statoliths on an underlying structure or is already saturated at 1g. When the statoliths were moved along the apical cell wall at 8g and the stimulation angle was gradually increased from 170 ° to 220 ° the gravitropic curvature reverted sharply when the cluster of statoliths passed over the cell pole. This experiment supports the hypothesis that in Chara protonemata asymmetrically distributed statoliths inside the apical dome displace the Spitzenkörper and thus the centre of growth, resulting in gravitropic bending. In contrast to the positively gravitropic Chara rhizoids, no modifications either in the transport of statoliths during basipetal acceleration (6g, stimulation angle 0 °, 5 h) or in the subsequent gravitropic response could be detected in the protonemata. The different effects of centrifugation on the positioning of statoliths in Chara protonemata and rhizoids indicate subtle differences in the function of the cytoskeleton in both types of cells.Dedicated to Prof. Dr. Zygmunt Hejnowicz on the occasion of his 70th birthday     

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     

In-vivo observations of a spherical aggregate of endoplasmic reticulum and of Golgi vesicles in the tip of fast-growing Chara rhizoids

In-vivo differential interference contrast microscopy was used to detect individual Golgi vesicles and a new structure in the tip of fast-growing rhizoids of Chara fragilis Desvaux. This structure is a spherical clear zone which is free of Golgi vesicles, has a diameter of 5 m and is positioned in the center of the apical Golgi-vesicle accumulation (Spitzenkörper). After glutaraldehyde fixation and osmium tetroxide-potassium ferricyanide staining of the rhizoid, followed by serial sectioning and three-dimensional reconstruction, the spherical zone shows a tight accumulation of anastomosing endoplasmic reticulum (ER) membranes. The ER membranes radiate from this aggregate towards the apical plasmalemma and to the membranes of the statolith compartments. Upon gravistimulation the ER aggregate changes its position according to the new growth direction, indicating its participation in growth determination. After treatment of the rhizoid with cytochalasin B or phalloidin the ER aggregate disappears and the statoliths sediment. It is concluded that the integrity of the ER aggregate is actin-dependent and that it is related to the polar organisation of the gravitropically growing cell tip.Abbreviations CB cytochalasin B - DIC differential interference contrast microscopy - DMSO dimethyl sulfoxide - ER endoplasmic reticulum     

Apical growth and mitosis are independent processes in Aspergillus nidulans

Summary. It is well established that cytoplasmic microtubules are depolymerized during nuclear division and reassembled as mitotic microtubules. Mounting evidence showing that cytoplasmic microtubules were also involved in apical growth of fungal hyphae posed the question of whether apical growth became disrupted during nuclear division. We conducted simultaneous observations of mitosis (fluorescence microscopy) and apical growth (phase-contrast microscopy) in single hyphae of Aspergillus nidulans to determine if the key parameters of apical growth (elongation rate and Spitzenkörper behavior) were affected during mitosis. To visualize nuclei during mitosis, we used a strain of A. nidulans, SRS27, in which nuclei are labeled with the green-fluorescent protein. To reveal the Spitzenkörper and measure growth with utmost precision, we used computer-enhanced videomicroscopy. Our analysis showed that there is no disruption of apical growth during mitosis. There was no decrease in the rate of hyphal elongation or any alteration in Spitzenkörper presence before, during, or after mitosis. Our findings suggest that apical growth and mitosis do not compete for internal cellular resources. Presumably, the population of cytoplasmic microtubules involved in apical growth operates independently of that involved in mitosis.Present address: Department of Plant Sciences, University of Oxford, Oxford, United Kingdom.     

Reorganization of the actin and microtubule cytoskeleton throughout blue-light-induced differentiation of characean protonemata into multicellular thalli

Summary The reorganization of the actin and microtubule (MT) cytoskeleton was immunocytochemically visualized by confocal laser scanning microscopy throughout the photomorphogenetic differentiation of tip-growing characean protonemata into multicellular green thalli. After irradiating dark-grown protonemata with blue or white light, decreasing rates of gravitropic tip-growth were accompanied by a series of events leading to the first cell division: the nucleus migrated towards the tip; MTs and plastids invaded the apical cytoplasm; the polar zonation of cytoplasmic organelles and the prominent actin patch at the cell tip disappeared and the tip-focused actin microfilaments (MFs) were reorganized into a homogeneous network. During prometaphase and metaphase, extranuclear spindle microtubules formed between the two spindle poles. Cytoplasmic MTs associated with the apical spindle pole decreased in number but did not disappear completely during mitosis. The basal cortical MTs represent a discrete MT population that is independent from the basal spindle poles and did not redistribute during mitosis and cytokinesis. Preprophase MT bands were never detected but cytokinesis was characterized by higher-plant-like phragmoplast MT arrays. Cytoplasmic actin MFs persisted as a dense network in the apical cytoplasm throughout the first cell division. They were not found in close contact with spindle MTs, but actin MFs were clearly coaligned along the MTs of the early phragmoplast. The later belt-like phragmoplast was completely depleted of MFs close to the time of cell plate fusion except for a few actin MF bundles that extended to the margin of the growing cell plate. The cell plate itself and young anticlinal cell walls showed strong actin immunofluorescence. After several anticlinal cell divisions, basal cells of the multicellular protonema produced nodal cell complexes by multiple periclinal divisions. The apical-dome cell of the new shoot which originated from a nodal cell becomes the meristem initial that regularly divides to produce a segment cell. The segment cell subsequently divides to produce a single file of alternating internodal cells and multicellular nodes which together form the complexly organized characean thallus. The actin and MT distribution of nodal cells resembles that of higherplant meristem cells, whereas the internodal cells exhibit a highly specialized cortical system of MTs and streaming-generating actin bundles, typical of highly vacuolated plant cells. The transformation from the asymmetric mitotic spindle of the polarized tip-growing protonema cell to the symmetric, higher-plant-like spindle of nodal thallus cells recapitulates the evolutionary steps from the more primitive organisms to higher plants.Abbreviations FITC fluorescein isothiocyanate - MF microfilament - MT microtubule - MSB microtubule-stabilizing buffer - PBS phosphate-buffered saline     

The tubulin cytoskeleton and its sites of nucleation in hyphal tips ofAllomyces macrogynus

Summary The tubulin cytoskeleton in hyphal tip cells ofAllomyces macrogynus was detected with an -tubulin monoclonal antibody and analyzed with microscopic and immunoblot techniques. The -tubulin antibody identified a 52 kilodalton polypeptide band on immunoblots. Immunfluorescence data were collected from formaldehyde-and cryofixed hyphae. Both methods provided similar images of tubulin localization. However, cryofixation yielded more consistent labeling and did not require detergent extraction or cell-wall lytic treatments. Tubulin was primarily localized as microtubules observed in the peripheral and central cytoplasmic regions and in mitotic spindles. Cytoplasmic microtubules were oriented parallel to the cells' longitudinal axis, with central microtubules more often varied in their alignment, and emanated from a region in the hyphal apex resulting in an apical zone of bright fluorescence. A thin layer of microtubules appearing as bands of fluorescence encircled many nuclei. Discrete spots of fluorescence were also associated with nuclei. The MPM-2 antibody, which recognizes phosphorylated epitopes of several proteins that may be involved in the regulation of microtubule nucleation, stained centrosomes but not apical regions of hyphae. Nocodazole was used to depolymerize the microtubule network and reveal its regions of origin. A hocodazole concentration of 0.01 g/ ml (3.3× 10^–8M) provided a 70 to 75% inhibition of hyphal tip growth and was used throughout this study. The number of cells having an apical zone of fluorescence declined by 15 min of exposure. This zone was present in only a few cells after 60 min. After 30 min, the central cytoplasm consisted of small microtubule fragments and nuclear-associated spots. A small number of peripheral microtubules and nuclear-associated spots persisted throughout nocodazole treatments. Spindle microtubules were restored by 30 min after removal of nocodazole. This was followed by the reappearance of the apical zone of fluorescence and then by central and peripheral cytoplasmic microtubules. Apical fluorescence coincided with the presence of a Spitzenkörper. The results suggest that the Spitzenkörper and centrosome function as centers of microtubule nucleation and organization during hyphal tip growth in this fungus.Abbreviations BSA bovine serum albumin - DAPI 4,6-diamidino-2-phenylindole - DMSO dimethylsulfoxide - FITC fluorescein isothiocyanate - IB incubation buffer - LN₂ liquid nitrogen - LSCM laser scanning confocal microscopy - MTOCs microtubule-organizing centers - PBS phosphate buffered saline - PIPES 1,4-piperazinedietha-nesulfonic acid - PFB PIPES fixation buffer - SDS-PAGE sodium dodecyl sulfate polyacrylamide gel electrophoresis - SPB spindle pole body - TEM transmission electron microscopy - YpSs yeast extract-inorganic phosphate-soluble starch     

Ultrastructural immunolocalization of actin in a fungus

Summary We have successfully localized fungal actin for the first time using immuno-electron microscopy and hyphal tips of the rice blast pathogenMagnaporthe grisea. Following ultrarapid freezing, samples were processed in a novel substitution fluid of 10% acrolein in anhydrous ethanol and embedded in LR White resin. A monoclonal anti-actin antibody, previously shown to recognizeM. grisea actin, bound specifically to filasomes concentrated in the peripheral cytoplasm of subapical regions, and to the core-region of the Spitzenkörper.Abbreviations IEM immuno-electron microscopy - TEM transmission electron microscopy