Fixation induces differential polarized translocations of organelles in hyphae ofSaprolegnia ferax

Expression and localization of calreticulin in tobacco anthers and pollen tubes

The developmental expression pattern and localization of calreticulin were studied in Nicotiana tabacum L. anthers, pollen and pollen tubes. High transcript and protein levels were detected throughout anther development. Immunolocalization of calreticulin in the anthers showed particular dense label in tapetum and pollen at developmental stage 2, when the tapetum is highly active and the pollen tetrads are formed. Much lower transcript and protein levels were detected in dry and hydrated pollen and in pollen tubes. Immunofluorescence labeling of both chemically fixed and cryo-fixed and freeze-substituted pollen tubes showed the presence of calreticulin in Golgi apparatus and endoplasmic reticulum (ER). Calreticulin was seen throughout the stacks in the Golgi apparatus and in the areas with coated-Golgi vesicles but much less so in the ER. Calreticulin was not found in the secretory vesicles. A relatively intense label was occasionally seen adjacent to the wall of the tube. No significant label was observed in mitochondria, vacuoles, generative cells, cell wall or callose plugs. The present results are consistent with a role of calreticulin in Ca2+-dependent folding of secreted glycoproteins in tapetum, pollen and pollen tubes.

Freeze-substitution: origins and applications

Freeze-substitution is a physicochemical process in which biological specimens are immobilized and stabilized for microscopy. Water frozen within cells is replaced by organic solvents at subzero temperatures. Freeze-substitution is widely used for ultrastructural and immunocytochemical analyses of cells by transmission and scanning electron microscopy. Less well recognized is its superiority over conventional chemical fixation in preserving labile and rare tissue antigens for immunocytochemistry by light microscopy. In the postgenome era, the focus of molecular genetics will shift from analyzing DNA sequence structure to elucidating the function of gene networks, the intercellular effects of polygenetic diseases, and the conformational rearrangements of proteins in situ. Novel strategies will be needed to integrate knowledge of chemical structures of normal and abnormal macromolecules with the physiology and developmental biology of cells and tissues from whole organisms. This review summarizes the progress and future prospects of freeze-substitution for such explorations.

Cytoskeletal and Ca2+ regulation of hyphal tip growth and initiation

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

Comparative analysis of Ca2+ and H+ flux magnitude and location along growing hyphae of Saprolegnia ferax and Neurospora crassa

Calcium and proton ion fluxes were mapped at the growing apices of two hyphal organisms, the oomycete Saprolegnia ferax and the ascomycete Neurospora crassa and pseudohyphal Saccharomyces cerevisiae using self-referencing ion-selective probes. S. ferax exhibited well-defined transport zones absent in N. crassa. Ca2+ fluxes were located within 8 microm of the growing hyphal tip; the net Ca2+ flux was either inward (75% of all experiments) or outward. The inward component of the net flux was inhibited by Gd3+, known to inhibit Ca2+ permeable stretch-activated channels. Because the Ca2+ flux is located at the region of maximal hyphal expansion, exocytosis may contribute to Ca2+ efflux, in addition to the stretch-activated channel mediated influx. Maximal inward H+ flux was observed 10-30 microm behind the hyphal tip where peak mitochondria densities taper off at the onset of a vacuolation zone, presumably due to highly localized H+ cotransporter activity. By contrast, N. crassa exhibited no net Ca2+ flux and a consistently inward H+ flux (93% of all experiments) that was homogeneously distributed up to 60 microm behind the hyphal apex. Both hyphal organisms have similar tip morphology and growth rates, and are reported to have tip-high cytosolic Ca2+ gradients associated with growth. Only S. ferax exhibited tip-localized Ca2+ fluxes and a well defined H+ influx zone just behind the tip. Differences in ecological habitats and cytology--S. ferax is an aquatic organism that grows as a migrating plug of cytoplasm while N. crassa is normally terrestrial with a cytoplasm-rich mycelium and highly active cytoplasmic streaming behind the growing margin--may account for the differences in the 'architecture' of ion transport occurring during the process of tip growth. Net Ca2+ efflux and H+ influx of growing S. cerevisiae pseudohyphae were also measured but localization was not possible due to small cell size.

Mechanisms of hyphal tip growth: tube dwelling amebae revisited

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

Roles of calcium gradients in hyphal tip growth: a mathematical model

A tip-high Ca2+ gradient is observed in growing fungal hyphae, but so far its role remains unknown. A mathematical model is presented, which provides evidence for the functions of such a Ca2+ gradient, in terms of its non-linear effect on the visco-elastic properties of the hyphal cytoskeleton. The model explains how the Ca2+ status at the tip may be responsible for the apical accumulation of vesicles and for an increase in the cytogel osmotic pressure, accompanied by the contraction of the cytoskeleton. The experimentally observed retraction of the spitzenkörper preceding the initiation of a branch is also reproduced, by simulating a subapical transient release of Ca2+ from internal stores.

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

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

An improved method for affinity probe localization in whole cells of filamentous fungi

The fungal cell wall, though phylogenetically variable, acts universally as a potent barrier to probing intracellular structures. Thus, the use of high-molecular-weight probes such as antibodies and lectins has proven a formidable challenge. We have devised a preparative method for use with various affinity probes that can be applied to a broad spectrum of filamentous fungal species and used for imaging whole cells. In this study, confocal imaging of whole-mount fungal hyphae after freeze substitution, methacrylate embedment/de-embedment, and infiltration with affinity probes has yielded remarkably improved renderings of the three-dimensional distribution of both microtubules (using antibodies against both alpha- and beta-tubulin) and concanavalin A binding sites. Using this protocol we have been able to document: (1) the three-dimensional distribution of microtubules in all regions of hyphae, (2) the presence of apparent foci for cytoplasmic microtubules, (3) persistent cytoplasmic microtubules during mitosis, and (4) a three-dimensional view of many compartments of the endomembrane system including Golgi-equivalent organelles and apical vesicles. The last result represents the first direct confirmation of apical vesicles comprising the Spitzenkörper.

Apical branching in a temperature sensitive mutant of Aspergillus niger

An apical branching, temperature-sensitive, mutant of Aspergillus niger (ramosa-1) was isolated by UV mutagenesis. Ramosa-1 has a wild type morphology at 23 degrees C, but branches apically when shifted to 34 degrees 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 arose de novo from 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 in ramosa-1 is triggered by a molecular event that induces a transient alteration in cytoskeleton organization.

Direct evidence for Ca2+ regulation of hyphal branch induction

Grinberg, A., and Heath, I. B. 1997. Direct evidence for Ca2+ regulation of hyphal branch induction. 22, 127-139. Irradiation of growing hyphae of Saprolegnia ferax with microbeams of UV (300-380 and 385-450 nm) light induced an increase in cytoplasmic [Ca2+] followed by precocious formation of one or more branches within about 4 min. The distribution of branches was strongly skewed toward the subapical side of the irradiation site, but otherwise was apparantly random. Apical (10-&mgr;m) irradiations were more effective than subapical (50-&mgr;m) ones in that they induced branches at comparable frequencies but with lower doses, consistent with higher concentrations of putative target intracellular Ca2+ storage structures in this region. Once formed, induced adjacent branches seem to compete for "resources," with those closer than approximately 50 &mgr;m inhibiting each other. The results are most consistent with Ca2+-induced accumulation of branch initiating factors being the cause, not the consequence, of branch formation, thus supporting a primary role for Ca2+ in regulation of hyphal tip growth. Copyright 1997 Academic Press. Copyright 1997 Academic Press

POLLEN GERMINATION AND TUBE GROWTH

Many aspects of Angiosperm pollen germination and tube growth are discussed including mechanisms of dehydration and rehydration, in vitro germination, pollen coat compounds, the dynamic involvement of cytoskeletal elements (actin, microtubules), calcium ion fluxes, extracellular matrix elements (stylar arabinogalactan proteins), and control mechanisms of gene expression in dehydrating and germinating pollen. We focus on the recent developments in pollen biology that help us understand how the male gamete survives and accomplishes its successful delivery to the ovule of the sperm to effect sexual reproduction.

The Cytoplasmic pH Influences Hyphal Tip Growth and Cytoskeleton-Related Organization

The regulatory role of protons in hyphal tip growth was investigated by using membrane-permeant weak acids to acidify cytoplasm of the oomycete Saprolegnia ferax. Acetic acid decreased cytoplasmic pH from approximately pH 7.2 to 6.8, as shown by SNARF-1 measurements of cytoplasmic pH. Inhibition of growth in a dose-dependent manner by acetic, propionic, and isobutyric acid was accompanied by changes in positioning and morphology of mitochondria and nuclei, condensation of chromatin, disruptions in peripheral actin, and increases in hyphal diameter. These cellular alterations were fully reversible, and during recovery, major cytoplasmic movements and extensive apical vacuolations were observed. The results are consistent with proton regulation of the cytoskeleton, nuclear matrix, and/or chromosomes. However, a macroscopic cytoplasmic gradient of H+ in hyphae was not revealed by SNARF-1, indicating that if such a H+ gradient were required, it must occur at a finer level than we detected.

Microinjection of fungal cells: a powerful experimental technique

Microinjection is an effective method for introducing membrane-impermeant molecules into cells. As yet however, mycologists have made only limited use of this technique. Recent improvements in both equipment and methodology may change this situation as it is now possible to routinely microinject small turgid cells. In this paper I will review microinjection techniques and evaluate these with regard to fungal cells. The potential of microinjection for furthering our knowledge of fungal biology will be discussed. Key words: microinjection, fungi, oomycetes, F-actin, calcium.