The dynamic structure of Spitzenkörpers of Trichosporon asahii examined by the fluorescent probe FM4-64

Yuntong Lv Zhikuan Xia Wenling Wang About the authors

Abstract

The Spitzenkörper is a dynamic and specialized multicomponent cell complex present in the tips of hyphal cells. The amphiphilic styryl dye FM4-64 was found to be ideal for imaging the dynamic changes of the apical vesicle cluster within growing hyphal tips. It is widely used as a marker of endocytosis and to visualize vacuolar membranes. Here we performed uptake experiments using FM4-64 to study the dynamic of the Spitzenkörper in Trichosporon asahii. We observed that Spitzenkörpers were present at the tip of the budding site of the spore, blastospore, and the germ tube of T. asahii. We also found that Spitzenkörpers were present at the tip of the hyphae as well as the subapical regions. Cytochalasin D, an inhibitor of actin polymerization, leads to abnormal Spitzenkörper formation and loss of cell polarity.

Keywords
Trichosporon asahii; Spitzenkörper; Polarized growth; Cytochalasin D

Introduction

Studies have shown that vesicle trafficking is fundamental to numerous activities in eukaryotic organisms, and is involved in cell growth and differentiation. The vesicle trafficking network includes exocytosis and endocytosis.11 Rothman JE. Mechanisms of intracellular protein transport. Nature. 1994;372:55-63. In filamentous fungi, vesicle trafficking is concerned with the polarized tip growth.22 Bartnicki-Garcia S, Hergert F, Gierz G. Computer simulation of fungal morphogenesis and the mathematical basis for hyphal (tip) growth. Protoplasma. 1989;153:46-57.,33 Howard RJ. Ultrastructural analysis of hyphal tip cell growth in fungi: Spitzenkörper, cytoskeleton and endomembranes after freeze-substitution. J Cell Sci. 1981;48:89-103. Vesicle trafficking to the apex during tip growth is highly organized and involves the activity of a specific, multicomponent organelle complex which, in most cases, is called the Spitzenkörper. The Spitzenkörper is a vesicle-organizing center that is intimately involved in fungal cell morphogenesis, and it spatially and temporally coincides with polarity-related components. The Spitzenkörper was originally recognized as a dark region in phase-contrast microscopy at the tip of actively growing hyphae.44 Girbardt M. Der Spitzenkörper von Polystictus versicolor. Planta. 1957;50:47-59. Subsequently, electron microscopy revealed that this structure is rich in secretory vesicles.55 Grove SN, Bracker CE. Protoplasmic organization of hyphal tips among fungi: vesicles and Spitzenkörper. J Bacteriol. 1970;104:989-1009. During tip growth, the dynamic behavior of the Spitzenkörper is predominated by secretory vesicles that form an “apical vesicle cluster,” which is intimately associated with the precise growth pattern of the hyphal apex.66 Lopez-Franco R, Bracker CE. Diversity and dynamics of the Spitzenkörper in growing hyphal tips of higher fungi. Protoplasma. 1996;195:90-111.

The Spitzenkörper regulates hyphal apical growth primarily via exocytosis. The role of Spitzenkörper in endocytosis and recycling is currently not clear. Here we report that the Spitzenkörper comprises early compartments of the endocytic pathway in Trichosporon asahii. We performed uptake experiments using FM4-64, a widely used dye for endocytosis, to study the vesicle trafficking.77 Read ND, Hickey PC. The Vesicle trafficking network and tip growth in fungal hyphae. In: Geitman A, ed. Cell Biology of Plant and Fungal Tip Growth. Amsterdam, The Netherlands: IOS Press; 2001:137-147. We observed that cytochalasin D, an inhibitor of actin polymerization, leads to abnormal Spitzenkörper formation and loss of cell polarity.

Methods

Strains and growth conditions

The type strain of T. asahii, strain CBS 2479, was purchased from Centraalbureau voor Schimmelcultures (Utrecht, Netherlands) and used in this study. Cells were propagated by incubation in YPD (1% yeast extract, 2% peptone, 2% dextrose) medium at 37 °C. For FM4-64 (Biotium) staining, 5 µL of the stock solution (1.64 mmol/L in dimethyl sulfoxide (DMSO)) was added directly to 20 mL of culture, followed by incubation for an additional 10 min. The cells were harvested by brief centrifugation and washed with phosphate-buffered saline (PBS, pH 7.4).

Spitzenkörper inhibition

Cytochalasin D (Fermentek Ltd.) was dissolved in DMSO to obtain a concentration of 2 mmol/L, and this was added to culture to a final concentration of 0.2, 0.5, 1, 2, or 5 µmol/L. Same amount of DMSO without Cytochalasin D was used as a control. The effects of the various concentrations of inhibitor were tested by pretreating the samples with the indicated compound for 15 min prior to the addition of FM4-64. In some experiments, the cells were treated with the inhibitor for 2 h, after which the inhibitor solution was removed, and the cells were washed once and then resuspended in fresh medium without inhibitor or dye. The cells were then allowed to recover for up to 4 h, after which the dye was added to the cells for analysis.

Fluorescence microscopy

Mounted slides were photographed using a Leica DM 3000 fluorescence microscope with a Leica DFC300FX camera and an LP560 filter (Ex543/Em560). The viability of the single-celled propagules was confirmed by taking aliquots and determining the percentage that germinated after overnight incubation in the medium. Viability of hyphae was confirmed by their general appearance, presence of cytoplasmic streaming, and observation of continued tip elongation and growth. Images were recorded using a real-time digital imaging setup. At least 30 individual cells were examined for each experiment, and all the experiments were performed using at least three independent batches of cells.

Results

Uptake of FM4-64 at different stages of cell growth and development

FM4-64 is a lipophilic probe that fluoresces strongly after binding to the outer plasma membrane. Ten minutes after FM4-64 was added to the culture medium, fluorescence was observed in both apical and subapical hyphal compartments. To determine the kinetics of FM4-64 staining, cells were cultured at room temperature in the presence of FM4-64 and samples were examined at various time-points.

At 8 h, a single fluorescent spot with a diameter of 0.5–1 µm was observed at the tip of the budding site of spores (Fig. 1A). Similar fluorescent spots were observed at the tip of the germ tube (Fig. 1B) at 16 h. Dim background staining was observed in the cytoplasm (Fig. 1A and B). After 24 h of culture, a larger and brighter fluorescent spot (1–2 µm in diameter) was observed at the apical or subapical hyphae (Fig. 1C). This fluorescent spot resembles the Spitzenkörper structure.88 Fischer-Parton S, Parton RM, Hickey PC, Dijksterhuis J, Atkinson HA, Read ND. Confocal microscopy of FM4-64 as a tool for analysing endocytosis and vesicle trafficking in living fungal hyphae. J Microsc. 2000;198(Pt 3):246-259. Fluorescent staining was also observed at septins (Fig. 1D), which could be the sites for branch projection. In addition, strong fluorescence was observed in the elongated spores of the pseudohyphae (Fig. 1E), as well as the chain-like spores (Fig. 1F). No Spitzenkörpers were noted in these structures.

Fig. 1
FM4-64 staining of T. asahii cells at different time points. Cells were cultured at room temperature in the presence of FM4-64 and were imaged after 8 h (A), 16 h (B) and 24 h (C–F). (A) Fluorescence spot at the tip of the budding site of a spore (arrow). Background staining was seen in cytoplasm (orange). (B) Fluorescence spot at the tip of a germ tube (arrow). Background staining was seen in cytoplasm (orange). (C) Staining of Spitzenkörper structure at the subapical hyphae (arrow). (D) Staining of septins (arrow). (E and F) Staining of elongated spores of the pseudohyphae and chain-like spores (F). Scale bar: 1 µm.

Inhibition of Spitzenkörper formation

FM4-64 uptake was assessed in the presence of Cytochalasin D, an inhibitor of filamentous actin. T. asahii cells were treated with different concentration of Cytochalasin D (0.2, 0.5, 1, 2, or 5 µmol/L) for 15 min prior to the addition of the FM4-64, and the inhibitor was kept in the solution throughout the course of the experiment.

Light microscopy observation revealed that as the increase of Cytochalasin D concentration (from 0.2 to 5 µmol/L), the inhibition effects also increased. Hyphal growth became slower and hyphae became shorter but wider (Fig. 2).

Fig. 2
Cytochalasin D treatment inhibited hyphal growth. Cells were treated with various concentration of Cytochalasin D (0.2, 0.5, 1, 2, or 5 µmol/L) and grew for 72 h. Cell were imaged with a bright filed light microscope. Scale bar: 1 µm.

When treated with a low dose of Cytochalasin D (0.2 µmol/L), the fluorescence was scattered in the central portion of the hyphae, but no obvious fluorescence was observed at the top of the hyphae (Fig. 3B). As the concentration increased, fluorescence was scattered further into the entire cell body (Fig. 3CE). At 5 µmol/L, the hyphal growth was completely blocked and only a low background fluorescence was observed (Fig. 3F). No Spitzenkörper was observed when cells were treated with any concentration of Cytochalasin D. In the absence of Cytochalasin D, FM4-64-stained apical vesicle clusters at the tip of hyphae (Fig. 3A).

Fig. 3
Cytochalasin D treatment blocked the formation of Spitzenkörper. Cells were treated with various concentration of Cytochalasin D (0, 0.2, 0.5, 1, 2, or 5 µmol/L) then added FM4-64 and grew for 72 h. Cells were imaged with a fluorescence microscope. The 0 µmol/L Cytochalasin D (A) was used as a control. Scale bar: 1 µm.

Discussion

The Spitzenkörper is a dynamic structure and closely related to polarized growth. It is continuously present at the hyphal tip at all stages of the cell cycle. In this study, we revealed the presence of Spitzenkörpers at the tip of the budding site of the spore, blastospore, and the germ tube of T. asahii. We also found that Spitzenkörpers were present at the tip of the hyphae as well as the subapical regions. In addition, the spores at the tip of the hyphae showed FM4-64 fluorescence, suggesting that the spore may have produced germ tubes in the opposite direction. Interestingly, some other structures of T. asahii, such as hyphae and pseudohyphae were also presented at both ends of the Spitzenkörper (Fig. 1E), suggesting that pseudohyphae could grow bi-directionally and continue to be regulated by the Spitzenkörper.

Using transmission electron microscopy, we showed previously that pseudohyphae produced germ tubes and hyphae.99 Wang WL, Yang RY, Ao JH. Uncommon characteristics of the structure and development of Trichosporon asahii. Chin Med J (Engl). 2009;122:1806-1810. The strong fluorescence at the elongated spores of the pseudohyphae further suggests that T. asahii pseudohyphae could form true hyphae. The phenomenon confirmed that T. asahii pseudohyphae did not lose polar growth momentum, and they continued the budding transition to hyphae.

Polarized growth, which enables cells to assume a shape typical for the species, is a fundamental feature for all fungal cells. In Saccharomyces cerevisiae, growth is confined to the daughter buds, which initially grow in a polarized fashion and then switch to isotropic growth.1010 Kron SJ, Gow NAR. Budding yeast morphogenesis: signalling, cytoskeleton and cell cycle. Curr Opin Cell Biol. 1995;7:845-855.1414 Rua D, Tobe BT, Kron SJ. Cell cycle control of yeast filamentous growth. Curr Opin Microbiol. 2001;4:720-727. In pseudohyphal cells, polarized growth persists, resulting in longer buds.1515 Kron SJ, Styles CA, Fink GR. Symmetric cell division in pseudohyphae of the yeast Saccharomyces cerevisiae. Mol Biol Cell. 1994;5:1003-1022. Polarized growth depends on the actin cytoskeleton, which consists of cortical actin patches and actin cables.1414 Rua D, Tobe BT, Kron SJ. Cell cycle control of yeast filamentous growth. Curr Opin Microbiol. 2001;4:720-727. In both Candida albicans and T. asahii, disruption of actin cables by cytochalasin A (for C. albicans) or cytochalasin D (for T. asahii) causes the hyphal tips swell and the growth mode switches from polarized to isotropic. Consistent to these reports, our current study showed that Cytochalasin D treatment caused the loss of polarity (Fig. 3), which could be caused, at least part, the diminishing of the Spitzenkörper.1616 Crampin H, Finley K, Gerami-Nejad M, et al. Candida albicans hyphae have a Spitzenkörper that is distinct from the polarisome found in yeast and pseudohyphae. J Cell Sci. 2005;118(Pt 13):2935-2947.

  • Associate Editor: Luis Henrique Souza Guimarães

Acknowledgements

We thank the staff of the Dermatology and Venereology Department, Beijing Military Command General Hospital of PLA for their assistance. This project was supported by the National Natural Science Foundation of China (No. 81271764) and the 11th Plan Project of PLA of China (No. 06MB078).

References

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    Rothman JE. Mechanisms of intracellular protein transport. Nature 1994;372:55-63.
  • 2
    Bartnicki-Garcia S, Hergert F, Gierz G. Computer simulation of fungal morphogenesis and the mathematical basis for hyphal (tip) growth. Protoplasma 1989;153:46-57.
  • 3
    Howard RJ. Ultrastructural analysis of hyphal tip cell growth in fungi: Spitzenkörper, cytoskeleton and endomembranes after freeze-substitution. J Cell Sci 1981;48:89-103.
  • 4
    Girbardt M. Der Spitzenkörper von Polystictus versicolor. Planta 1957;50:47-59.
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    Grove SN, Bracker CE. Protoplasmic organization of hyphal tips among fungi: vesicles and Spitzenkörper. J Bacteriol 1970;104:989-1009.
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    Lopez-Franco R, Bracker CE. Diversity and dynamics of the Spitzenkörper in growing hyphal tips of higher fungi. Protoplasma 1996;195:90-111.
  • 7
    Read ND, Hickey PC. The Vesicle trafficking network and tip growth in fungal hyphae. In: Geitman A, ed. Cell Biology of Plant and Fungal Tip Growth Amsterdam, The Netherlands: IOS Press; 2001:137-147.
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    Fischer-Parton S, Parton RM, Hickey PC, Dijksterhuis J, Atkinson HA, Read ND. Confocal microscopy of FM4-64 as a tool for analysing endocytosis and vesicle trafficking in living fungal hyphae. J Microsc 2000;198(Pt 3):246-259.
  • 9
    Wang WL, Yang RY, Ao JH. Uncommon characteristics of the structure and development of Trichosporon asahii. Chin Med J (Engl) 2009;122:1806-1810.
  • 10
    Kron SJ, Gow NAR. Budding yeast morphogenesis: signalling, cytoskeleton and cell cycle. Curr Opin Cell Biol 1995;7:845-855.
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    Nelson WJ. Adaptation of core mechanisms to generate cell polarity. Nature 2003;422:766-774.
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    Pruyne D, Bretscher A. Polarization of cell growth in yeast. J Cell Sci 2000;113(Pt 4):571-585.
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    Pruyne D, Evangelista M, Yang C, et al. Role of formins in actin assembly: nucleation and barbed-end association. Science 2002;297:612-615.
  • 14
    Rua D, Tobe BT, Kron SJ. Cell cycle control of yeast filamentous growth. Curr Opin Microbiol 2001;4:720-727.
  • 15
    Kron SJ, Styles CA, Fink GR. Symmetric cell division in pseudohyphae of the yeast Saccharomyces cerevisiae Mol Biol Cell. 1994;5:1003-1022.
  • 16
    Crampin H, Finley K, Gerami-Nejad M, et al. Candida albicans hyphae have a Spitzenkörper that is distinct from the polarisome found in yeast and pseudohyphae. J Cell Sci 2005;118(Pt 13):2935-2947.

Publication Dates

  • Publication in this collection
    Jan-Mar 2016

History

  • Received
    11 Apr 2013
  • Accepted
    17 June 2015
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