SUMMARY Most basidiomycete fungi actively eject their spores. The process begins with the condensation of a water droplet at the base of the spore. The fusion of the droplet onto the spore creates a momentum that propels the spore forward. The use of surface tension for spore ejection offers a new paradigm to perform work at small length scales. However, this mechanism of force generation remains poorly understood. To elucidate how fungal spores make effective use of surface tension, we performed a detailed mechanical analysis of the three stages of spore ejection: the transfer of energy from the drop to the spore, the work of fracture required to release the spore from its supporting structure and the kinetic energy of the spore after ejection. High-speed video imaging of spore ejection in Auricularia auricula and Sporobolomyces yeasts revealed that drop coalescence takes place over a short distance (∼5 μm) and energy transfer is completed in less than 4 μs. Based on these observations, we developed an explicit relation for the conversion of surface energy into kinetic energy during the coalescence process. The relation was validated with a simple artificial system and shown to predict the initial spore velocity accurately (predicted velocity: 1.2 m s–1; observed velocity: 0.8 m s–1 for A. auricula). Using calibrated microcantilevers, we also demonstrate that the work required to detach the spore from the supporting sterigma represents only a small fraction of the total energy available for spore ejection. Finally, our observations of this unique discharge mechanism reveal a surprising similarity with the mechanics of jumping in animals.
Surface tension propulsion of fungal spores
X. Noblin,Sylvia Yang,J. Dumais
Published 2009 in Journal of Experimental Biology
ABSTRACT
PUBLICATION RECORD
- Publication year
2009
- Venue
Journal of Experimental Biology
- Publication date
2009-09-01
- Fields of study
Biology, Materials Science, Physics, Environmental Science, Medicine
- Identifiers
- External record
- Source metadata
Semantic Scholar, PubMed
CITATION MAP
EXTRACTION MAP
CLAIMS
CONCEPTS
- animal jumping mechanics
The mechanical principles underlying jumping in animals, used here as a comparison point.
Aliases: jumping in animals
- artificial system validation
A simple constructed test system used to check whether the derived energy-conversion relation works as expected.
Aliases: validation with an artificial system
- calibrated microcantilevers
Force-sensing cantilevers calibrated for measuring the detachment work required to release a spore.
Aliases: microcantilever assay
- drop coalescence
The merging of the condensed water droplet with the spore at the start of ejection.
Aliases: droplet coalescence, coalescence of the water drop
- energy transfer
The movement of mechanical energy from the coalescing drop into the spore during the ejection event.
Aliases: transfer of energy
- fungal spore discharge mechanics
The mechanical features of the spore-launching process in basidiomycete fungi.
Aliases: spore discharge mechanics
- initial spore velocity
The spore speed immediately after ejection, before later aerodynamic effects dominate.
Aliases: launch velocity
- spore ejection
The rapid discharge of a fungal spore away from its supporting structure.
Aliases: spore discharge
- sterigma
The supporting fungal structure from which the spore must detach before ejection.
Aliases: supporting sterigma
- surface energy to kinetic energy conversion relation
The explicit relation derived here for converting surface energy released during coalescence into spore kinetic energy.
Aliases: surface-energy-to-kinetic-energy relation
- work of fracture
The energy required to separate the spore from the supporting sterigma.
Aliases: detachment work
REFERENCES
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