Ascus function: From squirt guns to ooze tubes

Unlike the mechanism of ballistospore discharge, which was not solved until the 1980s, the operation of asci as pressurized squirt guns is relatively straightforward and was understood in the nineteenth century. Since then, mycologists have sought to understand how structural adaptations to asci hav...

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Veröffentlicht in:	Fungal biology 2023-12, Vol.127 (12), p.1491-1504
Hauptverfasser:	Money, Nicholas P., Stolze-Rybczynski, Jessica, Smith, B. Eugene, Trninić, Dragana, Davis, Diana J., Fischer, Mark W.F.
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Sprache:	eng
Schlagworte:	asci Ascomycetes Ascomycota ascospores Biomechanics Dispersal fruits fungi microscopy momentum mycology Spores travel Turgor pressure
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creator	Money, Nicholas P. Stolze-Rybczynski, Jessica Smith, B. Eugene Trninić, Dragana Davis, Diana J. Fischer, Mark W.F.
description	Unlike the mechanism of ballistospore discharge, which was not solved until the 1980s, the operation of asci as pressurized squirt guns is relatively straightforward and was understood in the nineteenth century. Since then, mycologists have sought to understand how structural adaptations to asci have allowed the ascomycetes to expel spores of different shapes and sizes over distances ranging from a few millimeters to tens of centimeters. These modifications include the use of valves at the tips of asci that maintain ascus pressure and expel spores at the highest speeds, and gelatinous appendages that connect spores after release and create larger projectiles with greater momentum than single spores. Clever experiments in the twentieth century coupled with meticulous microscopic studies led investigators to understand how asci with complicated apical structures worked and mathematical models produced estimates of launch speeds. With the recent application of high-speed video microscopy, these inferences about ascus function have been tested by imaging the motion of spores on a microsecond timescale. These experiments have established that ascospore discharge is the fastest fungal movement and is among the fastest movements in biology. Beginning with the history of the study of asci, this review article explains how asci are pressurized, how spores are released, and how far spores travel after their release. We also consider the efficiency of ascospore discharge relative to the mechanism of ballistospore discharge and examine the way that the squirt gun mechanism has limited the morphological diversity of ascomycete fruit bodies. •Ascospore discharge is the fastest fungal movement.•Early ascus research inspired the most ingenious experiments in mycological history.•Ascospore and ballistospore discharge share the same underlying chemistry.
doi_str_mv	10.1016/j.funbio.2023.11.001
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Clever experiments in the twentieth century coupled with meticulous microscopic studies led investigators to understand how asci with complicated apical structures worked and mathematical models produced estimates of launch speeds. With the recent application of high-speed video microscopy, these inferences about ascus function have been tested by imaging the motion of spores on a microsecond timescale. These experiments have established that ascospore discharge is the fastest fungal movement and is among the fastest movements in biology. Beginning with the history of the study of asci, this review article explains how asci are pressurized, how spores are released, and how far spores travel after their release. 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Eugene</creatorcontrib><creatorcontrib>Trninić, Dragana</creatorcontrib><creatorcontrib>Davis, Diana J.</creatorcontrib><creatorcontrib>Fischer, Mark W.F.</creatorcontrib><title>Ascus function: From squirt guns to ooze tubes</title><title>Fungal biology</title><addtitle>Fungal Biol</addtitle><description>Unlike the mechanism of ballistospore discharge, which was not solved until the 1980s, the operation of asci as pressurized squirt guns is relatively straightforward and was understood in the nineteenth century. Since then, mycologists have sought to understand how structural adaptations to asci have allowed the ascomycetes to expel spores of different shapes and sizes over distances ranging from a few millimeters to tens of centimeters. These modifications include the use of valves at the tips of asci that maintain ascus pressure and expel spores at the highest speeds, and gelatinous appendages that connect spores after release and create larger projectiles with greater momentum than single spores. Clever experiments in the twentieth century coupled with meticulous microscopic studies led investigators to understand how asci with complicated apical structures worked and mathematical models produced estimates of launch speeds. With the recent application of high-speed video microscopy, these inferences about ascus function have been tested by imaging the motion of spores on a microsecond timescale. These experiments have established that ascospore discharge is the fastest fungal movement and is among the fastest movements in biology. Beginning with the history of the study of asci, this review article explains how asci are pressurized, how spores are released, and how far spores travel after their release. 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subjects	asci Ascomycetes Ascomycota ascospores Biomechanics Dispersal fruits fungi microscopy momentum mycology Spores travel Turgor pressure
title	Ascus function: From squirt guns to ooze tubes
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