Compression tests of Fusarium graminearum ascocarps provide insights into the strength of the perithecial wall and the quantity of ascospores

•A mechanical compression testing instrument was used to determine the failure of ascocarps.•Physical resiliency and number of spores increased with age of F.graminearum perithecia.•The age of perithecia is important to consider in plant disease models. The plant pathogenic ascomycete Fusarium grami...

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Bibliographic Details
Published in:Fungal genetics and biology 2016-11, Vol.96, p.25-32
Main Authors: David, Ray F., Reinisch, Michael, Trail, Frances, Marr, Linsey C., Schmale, David G.
Format: Article
Language:English
Subjects:
Ascomycetes
Ascospore
Cell Wall - physiology
Compressive Strength
Forcible discharge
Fungus
Fusarium - physiology
Fusarium graminearum
Fusarium head blight
Mechanical properties
Perithecium
Spores, Fungal - physiology
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Summary:•A mechanical compression testing instrument was used to determine the failure of ascocarps.•Physical resiliency and number of spores increased with age of F.graminearum perithecia.•The age of perithecia is important to consider in plant disease models. The plant pathogenic ascomycete Fusarium graminearum produces perithecia on corn and small grain residues. These perithecia forcibly discharge ascospores into the atmosphere. Little is known about the relationship among the strength of the perithecial wall, the age of the perithecium, and the quantity of ascospores produced. We used a mechanical compression testing instrument to examine the structural failure rate of perithecial walls from three different strains of F. graminearum (two wild type strains, and a mutant strain unable to produce asci). The force required to compress a perithecium by one micrometer (the mean perithecium compression constant, MPCC) was used to determine the strength of the perithecial wall. Over the course of perithecial maturation (5–12days after the initiation of perithecial development), the MPCC was compared to the number of ascospores contained inside the perithecia. The MPCC increased as perithecia matured, from 0.06Nμm−1 at 5d to 0.12Nμm−1 at 12d. The highest number of ascospores was found in older perithecia (12d). The results indicated that for every additional day of perithecial aging, the perithecia become more resilient to compression forces. Every additional day of perithecial aging resulted in ∼900 more ascospores. Knowledge of how perithecia respond to external forces may provide insight into the development of ascospores and the accumulation of turgor pressure. In the future, compression testing may provide a unique method of determining perithecial age in the field, which could extend to management practices that are informed by knowledge of ascospore release and dispersal.
ISSN:1087-1845
1096-0937
DOI:10.1016/j.fgb.2016.09.003