Incorporating evaporative water loss into bioenergetic models of hibernation to test for relative influence of host and pathogen traits on white-nose syndrome

Autor: Catherine G. Haase, Raina K. Plowright, Liam P. McGuire, Kaleigh J. O. Norquay, C. Reed Hranac, Craig K. R. Willis, Nathan W. Fuller, David T. S. Hayman, Sarah H. Olson, Kirk A. Silas
Jazyk: angličtina
Rok vydání: 2019
Předmět:
030110 physiology
0106 biological sciences
0301 basic medicine
Hibernation
Atmospheric Science
Bioenergetics
Physiology
Microclimate
Social Sciences
Biochemistry
01 natural sciences
Fats
Animal Wings
Microbial Physiology
Chiroptera
Bats
Medicine and Health Sciences
Psychology
Animal Anatomy
Mammals
0303 health sciences
Multidisciplinary
Animal Behavior
biology
Energetics
Microbial Growth and Development
Eukaryota
Myotis lucifugus
Lipids
Vertebrates
Host-Pathogen Interactions
Medicine
Seasons
Host adaptation
Anatomy
Arousal
Research Article
Fungal Growth
Science
Torpor
Zoology
Nose
Microbiology
010603 evolutionary biology
Hibernaculum
03 medical and health sciences
Meteorology
Animals
030304 developmental biology
Behavior
Winter
Organisms
Fungi
Biology and Life Sciences
Water
Humidity
biology.organism_classification
Amniotes
Earth Sciences
Physiological Processes
Developmental Biology
Zdroj: PLoS ONE
PLoS ONE, Vol 14, Iss 10, p e0222311 (2019)
DOI: 10.1101/750257
Popis: Hibernation consists of extended durations of torpor interrupted by periodic arousals. The ‘dehydration hypothesis’ proposes that hibernating mammals arouse to replenish water lost through evaporation during torpor. Arousals are energetically expensive, and increased arousal frequency can alter survival throughout hibernation. Yet we lack a means to assess the effect of evaporative water loss (EWL), determined by animal physiology and hibernation microclimate, on torpor bout duration and subsequent survival. White-nose syndrome (WNS), a devastating disease impacting hibernating bats, causes increased frequency of arousals during hibernation and EWL has been hypothesized to contribute to this increased arousal frequency. WNS is caused by a fungus, which grows well in humid hibernaculum environments and damages wing tissue important for water conservation. Here, we integrated the effect of EWL on torpor expression in a hibernation energetics model, including the effects of fungal infection, to determine the link between EWL and survival. We collected field data forMyotis lucifugus, a species that experiences high mortality from WNS, to gather parameters for the model. In saturating conditions we predicted healthy bats experience minimal mortality. Infected bats, however, suffer high fungal growth in highly saturated environments, leading to exhaustion of fat stores before spring. Our results suggest that host adaptation to humid environments leads to increased arousal frequency from infection, which drives mortality across hibernaculum conditions. Our modified hibernation model provides a tool to assess the interplay between host physiology, hibernaculum microclimate, and diseases such as WNS on winter survival.
Databáze: OpenAIRE
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