Abstract
Recently emerged fungal diseases, Batrachochytrium dendrobatidis (Bd) and Batrachochytrium salamandrivorans (Bsal) are an increasing threat to amphibians worldwide. In Europe, the threat of Bsal to salamander populations is demonstrated by the rapid decline of fire salamander populations in Germany, the Netherlands and Belgium. Although most European urodelans are susceptible to infection in infection trials, recent evidence suggests marked interspecific differences in the course of infection, with potentially far reaching implications for salamander conservation. As a salamander’s skin is the first line of defense against such pathogens, interspecific differences in innate immune function of the skin may explain differential susceptibility. Here we investigate if compounds present on a salamander’s skin can kill Bsal spores and if there is variation among species. We used a non-invasive assay to compare killing ability of salamander mucosomes of four different species (captive and wild Salamandra salamandra and captive Ichtyosaura alpestris, Cynops pyrrhogaster and Lissotriton helveticus) by exposing Bsal zoospores to salamander mucosomes and determining spore survival. In all samples, zoospores were killed when exposed to mucosomes. Moreover, we saw a significant variation in this Bsal killing ability of mucosomes between different salamander host species. Our results indicate that mucosomes of salamanders might provide crucial skin protection against Bsal, and could explain why some species are more susceptible than others. This study represents a step towards better understanding host species variation in innate immune function and disease susceptibility in amphibians.
Highlights
Wildlife diseases are an increasing threat to biodiversity [1,2]
The mucosome of fire salamanders killed a substantial amount of chytrid spores (Fig 1B), reduction in viable Batrachochytrium dendrobatidis (Bd) spores (54.5%) was significantly greater than Batrachochytrium salamandrivorans (Bsal) spores (26.5%) (t = 4.4, df = 11 p = 0.001)
This resulted in an average Bsal spore mortality of 28.8%, which is comparable to captive fire salamanders mucosomes (Fig 2)
Summary
Over the last two decades amphibian populations have declined due to recently emerged diseases [3,4,5]. Batrachochytrium salamandrivorans (hereafter Bsal), etiological agents of chytridiomycosis have been wreaking havoc on amphibian populations worldwide [6,7,8,9,10,11,12]. In Europe, Bsal emerged suddenly and severely, causing a population of fire salamanders to nearly collapse in the Netherlands, with less than 0.1% of the population remaining [13,14]. Originating in Asia [17,18] this pathogen may have a quick and devastating effect on most salamander species of Europe. The risk of further spread globally has caused proactive responses in the form of taskforces to emerge and trade restrictions to be implemented in the USA, Canada and Switzerland [19,20]
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