Abstract
Many amphibian species are at risk of extinction in their natural habitats due to the presence of the fungal pathogen Batrachochytrium dendrobatidis (Bd). For the most highly endangered species, captive assurance colonies have been established as an emergency measure to avoid extinction. Experimental research has suggested that symbiotic microorganisms in the skin of amphibians play a key role against Bd. While previous studies have addressed the effects of captivity on the cutaneous bacterial community, it remains poorly studied whether and how captive conditions affect the proportion of beneficial bacteria or their anti-Bd performance on amphibian hosts. In this study we sampled three amphibian species of the highly threatened genus, Atelopus, that remain in the wild but are also part of ex situ breeding programs in Colombia and Ecuador. Our goals were to (1) estimate the diversity of culturable bacterial assemblages in these three species of Atelopus, (2) describe the effect of captivity on the composition of skin microbiota, and (3) examine how captivity affects the bacterial ability to inhibit Bd growth. Using challenge assays we tested each bacterial isolate against Bd, and through sequencing of the 16S rRNA gene, we identified species from thirteen genera of bacteria that inhibited Bd growth. Surprisingly, we did not detect a reduction in skin bacteria diversity in captive frogs. Moreover, we found that frogs in captivity still harbor bacteria with anti-Bd activity. Although the scope of our study is limited to a few species and to the culturable portion of the bacterial community, our results indicate that captive programs do not necessarily change bacterial communities of the toad skins in a way that impedes the control of Bd in case of an eventual reintroduction.
Highlights
Global amphibian declines have been attributed to a variety of factors including habitat destruction, contamination, UV-B radiation, climate change, overexploitation, andHow to cite this article Flechas et al (2017), The effect of captivity on the skin microbial symbionts in three Atelopus species from the lowlands of Colombia and Ecuador
A total of 153 bacterial morphotypes were isolated from captive individuals: 70 from A. elegans, 62 from A. aff. limosus, and 21 from A. spurrelli
Given the high susceptibility of the genus to chytridiomycosis, and the lack of a cure that could allow them to survive in nature, conservation actions have been focused on keeping assurance colonies
Summary
Global amphibian declines have been attributed to a variety of factors including habitat destruction, contamination, UV-B radiation, climate change, overexploitation, andHow to cite this article Flechas et al (2017), The effect of captivity on the skin microbial symbionts in three Atelopus species from the lowlands of Colombia and Ecuador. Batrachochytrium dendrobatidis (Bd) (Longcore, Pessier & Nichols, 1999), and B. salamandrivorans (Bsal) (Martel et al, 2013) are highly pathogenic fungi, recognized as the etiological agents of the amphibian infectious disease known as chytridiomycosis. Bsal has been detected only in urodels (salamanders and newts) (Martel et al, 2013; Martel et al, 2014), while Bd is considered a generalist pathogen found in a wide variety of amphibian species across the three orders (i.e., Anura, Urodela and Gymnophiona). Bd has been detected in at least 520 amphibian species in 56 countries (Berger et al, 2016) causing population declines in at least 200 species across five continents (Skerratt et al, 2007; Fisher, Garner & Walker, 2009)
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