The effect of captivity on the skin microbial symbionts in three Atelopus species from the lowlands of Colombia and Ecuador.

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.

Introduction

Global amphibian declines have been attributed to a variety of factors including habitat destruction, contamination, UV-B radiation, climate change, overexploitation, and infectious diseases (Alford & Richards, 1999; Collins & Crump, 2009; Heard et al., 2013). Diseases caused by microparasites have been linked to massive mortality events and extinctions, and the causative agents can be viral, bacterial, or caused by protists and fungi (Latney & Klaphake, 2013; Chambouvet et al., 2015). Emerging diseases caused by fungi have become more problematic and the impact on the affected groups are much more alarming (Wake & Vredenburg, 2008; Fisher et al., 2012). 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).

Conservation strategies focused on ameliorating the lethal effects of the fungal pathogen have been mainly restricted to establishing disease-free ex situ colonies, with the aim of ensuring the survival of susceptible species (Becker et al., 2014; Tapley et al., 2015). Captive programs are a short-term intervention to prevent extinction where the final goal is to reintroduce the animals to their native habitat (Mendelson et al., 2006). Although, a strategy that ensures host survival despite Bd presence is still needed. Meanwhile, ex situ programs may be the best option for many threatened amphibians occurring in complex environments, where in situ strategies are difficult to apply (Bosch et al., 2015). The conditions under which amphibians are maintained in captivity may disturb their associated symbiotic microbes (Kueneman et al., 2016; Loudon et al., 2014), which would affect health status (Li et al., 2008; Becker et al., 2015) and survival rates if released into the wild (Redford et al., 2012; Michaels, Downie & Campbell-Palmer, 2014).

Cutaneous microbes can inhibit or delay the growth of Bd (Harris et al., 2006; Harris et al., 2009; Woodhams et al., 2007), and therapies where beneficial microbes are augmented in the host skin have been considered as an option to treat Bd-susceptible species in situ (Woodhams et al., 2011; Bletz et al., 2013; Woodhams et al., 2016). However, new approaches should take into account the complex interactions among the host, its symbiotic bacteria and the fungal pathogen without neglecting the role of the environmental context on these interactions (McKenzie et al., 2012; Kueneman et al., 2014; Bosch et al., 2015). Captivity imposes a different environment that might affect the microbial composition, and thus, the response of the host to the pathogen. Various studies have suggested that skin associated microbes of individuals in captivity differ from those in the wild (Becker et al., 2014; Kueneman et al., 2016; Sabino-Pinto et al., 2016). In the case of the red-eyed tree frog (Agalychnis callidryas), community composition, species richness, and abundance of bacterial groups seem to be influenced mainly by the availability of carotenoids in their diet (Antwis et al., 2014), and by the cover provided in the enclosures (Michaels, Antwis & Preziosi, 2014). However, other factors including humidity, temperature, pH and disinfection methods affect the presence of certain bacterial species and could facilitate or impede colonization and establishment in the host skin (Mendoza et al., 2012). Some studies have demonstrated that OTU (Operational Taxonomic Units) richness and phylogenetic diversity are significantly higher in captive animals (i.e., in Atelopus zeteki, Becker et al., 2014), while other studies find the opposite, where wild animals harbor a higher bacterial diversity (i.e., Cynops pyrrhogaster, Sabino-Pinto et al., 2016 and, Anaxyrus boreas, Kueneman et al., 2016).

Although changes in the bacterial assemblage composition due to captivity seem to vary depending on the species, understanding how changes in the bacterial community structure affect the host response to Bd infection may be key to successful ex situ programs. For example, Becker et al. (2015) showed that survival rates after exposure to Bd seem to be associated with the initial composition of the skin bacterial community, so different initial communities result in different outcomes for the host. Even though scientists have provided important insights on how different factors affect microbial assemblages in captive conditions (Antwis et al., 2014; Michaels, Antwis & Preziosi, 2014; Michaels, Downie & Campbell-Palmer, 2014), additional research is required to determine the impact of captivity on the proportion of bacteria with anti-Bd properties for specific amphibian species. Knowing how captive conditions affect the proportion and performance of bacteria with antifungal capacities will allow us to more accurately predict the fate of species considered for reintroduction into the wild.

Harlequin toads from the genus Atelopus are considered one of the most threatened groups of amphibians worldwide, with at least 71% of the species listed as critically endangered according to the International Union for Conservation of Nature (2016). Although many species have been declining, some species from the lowlands still persist in their natural habitats (Flechas, Vredenburg & Amézquita, 2015). Other species, such as A. elegans from Ecuador, has only been found in one of its historical collection localities. Given the crisis of wild amphibian populations and the highly susceptibility of Atelopus to the fungal disease, conservation actions have been focused on keeping assurance colonies in order to protect these species. Conservation initiatives are committed to protecting those species facing the highest risk of extinction, and have included at least 15 species of the genus Atelopus in rescue programs (http://progress.amphibianark.org/model-programs). In this study, we evaluated the effect of ex situ conditions on bacteria with anti-Bd activity. To accomplish this, we performed antagonism assays to determine which bacterial species can inhibit Bd growth. Then we compared the activity between bacteria isolated from individuals in the wild with those maintained in captivity. We use culture-dependent methods to compare the skin bacterial community in three Atelopus species that persist in the wild but are also part of an ex situ breeding program. Our main goal was to evaluate the effect of captivity on the composition of the skin microbial community, focusing mainly in those that exhibit anti-Bd properties. Since captive environments have been described as less heterogeneous and less diverse compared with natural habitats, we hypothesized that animals in the wild would support a more diverse bacterial community and therefore a higher capacity to inhibit Bd growth, increasing chances of host survival.

Materials & Methods

Research permits to conduct this study were provided by the Colombian National Parks Authority, the Ministerio de Ambiente de Colombia, and the Ministerio del Ambiente Ecuador (MAE) under permits DTSO 019-09, DTSO 001-09, No 10-07032012, 001-11 IC-FAU-DNB/MA and 11-2012-FAU-DPAP-MA.

Study species

We studied three Atelopus species from the lowlands, two occurring in the Pacific coastal forests of Colombia and one in Ecuador (Fig. 1). We took skin bacterial samples of A. spurrelli, in the municipality of Arusí (5.57°N, 77.50°W; 90 m), A. aff. limosus, a species occurring near Capurganá (8.60°N, 77.33°W; 150 m) near the border between Colombia and Panama, and A. elegans from the Esmeraldas Province in northwestern Ecuador (1.04°N, 78.62°W; 265 m). In addition, we took skin swabs from captive A. elegans, A. aff. limosus and A. spurrelli from the ex situ programs in the Cali Zoo (Cali, Colombia) and the “Balsa de los Sapos” Conservation Initiative at the Pontificia Universidad Católica del Ecuador (Quito, Ecuador). Individuals in captivity came from the same populations where wild samples were collected (Table 1).

Figure 1

Sampling sites.

Map showing the localities where bacterial samples were obtained Atelopus aff. limosus (green dot), Atelopus spurrelli (blue triangle) and Atelopus elegans (red square). Individuals brought to captivity were collected in the same localities where samples from wild individuals were obtained. The map was created using the profiles provided by GADM.

Table 1

Number of sampled individuals of each Atelopus species in wild and captive conditions.

The table includes the localities in Colombia and Ecuador where Atelopus individuals were sampled, the year when individuals were collected and entered into an ex situ facility, as well as the year when bacterial samples were taken for the analysis of the culturable portion of the skin microbiota.

Species	Site of collection	Stage	Captive ind.	Year of collection	Date of sampling captive individuals	Wild ind.	Date of sampling wild individuals
Atelopus elegans	Esmeraldas, Ecuador	Juvenile	2	1 ind - 2009 1 ind - 2010	2012	–	–
		Adult	8	2 ind - 2009 3 ind - 2010 1 ind - 2011 2 ind - 2012	2012	5	2012
Atelopus aff. limosus	Capurganá, Colombia	Juvenile	2	Born in captivity in 2011	2012	–	–
		Adult	5	2 ind - 2008 3 ind -2009	2012	8	2009
Atelopus spurrelli	Arusí, Colombia	Adult	4	2011	2012	5	2009

Ex situ conditions

Atelopus spurrelli and A. aff. limosus were brought to the Cali Zoo facilities and kept isolated during quarantine (60 days). Then individuals were transferred to the enclosures (1m × 0.5m × 0.5m) built using 6 mm-thick glass. To better simulate natural conditions, we created a 10 cm-depth pool that occupied a fifth of the tank’s base. Each terrarium was connected to an external canister filter AE 306 Resun® (flow: 700L/H, power: 12 watts). The filters were placed below each terrarium and connected with ” tubing. Natural plants were placed in the tank to provide shelter, sleeping sites and visual barriers for the frogs, as well as to maintain high humidity, good water quality and low levels of nitrogenous waste. Bromeliads, aroids, mosses, orchids and calatheas were preferred because they tolerate high humidity levels. All individuals were fed five times a week with domestic crickets and fruit flies enriched with vitamin-mineral supplements. Because our study species occur in the lowlands of Colombia, we kept air temperature within enclosures between 24–30 °C and water temperature at 20.5–22 °C.

Individuals of A. elegans at “Balsa de los Sapos” Conservation Initiative were maintained isolated in independent containers during quarantine (60 days). Afterward, toads were transferred to plastic enclosures (30cm × 20cm × 20cm) in which they were kept individually. Each terrarium contained natural plants, leaf litter, and a coconut bark to provide shelter and sleeping sites for the toads. Each container had 3 cm of water under false floor to maintain high levels of relative humidity. Clean water simulating artificial rain fell four times a day into each container during 5 min from a purification system with four filters: polyester film, UV, activated charcoal, and fabric filtration. All toads were fed three times a week with crickets that were sprinkled with vitamins and calcium supplement (Repashi Superfoods). Room temperature ranged between 19.6–22.9 °C.

Bacterial isolation

In order to determine the effect of captive conditions on the composition of cutaneous bacteria, we took skin bacterial samples from captive animals: four A. spurrelli, seven A. aff. limosus and ten individuals of A. elegans. All bacterial swab samples from captive animals were collected in 2012 (Table 1). To compare bacterial communities of captive and wild frogs, samples from wild animals were taken from five individuals of A. elegans from Esmeraldas (Ecuador). For wild individuals of A. spurrelli and A. aff. limosus we used the published data from Flechas et al. (2012).

Individuals were handled with new nitrile gloves and rinsed with 20 mL of sterile water to remove transient cutaneous microbiota. Each animal was sampled by running a sterile synthetic rayon swab (Medical Wire Equipment MWE 100) on their left, right of their body and ventral surfaces, hindlimbs, and interdigital membranes for a total of 50 strokes. Swabs were stored in 2 mL cryovials containing 1 mL DS solution, i.e., a weak salt solution resembling pond water (Boyle et al., 2003). Samples were refrigerated within 24 h and processed within 48 h after sampling. To isolate pure colonies, we followed the protocol described previously by Flechas et al. (2012). Each isolate was cryopreserved in nutritive broth with 30% glycerol at −80 °C.

Growth inhibition assays

To determine the ability of each isolate to inhibit Bd growth we performed antagonism assays as previously published (Harris et al., 2006; Lam et al., 2010; Flechas et al., 2012). Assays were conducted using two Bd strains: JEL423 (provided by JE Longcore, University of Maine, Orono, USA) and EV001 (Flechas et al., 2013). Bacterial isolates from captive animals of the three Atelopus species and from wild A. elegans were challenged against both Bd strains in duplicate. Bacterial strains isolated from wild Colombian Atelopus were only tested against the strain JEL 423 since the Colombian strain was not available before 2012. Query bacteria that produced a clear halo were considered as inhibitory (see Fig. 1 in Flechas et al., 2012). Isolates that showed signs of growth inhibition were photographed under similar resolution and lighting conditions in a dark background in order to estimate antifungal ability.

Sections of approximately 3.0cm × 1.75cm were taken from digital images of each culture plate: one section was taken from close to the bacterial growth (query bacteria) and two from sections were only Bd was present (control section of the plate). To estimate the antifungal action of bacteria, a graphical approach was developed using programming routines for R software (R Development Core Team, 2016). The three images were read into R using the function raster of ‘raster’ package (Hijmans, 2015) and then a frequency table was created based on the color present in each pixel using the function freq of the same package. We generated a continuous color scale ranging from 0 (white—representing only presence of Bd) to 255 (black—representing complete absence of Bd). To ensure these extreme values were present in the picture, two circles of equal dimensions (one of each color) were manually added to each image.

Because Bd does not grow uniformly over the plate’s surface, two control assessments were employed: (a) We obtained kernel density estimates for each control picture and the average of the modal color value from each picture was used in all posterior analyses. For this step, we used the function density from the ‘stats’ package in R (R Development Core Team, 2016) with its default arguments, and, (b) the frequency tables of each control picture were averaged by color, and then the color value corresponding to the mode of the kernel density estimates was used as control. These two control values were compared to the modal color value of the picture showing the bacterial effect on Bd growth. We assumed that lower experimental values than the control imply Bd inhibition (darker background in picture), and no differences between control and experimental values imply no antifungal effect (S1).

Identification of bacterial isolates

DNA from pure cultures, including inhibitory and non-inhibitory strains were extracted as follows: one colony of each morphotype was re-suspended in 10 mL of pure water HPLC grade in a 0.2 mL PCR tube and boiled for 7 min at 95 °C. PCR amplifications were performed using universal primers 27F and 1492R (Lane, 1991) and the following parameters: an initial denaturation of 3 min at 95 °C, followed by 35 cycles of 45 s at 95 °C, 45 s at 52 °C and 90 s at 72 °C, and a final extension of 7 min at 72 °C. Each reaction consisted of 0.5 μL of each primer (1 μM), 3.0 μL of doubly distilled DNA-free water, 6 μL of GoTaq® Green Master Mix (1X; Promega) and 2 μL of the DNA extract. PCR results were checked by electrophoresis in 1% agarose gels. DNA sequences were cleaned and assembled using Geneious (Kearse et al., 2012). 16S rRNA sequences were then identified using BLASTn (Altschul et al., 1990) against the complete GenBank nucleotide database (http://www.ncbi.nlm.hih.gov) and the Greengenes database (http://greengenes.lbl.gov) using default parameters in both cases.

Statistical analyses

In order to determine the variable (species or condition) that best explained the composition of the skin-associated bacterial community we used a Canonical Correspondence Analysis—CCA using the function cca in the ‘vegan’ package in R (Oksanen et al., 2015). In addition, to compare bacterial diversity between wild and captive animals, we counted the number of bacterial species in each category (species and condition) and then we performed a chi-square test using the ‘stats’ package in R (R Development Core Team, 2016). In order to determine the effect of captivity on bacterial assemblages, we used a chi-square test to check if there were differences in the proportion of bacterial species with antibacterial properties between conditions (wild vs. captive). Lastly, to test for differences in the capacity of bacterial species to inhibit Bd depending on their origin (wild vs. captive), we performed an ANOVA using the data obtained from the image analysis, after testing for normality and homogeneity of variances using Shapiro–Wilk and Bartlett tests, respectively.

Results

Isolated bacteria from wild and captive individuals

Based on morphological characteristics, 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. We recovered 40 morphotypes from wild A. elegans. Fifteen (21%) bacterial morphotypes from captive and 11 (27%) from wild individuals of A. elegans inhibited Bd growth in the antagonism assays. For captive A. aff. limosus and A. spurrelli, 29 of 62 and six of 21 morphotypes inhibited Bd growth, respectively (Table 2). Since identification of bacteria based only on morphology is not completely reliable, we sequenced the 16S rRNA gene for all the isolated morphotypes. From 193 culturable morphotypes, we were able to identify bacteria representing 74 OTUs belonging to 37 genera. Through antagonism assays we found 28 OTUs (38%) in 13 genera showed some degree of anti-Bd activity. To define bacterial species we used a cut of 97% similarity. Sequences are available in GenBank with the following accession numbers: KY910042–KY910115 and KY938077 –KY938172.

Table 2

Summary of the number of bacterial isolates recovered from three Atelopus species in captive and wild conditions.

The number in parenthesis represents the percentage of isolates with anti-Bd properties. In the last column we detailed the number of bacterial species that exhibit some degree of anti-Bd activity.

Species	Condition	# of isolates	# Anti-Bd isolates	# Bacterial species with anti-Bd activity
Atelopus elegans	Captive	70	15 (21%)	7 from 3 genera
	Wild	40	11 (27%)	9 from 7 genera
Atelopus aff. limosus	Captive	62	29 (47%)	11 from 6 genera
	Wild	77	20 (26%)	7 from 3 genera
Atelopus spurrelli	Captive	21	6 (28%)	4 from 4 genera
	Wild	21	6 (28%)	5 from 2 genera

Effect of captivity on the composition of skin bacterial community

Although captive and wild individuals from the same host species harbor cutaneous bacteria belonging to the same genera (Fig. 2), we found little overlap in bacterial species diversity between conditions (CCA: , F = 1.23, P = 0.02) (Table 3, Fig. 3). We did not find evidence for reduction in the number of bacterial species between wild and captive animals (, P = 0.1608, Fig. 4). Antagonism experiments revealed that animals in the wild and individuals kept in ex situ facilities harbor in their skin bacteria with antifungal capacities. Differences in the proportion of bacteria with antifungal abilities between captive (22/64) and wild individuals (18/53) were not significant (Fisher exact test, P = 1, Odds ratio = 1.01, Fig. 4).

Figure 2

Differences in the relative abundance of culturable bacterial genera isolated from the skin of captive and wild individuals in three species of Atelopus.

Bars are grouped by species and condition. Numbers inside the bars denote the number of toads sampled per category. C, Captive; W, Wild.

Table 3

Bacterial species isolated from the skin of Atelopus elegans, Atelopus aff. limosus and Atelopus spurrelli.

C, Captive; W, Wild. The number in parenthesis represents the number of individuals sampled in each condition. Numbers in each cell represent the number of isolates for each bacterial species. Species that showed anti-Bd activity are marked with an asterisk (*). Bacteria highlighted in grey correspond to those present in captive and wild animals.

Family	Bacterial isolates	A. elegans		A. aff. limosus		A. spurrelli
		C (10)	W (5)	C (7)	W (8)	C (4)	W (5)
Moraxellaceae	Acinetobacter baumannii	–	–	1	3	–	2
Moraxellaceae	Acinetobacter bereziniae	–	–	1	–	–	–
Moraxellaceae	Acinetobacter calcoaceticus	–	–	1	2	–	1
Moraxellaceae	Acinetobacter genomosp.	–	–	–	1	–	–
Moraxellaceae	Acinetobacter haemolyticus	–	–	–	–	–	1*
Moraxellaceae	Acinetobacter gyllenbergii	–	–	–	5*	–	1*
Moraxellaceae	Acinetobacter junii	–	–	–	1	–	–
Moraxellaceae	Acinetobacter sp.	2	–	3*	7*	2	2*
Moraxellaceae	Acinetobacter venetianus	–	–	–	1	–	–
Aeromonadaceae	Aeromonas hydrophilia	1	–	–	–	–	–
Aeromonadaceae	Aeromonas sp.	1	–	–	–	–	–
Alcaligenaceae	Alcaligenes faecalis	–	–	1*	–	–	–
Bacillaceae	Bacillus sp.	–	–	1	–	–	–
Bacillaceae	Bacillus cereus	–	–	2*	–	–	–
Sphingomonadaceae	Blastomonas natatoria	4	3*	–	–	–	–
Brevibacteriaceae	Brevibacterium aureum	–	–	1	–	–	–
Caulobacteraceae	Brevundimonas aurantiaca	1	1	–	–	–	–
Caulobacteraceae	Caulobacter crescentus	–	1	–	–	–	–
Caulobacteraceae	Caulobacter vibroides	–	1	–	–	–	–
Flavobacteriaceae	Chryseobacterium indologenes	–	–	2*	–	–	–
Flavobacteriaceae	Chryseobacterium meningosepticum	–	–	1*	1*	2*	1
Flavobacteriaceae	Chryseobacterium sp.	–	–	2*	5*	–	–
Enterobacteriaceae	Citrobacter freundii	–	1*	–	–	–	–
Enterobacteriaceae	Citrobacter sp.	1*	–	–	–	–	–
Comamonadaceae	Comamonas sp.	3	–		1	1	1
Comamonadaceae	Comamonas testosteroni	–	–	2	1	1*	2
Oxalobacteraceae	Duganella sp.	–	1	–	–	–	–
Dermacoccaceae	Dermacoccus sp.	–	–	1	–	–	–
Enterobacteriaceae	Enterobacter asburiae	1*	–	–	–	–	–
Enterobacteriaceae	Enterobacter sp.	2	2	–	–	–	–
Enterobacteriaceae	Erwinia amylovora	–	1	–	–	–	–
Streptomycetaceae	Kitasatospora phosalacinea	–	–	1	–	–	–
Enterobacteriaceae	Klebsiella oxytoca	1	–	–	–	–	–
Enterobacteriaceae	Klebsiella sp.	–	1	–	–	–	–
Enterobacteriaceae	Kluyvera ascorbata	–	1*	–	–	–	–
Microbacteriaceae	Leucobacter sp.	–	–	1	–	–	–
Listeriaceae	Listeria sp.	–	–	1	–	–	–
Xanthomonadaceae	Luteibacter rhizovicinus	–	1*	–	–	–	–
Oxalobacteraceae	Massilia sp.	1	–	–	–	–	–
Microbacteriaceae	Microbacterium foliorum	1	–	–	–	–	–
Microbacteriaceae	Microbacterium sp.	1	–	–	–	–	–
Microbacteriaceae	Microbacterium testaceum	–	1	–	–	–	–
Enterobacteriaceae	Morganella morganii	1	–	–	–	–	–
Sphingomonadaceae	Novosphingobium aromaticivorans	1	–	–	–	–	–
Sphingomonadaceae	Novosphingobium subterraneum	2	3*	–	–	–	–
Enterobacteriaceae	Pantoea agglomerans	1	–	–	–	–	–
Comamonadaceae	Pelomonas puraquae	3	–	–	–	–	–
Pseudomonadaceae	Pseudomonas aeruginosa	1*	–	–	–	–	–
Pseudomonadaceae	Pseudomonas fulva	1	1*	–	–	–	–
Pseudomonadaceae	Pseudomonas geniculata	–	–	1*	–	–	–
Pseudomonadaceae	Pseudomonas montielli	–	–	–	–	1*	–
Pseudomonadaceae	Pseudomonas mosselii	1*	–	1*	–	–	–
Pseudomonadaceae	Pseudomonas plecoglossicida	–	–	1	–	–	1*
Pseudomonadaceae	Pseudomonas putida	2*	1*	2*	1	1	2*
Pseudomonadaceae	Pseudomonas saccharophilia	1	–	–	–	–	–
Pseudomonadaceae	Pseudomonas sp.	4*	2*	2	1	1	1
Pseudomonadaceae	Pseudomonas nitroreducens	–	–	–	–	–	1
Pseudomonadaceae	Pseudomonas straminea	–	–	–	–	–	1
Pseudomonadaceae	Pseudomonas tolaasii	–	–	–	1	–	1
Pseudomonadaceae	Pseudomonas veronii	–	–	–	6*	–	–
Pseudomonadaceae	Pseudomonas vranovensis	2*	–	–	–	–	–
Enterobacteriaceae	Raoultella ornithinolytica	–	1	–	–	–	–
Rhizobiaceae	Rhizobium sp.	1	1	–	–	–	–
Sphingomonadaceae	Sphingobium yanoikuyae	2	–	–	–	–	–
Sphingomonadaceae	Shipngomonas paucimobilis	1	–	–	–	–	–
Sphingomonadaceae	Sphingomonas sp.	4	1	–	–	–	–
Sphingomonadaceae	Sphingopyxis sp.	4	–	–	–	–	–
Staphylococcaceae	Staphylococcus capitis	–	1	–	–	–	–
Xanthomonadaceae	Stenotrophomonas maltophilia	–	1	4*	–	1	1
Xanthomonadaceae	Stenotrophomonas sp.	–	1	2*	–	1*	–
Nocardiaceae	Tsukamurella sp.	1	–	–	–	–	–
Nocardiaceae	Tsukamurella tyrosinosolvens	1	–	–	–	–	–
Enterobacteriaceae	Yokenella regensburgei	–	1	–	–	–	–

Figure 3

Culturable bacterial communities between captive and wild individuals of Atelopus exhibit little overlap.

Non-metric Multidimensional Scaling (NMDS) ordination of Bray–Curtis distances between microbial communities. Each symbol represents one sampled individual. Ellipses represent 95% confidence intervals (Dark grey, wild; light grey, captive).

Figure 4

Atelopus in the wild and in captivity harbor in their skin culturable bacteria with antifungal abilities.

Darker bars show the total number of isolated bacteria in each condition (wild vs. captive). Lighter bars represent the number of bacterial species with anti-Bd activity in each condition (wild vs. captive).

Anti-Bd activity in shared bacterial strains

To determine if anti-Bd activity changes depending on the origin of the bacteria, we compared the ability to inhibit Bd only for those bacterial species that were found in both captive and wild animals. We detected five bacterial species that inhibited Bd growth in both conditions including: Acinetobacter sp., Chryseobacterium sp., C. meningosepticum, Pseudomonas putida, and Pseudomonas sp. The inhibition was measured as a reduction of density of Bd colonies (based on the presence of darker pixels in the experimental area). Differences in the extent of inhibition between bacteria isolated from wild and captive animals were not detected (F = 0.503, P = 0.73; Fig. 5). Bacteria inhibit Bd growth irrespective of the Bd strain used (JEL or EV001, Fisher exact test, P = 0.051, Odds ratio = 0.385).

Figure 5

Bacteria isolated from wild and captive animals did not differ in the extent of Bd inhibition.

Colored dots were only used for those bacteria that were identified to species. Black dots correspond to the bacteria that were identified to genus.

Discussion

The genus Atelopus is one of the most threatened groups of amphibians worldwide. Although more than 70% of the species in the genus are listed as critically endangered according to the International Union for Conservation of Nature (2016), some species have persisted in the wild (Flechas, Vredenburg & Amézquita, 2015). In other cases, such as A. elegans from Ecuador, this species has been recently rediscovered but only in one of the historical localities. 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. In this study, we describe culturable bacterial assemblages for individuals of three Atelopus species that remain in the wild, in apparently healthy conditions, and individuals (from the same species and collection localities) brought into captivity. This study sought to determine the effect of captive conditions on the anti-Bd bacterial community in one of the most threatened genera worldwide (La Marca et al., 2005; Mendelson et al., 2006). Our main goal was not only to describe the culturable portion of the bacterial community for each condition, but the effect of captivity on the proportion of beneficial bacteria and their performance as Bd inhibitors. Although our results show that captive individuals harbor bacteria with anti-Bd properties, further long-term research is key to evaluate the interactions between the skin microbial communities and their amphibian hosts since those can differ from one population to the next even if the bacterial community composition is similar (Rebollar et al., 2016).

Several studies have reported changes in the microbial associated communities when animals are moved from the wild to captive environments (Isaacs et al., 2009; Dhanasiri et al., 2011; Wienemann et al., 2011; Nelson et al., 2013). In amphibians, research assessing the effect of captivity on bacterial communities is increasing (Antwis et al., 2014; Becker et al., 2014; Michaels, Antwis & Preziosi, 2014; Kueneman et al., 2016). Through culture-independent and dependent approaches, these studies have demonstrated changes in the skin bacterial community composition due to conditions imposed by captivity. Our results suggest that ex situ conditions, at least for these three Atelopus species, did not reduce the diversity of bacteria or the proportion of anti-Bd bacteria, as determined by culture-based assays. Moreover, we found a higher number of culturable bacterial species in captive animals compared to wild individuals. Our findings are consistent with those obtained for other vertebrates including birds and mammals (Xenoulis et al., 2010; Nelson et al., 2013), where gut microbial diversity was higher in captive animals, and are also consistent with the findings for the Panamanian golden frogs (A. zeteki) where OTU richness and phylogenetic diversity was higher in captive frogs (Becker et al., 2014). We found that species of bacteria belonging to the genera Pseudomonas, Chryseobacterium and Acinetobacter isolated from wild and captive animals inhibited Bd in the challenge assays. In a recent study, bacterial isolates from these three groups were also reported as Bd inhibitors and they appeared to be widely distributed. The proportion of bacteria that showed anti-Bd activity for those genera was 73% for Pseudomonas, 55% for Chryseobacterium and 37% for Acinetobacter (Woodhams et al., 2015).

Variations in bacterial communities due to captive conditions have been demonstrated in red-backed salamanders (Plethodon cinereus), where environmental microbes seemed to affect host-microbial diversity and appeared to be important as regulators of the host core community (Loudon et al., 2014). In terms of their associated microbiota, captive environments appear to be less diverse and less heterogeneous than wild habitats, which might imply that host associated bacterial communities for animals in ex situ facilities should be less diverse (Sabino-Pinto et al., 2016). The enclosures where frogs are maintained provide a modified environment that can also vary depending on the zoo or facility. These conditions could facilitate the transmission of new bacteria capable of colonizing the frog skin, as suggested for other animals in captivity (Nelson et al., 2013). We found that culturable bacterial communities from captive animals at the Cali Zoo (A. aff. limosus and A. spurrelli) were not the same but more similar to each other than compared with A. elegans. The slight difference between captive A. aff. limosus and A. spurrelli (Fig. 2), suggests that a “host” component is also playing a role shaping skin bacterial communities, as suggested previously for Japanese amphibians (Sabino-Pinto et al., 2016). Although the cages used in this study simulated natural conditions, we propose that the observed differences between frogs from both ex situ facilities might be related to the environmental conditions inside the enclosures (i.e., substrate and water sources). Although, there is no solid evidence on which mechanisms are the frogs using to acquire bacteria from the environment, and which are the key factors modeling bacterial assemblages, we suggest that either the environment or host characteristics are modeling bacterial communities in these species of harlequin toads.

A cure or mechanism that allows threatened amphibian species to survive chytridiomycosis in their natural habitats is still needed. Although many different disease mitigation strategies have been proposed (Woodhams et al., 2011; Bosch et al., 2015), keeping viable assurance colonies in captivity seems to be the best option for Bd-susceptible species yet (Gratwicke et al., 2015). The main goal of ex situ programs is to eventually reintroduce animals to their natural habitats. Management in captivity can lead to alterations of the species’ microbiota that may reduce survival chances after reintroduction (Redford et al., 2012). In this study, we isolated a similar number of bacterial species with anti-Bd activity from captive and wild individuals of three Atelopus species, suggesting that they might count on their skin bacteria as a potential defense barrier against Bd. Redford et al. (2012) proposed that more studies are needed to determine changes and alterations in the animals’ microbiome in order to increase the success of reintroduction efforts. Here, we presented evidence that although bacterial community structure changed in captivity, the predicted anti-Bd function remained intact. In addition, it seems that animals are acquiring new microorganisms that are also providing protection against the fungal pathogen. Our findings suggest that selection acted on bacterial community function (e.g., antifungal activity and protection) as opposed to selection for specific community structures. We hope this study might be considered when reintroduction plans are proposed as the next step for many species that are now part of ex situ programs.

Accession numbers for bacteria isolated from the skin of three Atelopus species

The table summarize the information of each isolate.

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Photometric method

Control and experimental digital images from two tests: upper panels show an experiment where we visually detected antifungal activity; lower panels show an experiment where tested bacterium did not inhibit Bd growth. On the right, kernel density estimates for color composition in experimental images (solid blue line) and its mode (dashed blue line). Red and brown dashed lines represent the modes of the kernel density estimates for the two assessment methods.

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