Time-related immunomodulation by stressors and corticosterone transdermal application in toads
Authors:
Stefanny Christie Monteiro Titon aff001; Braz Titon, Jr aff001; Adriana Maria Giorgi Barsotti aff001; Fernando Ribeiro Gomes aff001; Vania Regina Assis aff001
Authors place of work:
Departamento de Fisiologia, Instituto de Biociências, Universidade de São Paulo, São Paulo, SP, Brasil
aff001
Published in the journal:
PLoS ONE 14(9)
Category:
Research Article
doi:
https://doi.org/10.1371/journal.pone.0222856
Summary
Immune responses have been mostly studied at a specific time in anuran species. However, time-changes related to immunomodulation associated with glucocorticoid (GC) alterations following stressors and GC treatment are complex. The present study describes time-related changes in immune response and corticosterone (CORT) plasma levels following restraint challenge, short, mid and long-term captivity, and CORT exogenous administration by transdermal application (TA) in Rhinella ornata toads. We observed increased neutrophil: lymphocyte ratios after restraint challenge and CORT TA, without changes following short and mid-term captivity. Plasma bacterial killing ability was sustained in all treatments, except long-term captivity, with decreased values after 90 days under such conditions. Phagocytic activity of peritoneal cells increased after mid-term captivity, and the phytohemagglutinin swelling response was impaired in those animals treated with CORT TA for 20 consecutive days. Plasma CORT levels increased or were sustained after restraint challenge (depending on initial values), decreased following mid and long-term captivity (for those animals showing high CORT in the field) and increased after 20 days of CORT TA. By performing assessments of time-changes in immune processes and CORT plasma levels in R. ornata, we demonstrate immuno-enhancing effects following restraint, short and mid-term stressors, while long-term stressors and CORT TA promoted immunosuppression in these toads.
Keywords:
Biology and life sciences – Cell biology – Organisms – Eukaryota – Cell processes – Animals – Cellular types – Animal cells – Anatomy – Medicine and health sciences – Pathology and laboratory medicine – Physiology – Vertebrates – Diagnostic medicine – Signs and symptoms – immunology – Immune response – Body fluids – Blood – blood plasma – Blood cells – White blood cells – immune cells – Amphibians – Lymphocytes – Cellular stress responses – Edema – Neutrophils – Phagocytosis – Toads
Introduction
Stress-induced immunomodulation is complex and frequently associated with immune suppressive effects. However, recent studies have shown that changes in immune responses are mostly dependent on the stress duration and intensity, and can vary over time [1,2]. While long-term stress usually results in immune suppressive effects, short-term stress can enhance the immune response [2]. Meanwhile, glucocorticoids (GCs), one of the major mediators of the stress response, influence immune cell redistribution and immune function in several vertebrates, including amphibians [3–7]. Leukocyte redistribution is associated with wound healing by increasing immune responsiveness in body compartments requiring immune protection [3,8,9]. As a result, this leukocyte redistribution is reflected as an increase in blood neutrophil: lymphocyte ratios (NLR), a common proxy of the stress response in both field and laboratory studies [8]. Recent studies have shown increased NLR following an array of stressors and GC treatment in several vertebrates, including anurans submitted to restraint challenge and corticosterone (CORT) treatments [4,8,10–13].
Immune cellular components are strongly sensitive to stressors, being upregulated within hours by the acute stress response and GC exogenous administration [14–17]. Commonly observed immune-enhancement responses include changes in leukocyte trafficking, maturation, and augmentation of cell function, including: phagocytosis activity, and production of antibodies and cytokines [2,14,18]. On the other hand, delayed wound healing, down-regulation of adaptive immunity, and anti-inflammatory actions are more pronounced days after stress exposure and GC treatment [1,2,18,19]. Specifically in the context of regulation of the inflammatory response, the immunosuppressive effects of the GCs are important for the inflammatory resolution phase [3,5]. However, long-term stress and chronic GCs exposure and their inducing anti-inflammatory actions impair mounting of the inflammatory/innate immune response [2]. Although temporal patterns of stress-induced immunomodulation have been well-described for mammals [2], data for other vertebrates are still scarce [1].
In amphibians an array of stress protocols have been used in order to investigate stress-induced CORT changes, including restraint, captivity and exogenous CORT administration [12,20–27], with recent studies also investigating stress-induced immunomodulation [12,20–23,27]. Restraint and captivity stress-induced changes include increased CORT along with both immune- enhancing or suppressive effects in anurans, depending on the studied immune parameter, as well as variation in stress duration and intensity [11,12,21,23,27]. The NLR, for example, increased following restraint without movement restriction, but even higher values were observed after restraint with movement restriction, indicating the NLR changes are correlated with intensity of the stressor [11]. Phagocytosis activity is also up-regulated following acute restraint and CORT exogenous application [12,23]. Additionally, changes in cellular and non-cellular aspects of immune response are not synchronized following long-term captivity in toads, with down-regulation of phagocytic activity and bacterial killing ability (BKA) being observed at different time-points of captivity [27,28]. Although evidences of stress-induced immunomodulation in anurans has been provided, they are generally derived from different combinations of experimental protocols (i.e., restraint, captivity, hormonal exogenous administration), and immune parameters, such as, NLR, phagocytosis, BKA, phytohemaglutinin (PHA) swelling response, among others [4,20,21,28,29]. Moreover, immune assessment has been usually performed in each of these experiments at single sampling time-points, and the studies were conducted with different species [4,21,23,29]. The multiplicity of experimental protocols, immune parameters and species used, along with measurements performed at single time-points after treatments, limit our understanding of the temporal patterns of interaction between response to stressors, CORT and immune responses in amphibians.
In this study, we investigated time-related patterns of immunomodulation in response to short and long-term stressors (restraint and captivity) and exogenous CORT administration in a single toad species, Rhinella ornata. We hypothesized that exposure of toads to short-term stressors would generate immuno-enhancing effects, while exposure of toads to long-term stressors and daily CORT administration for 20 days would generate immunosuppression. In order to test these hypotheses, we measured time-related changes in CORT plasma levels, NLR, BKA, PHA swelling response and phagocytic activity from peritoneal and blood leukocytes in response to short-term restraint challenge (1 and 24 hours), short, mid and long-term captivity (7 days, 30 days, and 60 to 90 days, respectively), and CORT exogenous administration (transdermal application–TA for 20 days) in R. ornata toads. We predicted: (1) Increased CORT plasma levels and NLR following restraint, short and long-term captivity and CORT TA; (2) Increased BKA and phagocytosis activity in response to short-term restraint and short-term captivity; (3) Decreased BKA, phagocytosis activity and PHA edema in response to long-term captivity maintenance and CORT TA; (4) mid-term captivity (30 days) would represent a transient period, when patterns of stress response of NLR, BKA and phagocytosis percentage (PP) would be less obvious.
Results
Except for PHA relative edema, which was positively affected by body mass and snout-vent length (P = 0.036 and P < 0.001, respectively), there were no relationship between morphological measures (body mass, snout-vent length and body index) and any other studied variable at any circumstance: NLR (P ≥ 0.193); BKA (P ≥ 0.101); PP (P ≥ 0.062); CORT plasma levels (P ≥ 0.193); PHA (P ≥ 0.541, for body index).
Toads displaying high CORT levels in the field (those exhibiting calling behavior at the moment of capture [27]) showed a tendency to decrease CORT after restraint for 24h (S1 Table, P = 0.082, Fig 1A). Meanwhile, toads characterized by low CORT levels at time 0h (before initiating restraint) showed increased CORT plasma levels after 1 and 24h post-restraint (S1 Table, P = 0.003, Fig 1B). Short-term captivity showed no effect on CORT plasma levels (S1 Table, P = 0.844–7 days, Fig 1C). Otherwise, for those animals exhibiting high CORT in the field, mid or long-term captivity decreased CORT plasma levels (S1 and S2 Tables, P = 0.049–30 days, Fig 1D; P ≤ 0.001–7 to 90 days, Fig 1E). In the CORT TA experiment, toads from control and placebo groups did not differ in CORT plasma levels (S3 and S4 Tables, P = 1.000). Subsequently, they were grouped for further analyses and thereafter referred to as the control group. Plasma CORT levels were 14 times higher in TA-treated toads compared to controls (S2 Table, P ≤ 0.001, Fig 1F).
Corticosterone plasma levels following stressors and corticosterone transdermal application in R. ornata toads.
(A) Experiment 1: Restraint–field vs. 24h. (B) Experiment 2: Restraint– 0h vs. 1h vs. 24h. (C) Experiment 3: Captivity–field vs. 7 days. (D) Experiment 4: Captivity–field vs. 30 days. (E) Experiment 5: Captivity–field vs. 7 vs. 30 vs. 60 vs. 90 days. (F) Experiment 6: Corticosterone transdermal application. Bars represent mean ± standard error. The N is indicated inside each bar. Letters above the bars represent statistical differences for Bonferroni adjustments in ANOVAs or Student t-test, with different letters representing statistical difference within groups with P ≤ 0.05. Abbreviation: Exp.: Experiment. CORT TA: Corticosterone transdermal application. Legend: Control: control and placebo group; Experimental: corticosterone group.
Increased values for NLR were found following restraint challenge (S5 Table, P = 0.025 – 24h, Fig 2A). No differences were observed in NLR following short and mid-term captivity (S5 Table, P = 0.341–7 days, Fig 2B and P = 0.540–30 days, Fig 2C). Toads from both control and experimental treatments showed increased NLR after 20 days of the CORT TA treatment (P = 0.031), without treatment effects (S6 Table, Fig 2D).
Neutrophil Lymphocyte ratio following stressors and corticosterone transdermal application in R. ornata toads.
(A) Experiment 1: Restraint–field vs. 24h. (B) Experiment 3: Captivity–field vs. 7 days. (C) Experiment 4: Captivity–field vs. 30 days. (D) Experiment 6: Corticosterone transdermal application. Bars represent mean ± standard error. The N is indicated inside each bar. Letters above the bars represent statistical differences for Bonferroni adjustments in ANOVAs or Student t-test, with different letters representing statistical difference within groups with P ≤ 0.05. Asterisk represents statistical differences between pre and post-treatment, independently of the treatment (Control and experimental groups). Abbreviation: Exp.: Experiment; CORT TA: Corticosterone transdermal application. Legend: Control: control and placebo group; Experimental: corticosterone group.
Plasma BKA was not altered by restraint (S7 Table, P = 0.173 – 24h, Fig 3A and P = 0.787–1 and 24h, Fig 3B) or short-term captivity (P = 0.500–7 days, Fig 3C). Mid-term captivity for 30 days showed no effect on BKA (S7 Table, P = 0.326–30 days, Fig 3D). Meanwhile, BKA was lower on the 90th day of captivity when compared to field values (S8 Table, P = 0.006, Fig 3E). CORT TA for 20 consecutive days did not affect BKA (S8 Table, P = 0.648, Fig 3F).
Bacterial killing ability following stressors and corticosterone transdermal application in R. ornata toads.
(A) Experiment 1: Restraint–field vs. 24h. (B) Experiment 2: Restraint– 0h vs. 1h vs. 24h. (C) Experiment 3: Captivity–field vs. 7 days. (D) Experiment 4: Captivity–field vs. 30 days. (E) Experiment 5: Captivity–field vs. 7 vs. 30 vs. 60 vs. 90 days. (F) Experiment 6: Corticosterone transdermal application. Bars represent mean ± standard error. The N is indicated inside each bar. Letters above the bars represent statistical differences for Bonferroni adjustments in ANOVAs or Student t-test, with different letters representing statistical difference within groups with P ≤ 0.05. Abbreviation: Exp.: Experiment; CORT TA: Corticosterone transdermal application. Legend: Control: control and placebo group; Experimental: corticosterone group.
Phagocytosis percentage (PP) was not affected by restraint for 1 or 24h (S9 Table, P = 0.897, Fig 4A). Whereas, PP was affected by captivity (S9 Table, P = 0.053–7 to 90 days), with the maximum mean value on the 30th day of captivity (Fig 4B).
Phagocytosis activity and inflammatory response following stressors and corticosterone transdermal application in R. ornata toads.
(A) Experiment 2: Restraint– 0h vs. 1h vs. 24h. (B) Experiment 5: Captivity– 7 vs. 30 vs. 90 days. Phytohemagglutinin relative edema. (C) after 12 and 24h post PHA injection at the end of Experiment 6: Corticosterone transdermal application. Bars represent mean ± standard error. The N is indicated inside each bar. Letters above the bars represent statistical differences for Bonferroni adjustments in ANOVAs, with different letters representing statistical difference within groups with P ≤ 0.05. The asterisks represent ANCOVA statistical differences (P ≤ 0.05) between treatment groups (control vs. experimental) at each specific time (12 or 24h). Abbreviation: Exp.: Experiment; CORT TA: Corticosterone transdermal application; PHA: Phytohemagglutinin. Legend: Control: control and placebo group; Experimental: corticosterone group.
The PHA relative edema was affected by both body mass and CORT TA treatment (P = 0.010), being higher at 12h when compared to 24h for both groups (Fig 4C). However, the experimental group had lower PHA swelling at both 12 and 24h when compared with control group (S10 Table, Fig 4C). There were no differences in body mass and snout-vent length between treatment groups (t17 = -1.245, P = 0.230 and t17 = -1.540, P = 0.142, respectively).
Compiled results are schematically summarized in Table 1. Complete statistical tables regarding results described at this section are presented as supplementary material (S1 to S10 Tables).
Stress and corticosterone transdermal application-related corticosterone plasma levels and immune modulation of R. ornata toads.
Discussion
Plasma CORT levels increased following restraint and CORT TA, but contrary to our prediction, decreased in response to short, mid and long-term captivity in R. ornata toads (Table 1). These results indicate that restraint was perceived by these toads as a stressor, but they might be less sensitive to captivity maintenance. Moreover, CORT TA increased CORT plasma levels 1h after treatment and may have simulated the hormonal response to a repeated stressor. As we expected, NLR increased after restraint and peritoneal PP showed increased values following mid-term captivity, indicating an immune enhancing effect during this period (Table 1). Moreover, BKA and PHA edema were impaired after long-term captivity and CORT TA, which could be associated with chronic stress and GC-induced immunosuppressive effects, respectively (Table 1).
As expected, for males showing low CORT at 0h, restraint increased CORT plasma levels, as previously described for anurans including R. ornata [11,13,22,23,30]. Additionally, our results showed maximum CORT values 1h of after restraint compared to 24h, which might indicate negative feedback of the hypothalamic-hypophyseal-interrenal axis [31]. Meanwhile, for the individuals in the field displaying high baseline CORT, we observed a tendency to decrease CORT plasma levels following 24h restraint. These toads were already displaying high CORT in the field probably due to reproductive behavior (calling activity) [27], precluding the assessment of increased CORT values 24h post-restraint [11]. Moreover, the trend to decreased CORT 24h post-restraint in these toads also corroborates the observation that the peak of GC release in response to restraint occurs before 24h of exposure to this stressor. Rhinella ornata toads that were engaged in calling activity and displayed high CORT in the field also showed decreased CORT plasma levels in response to captivity maintenance, which could be associated with the interruption of vocal behavior [27,32]. In addition, neither short nor long-term captivity elicited NLR changes in these toads. The absence of response in NLR along with low CORT plasma levels, suggest that these R. ornata males were less affected by captivity than males from other species in the same genus exposed to captivity [21,27,28]. We also described changes in CORT plasma levels following CORT TA, with increased CORT in the experimental group 14 times higher than the control group after 20 consecutive days of CORT TA. Although CORT plasma levels after CORT TA were extremely high in the experimental group (348 ± 54ng/ml, mean ± standard error), high CORT levels (282 ± 52ng/ml, mean ± standard error) were reported for this same species following severe dehydration [13], evidencing these animals are physiologically able to reach such high circulating CORT levels.
Increased NLR was observed after restraint challenge (24h) and submission to the CORT TA experiment (both control and experimental groups) for 20 days. Additionally, in CORT TA experiment, we did not find differences between control and CORT group, which might indicate that daily manipulation itself is a stressor for R. ornata. Increased NLR following restraint challenge and post-CORT TA were reported for Rhinella toads, including R. ornata [11,12]. Increased NLR was also described for salamanders 50h post-capture following both ACTH and saline injection, even with a concomitant decrease in CORT [33]. Accordingly, the increased NLR observed in R. ornata following restraint challenge and 20 days post-TA was not associated with changes in CORT, even considering that TA-induced increase in CORT plasma levels was so prominent. Besides the prominent increase in CORT plasma levels resulting from CORT TA, toads from the control group also showed a tendency to increase CORT throughout the experiment. This tendency might indicate that daily manipulation (box opening and water removal and return) could represent a stressor for all groups, resulting in increased NLR for both control and CORT TA groups. In general, although we observed both increased CORT plasma levels and NLR in response to the set of different stressors applied in the present study, these response variables could not be easily associated, as already observed in other contexts and study models [8].
Our results demonstrate preserved BKA in almost all treatments (restraint, short and mid-term captivity and TA) except after long-term captivity, given that a reduction in values was observed in the 90th day of captivity maintenance. Plasma BKA is an innate, non-cellular immune response mediated through the complement system and lysozymes, both of which promote lysis of invading microorganisms [34,35]. Studies conducted in birds, reptiles and mammals have demonstrated both acute and/or prolonged regulation of BKA-associated proteins following stressors [36–39]. In amphibians, impaired BKA has been described following acute [23] and long-term [21,27,28] stressors and GCs exogenous treatment [21]. However, temporal patterns of BKA stress-associated responses are diverse. Decreased BKA following long-term captivity was transient for R. schneideri, but sustained for R. icterica [27,28]. The absence of changes in response to most of the short and mid-term stressors and CORT treatment, along with decreased values only after long-term captivity maintenance, suggest that BKA presents robust immune mediators in R. ornata toads.
Regarding immune cellular activity, we did not observe changes in blood PP 1h and 24h after restraint in R. ornata. In contrast, increased phagocytosis 13h after restraint was described in another Rhinella species [23]. Thus, the lack of response in PP 1 and 24h post restraint could indicate these time points are ideal for ascertaining how restraint influences any blood phagocytosis alterations in R. ornata toads [1,2]. Meanwhile, phagocytosis of peritoneal cells was affected by mid-term captivity, with increased mean values for PP on the 30th day. Up-regulation of immune responses following stressors, including phagocytic activity, is often observed in several vertebrates, but in a context of acute stress [1,2,14,40,41]. Results of phagocytic stress-driven changes are unclear as studies have presented conflicting results [27,28]. Meanwhile, increased phagocytosis was previously observed in response to 13h restraint [23] and after a month following CORT treatments, such as CORT TA [12], capsule implant and immersion in CORT-treated water [4]. Our study showed maximum values for PP on the 30th day compared to the 7th and 90th day in captivity. Moreover, mean CORT values were maximum on the 30th day compared to the other days in captivity, which could be associated with the increased phagocytic activity following mid-term captivity. Specifically Falso et al. (2015) [4], found that CORT treatment was associated with increased phagocytosis and increased neutrophil concentration in the blood (a parameter not measured in our captivity experiment–field to 90 days), along with high CORT levels [4]. These results indicate a complex relationship between stress and immunity, and the importance in accounting for time-related changes of distinct branches of immune system in response to a stress challenge in anurans.
The inflammatory response, measured as PHA relative edema, was affected by the CORT TA at both 12h and 24h in R. ornata toads. The inflammatory and cell-mediated immune response is strongly associated with stress intensity (high CORT and catecholamine levels) and duration (reviewed in [2]). While an acute increase in CORT stimulates the inflammatory response, persistent GCs elevations suppress it [2,15,17]. The inflammatory response can be suppressed at multiple levels, including the inhibition of leukocyte recruitment or reduced leukocyte pro-inflammatory cytokine expression, among others [2,16]. In amphibians, chronic treatment with high doses of CORT delays cutaneous wound healing in salamanders [42] and frogs (Madelaire et al., unpublished data). Therefore, the acute daily increase in CORT plasma levels, by CORT TA, could have promoted an anti-inflammatory effect in R. ornata toads, a common effect following chronical or several acute elevations of GCs in mammals [2].
Conclusions
In summary, different time-related trajectories for CORT plasma levels and immune parameters were described in R. ornata toads following stressors and CORT TA. Since CORT levels were sustained (for those animals with low levels in the field) or decreased (for those individuals displaying high levels in the field) in response to short and mid-term captivity, along with no changes in BKA and NLR, it appears that captivity for a 30 days does not represent a stressor for this species. However, mid and long-term captivity increased phagocytosis activity of peritoneal cells in the 30th and decreased BKA in the 90th day, respectively, indicating captivity promotes immune changes, with captivity maintenance for 90 days potentially representing a low-intensity stress condition. In the meantime, CORT changes along with increased NLR indicate a stress response following restraint challenge. Moreover, increased CORT associated with a reduction in PHA swelling response after 20 consecutive days of CORT TA, indicate a chronic stress situation for R. ornata. Together, these results demonstrate immuno-enhancing effects following restraint, short and mid-term stressors, while long-term stressors and CORT administration promoted immunosuppression. Additionally, our results indicate cellular immunity are more responsive to stressors and high CORT levels induced by CORT TA than non-cellular immune response in R. ornata toads. Therefore, we encourage researchers working within the ecoimmunology area, at the field and under laboratory conditions, to conduct studies that include a number of different stress protocols and sampling at multiple time-points, to better understand patterns of stress-related immunomodulation in vertebrates.
Materials and methods
Study sites and animals
Adult males of R. ornata were collected at the Biosciences Institute of University of Sao Paulo, Sao Paulo/Brazil (23°33'51.3"S, 46°43'48.5"W) in August 2012 (N = 27) and 2018 (N = 7), Botanic Garden of Sao Paulo, Sao Paulo/Brazil (23°38'19.8"S, 46°37'18.5"W) in August 2016 (N = 10), and in Botucatu (22°53'21.1"S 48°28'20.1"W) Sao Paulo/Brazil in August 2014 (N = 24) and August 2016 (N = 42). Toads were collected under license from the Instituto Chico Mendes de Conservação da Biodiversidade (ICMBio n° 29896). The Ethic committee of the Biosciences Institute of University of Sao Paulo approved all procedures for this study (CEUA n° 142/2011; 054/2013; 249/2016).
Field procedures
Toads were visually located and hand captured. Blood samples were collected in August 2012 (N = 7), August 2014 (N = 20) and August 2016 (N = 21), for baseline (field) measurements (CORT plasma levels, NLR and BKA). All toads were weighed (to the nearest 0.01g) and measured (to the nearest 0.01mm) after capture. Animals were released at their respective collection point following restraint challenge and fieldwork, or were kept in individual plastic containers and then transported to the laboratory. Detailed collection and experimental information are in Table 2.
Detailed information regarding year of collection and experimental procedures, statistical comparisons and studied parameters of R. ornata toads.
Restraint challenge (Experiment 1: Field vs. 24h and Experiment 2: 0h vs. 1h vs. 24h)
Immediately after blood collection in the field for baseline measurements (August 2014), the same toads (N = 20) were exposed to restraint challenge (Experiment 1), by placing individuals into wet cloth bags and then inside individual plastic bins (29 x 18 x 15 cm) for 24h according to [11,21]. All bins had lids with holes to allow air circulation. After 24h, all toads were bled again to reassess the same physiological variables measured at baseline (CORT, NLR and BKA). Upon termination of this experimental protocol, toads were weighed (body mass, 0.01 g), and returned to their collection point at night.
Rhinella ornata toads (August 2018) kept in captivity for 7 days, under the same conditions as toads in experiment 4 and 5, were bled (0h), then immediately placed into wet cloth bags and then inside individual plastic bins (29 x 18 x 15 cm) for 24h according to [11,21]. These same animals were bled again 1 and 24h after the restraint protocol (Experiment 2) in order to compare physiological variables measured at the three-sampling time (CORT, NLR, BKA and blood PP). Upon termination of this experimental protocol, toads were weighed (body mass, 0.01 g), and returned to their captivity conditions for further studies.
Short-term captivity (Experiment 3: Field vs. 7 days) and Corticosterone transdermal application (Experiment 6: Control vs. placebo vs. corticosterone)
Captive toads collected in August 2012 (N = 24) were kept individually in plastic bins (43.0 x 28.5 x 26.5 cm) with free access to water and lids with holes to allow air circulation. Each toad was fed cockroaches once per week and provided ad libitum access to water. The room was kept on 11/13 LD photoperiod (lights on at 7:40 am and off at 6:40 pm) at a temperature of 21 ± 2°C. After 7 days, a blood sample was collected from each individual, to evaluate CORT, NLR and BKA (Experiment 3). Toads were also weighed by the initial and last day of the experiment.
To perform the CORT TA (Experiment 6), toads were divided in three groups according to [21]: control (no treatment), placebo (5ul sesame oil application on the back of the animals) and experimental (5ul CORT [Sigma C27840] + sesame oil application– 3ug CORT /1ul sesame oil). Following [21] protocol, all the animals received the same amount of CORT solution, since no relationship was found between body mass and CORT in these toads in field conditions (ρ = -0.594; P = 0.160). Water was removed from each box to ensure complete absorption of the treatment (vehicle or CORT solution) for all groups before daily application and was returned 3h after treatment. CORT TA occurred for 20 consecutive days. On the last day, a new blood sample was collected from each animal, 1h after the TA, to evaluate the same variables as in a week in captivity (Experiment 3: CORT, NLR and BKA). In order to assess an inflammatory response, one day after the end of the CORT TA, all individuals were exposed to the PHA immune challenge.
Mid-term captivity (Experiment 4: Field vs. 30 days)
Captive toads collected in August 2016 were kept individually in plastic bins (43.0 x 28.5 x 26.5 cm) with leaf litter as a substrate and provided ad libitum access to water. The lids of the bins had holes to allow air circulation. Each toad was fed with cockroaches once per week. The room was kept on 11/13 LD photoperiod (lights on at 7:40 am and off at 6:40 pm) and temperature of 21 ± 2°C.
Toads from Botanical Garden of Sao Paulo (N = 10) were bled again only after 30 days in captivity (Experiment 4), in order to evaluate the effects of 30 days in captivity on plasma CORT levels, BKA and NLR.
Long-term captivity (Experiment 5: 0 vs. 7 vs. 30 vs. 60 vs. 90 days)
Toads from Botucatu (N = 29) were kept under the same conditions described for toads in experiment 4 and divided in four groups to be sampled after 7, 30, 60, and 90 days under captivity (Experiment 5), in order to evaluate the effects of time in captivity on plasma CORT levels, BKA and peritoneal PP according [27,28]. After bleeding on each specific day (7, 30, 60 and 90), animals were euthanized with an intraperitoneal injection (75mg/kg) of sodium thiopental (Thiopenthax®) solution (25mg/ml).
Blood collection
Blood samples from each individual were collected (~ 140 ul) by cardiac puncture using a heparinized 1 ml syringe and 26Gx1/2” needle within 3 minutes of capture. Blood samples were collected, kept on ice (< 2 hours) until blood smears could be performed (for determine the NLR), and then centrifuged (4 min at 604 g) to isolate the plasma. Plasma samples were stored at -80°C freezer until analysis.
Neutrophil: Lymphocyte ratio (NLR)
A drop of blood was used to perform each blood smear. The slide was stained with Giemsa solution (10%) and observed under an optical microscope (100X objective, using oil immersion—Nikon E200, 104c). One hundred leukocytes were counted on each slide, and classified based on morphology as neutrophils, lymphocytes, eosinophils, basophils, and monocytes [43]. The NLR was calculated as the number of neutrophils divided by the number of lymphocytes on each slide.
Bacterial killing ability (BKA)
The BKA assay was conducted according [44]. Briefly, plasma samples diluted in amphibian Ringer's solution (10 ul plasma: 190 ul Ringer) were mixed with 10 ul of Escherichia coli working solution (~ 104 microorganisms, E. coli; ATCC 8739). Positive controls consisted of 10 ul of E. coli working solution in 200 ul of Ringer's solution, and negative control contained 210 ul of Ringer's solution. All samples and controls were incubated by 60 min at 37°C (optimal temperature for bacterial growth). Thereafter, 500 ul of tryptic soy broth were added to each sample, vortexed and transferred (in duplicates) to a 96 wells microplate (300 ul per well), which was incubated at 37ºC for 2h. Following that, the optical density of the samples was measured hourly in a plate spectrophotometer (wavelength 600 nm). The BKA was evaluated at the beginning of the bacterial exponential growth phase and calculated according to the formula: 1 - (optical density of sample / optical density of positive control), which represents the proportion of killed microorganisms in the samples compared to the positive control.
Phagocytosis
In order to assess the cellular immune measure, we performed a phagocytosis assay with blood (experiment 2) or peritoneal (experiment 5) leukocytes. Phagocytic activity was evaluated as previously described by [28]. The phagocytosis assay was performed by adding 100 ul of zymosan (Sigma Z4250) labeled with green fluorescence (CFSE Sigma 21888F) suspension (1 x 106 particles) in 1000 ul of APBS containing 2 x 105 cells (macrophages/neutrophils). Samples were incubated for 60 min, under agitation at 25°C, and then washed with 2mL of cold (4°C) 6mM of ethylenediamine tetra acetic acid (EDTA) solution, in order to stop phagocytosis and to wash off the excess of free zymosan particles. After centrifugation (4°C, 259g, 7min), pellets were ressuspended in 200 ul of cold (4°C) paraformaldehyde (1%) for cell fixation. After 1 hour, 500ul of APBS were added, samples were centrifuged (4°C, 259g, 7min) and pellets were ressuspended in 100ul of APBS for flow cytometry.
Cells were analyzed on an image flow cytometer (AMNIS Flowsight imaging flow cytometer Merck-Millipore, German) interfaced with a DELL computer with 10,000 events collected using the 488nm laser at a 20x magnification, through INSIRE software. Data analysis was performed using IDEAS analysis software (EMD Millipore) version 6.1 for windows. After gating on side scatter vs. brightfield plot, phagocytosis of peritoneal cells was measured by phagocytosis percentage (PP), which represents the percentage of cells that engulfed at least one zymosan particle (the percentage of green positive cells).
Phytohemagglutinin (PHA) swelling assay
The PHA challenge was performed in order to assess the inflammatory response 24h after the TA (Exp. 6) in R. ornata, according to [21,45]. Specifically, the hind fleshy base of the right foot was injected with 10ul of PHA (20 mg PHA [Sigma L8754]/ml sterile saline solution) using a 10 ul glass syringe and 30Gx1/2″ needle. The hind fleshy base of the left foot of the same animal was injected with 10 ul of sterile saline solution, as a control. The thickness of each injected hind fleshy base of each animal was measured with a thickness gauge (Digimess, accuracy 0.01 mm) before, 12 and 24h after PHA and saline injections. Measurements consisted of three successive thickness measurements. At each time point, three successive measurements of thickness were taken, with the mean of these values was used in analysis. The swelling in response to PHA and saline was calculated from the proportional change in foot thickness before, 12 and 24h after injection. The relative swelling was considered as the thickness in 12 or 24 hours divided by initial thickness multiplied by 100. The PHA relative edema was calculated as the PHA relative swelling minus the saline relative swelling.
At the end of the 24h swelling measurement, individuals were euthanized with an intraperitoneal injection (75mg/kg) of sodium thiopental (Thiopenthax®) solution (25mg/ml).
Corticosterone assays
Steroid hormones were initially extracted with ether according to [11,21]. CORT were determined using EIA kits (CORT number 501320; Cayman Chemical), according to the manufacturer’s instructions and previous studies conducted with Rhinella toads, including R. ornata species [11]. The mean values for intra and inter-assay variation were 6.83% and 4.77% respectively. Sensitivity of the assays was 32 pg/ml.
Statistical analyses
All statistical analyses were performed in IBM SPSS Statistics 22. Normality of all data were assessed via the Shapiro-Wilk normality test. With the exception of BKA in restraint challenge and captivity treatments, all variables were normal.
Sets of ANCOVAs for independent or repeated measures (as applicable for each set of data, Table 2) were used to investigate the effect of each experiment (1–6: Restraint challenge, Captivity and TA) on studied variables. CORT, NLR, BKA, PHA relative edema and PP were used as dependent variables, body mass and snout-vent length as co-variables and each treatment and/or time as a factor. Unstandardized residuals of a linear regression of body mass as a function of snout-vent length were used as body index and also included as co-variable in the ANCOVAs.
For the dependent variables not significantly affected by body mass, snout-vent length and body index a set of ANOVAs was then performed with treatment (Experiment 2: Restraint hour [0, 1, 24h]; Experiment 5: captivity days [field, 7, 30, 60, 90]; or Experiment 6: TA group [control, placebo, experimental]) as factor. The ANOVAs were followed by tests for mean multiple comparisons with Bonferroni adjustments. Paired comparisons with Student-t test were performed for the dependent variables not significantly affected by body mass in the experiments with only two comparisons (Experiment 1: Restraint [baseline vs. 24h post restraint]; Experiment 3 and 4: captivity [field vs. 7 days and field vs. 30 days]). Since BKA showed absence of normality, we used the Wilcoxon Signed Ranks test, which is a non-parametric test.
Full raw data are available in the S1 File.
Supporting information
S1 Table [docx]
Corticosterone plasma levels student-t test after stressors in toads.
S2 Table [docx]
Corticosterone plasma levels analysis of variance after stressors and corticosterone transdermal application in . toads.
S3 Table [docx]
Corticosterone plasma levels analysis of variance after corticosterone transdermal application in . toads.
S4 Table [docx]
Corticosterone plasma levels analysis of variance after stressors and corticosterone transdermal application in . toads with Bonferroni comparisons.
S5 Table [docx]
Neutrophil: Lymphocyte ratio student-t test after stressors in toads.
S6 Table [docx]
Neutrophil: Lymphocyte ratio analysis of variance after corticosterone transdermal application in . toads.
S7 Table [docx]
Plasma bacterial killing ability student-t test after stressors in toads.
S8 Table [docx]
Plasma bacterial killing ability analysis of variance after stressors and corticosterone transdermal application in . toads.
S9 Table [docx]
Phagocytosis percentage analysis of variance after corticosterone transdermal application in . toads.
S10 Table [docx]
Phytohemaglutinin relative edema analysis of variance after corticosterone transdermal application in . toads.
S1 File [docx]
Data availability file.
Zdroje
1. Martin LB. Stress and immunity in wild vertebrates: Timing is everything. Gen Comp Endocrinol. Elsevier Inc.; 2009;163: 70–76. doi: 10.1016/j.ygcen.2009.03.008 19318107
2. Dhabhar FS. Effects of stress on immune function: The good, the bad, and the beautiful. Immunol Res. 2014;58: 193–210. doi: 10.1007/s12026-014-8517-0 24798553
3. Dhabhar FS. Enhancing versus Suppressive Effects of Stress on Immune function. Implications for Immunoprotection and Immunopathology. NeuroImmune Biol. 2008;7: 207–224. doi: 10.1016/S1567-7443(07)00211-6
4. Falso PG, Noble CA, Diaz JM, Hayes TB. The effect of long-term corticosterone treatment on blood cell differentials and function in laboratory and wild-caught amphibian models. Gen Comp Endocrinol. Elsevier Inc.; 2015;212: 73–83. doi: 10.1016/j.ygcen.2015.01.003 25616196
5. Madelaire CB, Cassettari B de O, Gomes FR. Immunomodulation by testosterone and corticosterone in toads: Experimental evidences from transdermal application. Gen Comp Endocrinol. Elsevier; 2019;273: 227–235. doi: 10.1016/j.ygcen.2018.09.005 30195026
6. Berger S, Martin LB, Wikelski M, Romero LM, Kalko EKV, Vitousek MN, et al. Corticosterone suppresses immune activity in territorial Galápagos marine iguanas during reproduction. Horm Behav. 2005;47: 419–429. doi: 10.1016/j.yhbeh.2004.11.011 15777807
7. Martin LB, Gilliam J, Han P, Lee K, Wikelski M. Corticosterone suppresses cutaneous immune function in temperate but not tropical House Sparrows, Passer domesticus. Gen Comp Endocrinol. 2005;140: 126–135. doi: 10.1016/j.ygcen.2004.10.010 15613275
8. Davis AK, Maney DL. The use of glucocorticoid hormones or leucocyte profiles to measure stress in vertebrates: What’s the difference? Methods Ecol Evol. 2018;9: 1556–1568. doi: 10.1111/2041-210X.13020
9. Sapolsky RM, Romero LM, Munck AU. How do glucocorticoids influence stress responses? Integrating permissive, suppressive, stimulatory, and preparative actions. Endocr Rev. 2000;21: 55–89. doi: 10.1210/edrv.21.1.0389 10696570
10. Davis AK, Maney DL, Maerz JC. The use of leukocyte profiles to measure stress in vertebrates: A review for ecologists. Funct Ecol. 2008;22: 760–772. doi: 10.1111/j.1365-2435.2008.01467.x
11. Assis VR, Titon SCM, Gomes FR. Acute stress, steroid plasma levels, and innate immunity in Brazilian toads. Gen Comp Endocrinol. Elsevier; 2019;273: 86–97. doi: 10.1016/j.ygcen.2018.05.008 29750968
12. Assis VR, Titon SCM, Queiroz-Hazarbassanov NGT, Massoco CO, Gomes FR. Corticosterone transdermal application in toads (Rhinella icterica): Effects on cellular and humoral immunity and steroid plasma levels. J Exp Zool Part A Ecol Integr Physiol. 2017;327: 200–213. doi: 10.1002/jez.2093 29356458
13. Barsotti AMG, Titon Junior B, Titon SCM, Gomes FR. Dehydration as a stressor in toads (Rhinella ornata). J Exp Zool Part A Ecol Integr Physiol. 2019;331: 168–174. doi: 10.1002/jez.2250 30569667
14. Barriga C, Martín MI, Tabla R, Ortega E, Rodríguez AB. Circadian rhythm of melatonin, corticosterone and phagocytosis: Effect of stress. J Pineal Res. 2001;30: 180–187. doi: 10.1034/j.1600-079X.2001.300307.x 11316329
15. Dhabhar FS, McEwen BS. Acute stress enhances while chronic stress suppresses immune function in vivo: A potential role for leukocyte trafficking. Brain Behav Immun. 1997;11: 286–306. doi: 10.1006/brbi.1997.0508 9512816
16. Dhabhar FS, McEwen BS. Enhancing versus suppressive effects of stress hormones on skin immune function. Proc Natl Acad Sci. 1999;96: 1059–1064. doi: 10.1073/pnas.96.3.1059 9927693
17. Dhabhar FS, McEwen BS. Stress-induced enhancement of antigen-specific cell-mediated immunity. J Immunol. 1996;156: 2608–2615. Available: http://www.jimmunol.org/content/156/7/2608 8786326
18. Silberman DM, Wald MR, Genaro AM. Acute and chronic stress exert opposing effects on antibody responses associated with changes in stress hormone regulation of T-lymphocyte reactivity. J Neuroimmunol. 2003;144: 53–60. doi: 10.1016/j.jneuroim.2003.08.031 14597098
19. Webster Marketon JI, Glaser R. Stress hormones and immune function. Cell Immunol. 2008;252: 16–26. doi: 10.1016/j.cellimm.2007.09.006 18279846
20. Barsotti AMG, de Assis VR, Titon SCM, Titon B, da Silva Ferreira ZF, Gomes FR. ACTH modulation on corticosterone, melatonin, testosterone and innate immune response in the tree frog Hypsiboas faber. Comp Biochem Physiol -Part A Mol Integr Physiol. Elsevier Inc.; 2017;204: 177–184. doi: 10.1016/j.cbpa.2016.12.002 27923708
21. Assis VR, Titon SCM, Barsotti AMG, Titon B, Gomes FR. Effects of acute restraint stress, prolonged captivity stress and transdermal corticosterone application on immunocompetence and plasma levels of corticosterone on the cururu toad (Rhinella icterica). PLoS One. 2015;10: 1–21. doi: 10.1371/journal.pone.0121005 25831055
22. Gomes FR, Oliveira RV, Assis VR de, Junior BT, Moretti EH, Mendonça MT. Interspecific Variation in Innate Immune Defenses and Stress Response of Toads from Botucatu (São Paulo, Brazil). South Am J Herpetol. 2012;7: 1–8. doi: 10.2994/057.007.0101
23. Graham SP, Kelehear C, Brown GP, Shine R. Corticosterone-immune interactions during captive stress in invading Australian cane toads (Rhinella marina). Horm Behav. Elsevier Inc.; 2012;62: 146–153. doi: 10.1016/j.yhbeh.2012.06.001 22713726
24. Narayan EJ, Hero JM. Repeated thermal stressor causes chronic elevation of baseline corticosterone and suppresses the physiological endocrine sensitivity to acute stressor in the cane toad (Rhinella marina). J Therm Biol. Elsevier; 2014;41: 72–76. doi: 10.1016/j.jtherbio.2014.02.011 24679975
25. Narayan EJ, Cockrem JF, Hero JM. Urinary corticosterone metabolite responses to capture and captivity in the cane toad (Rhinella marina). Gen Comp Endocrinol. 2011;173: 371–377. doi: 10.1016/j.ygcen.2011.06.015 21756910
26. Narayan EJ, Hero JM. Acute thermal stressor increases glucocorticoid response but minimizes testosterone and locomotor performance in the cane toad (Rhinella marina). PLoS One. 2014;9: 1–6. doi: 10.1371/journal.pone.0092090 24643017
27. Titon SCM, Titon Junior B, Assis VR, Kinker GS, Fernandes PACM, Gomes FR. Interplay among steroids, body condition and immunity in response to long-term captivity in toads. Sci Rep. 2018;8: 17168. doi: 10.1038/s41598-018-35495-0 30464319
28. Titon SCM, Assis VR, Titon B Junior, Cassettari B de O, Fernandes PACM, Gomes FR. Captivity effects on immune response and steroid plasma levels of a Brazilian toad (Rhinella schneideri). J Exp Zool Part A Ecol Integr Physiol. 2017;327: 127–138. doi: 10.1002/jez.2078 29356402
29. Narayan E, Hero JM. Urinary corticosterone responses and haematological stress indicators in the endangered Fijian ground frog (Platymantis vitiana) during transportation and captivity. Aust J Zool. 2011;59: 79–85. doi: 10.1071/ZO11030
30. Narayan EJ, Hero J-M, Cockrem JF. Inverse urinary corticosterone and testosterone metabolite responses to different durations of restraint in the cane toad (Rhinella marina). Gen Comp Endocrinol. 2012;179: 345–349. doi: 10.1016/j.ygcen.2012.09.017 23036735
31. Romero LM. Physiological stress in ecology: Lessons from biomedical research. Trends Ecol Evol. 2004;19: 249–255. doi: 10.1016/j.tree.2004.03.008 16701264
32. Assis VR, Navas CA, Mendonça MT, Gomes FR. Vocal and territorial behavior in the Smith frog (Hypsiboas faber): Relationships with plasma levels of corticosterone and testosterone. Comp Biochem Physiol—A Mol Integr Physiol. Elsevier Inc.; 2012;163: 265–271. doi: 10.1016/j.cbpa.2012.08.002 22903053
33. DuRant SE, Hopkins WA, Davis AK, Romero LM. Evidence of ectoparasite-induced endocrine disruption in an imperiled giant salamander, the eastern hellbender (Cryptobranchus alleganiensis). J Exp Biol. 2015;218: 2297–2304. doi: 10.1242/jeb.118703 26034123
34. Düring K, Porsch P, Mahn A, Brinkmann O, Gieffers W. The non-enzymatic microbicidal activity of lysozymes. FEBS Lett. 1999;449: 93–100. doi: 10.1016/s0014-5793(99)00405-6 10338111
35. Sarma JV, Ward PA. The complement system. Cell Tissue Res. 2011;343: 227–235. doi: 10.1007/s00441-010-1034-0 20838815
36. Buehler DM, Bhola N, Barjaktarov D, Goymann W, Schwabl I, Tieleman BI, et al. Constitutive Immune Function Responds More Slowly to Handling Stress than Corticosterone in a Shorebird. Physiol Biochem Zool. 2008;81: 673–681. doi: 10.1086/588591 18752420
37. French SS, Denardo DF, Greives TJ, Strand CR, Demas GE. Human disturbance alters endocrine and immune responses in the Galapagos marine iguana (Amblyrhynchus cristatus). Horm Behav. Elsevier Inc.; 2010;58: 792–799. doi: 10.1016/j.yhbeh.2010.08.001 20708010
38. Zylberberg M. Common measures of immune function vary with time of day and sampling protocol in five passerine species. J Exp Biol. 2015;218: 757–766. doi: 10.1242/jeb.111716 25617452
39. Hernández-Arciga U, Herrera M LG, Ibáñez-Contreras A, Miranda-Labra RU, Flores-Martínez JJ, Königsberg M. Baseline and post-stress seasonal changes in immunocompetence and redox state maintenance in the fishing bat Myotis vivesi. PLoS One. 2018;13: 1–27. doi: 10.1371/journal.pone.0190047 29293551
40. Hopkins WA, DuRant SE. Innate immunity and stress physiology of eastern hellbenders (Cryptobranchus alleganiensis) from two stream reaches with differing habitat quality. Gen Comp Endocrinol. Elsevier Inc.; 2011;174: 107–115. doi: 10.1016/j.ygcen.2011.08.006 21872597
41. Tort L. Stress and immune modulation in fish. Dev Comp Immunol. Elsevier Ltd; 2011;35: 1366–1375. doi: 10.1016/j.dci.2011.07.002 21782845
42. Thomas JR, Woodley SK. Treatment with corticosterone delays cutaneous wound healing in male and female salamanders. Gen Comp Endocrinol. Elsevier Inc.; 2015;216: 33–38. doi: 10.1016/j.ygcen.2015.04.013 25913258
43. Campbell T. Hematology of Amphibians. In: Trall M, editor. Veterinary Hematology and Clinical Chemistry. Oxford, UK.: John Wiley & Sons, Inc; 2012.
44. Assis VR de Titon SCM, Barsotti AMG, Spira B, Gomes FR. Antimicrobial Capacity of Plasma from Anurans of the Atlantic Forest. South Am J Herpetol. 2013;8: 155–160. doi: 10.2994/SAJH-D-13-00007.1
45. Titon SCM, de Assis VR, Titon B, Barsotti AMG, Flanagan SP, Gomes FR. Calling rate, corticosterone plasma levels and immunocompetence of Hypsiboas albopunctatus. Comp Biochem Physiol -Part A Mol Integr Physiol. Elsevier Inc.; 2016;201: 53–60. doi: 10.1016/j.cbpa.2016.06.023 27364933
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