Introduction
Batrachochytrium dendrobatidis, also referred to as Bd, is a pathogenic chytrid fungus implicated in the decline and extinction of hundreds of amphibian species worldwide (Scheele et al., 2019). This water borne fungus reproduces via sporangia, and is spread by the dispersion of infectious, flagellated zoospores (Longcore, Pessier & Nichols, 1999). Infections may be transmitted via direct contact with an infected host or with the free-swimming mobile zoospores. Indirect exposure is thought to occur through contact with contaminated environmental reservoirs (e.g., sediment (Kirshtein et al., 2007), boulders (Longcore, Pessier & Nichols, 1999; Wixson & Rogers, 2009), bromeliads (Cossel & Lindquist, 2009), aquatic birds (Garmyn et al., 2012; Burrowes & De la Riva, 2017) or snakes (Kilburn, Ibáñez & Green, 2011)), although transmission through this route has not been confirmed.
In amphibians, Bd infection can impact the keratinized layer of the epidermis and can cause pathological features such as skin degradation, sloughing, hyperkeratosis, hyperplasia, ulceration, erosions, and necrosis (Berger et al., 1998; Grogan et al., 2018). Infected amphibians may also show evidence of lethargy, loss of appetite, behavioral changes and in many instances, mortality (Gabor, Fisher & Bosch, 2015). The epidermis is critically important to physiological processes such as osmoregulation, thermoregulation, gas exchange and indirectly cardiac function. Bd infections have been directly implicated in the disruption of osmoregulation, including imbalances in sodium and potassium ion concentrations (Peterson et al., 2013; Voyles et al., 2009) and cardiac dysfunction, including decreased stroke volume, delayed cardiac cycles (Salla et al., 2018) and asystolic cardiac arrest (Voyles et al., 2009), any of which can lead to mortality.
Bd metabolites, water soluble chemicals produced by the chytrid fungus, have also been shown to cause pathological outcomes in amphibians. While the exact chemical composition of Bd metabolites is still unknown, we know that Bd produces proteolytic enzymes which have been implicated in skin disorders. Other metabolites have been shown to have immunomodulatory and inhibitory potential (e.g., methylthioadenosine, tryptophan, and polyamine spermidine; Rollins-Smith, Reinert & Burrowes, 2015; Rollins-Smith et al., 2019). Interestingly, Bd metabolites have also been shown to produce prophylactic effects, although the exact metabolites responsible have not been identified. This may be because the composition of metabolites Bd produces changes depending on the local environment (Rollins-Smith, Reinert & Burrowes, 2015). Specific Bd metabolites may have different impacts, some detrimental and others potentially prophylactic. Differences in the concentration of Bd metabolites an organism is exposed to may also account for the range of impacts, from toxic to pharmaceutically beneficial. While exposure to high doses of Bd metabolites may be detrimental to some freshwater species (McMahon et al., 2013; Nordheim, Grim & McMahon, 2021), studies have shown that exposure to low doses of Bd metabolites may actually produce beneficial effects. Indeed, amphibians exposed to Bd metabolites responded to this prophylactic treatment exposure, and had reduced subsequent Bd infection loads, and in some cases, there was even lower infection prevalence (McMahon et al., 2014, 2023, 2024; Barnett et al., 2021, 2023; Nordheim et al., 2022). Additionally, tadpoles exposed to low concentrations of Bd metabolites experienced higher developmental speeds, while maintaining equal growth and survival compared to control tadpoles (McMahon, Laggan & Hill, 2019). These findings suggest that while high concentrations of Bd metabolites may impact important physiological processes such as gas exchange and osmoregulation, lower concentrations may be neutral or may even present a prophylactic potential against Bd infection, including reduced pathogen load, increased tolerance or resistance and potentially reducing adverse outcomes such as disease severity and mortality.
The concept that Bd metabolites may be beneficial is not entirely novel. Other fungal species have been shown to produce metabolites with pharmaceutically beneficial effects for freshwater organisms. The fungal species Aspergillus niger, for example, has been shown to increase survival in white shrimp (Zhang et al., 2023) in aquaculture. In fact, A. niger has been shown to enhance growth, immunity and disease resistance (Cheng et al., 2023). Additionally, fungal polysaccharides have been found to yield immunostimulation, increased pathogen resistance and even improve growth in crustaceans (Mohan et al., 2019). Indeed, many fungal species have been shown to produce bioactive metabolites with antimicrobial, including antifungal properties, that have proved critical to the aquaculture industry (Xu et al., 2021; Du et al., 2022).
In this study, we examined the effects of Bd metabolites on the freshwater species, Palaemonetes paludosus, more commonly known as ghost shrimp. It is important to note that despite Bd’s prevalence within amphibian populations, it is not exclusive to amphibians as it has been identified on non-amphibian organisms, such as wading birds (Garmyn et al., 2012) and snakes (Kilburn, Ibáñez & Green, 2011), and confirmed on museum specimens of aquatic birds originating from the Bolivian Andes (Burrowes & De la Riva, 2017). In its non-amphibian hosts, specifically crayfish, Bd has been identified growing in the gastrointestinal tract and on the exoskeleton (McMahon et al., 2013; Brannelly et al., 2015; Román, O’Neil & James, 2016; Oficialdegui et al., 2019). Bd related mortality in these freshwater invertebrates is likely due to gill damage and the resulting impairment in gas exchange (McMahon et al., 2021; Nordheim, Grim & McMahon, 2021), and potentially osmoregulation, given the role the gills play in these processes. Similarly, Bd metabolites have been shown to cause pathological outcomes in non-amphibian organisms. Research has demonstrated that gill damage and mortality can occur in crayfish exposed to high concentrations of Bd metabolites, and that these detrimental impacts occur even in the absence of Bd infection (McMahon et al., 2013; Nordheim, Grim & McMahon, 2021). It should be noted that these detrimental effects were not seen when crayfish were exposed to low concentrations of Bd metabolites, suggesting that not only might specific metabolites confer prophylactic benefits, but that a concentration dependent relationship between the prophylactic and pathological effects of Bd metabolites may exist (McMahon et al., 2013; Nordheim, Grim & McMahon, 2021).
Ghost shrimp are native to the southeastern coastal plains of North America and reside in shallow regions of freshwater ponds, lakes, and streams. These small invertebrates are scavengers and bioturbators, and they co-occur with Bd and amphibians. Through borrowing activities, ghost shrimp can alter carbon and nutrient cycling, and influence microbiota interactions and dispersal. They are a critical freshwater species, making them an ideal model to understand the impact of Bd metabolites and indirect exposure to Bd on freshwater organisms (Wada, Urakawa & Tamaki, 2016; Adhikary, Klerks & Chistoserdov, 2024). Additionally, ghost shrimp are ideal for studying bioactive compounds because their characteristic behavioral responses to threats, e.g., hiding and escape responses, offer strong opportunities to understand the effects of Bd metabolites on well-studied critical behaviors. The biochemical pathways, including those that regulate these behaviors, have also been characterized extensively in crayfish, which share neurochemical homology to ghost shrimp (Sosa et al., 2004; Wongprasert et al., 2006; Fossat et al., 2014). Finally, ghost shrimp’s characteristic translucent carapace and bodies allow for unpresented physical assessment, including monitoring of heart rate and changes to the physical appearance of the carapace.
To date, we know little about the direct and indirect effects of Bd on non-amphibian organisms. Indeed, most research on Bd has focused on amphibian conservation, which is not surprising given the severe decline in this taxon. The goal of this study was to better understand the effects of Bd metabolites on non-amphibian, freshwater organisms, which is particularly critical if Bd metabolites are to be used as a prophylactic at a community level. Additionally, understanding the complex dynamics of indirect exposure to Bd on co-occurring freshwater invertebrates may provide important insight into the mechanisms through which Bd is affecting population dynamics, and will provide a more holistic view of how Bd impacts the freshwater ecosystems.
Materials and Methods
Animal husbandry
Ghost shrimp (Palaemonetes paludosus) obtained from Northeast Brine Shrimp, LLC (Marietta, GA, USA) were individually housed in plastic containers containing 800 ml fresh artificial spring water (ASW; Cohen, Neimark & Eveland, 1980), with a single aeration stone and gentle aeration. Half of the tank was covered on all sides including the lid, to create a dark and light environment within the same container. Shrimp were maintained on a 12:12 h light/dark cycle at ~21 °C and they were fed every other day with high quality shrimp food (Hikari Sales USA Inc., Hayward, CA, USA). The uneaten food was removed daily to avoid water fowling and cross contamination was avoided. Shrimp were checked daily for mortality, molting, and overall health status, and visibly distressed (laying on back, pale white color) or dead animals were promptly removed and processed for future analysis.
Treatment and experimental procedures
To verify that the shrimp were Bd negative, we swabbed the carapace of each shrimp 10 times and made sure to swab the entire surface of the carapace. These swabs were frozen in a lab grade −20 °C freezer and were processed for presence of Bd with quantitative polymerase chain reaction (qPCR; see below for qPCR methods). All shrimp were Bd negative prior to the start of this experiment. Baseline measurements of heart rate (see below for heart rate analysis methods), and total extended length of shrimp (mm) were recorded prior to the start of the experiment.
Prior to dosing, referred to hereafter as pre-exposure, shrimp were allowed to acclimate in their container for 3 days and shrimp were not removed from this container during the experimental trials. As a baseline for our behavioral monitoring, we conducted daily pre-exposure behavioral assays noting shrimp: activity, position in the container (light vs dark side of container), and height of shrimp in the water column for 3 days prior to dosing (see Behavioral monitoring for methods). Shrimp were randomly split into two treatment groups (n = 20 shrimp/treatment). On day 4, shrimp were dosed with 1 ml of either an ASW control or Bd metabolite treatment (see below for Bd culture and Bd metabolite prophylaxis preparation methods). Post exposure behavioral testing was completed on days 4–14, and all remaining shrimp were euthanized by flash freezing and processed on post exposure day 14.
Heart rate analysis
A three-second video was taken of the heart of all living shrimp at the beginning and end of the experiment. Ghost shrimp are mostly translucent and their heart is clearly visible through their carapace. The pre-exposure heart rate was determined for all shrimp and the post-exposure heart rate was determined for all shrimp that survived to the end of the experiment.
Bd culture and Bd metabolite prophylaxis preparation
Bd (strain JEL 419; strain isolated in Panamá during an amphibian decline event) was cultured on 1% tryptone agar plates for 14 days at 17 °C. These cultures were flooded with ASW for 10 min and then the ASW and Bd from all plates were homogenized to create the Bd positive stock (1 × 105 zoospores/ml). We used the same method to create the Bd metabolite prophylaxis here as our previous amphibian exposure work (please see Nordheim et al., 2022 for detailed methods). In brief, to create the Bd metabolite prophylaxis for this study, the Bd positive stock was frozen, thawed and then passed through a 1.2 µm filter (GE Whatman Laboratory Products, Kent, UK) to remove all the zoospores and zoosporangia. This remaining homogenate contained just the water-soluble metabolites that the Bd produced while suspended in the stock (Bd metabolite prophylaxis: 1 × 105 zoospores removed/ml). We visually verified there was no viable Bd left in the Bd metabolite prophylaxis with a compound microscope. Additionally, we plated the Bd metabolite prophylaxis on 1% tryptone agar plates (n = 3 plates) and monitored for growth for 14 days. There was no Bd growth. The Bd metabolite concentration was chosen because it was found to negatively impact crayfish (McMahon et al., 2013; Nordheim, Grim & McMahon, 2021) and therefore might be in the range that could impact ghost shrimp as well. Additionally, it was higher than the effective prophylaxis concentration (McMahon et al., 2024) and so this would give us a strong chance of seeing deleterious impacts if there are some.
Behavioral monitoring
Behavioral screening was performed daily pre-exposure (during the 3-day acclimation period to establish a baseline and to account for individual variation), and post-exposure (to assess the effects of Bd metabolites on ghost shrimp behavior and activity level). All behavioral screening was performed in the morning during the light cycle, in the shrimps’ home tank and it occurred without disturbing the shrimp.
Activity monitoring: Ghost shrimp activity level was scored on a three-point scale, with 1 = no activity, 2 = mild activity, 3 = swimming actively. Ghost shrimp height was recorded as distance (cm) from the bottom of the container.
Modified light dark box test: Briefly, to assess whether ghost shrimp were found on the light or dark side of the tank, a modified light dark box was created. The shrimp tank, or chamber, was made of a clear plastic, which allowed light to pass through. One half of the chamber remained uncovered, and the other half was fully covered with dark construction paper on the sides, bottom and top. This set up created a shrimp tank that allowed light on one side and was dark on the other. We identified whether the ghost shrimp were on the dark or light side of the chamber daily during the pre- and post-exposure sections of the experiment.
Escape response test: Four days post-exposure, each shrimp’s escape response was measured by physically touching the telson of the ghost shrimp with a sterile plastic inoculation loop to determine whether each shrimp exhibited an evasive movement in response to a stimulus.
Gill damage
Gill damage (gill tissue recession) was measured following the protocol established for crayfish (see McMahon et al., 2013 and Nordheim, Grim & McMahon, 2021). In brief, ghost shrimp were frozen and then thawed prior to dissection and gill extraction. A large section of gill was removed from each ghost shrimp to ensure there was ample undamaged gill tissue to photograph, and photographs of each gill were taken with a compound light microscope at 10× magnification. ImageJ was used to collect measurements from each gill and all measurements were collected double-blind. We measured the distance between the tip of the external gill cuticle to the hemolymph and gill tissue (n = 3 measurements/gill).
qPCR methods
The qPCR protocol proposed by Boyle et al. (2004) was followed to verify the ghost shrimp were Bd negative prior to the start of the experiment. Briefly, DNA was extracted from the swabs using PrepMan Ultra (Applied Biosystems, Foster City, CA, USA) and TaqMan Exogenous Internal Positive Control Reagents (Applied Biosystems, Foster City, CA, USA) were used to verify there was no inhibition; there was no evidence of inhibition. All samples were run on one 96 well plate and the standard curve ranged from 0.84–840 genome equivalents (GE; standards were Bd/Bsal plasmid standards purchased from Pisces Molecular). All ghost shrimp were Bd negative at the beginning of the experiment (we have never received Bd infected ghost shrimp from this company).
Statistical analysis
All analyses were conducted in R using R studio (version 4.2.2; R Core Team, 2022). A general linear model (package: stats, function: glm, family: gaussian; R Core Team, 2022) was used to verify that there was no difference in initial shrimp length between the treatment groups prior to the start of the experiment. A generalized linear model (package: glmmTMB, function: glmmTMB, family: gaussian; Brooks et al., 2017) was used to determine if there was an effect of treatment on whether ghost shrimp spent more time on the dark side of the enclosure post treatment exposure. Time spent on the dark side pre-exposure, number of observations post-exposure (number of times behavioral observations were made for each individual after exposure; this number varied due to mortality), and mortality status were accounted for as covariates in the model.
A general linear model (package: stats, function: glm, family: gaussian) was used to determine whether there was an effect of treatment or time after exposure on gill recession, whether there was a correlation between gill recession and activity level, whether there was an effect of treatment or number of post exposure observations on post exposure activity level, whether there was an effect of treatment or number of post exposure observations on height post exposure (taking into consideration average height pre-exposure), and whether there was an effect of treatment or number of post exposure observations on total number of molts post exposure. A general linear model (package: stats, function: glm, family: gaussian) was also used to determine if there was a difference in initial heart rate between the treatment groups prior to exposure to the treatments and to determine whether there was an effect of treatment on final heart rate (taking into consideration the initial heart rate of each shrimp). We used a general linear model (package: stats, function: glm, family: gaussian) to determine if treatment had an effect on whether shrimp exhibited an evasive movement in response to a stimulus. A survival analysis was performed and the data was fit to a cox proportional hazards regression (package: survival, function: coxph; Therneau, 2024) to determine if there was an effect of treatment on mortality.
Figures 1–3 were created in R (Fig. 1: package: survminer, function: ggsurvplot (Kassambara, Kosinski & Biecek, 2024)); Figs. 2 and 3: package: ggplot2, function: ggplot; Wickham, 2016, and Fig. 4 was created in Excel (Version 16.78.3).
Enlarge this image.Figure 1: Bd metabolites reduced mortality in ghost shrimp. Ghost shrimp (Palaemonetes paludosus) exposed to the Batrachochytrium dendrobatidis (Bd) metabolite treatment had increased survival compared to those exposed to an ASW control (n = 20 shrimp/treatment). The Kaplan-Meier curve was generated in RStudio. DOI: 10.7717/peerj.19815/fig-1
Enlarge this image.Figure 2: Bd metabolites reduced heartrate in ghost shrimp. Ghost shrimp (Palaemonetes paludosus) exposed to the Batrachochytrium dendrobatidis (Bd) metabolite treatment had a reduced final heart rate compared to those exposed to an ASW control (n = 20 shrimp/treatment). The top and bottom of the box represents the 75th and 25th percentiles, respectively, the line = median, the x = mean, and the whiskers = the minimum and maximum values. DOI: 10.7717/peerj.19815/fig-2
Enlarge this image.Figure 3: Ghost shrimp exposed to the Bd metabolites spent less time on the dark side of the enclosure post exposure. Ghost shrimp (Palaemonetes paludosus) exposed to the Batrachochytrium dendrobatidis (Bd) metabolite treatment spent less time on the dark side of the enclosure post exposure compared to those exposed to the ASW control (n = 20 shrimp/treatment). The top and bottom of the box represents the 75th and 25th percentiles, respectively, the line = median, the x = mean, and the whiskers = the minimum and maximum values. DOI: 10.7717/peerj.19815/fig-3
Enlarge this image.Figure 4: Fewer ghost shrimp exposed to the Bd metabolites exhibited evasive movements compared to those exposed to the ASW control. Fewer ghost shrimp (Palaemonetes paludosus) exposed to the Batrachochytrium dendrobatidis (Bd) metabolite treatment exhibited evasive movements when stimulated on the telson 8 days after exposure compared to ghost shrimp exposed to the ASW control (n = 20 shrimp/treatment). The proportion of the overall population of ghost shrimp that exhibited an escape response ± SE is shown. DOI: 10.7717/peerj.19815/fig-4
Results
Bd metabolites reduced mortality in ghost shrimp
There was reduced mortality in ghost shrimp exposed to the Bd metabolite treatment compared to the ASW control (z = −2.23, p = 0.026; Fig. 1). Ghost shrimp exposed to the Bd metabolite treatment had 48.4% lower mortality than those exposed to the ASW control (95% Confidence Interval (CI) for mortality proportion for ASW control: 0.454 and 0.883, and Bd metabolites: 0.082 and 0.503, lower and upper limit respectively; calculated using a method described by Wilson, 1927).
Bd metabolites reduced heartrate but did not induce gill recession in ghost shrimp
Ghost shrimp heart rate was measured over a 3 s period pre and post exposure to Bd metabolites. Ghost shrimp exposed to the Bd metabolites had reduced heart rates compared to those exposed to the ASW controls 8 days after exposure (t = −2.56, p = 0.017; Fig. 2). Ghost shrimp exposed to the Bd metabolite treatment had 19.57% lower heart rates than those exposed to the ASW control. There was no difference in initial heart rate between the treatment groups (t = −1.39, p = 0.176), however there was a positive correlation between initial heart rate and final heart rate (t = 2.87, p = 0.008).
There was no effect of treatment on gill recession (t = 1.27, p = 0.217) and this did not change with time after exposure (t = 0.343, p = 0.734). There was also no correlation between gill recession and activity level (t = −0.703, p = 0.489).
Bd metabolites modulate ghost shrimp threat based behavioral responses
Bd metabolites did have an effect on ghost shrimp behaviors. Ghost shrimp exposed to the Bd metabolites spent 17.77% less time on the dark side of the enclosure post exposure compared to those exposed to the ASW control (z = −1.965, p = 0.0494; Fig. 3). The amount of time spent on the dark side pre-exposure, the number of observations made post-exposure, and mortality status did not have an effect on time spent on dark side of the container post-exposure (z = 3.95, p = 0.693, z = −1.172, p = 0.241; z = −1.442, p = 0.149, respectively).
Ghost shrimp exposed to the Bd metabolites were 70% less likely to exhibit evasive movements 8 days after exposure when stimulated compared to ghost shrimp exposed to the ASW control (t = −2.82, p = 0.015; Fig. 4). There was no effect of treatment or number of post exposure observations on post exposure activity level (t = −0.394, p = 0.697, t = 1.68, p = 0.107, respectively).
There was no effect of treatment, average pre-exposure height or number of post exposure observations on post exposure height (t = −0.321, p = 0.751, t = 0.371, p = 0.715, t = 1.35, p = 0.191, respectively). There was no effect of treatment on the total number of molts post-exposure (t = −1.62, p = 0.12), but there was an impact of the number of post exposure observations on the number of molts (t = 3.48, p = 0.002). There was no difference in ghost shrimp length between the two treatment groups at the beginning of the experiment (t = 1.516, p = 0.138).
Discussion
This study found that exposure to Bd metabolites altered ghost shrimp behavior and mortality, but not necessarily in an expected manner. We found that ghost shrimp exposed to Bd metabolites experienced decreased mortality when compared to those exposed to ASW, suggesting that Bd metabolites may actually improve survival. The mechanism for increased survival in ghost shrimp was not studied here, but previous research found that Bd metabolites altered the host microbiome, shifting the microbiome towards more protective biota (Siomko et al., 2023). The microbiome, particularly the gut microbiome, has been shown to be intrinsically related to immune function (Holt et al., 2021). It is certainly possible that the ghost shrimp experienced a beneficial microbiome shift as well, though further research is needed to better understand this possible dynamic, the mechanism behind the increased survival conferred by Bd metabolite exposure, and its beneficial effects in other organisms.
Similar results were seen in studies in amphibians, with prophylactic exposure to Bd metabolites leading to reduced disease outcomes (Nordheim et al., 2022; Barnett et al., 2023), which would likely increase survival (McMahon et al., 2014). Indeed, tadpoles exposed to Bd metabolites experienced more rapid development while still maintaining strong growth and survival (McMahon, Laggan & Hill, 2019). This is unexpected, as typically when tadpoles develop faster due to local environmental conditions there is a negative trade off, including smaller size and higher mortality (see Newman, 1988; Bridges, 2002; Rohr et al., 2004). These results support observations in ghost shrimp, and further highlight possible beneficial impacts on survival of exposure to Bd metabolites.
We found that Bd metabolites did not induce gill recession in ghost shrimp. This finding was important given that previous studies in crayfish have reported gill recession which was associated with increased mortality (McMahon et al., 2013; Nordheim, Grim & McMahon, 2021). Importantly, in those previous studies, gill damage was associated with higher doses of Bd metabolites; in fact, low doses of Bd metabolites did not cause damage in crayfish either. The different responses in gill damage between crayfish and ghost shrimp may be associated with the effects of actual Bd infection vs exposure to just the Bd metabolites. It should be noted that Bd positive ghost shrimp have been found in the field (Rowley, Alford & Skerratt, 2006 but see Rowley et al., 2007, as well) and so, it is certainly possible that ghost shrimp are tolerant to Bd metabolites. The differential effects in gill damage may also be due to exposure to different specific metabolites as Bd produces different metabolites depending on the environment (Rollins-Smith, Reinert & Burrowes, 2015). Finally, previous research has found lower concentrations of Bd metabolites were not deleterious to other crustaceans (McMahon et al., 2013; Nordheim, Grim & McMahon, 2021), suggesting different concentrations of Bd metabolites may also confer differential effects.
Ghost shrimp exposed to Bd metabolites experienced impacts on the cardiac system and had a decreased final heart rate compared to those exposed to ASW. While this finding was based on a 3-s view of the heart rate pre- and post-exposure, the results are interesting, given our observations of increased survival and no gill recession. Some studies have reported cardiac disruptions in amphibians following active Bd infections, including decreased stroke volume and delayed cardiac cycles (Salla et al., 2018). Additionally, amphibians experiencing effects of chytridiomycosis have impaired epidermal osmoregulation, which was associated with asystolic cardiac arrest (Voyles et al., 2009). While we have no evidence that the decreased heart rate is detrimental in the ghost shrimp in our study, and the exact mechanism through which cardiac disruption is precipitated is not known, our findings indicate that the Bd metabolites may be associated with altered cardiac function. Further research is needed to fully understand the dynamics associated with Bd metabolite exposure on cardiac function because there are likely multiple physiological mechanisms at play, and the impact of Bd metabolites on cardiac function may point toward important mechanistic differences between direct exposure to Bd, and indirect exposure to Bd metabolites.
Ghost shrimp exposed to Bd metabolites were observed to spend less time on the dark side of their tank post treatment compared to ASW and were also less likely to exhibit escape behavior in response to an approaching foreign object. Both behaviors deviate from ghost shrimp’s expected natural behavioral profile, which include a preference for the dark or covering, and a tendency toward escape, behaviors aimed at avoiding predation. Reduced threat response behaviors, which are likely to increase ghost shrimps’ risk of predation, have been linked to disruption of the serotonergic pathway (Guler & Ford, 2010; Fossat et al., 2014, 2015). This connection has been supported through research in other decapods, with one study showing that animals exposed to antidepressants such as serotonin reuptake inhibitors, which target the serotonergic pathway, display reduced hiding and escape behavior (Guler & Ford, 2010). Indeed, tryptophan, which was identified as one of the most abundantly secreted metabolites in the Bd supernatant (Rollins-Smith, Reinert & Burrowes, 2015), is an essential amino acid and precursor to serotonin, a neurotransmitter critical in regulating behavior. Additionally, kynurenine, another Bd metabolite, is also central to the serotonergic pathway and immune regulation. Kynurenine, like serotonin, is a metabolite of tryptophan and represents a distinct pathway branchpoint to serotonin, making these two metabolic products key regulators of tryptophan and each other. Importantly, serotonin has been connected to Bd susceptibility in amphibians. One study in particular demonstrated correlations between skin serotonin levels and the susceptibility to Bd, and perhaps disease progression (Claytor et al., 2019). Serotonin was shown to inhibit the growth of Bd sporangia in vitro, and studies in Candida albicans showed that serotonin attenuated virulence in the fungus (Mayr et al., 2005). Altogether, this points toward a possible role for Bd metabolites, specifically tryptophan, in not only the pathogenesis and virulence of Bd, but as prophylactic agents.
This research found that exposure to Bd metabolites was not directly deleterious to ghost shrimp, but we did find that these metabolites had potentially adverse impacts that could be detrimental in the field. Given that researchers have been developing a Bd metabolite prophylaxis it is crucial that more research be done to understand the impact of these metabolites on critical freshwater organisms. Studies have been mixed in regards to the effects of Bd metabolites, with some showing evidence that exposure to high concentrations of Bd metabolites can increase mortality (e.g., see McMahon et al., 2013; Nordheim, Grim & McMahon, 2021) and others finding Bd metabolites confer prophylactic effects (e.g., see Barnett et al., 2023; McMahon et al., 2023, 2024). These discrepancies may be due to differences in concentration of metabolites, or the composition of metabolites organisms are exposed to, which can be dependent on the environment (Rollins-Smith, Reinert & Burrowes, 2015). It is also plausible that different strains of Bd may have differential impacts on organisms (e.g., see Barnett et al., 2021). Different organisms may also display differential responses to Bd metabolites, due to inherent physiological differences. It is important that we continue to examine the mechanisms through which Bd mediates its impact, including the role of specific metabolites. This is not only important in elucidating the mechanisms through which Bd induces deleterious impacts, but also potential targets for prophylactic and therapeutic intervention. The serotonergic pathway may be an important target given existing research showing a key role for serotonin in Bd virulence and animal susceptibility, and the identification of tryptophan and kynurenine as Bd metabolites. Addressing Bd’s impact on freshwater organisms may lie in our ability to modulate, at least in part, Bd’s effects on serotonin and its metabolites.
There have also been few studies focused on understanding the effects of Bd metabolites on non-amphibian organisms, despite evidence that they co-occur with amphibians and can be infected by and carry Bd. Many freshwater invertebrates, e.g., ghost shrimp and crayfish, could play an important role in understanding the impact of direct and indirect exposure to Bd because they are easy to maintain in the lab, their physiology and behavioral responses are well studied, many have transparent bodies and many are not experiencing dramatic declines in the wild. Instead of over utilizing amphibians in this type of work, freshwater invertebrates could be a crucial part of developing and implementing multilayered conservation efforts to protect critically endangered amphibian populations. Indeed, studying the impact of Bd and the metabolites it produces on freshwater invertebrates may provide much needed insight into the mechanisms associated with the pathogenicity and virulence of Bd as well as its impact on community ecology.
Conclusions
This study examined the effects of Bd metabolites in a ghost shrimp model system, focusing on the effects on behavior, cardiac function and mortality. We found that ghost shrimp exposed to Bd metabolites experienced reduced mortality when compared to those exposed to a water control and we observed decreased heart rate and reduced threat response behaviors. Previous studies reported increased mortality in crayfish following exposure to high concentrations of Bd metabolites, these disparate outcomes underscore the need for more research into understanding the impacts of Bd metabolites. Previous research has found that Bd metabolites can be used as a prophylaxis for amphibians, however, the use of Bd metabolites in a large-scale conservation effort in the field would likely yield exposure of both amphibian and non-amphibian organisms to these prophylactic agents. This work is promising, but it would only be feasible if we continue to do work to understand the impact of Bd metabolites on critical non-amphibian organisms.
Supplemental Information
Dataset.
All heart rate, behavioral and other significant measurements for ghost shrimp exposed to Bd metabolites or ASW control.
DOI: 10.7717/peerj.19815/supp-1
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Code Book for Data to convert numbers to their respective factors.
DOI: 10.7717/peerj.19815/supp-2
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Additional Information and Declarations
Competing Interests
The authors declare that they have no competing interests.
Author Contributions
Ellisa Carla Parker-Athill conceived and designed the experiments, performed the experiments, authored or reviewed drafts of the article, and approved the final draft.
Liam C. Muldro performed the experiments, authored or reviewed drafts of the article, and approved the final draft.
Aiza J. Malinias performed the experiments, authored or reviewed drafts of the article, and approved the final draft.
Taegan A. McMahon conceived and designed the experiments, performed the experiments, analyzed the data, prepared figures and/or tables, authored or reviewed drafts of the article, and approved the final draft.
Data Availability
The following information was supplied regarding data availability:
The raw data is available in the Supplemental Files.
Funding
This work was funded by the National Institutes of Health (Taegan A. McMahon: 1R01GM135935-01) and the Sloan Scholars Mentoring Network Seed Grant (E. Carla Parker-Athill). The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.
Adhikary NRD, Klerks PL, Chistoserdov AY. 2024. Bacterial community composition in the Northern Gulf of Mexico intertidal sediment bioturbated by the ghost shrimp Lepidophthalmus louisianensis. Antonie van Leeuwenhoek 117(1):21
Barnett KM, Detmering SE, McMahon TA, Civitello DJ. 2021. Asymmetric cross-strain protection for amphibians exposed to a fungal-metabolite prophylactic treatment. Biology Letters 17(8):20210207
Barnett KM, Hilgendorff BA, Civitello DJ, McMahon TA. 2023. Fungal metabolites provide pre-exposure protection but no postexposure benefit or harm against Batrachochytrium dendrobatidis. The Journal of Wildlife Diseases 59(2):217-223
Berger L, Speare R, Daszak P, Green DE, Cunningham AA, Goggin CL, Slocombe R, Ragan MA, Hyatt AD, McDonald KR, Hines HB, Lips KR, Marantelli G, Parkes H+4 more. 1998. Chytridiomycosis causes amphibian mortality associated with population declines in the rain forests of Australia and Central America. Proceedings of the National Academy of Sciences of the United States of America 95(15):9031-9036
Boyle D, Boyle D, Olsen V, Morgan J, Hyatt A. 2004. Rapid quantitative detection of chytridiomycosis (Batrachochytrium dendrobatidis) in amphibian samples using real-time Taqman PCR assay. Diseases of Aquatic Organisms 60:141-148
Brannelly L, McMahon T, Hinton M, Lenger D, Richards-Zawacki C. 2015. Batrachochytrium dendrobatidis in natural and farmed Louisiana crayfish populations: prevalence and implications. Diseases of Aquatic Organisms 112(3):229-235
Bridges CM. 2002. Tadpoles balance foraging and predator avoidance: effects of predation, pond drying, and hunger. Journal of Herpetology 36:627-634
Brooks ME, Kristensen K, van Benthem KJ, Magnusson A, Berg CW, Nielsen A, Skaug HJ, Mächler M, Bolker BM. 2017. glmmTMB balances speed and flexibility among packages for zero-inflated generalized linear mixed modeling. The R Journal 2:378-400
Burrowes PA, De la Riva I. 2017. Detection of the amphibian chytrid fungus Batrachochytrium dendrobatidis in museum specimens of Andean aquatic birds: implications for pathogen dispersal. Journal of Wildlife Diseases 53(2):349-355
Cheng A-C, Peng X, Chen W, Tseng D-Y, Tan Z, Liu H, Qin Z, Ballantyne R, Liu C-H. 2023. Dietary probiotic Aspergillus niger preparation improves the growth performance, health status, and gut microbiota of white shrimp, Penaeus vannamei. Aquaculture 577:739988
Claytor SC, Gummer JPA, Grogan LF, Skerratt LF, Webb RJ, Brannelly LA, Berger L, Roberts AA. 2019. Susceptibility of frogs to chytridiomycosis correlates with increased levels of immunomodulatory serotonin in the skin. Cellular Microbiology 21(10):e13089
Cohen LM, Neimark H, Eveland LK. 1980. Schistosoma mansoni: response of cercariae to a thermal gradient. The Journal of Parasitology 66:362-364
Cossel JO, Lindquist ED. 2009. Batrachochytrium dendrobatidis in arboreal and lotic water sources in Panama. Herpetological Review 1:45-47
Du H-F, Zhang Y-H, Zhang M, Liu Q-A, Zhu H-J, Cao F. 2022. Marine fungal metabolites as a source of drug leads against aquatic pathogens. Applied Microbiology and Biotechnology 106(9–10):3337-3350
Fossat P, Bacqué-Cazenave J, Deurwaerdère PD, Cattaert D, Delbecque J-P. 2015. Serotonin, but not dopamine, controls the stress response and anxiety-like behavior in the crayfish Procambarus clarkii. Journal of Experimental Biology 218(Suppl. 3):2745-2752
Fossat P, Bacqué-Cazenave J, Deurwaerdère PD, Delbecque J-P, Cattaert D. 2014. Anxiety-like behavior in crayfish is controlled by serotonin. Science 344(6189):1293-1297
Gabor CR, Fisher MC, Bosch J. 2015. Elevated corticosterone levels and changes in amphibian behavior are associated with Batrachochytrium dendrobatidis (Bd) infection and Bd lineage. PLOS ONE 10(4):e0122685
Garmyn A, Rooij PV, Pasmans F, Hellebuyck T, Broeck WVD, Haesebrouck F, Martel A. 2012. Waterfowl: potential environmental reservoirs of the chytrid fungus Batrachochytrium dendrobatidis. PLOS ONE 7(4):e35038
Grogan LF, Robert J, Berger L, Skerratt LF, Scheele BC, Castley JG, Newell DA, McCallum HI. 2018. Review of the amphibian immune response to chytridiomycosis, and future directions. Frontiers in Immunology 9:2536
Guler Y, Ford AT. 2010. Anti-depressants make amphipods see the light. Aquatic Toxicology 99(3):397-404
Holt CC, Bass D, Stentiford GD, van der Giezen M. 2021. Understanding the role of the shrimp gut microbiome in health and disease. Journal of Invertebrate Pathology 186(9):107387
Kassambara A, Kosinski M, Biecek P. 2024. survminer: drawing survival curves using “ggplot2”. R package version 0.5.0.999
Kilburn V, Ibáñez R, Green D. 2011. Reptiles as potential vectors and hosts of the amphibian pathogen Batrachochytrium dendrobatidis in Panama. Diseases of Aquatic Organisms 97(2):127-134
Kirshtein J, Anderson C, Wood J, Longcore J, Voytek M. 2007. Quantitative PCR detection of Batrachochytrium dendrobatidis DNA from sediments and water. Diseases of Aquatic Organisms 77:11-15
Longcore JE, Pessier AP, Nichols DK. 1999. Batrachochytrium dendrobatidis gen. et sp. nov., a chytrid pathogenic to amphibians. Mycologia 91(2):219-227
Mayr A, Hinterberger G, Dierich MP, Lass-Flörl C. 2005. Interaction of serotonin with Candida albicans selectively attenuates fungal virulence in vitro. International Journal of Antimicrobial Agents 26(4):335-337
McMahon TA, Brannelly LA, Chatfield MWH, Johnson PTJ, Joseph MB, McKenzie VJ, Richards-Zawacki CL, Venesky MD, Rohr JR. 2013. Chytrid fungus Batrachochytrium dendrobatidis has nonamphibian hosts and releases chemicals that cause pathology in the absence of infection. Proceedings of the National Academy of Sciences of the United States of America 110(1):210-215
McMahon TA, Garcia AM, Malinias AJ, Monsalve M, Muldro LC, Sisson EO, Johnson PTJ, Rohr JR, Civitello DJ. 2024. Efficacy of Bd metabolite prophylaxis dose and duration on host defense against the deadly chytrid fungus Batrachochytrium dendrobatidis. Journal of Applied Ecology 61(12):3139-3147
McMahon TA, Hill MN, Lentz GC, Scott EF, Tenouri NF, Rohr JR. 2021. Amphibian species vary in their learned avoidance response to the deadly fungal pathogen Batrachochytrium dendrobatidis. Journal of Applied Ecology 58(8):1613-1620
McMahon T, Laggan N, Hill M. 2019. Metabolites produced by Batrachochytrium dendrobatidis alter development in tadpoles, but not growth or mortality. Diseases of Aquatic Organisms 135(3):251-255
McMahon T, Nordheim C, Detmering S, Johnson P, Rohr J, Civitello D. 2023. Pseudacris regilla metamorphs acquire resistance to Batrachochytrium dendrobatidis after exposure to the killed fungus. Diseases of Aquatic Organisms 155:193-198
McMahon TA, Sears BF, Venesky MD, Bessler SM, Brown JM, Deutsch K, Halstead NT, Lentz G, Tenouri N, Young S, Civitello DJ, Ortega N, Fites JS, Reinert LK, Rollins-Smith LA, Raffel TR, Rohr JR+7 more. 2014. Amphibians acquire resistance to live and dead fungus overcoming fungal immunosuppression. Nature 511(7508):224-227
Mohan K, Ravichandran S, Muralisankar T, Uthayakumar V, Chandirasekar R, Seedevi P, Rajan DK. 2019. Potential uses of fungal polysaccharides as immunostimulants in fish and shrimp aquaculture: a review. Aquaculture 500(1):250-263
Newman RA. 1988. Adaptive plasticity in development of Scaphipus couchii tadpoles in desert ponds. Evolution Education and Outreach 42(4):774-783
Nordheim CL, Detmering SE, Civitello DJ, Johnson PTJ, Rohr JR, McMahon TA. 2022. Metabolites from the fungal pathogen Batrachochytrium dendrobatidis (bd) reduce Bd load in Cuban treefrog tadpoles. Journal of Applied Ecology 59(9):2398-2403
Nordheim C, Grim J, McMahon T. 2021. Batrachochytrium dendrobatidis (Bd) exposure damages gill tissue and inhibits crayfish respiration. Diseases of Aquatic Organisms 146:67-73
Oficialdegui FJ, Sánchez MI, Monsalve-Carcaño C, Boyero L, Bosch J. 2019. The invasive red swamp crayfish (Procambarus clarkii) increases infection of the amphibian chytrid fungus (Batrachochytrium dendrobatidis) Biological Invasions 21(11):3221-3231
Peterson JD, Steffen JE, Reinert LK, Cobine PA, Appel A, Rollins-Smith L, Mendonça MT. 2013. Host stress response is important for the pathogenesis of the deadly amphibian disease, chytridiomycosis, in Litoria caerulea. PLOS ONE 8:e62146
R Core Team. 2022. R: a language and environment for statistical computing. Vienna, Austria: R Foundation for Statistical Computing.
Rohr JR, Elskus AA, Shepherd BS, Crowley PH, McCarthy TM, Niedzwiecki JH, Sager T, Sih A, Palmer BD. 2004. Multiple stressors and salamanders: effects of an herbicide, food limitation and hydroperiod. Ecological Applications 14(4):1028-1040
Rollins-Smith L, Reinert L, Burrowes P. 2015. Coqui frogs persist with the deadly chytrid fungus despite a lack of defensive antimicrobial peptides. Diseases of Aquatic Organisms 113(1):81-83
Rollins-Smith LA, Ruzzini AC, Fites JS, Reinert LK, Hall EM, Joosse BA, Ravikumar VI, Huebner MI, Aka A, Kehs MH, Gillard BM, Doe E, Tasca JA, Umile TP, Clardy J, Minbiole KPC+6 more. 2019. Metabolites involved in immune evasion by Batrachochytrium dendrobatidis include the polyamine spermidine. Infection and Immunity 87(5):10.1128/iai.00035-19
Román CMB, O’Neil CC, James TY. 2016. Rethinking the role of invertebrate hosts in the life cycle of the amphibian chytridiomycosis pathogen. Parasitology 143(13):1723-1729
Rowley JJL, Alford RA, Skerratt LF. 2006. The amphibian chytrid Batrachochytrium dendrobatidis occurs on freshwater shrimp in rain forest streams in Northern Queensland, Australia. EcoHealth 3(1):49-52
Rowley JJL, Hemingway VA, Alford RA, Waycott M, Skerratt LF, Campbell R, Webb R. 2007. Experimental infection and repeat survey data indicate the amphibian chytrid Batrachochytrium dendrobatidis may not occur on freshwater crustaceans in Northern Queensland, Australia. EcoHealth 4(1):31
Salla RF, Rizzi-Possignolo GM, Oliveira CR, Lambertini C, Franco-Belussi L, Leite DS, Silva-Zacarin ECM, Abdalla FC, Jenkinson TS, Toledo LF, Jones-Costa M+1 more. 2018. Novel findings on the impact of chytridiomycosis on the cardiac function of anurans: sensitive vs. tolerant species. PeerJ 6:e5891
Scheele BC, Pasmans F, Skerratt LF, Berger L, Martel A, Beukema W, Acevedo AA, Burrowes PA, Carvalho T, Catenazzi A, de la Riva I, Fisher MC, Flechas SV, Foster CN, Frías-Álvarez P, Garner TWJ, Gratwicke B, Guayasamin JM, Hirschfeld M, Kolby JE, Kosch TA, La Marca E, Lindenmayer DB, Lips KR, Longo AV, Maneyro R, McDonald CA, Mendelson J, Palacios-Rodriguez P, Parra-Olea G, Richards-Zawacki CL, Rödel M-O, Rovito SM, Soto-Azat C, Toledo LF, Voyles J, Weldon C, Whitfield SM, Wilkinson M, Zamudio KR, Canessa S+31 more. 2019. Amphibian fungal panzootic causes catastrophic and ongoing loss of biodiversity. Science 363(6434):1459-1463
Siomko SA, Greenspan SE, Barnett KM, Neely WJ, Chtarbanova S, Woodhams DC, McMahon TA, Becker CG. 2023. Selection of an anti-pathogen skin microbiome following prophylaxis treatment in an amphibian model system. Philosophical Transactions of the Royal Society B: Biological Sciences 378(1882):20220126
Sosa MA, Spitzer N, Edwards DH, Baro DJ. 2004. A crustacean serotonin receptor: cloning and distribution in the thoracic ganglia of crayfish and freshwater prawn. Journal of Comparative Neurology 473(4):526-537
Therneau T. 2024. A package for survival analysis in R. R package version 3.8-4
Voyles J, Young S, Berger L, Campbell C, Voyles WF, Dinudom A, Cook D, Webb R, Alford RA, Skerratt LF, Speare R+1 more. 2009. Pathogenesis of chytridiomycosis, a cause of catastrophic amphibian declines. Science 326(5952):582-585
Wada M, Urakawa T, Tamaki A. 2016. Dynamics of bacterial community structure on intertidal sandflat inhabited by the ghost shrimp Nihonotrypaea harmandi (Decapoda: Axiidea: Callianassidae) in Tomioka Bay, Amakusa, Japan. Gene 576(2):657-666
Wickham H. 2016. ggplot2: elegant graphics for data analysis. Vienna, Austria: Springer-Verlag New York.
Wilson EB. 1927. Probable inference, the law of succession, and statistical inference. Journal of the American Statistical Association 22(158):209-212
Wixson JG, Rogers KB. 2009. Detecting Batrachochytrium dendrobatidis in the wild when amphibians are absent. Herpetological Review 40:313-316
Wongprasert K, Asuvapongpatana S, Poltana P, Tiensuwan M, Withyachumnarnkul B. 2006. Serotonin stimulates ovarian maturation and spawning in the black tiger shrimp Penaeus monodon. Aquaculture 261(4):1447-1454
Xu K, Li X-Q, Zhao D-L, Zhang P. 2021. Antifungal secondary metabolites produced by the fungal endophytes: chemical diversity and potential use in the development of biopesticides. Frontiers in Microbiology 12:689527
Zhang M, Liang H, Lei Y, Zhang Y, Tan Z, Chen W, Li S, Peng X, Tran NT. 2023. Aspergillus niger confers health benefits and modulates the gut microbiota of juvenile Pacific white shrimp (Penaeus vannamei) under farming conditions. Frontiers in Marine Science 10:1211993
Department of Biology, Connecticut College, New London, Connecticut, United States
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