Spring Peepers Pseudacris Crucifer Research Articles

Parasite-induced vulnerability to predation in larval anurans.

Within communities, pathogens and parasites have the potential to indirectly influence predator-prey interactions. For instance, prey that exhibit pathology or altered traits (e.g. behavioral shifts) following infection could be more prone to predation, which is known as parasite-induced vulnerability to predation (PIVP). PIVP has been frequently documented for pathogens with trophic transmission, because predators are often critical in the pathogen's life cycle. However, for pathogens without trophic transmission, PIVP can lead to a healthy herds effect, thereby reducing transmission in the system. In this study, we explored whether the pathogen ranavirus (family Iridoviridae) enhances vulnerability of 4 species of larval amphibians (spring peepers Pseudacris crucifer, gray treefrogs Hyla versicolor, American toads Anaxyrus americanus, and northern leopard frogs Lithobates pipiens) to 2 common tadpole predators (larval green darners Anax junius [hereinafter Anax] and adult water bugs Belostoma flumineum [hereinafter Belostoma]). For each anuran species, we conducted short-term microcosm experiments to assess predation rates on individuals that were or were not exposed to virus. For 3 of the 4 species, we found that exposure to ranavirus decreased survival rates with Anax between 2- and 9-fold. However, we did not see the same trend with Belostoma, which indicates that predator identity is important in this interaction. More specifically, the higher efficiency of Anax in capturing and consuming prey, relative to Belostoma, may allow Anax to capitalize on trait changes induced by virus exposure and enhance the PIVP effect. Our results indicate that trait-mediated indirect effects could play a role in creating healthy herds in amphibian communities.

Spring peepers Pseudacris crucifer modify their call structure in response to noise

Abstract Acoustic interference can impede effective communication that is important for survival and reproduction of animals. In response to acoustic interference, some animals can improve signalling efficacy by altering the structure of their signals. In this study, we played artificial noise to 46 male spring peepers Pseudacris crucifer, on their breeding grounds, and tested whether the noise affected the duration, call rate, and peak frequency of their advertisement calls. We used two experimental noise treatments that masked either the high- or low-frequency components of an average advertisement call; this allowed us to evaluate whether frogs adaptively shift the peak frequency of their calls away from both types of interference. Our playback treatments caused spring peepers to produce shorter calls, and the high-frequency noise treatment caused them to lower the frequency of their calls immediately after the noise ceased. Call rate did not change in response to playback. Consistent with previous studies, ambient temperature was inversely related to call duration and positively related to call rate. We conclude that noise affects the structure of spring peeper advertisement calls, and that spring peepers therefore have a mechanism for altering signal structure in response to noise. Future studies should test if other types of noise, such as biotic or anthropogenic noise, have similar effects on call structure, and if the observed changes to call structure enhance or impair communication in noisy environments [Current Zoology 60 (4): 438–448, 2014].

Preliminary Amphibian Health Survey in the Delaware Water Gap National Recreation Area

To detect aquatic animal diseases of national concern, 111 individual amphibians, including wood frogs Rana sylvatica (28), spring peepers Pseudacris crucifer (35), red-spotted newts Notophthalmus viridescens (41), and gray tree frogs Hyla versicolor (7), were sampled at seven different sites in the Delaware Water Gap National Recreation Area (DGNRA), Pennsylvania, from June 14 to July 19, 2007. These samples were screened for Batrachochytrium dendrobatidis and viral pathogens at the U.S. Fish and Wildlife Service's Fish Health Center in Lamar, Pennsylvania. Cell culture revealed cytopathic effect (CPE) in two cell lines (epithelioma papillosum cyprini and fathead minnow) inoculated with liver, kidney, and spleen samples from one sample pool of Notophthalmus viridescens (4 individuals). Polymerase chain reaction was conducted on cell culture supernatant exhibiting CPE. Sequencing revealed the resulting product to be identical to frog virus 3, a ranavirus in the family Iridoviridae. Upon gross examination, two Notophthalmus viridescens were found to exhibit dermal swelling and lethargy. Histological examination of these lesions revealed involvement by an Ichthyophonus sp. In summary, two pathogens of concern were found in amphibians in the DGNRA: a ranavirus with a major capsid protein sequence identical to that of frog virus 3 and a mesomycetozoan, Ichthyophonus sp. Although no epizootic die-offs were observed during this health survey, the results warrant further research into the distribution of these pathogens throughout the DGNRA because they have the potential to cause mass mortalities in amphibians.

Water molds of the genera Saprolegnia and Leptolegnia are pathogenic to the North American frogs Rana catesbeiana and Pseudacris crucifer, respectively

Water molds are commonly associated with amphibian mortality. Since water molds often act as saprophytes, it is important to test their effects on amphibians to determine whether they can also act as pathogens. In controlled experiments, the eggs of 2 amphibian species, the American bullfrog Rana catesbeiana and the spring peeper Pseudacris crucifer, suffered higher mortality when they were exposed to zoospores of water molds of the genera Saprolegnia and Leptolegnia, respectively. Water molds are important pathogens in many amphibian systems, yet their ecological impact on amphibians remains mostly unknown.

More bang for your buck: the effect of caller position, habitat and chorus noise on the efficiency of calling in the spring peeper

Many animals use acoustic signals as a means of intra- and inter-specific communication. For example, male anuran amphibians produce advertisement calls to attract females for breeding, and as a territorial signal. The production of acoustic signals can be energetically costly, and the distance over which a signal is effective depends on a range of variables including the location of the caller and receiver, ambient conditions and the habitat through which the sound travels. This paper presents a spatially explicit model of the propagation of an anuran advertisement call across a landscape, using the example of the northern spring peeper Pseudacris crucifer crucifer. The model is used to investigate (a) the effect of habitat, caller position and chorus noise on the effective distance of a call with a frequency of approximately 3 kHz; and (b) the energetics and efficiency of calling at different intensities and from different locations in the landscape. Calling next to still water or from an elevated perch increases, while calling in a chorus decreases, the distance over which a female can distinguish an individual male's call. For a given call intensity and calling rate, a male spring peeper will get the greatest “bang for its energetic buck” if it calls next to still water in the absence of chorus noise. However, when a chorus of spring peepers is gathered at a pond, calling from an elevated position away from the pond (and the chorus noise) will maximise the effective distance of an individual call, although this may entail other costs. The model presented here is the first realistic, interactive mathematical model of the propagation of animal sounds across a landscape, and uses a gis interface to display the effect of habitat and caller position on animal communication. It has applications for both research and teaching, and a copy can be obtained free of charge by contacting the author.

Ichthyophonus-like infection in wild amphibians from Québec, Canada.

Myositis associated with infection by Ichthyophonus-like organisms was diagnosed in 35 of 260 (13%) wild amphibians collected in Quebec, Canada, from 1959 to 1964 (n = 30), and 1992 to 1999 (n = 230). Infection was diagnosed in 17 green frogs Rana clamitans, 9 wood frogs R. sylvatica, 4 red-spotted newts Notophthalmus viridescens, 3 bullfrogs R. catesbeiana, 1 spring peeper Pseudacris crucifer, and 1 pickerel frog R. palustris. The spring peeper and one of the bullfrogs were collected in 1964 from the Mont Saint-Hilaire Biosphere Reserve, indicating long-term presence of the organism. Spores of the organisms invaded striated muscle fibers and were associated with variable degrees of granulomatous and eosinophilic inflammation. Infection was considered fatal in 2 green frogs, 1 wood frog, and 1 red-spotted newt. It was considered potentially significant in 3 additional green frogs in which up to 100% of the fibers of some muscles were replaced by spores associated with a severe granulomatous reaction. Ultrastructural features of Ichthyophonus-like spores included a thick trilaminated wall, a paramural cytoplasm, multiple nuclei, oval mitochondria with short tubulo-vesicular cristae and numerous ribosomes. This report represents 4 new host records and shows that ichthyophonosis is enzootic in amphibians from Quebec.

Organ Metabolism and Cryoprotectant Synthesis during Freezing in Spring Peepers Pseudacris crucifer

The effects of freezing on organ metabolism were monitored over a 36-h time period at -4 C in spring-collected specimens of a freeze-tolerant frog, Pseudacris crucifer. Within 2 min after nucleation, glycogenolysis in liver was activated as indicated by elevated levels of hexose phosphates; and levels of the cryoprotectant, glucose, rose quickly thereafter. Freezing stimulated a 3.3-fold increase in liver glycogen phosphorylase a activity, and a rapid phase of liver glucose production was maintained for at least the first hour of freezing (21 imol ? g wet mass-' h-1), followed by a steady rate of glucose increase of about 3 pmol ? gwm-1 h-1. Final liver glucose levels reached 141 pmol gwm-1 after 36 h. Changes in the concentrations of hexose phosphates and fructose-1,6-bisphosphate in liver indicated that glucose production was promoted by an inhibitory block on glycolysis at the phosphofructokinase reaction. Other organs accumulated the glucose exported by liver and cryoprotectant asccumulation by heart paralleled the rise in liver glucose levels. Liver energetics were not disrupted during early freezing but with prolonged freezing (4-36 h), ATP content fell, ADP and AMP increased, and energy charge, [ATP + ADP/2]/[ATP + ADP + AMP], was reduced from 0.90 in controls to 0.57 after 36 h freezing. Liver metabolism during freezing was supported by fermentative reactions with anaerobic glycolysis leading to lactate and alanine accllmnlation; concomitantly, levels of fermentable-free amino acids (aspartate and glutamate) decreased. Changes in free amino acid patterns in skeletal muscle and heart also indicated a reliance on amino acid fermentation during freezing, but additional increases in the levels of several other amino acids suggested that freezing might also elevate proteolysis. The results show a role for amino acids in anuran freezing survival and demonstrate that the biochemical mechanisms involved in con-

Effects of dehydration on organ metabolism in the frog Pseudacris crucifer: hyperglycemic responses to dehydration mimic freezing-induced cryoprotectant production.

The metabolic effects of evaporative water loss at 5 degrees C were assessed for both fall- and spring-collected spring peepers Pseudacris crucifer. Frogs readily endured the loss of 50% of total body water. During dehydration organ water content was defined with no change in water content in skeletal muscle, gut, and kidney of 50% dehydrated frogs and reduced water content in liver, brain and heart. Dehydration stimulated a rapid and massive increase in liver glucose production. In fall-collected frogs liver glucose rose by 120-fold to 2690 +/- 400 nmol.mg protein-1 or 220 mumol.g ww-1 in 50% dehydrated frogs and glucose in other organs increased by 2.6- to 60-fold. Spring-collected frogs showed the same qualitative response to dehydration although absolute glucose levels were lower, rising maximally by 8.4-fold in liver. Glucose synthesis was supported by glycogenolysis in liver and changes in the levels of glycolytic intermediates in liver indicated that an inhibitory block at the phosphofructokinase locus during desiccation helped to divert hexose phosphates into the production of glucose. Liver energy status (ATP, total adenylates, energy charge) was maintained even after the loss of 35% of total body water but at 50% dehydration all parameters showed a sharp decline; for example, energy charge fell from about 0.85 to 0.42. Severe dehydration also led to an accumulation of lactate in four organs, probably hypoxia-induced due to impaired circulation.(ABSTRACT TRUNCATED AT 250 WORDS)