Carrie K. Vance

Applied reproductive technologies and genetic resource banking for amphibian conservation

As amphibian populations continue to decline, both government and non-government organisations are establishing captive assurance colonies to secure populations deemed at risk of extinction if left in the wild. For the most part, little is known about the nutritional ecology, reproductive biology or husbandry needs of the animals placed into captive breeding programs. Because of this lack of knowledge, conservation biologists are currently facing the difficult task of maintaining and reproducing these species. Academic and zoo scientists are beginning to examine different technologies for maintaining the genetic diversity of founder populations brought out of the wild before the animals become extinct from rapidly spreading epizootic diseases. One such technology is genetic resource banking and applied reproductive technologies for species that are difficult to reproduce reliably in captivity. Significant advances have been made in the last decade for amphibian assisted reproduction including the use of exogenous hormones for induction of spermiation and ovulation, in vitro fertilisation, short-term cold storage of gametes and long-term cryopreservation of spermatozoa. These scientific breakthroughs for a select few species will no doubt serve as models for future assisted breeding protocols and the increasing number of amphibians requiring conservation intervention. However, the development of specialised assisted breeding protocols that can be applied to many different families of amphibians will likely require species-specific modifications considering their wide range of reproductive modes. The purpose of this review is to summarise the current state of knowledge in the area of assisted reproduction technologies and gene banking for the conservation of amphibians.

Fecal estrogen, progestagen and glucocorticoid metabolites during the estrous cycle and pregnancy in the giant anteater (Myrmecophaga tridactyla): evidence for delayed implantation

BackgroundDeclining numbers of wild giant anteaters highlight the importance of sustainable captive populations. Unfortunately, captive reproductive management is limited by the lack of external physical indicators of female reproductive status and the aggressive behavior of males. We examined the endocrinology of the estrous cycle and pregnancy, and whether delayed implantation is a gestational strategy for giant anteaters as described for other xenarthrans.MethodsFeces were collected from seven captive females 3–5 times weekly and mating was recorded. Concentrations of estrogen (estrone–glucuronide, E1, and estradiol–17β, E2), progestagen (20–oxo–progestagens, P4), and glucocorticoid (GC) metabolites were examined in fecal extracts by enzyme immunoassay.ResultsEstrous cycles for nulliparous females (6 cycles, n = 2) compared to the multiparous female (6 cycles, n = 1) were shorter (47.3 +/− 4.3 days versus 62.5 +/− 2.6 days) with relatively lower luteal phase concentrations of P4 (49.4 +/− 2.9 ng/g versus 136.8 +/− 1.8 ng/g). The four remaining females had unclear ovarian activity: two females exhibited apparent luteal activity but unclear fluctuations in estrogens, while the other two females had parallel fecal P4 and estrogens concentrations. Pregnancy ranged 171–183 days with females returning to estrus post–partum as early as 60 days (n = 3, 1.8-4 years of age at mating). Delayed implantation was indicated by a biphasic elevation in fecal P4 metabolites: the initial 4–fold increase occurred for 81–105 days and was followed by a 26–fold secondary rise in P4 metabolites lasting 66–94 days prior to parturition. Fecal GC was correlated with fecal estrogens and greatest during estrus, late pregnancy, and six days prior to parturition (estrous cycle GC, 14.4-62.8 ng/g; pregnancy GC, 13.6-232.7 ng/g).ConclusionsEstrous cycles of giant anteaters occurred year–round, but were shorter and more intermittent in younger nulliparous animals compared to a multiparous female. A pronounced elevation in fecal P4, estrogen, and GC occurred during late gestation after an initial post-mating delay providing evidence for delayed implantation. Adrenocorticoid activity indicated impending parturition. Differences in estrous cycle characteristics with age and the protracted but variable gestation length must be considered to improve reproductive success and neonatal survival in giant anteaters.

A comparison of human chorionic gonadotropin and luteinizing hormone releasing hormone on the induction of spermiation and amplexus in the American toad (Anaxyrus americanus)

BackgroundCaptive breeding programs for endangered amphibian species often utilize exogenous hormones for species that are difficult to breed. The purpose of our study was to compare the efficacy of two different hormones at various concentrations on sperm production, quantity and quality over time in order to optimize assisted breeding.MethodsMale American toads (Anaxyrus americanus) were divided into three separate treatment groups, with animals in each group rotated through different concentrations of luteinizing hormone releasing hormone analog (LHRH; 0.1, 1.0, 4.0 and 32 micrograms/toad), human chorionic gonadotropin (hCG; 50, 100, 200, and 300 IU), or the control over 24 hours. We evaluated the number of males that respond by producing spermic urine, the sperm concentration, percent motility, and quality of forward progression. We also evaluated the effects of hCG and LHRH on reproductive behavior as assessed by amplexus. Data were analyzed using the Generalized Estimating Equations incorporating repeated measures over time and including the main effects of treatment and time, and the treatment by time interaction.ResultsThe hormone hCG was significantly more effective at stimulating spermiation in male Anaxyrus americanus than LHRH and showed a dose-dependent response in the number of animals producing sperm. At the most effective hCG dose (300 IU), 100% of the male toads produced sperm, compared to only 35% for the best LHRH dose tested (4.0 micrograms). In addition to having a greater number of responders (P < 0.05), the 300 IU hCG treatment group had a much higher average sperm concentration (P < 0.05) than the treatment group receiving 4.0 micrograms LHRH. In contrast, these two treatments did not result in significant differences in sperm motility or quality of forward progressive motility. However, more males went into amplexus when treated with LHRH vs. hCG (90% vs. 75%) by nine hours post-administration.ConclusionThere is a clear dichotomy between the two hormones’ physiological responses on gamete production and stimulation of amplexus. Understanding how these two hormones influence physiology and reproductive behaviors in amphibians will have direct bearing on establishing similar breeding protocols for endangered species.

Fecal Near Infrared Spectroscopy to Discriminate Physiological Status in Giant Pandas

Giant panda (Ailuropoda melanoleuca) monitoring and research often require accurate estimates of population size and density. However, obtaining these estimates has been challenging. Innovative technologies, such as fecal near infrared reflectance spectroscopy (FNIRS), may be used to differentiate between sex, age class, and reproductive status as has been shown for several other species. The objective of this study was to determine if FNIRS could be similarly used for giant panda physiological discriminations. Based on samples from captive animals in four U.S. zoos, FNIRS calibrations correctly identified 78% of samples from adult males, 81% from adult females, 85% from adults, 89% from juveniles, 75% from pregnant and 70% from non-pregnant females. However, diet had an impact on the success of the calibrations. When diet was controlled for plant part such that “leaf only” feces were evaluated, FNIRS calibrations correctly identified 93% of samples from adult males and 95% from adult females. These data show that FNIRS has the potential to differentiate between the sex, age class, and reproductive status in the giant panda and may be applicable for surveying wild populations.

Review: Near infrared spectroscopy in wildlife and biodiversity

Near infrared (NIR) spectroscopy has been used to answer a wide variety of questions in wildlife and biodiversity research. Whereas agricultural systems and manufacturing seek to limit variation in production systems, wildlife and biodiversity research must embrace it. Variation amongst individuals is the material on which natural selection operates and NIR spectroscopy provides a means to catalogue this variation and to use it in broader ecological and evolutionary analyses and for practical conservation outcomes. In this review we describe how NIR spectroscopy has been applied in wildlife and biodiversity research to obtain data that we could not obtain otherwise. Here we describe a range of applications for which NIR spectroscopy has been applied to questions in taxonomy, physiology, habitat evaluation and population monitoring and highlight new approaches that will allow NIR spectroscopy to be used more widely in wildlife and ecological studies.

Nutrient and mineral composition during shoot growth in seven species of Phyllostachys and Pseudosasa bamboo consumed by giant panda.

During the annual period of bamboo shoot growth in spring, free-ranging giant pandas feed almost exclusively on the shoots while ignoring the leaves and full- height culm. Little is known about the nutritional changes that occur during bamboo shoot growth, if nutritional changes differ among species, or how these changes might influence forage selection. Our objective was to examine the nutrient and mineral composition during three phases of shoot growth (<60, 90-150 and >180 cm) for seven species of bamboo (Phyllostachys (P.) aurea, P. aureosulcata, P. bissetii, P. glauca, P. nuda, P. rubromarginata, Pseudosasa japonica) fed to captive giant pandas at the Memphis Zoo. Total dietary fiber content of bamboo shoots increased (p < 0.0001) from an overall species average of 61% dry matter (DM) at < 60 cm to 75% DM at shoot heights > 180 cm, while crude protein, fat and ash exhibited significant declines (p < 0.05). Phyllostachys nuda had the overall greatest (p = 0.007) crude protein (21% DM) and fat (4% DM) content, and lowest overall total fibre (61% DM) content compared to the other species examined. In contrast, Pseudosasa japonica had the overall lowest crude protein and fat, and relatively higher fibre content (9%, 3% and 74% respectively). Concentrations of Zn and Fe were highest in shoots <60 cm (10-50 μg/g DM) and decreased (p < 0.05) during growth in all species examined. Concentrations of Ca, Cu, Mn, Na and K varied among species and were largely unaffected by growth stage. Due to their higher concentrations of nutrients and lower fibre content in comparison to culm and leaf, bamboo shoots should be a major component of captive giant panda diets when available.

Near infrared spectroscopy applications in amphibian ecology and conservation: gender and species identification

Introduction C onservation biology and ecological monitoring are two emerging frontiers for near infrared (NIR) reflectance spectroscopy in which both simple and complex questions may possibly be addressed. We use NIR both in situ and ex situ to assess animal physiology; specifically, our applications are to aid conservation efforts that are focused on demography, reproduction or disease control for critically endangered populations. The rapid data collection, minimal sample preparation and immediate results afforded by NIR after calibration make it an especially attractive technology for field work in conservation ecology in which specimens of endangered species are not “collectable” for study and little may be known about them. Here, we discuss how NIR can facilitate conservation efforts to save “at risk” amphibian species from extinction.

116 INCORPORATION AND DEVELOPMENTAL TOXICITY OF QUANTUM DOT NANOPARTICLES IN AMPHIBIAN LARVAE

The use of nanoparticles both commercially and pharmaceutically has increased over the past decade, including fluorescent quantum dot nanoparticles (QD) in biochemical research for in vivo imaging. Previous studies have reported the toxic effects of nanoparticles, but their effects on larval metamorphosis and animal development and growth have not been thoroughly examined. Additionally, the method of uptake of nanoparticles by larval systems is unknown. Amphibian larvae are an ideal model for assessing toxicity because of their sensitivity to environmental contaminants and rapid and easily observable developmental stages. We used Anaxyrus fowleri tadpoles to investigate QD (≤ 25nm diameter) integration into larvae and possible deleterious effects on their growth and development. Tadpoles (A. fowleri; n=5/group) were placed in 24-well plates containing 1mL of distilled water and increasing concentrations of QD (0, 1, and 2 nM) 72h post-hatch. The fluorescence emission of QD in wells was detected at various time points (1, 2, 24, 48, and 72h) using the in vivo imaging system (IVIS). A subset of tadpoles was killed (MS-222) and sectioned for histopathology. Remaining tadpoles were monitored throughout development. Fluorescence emission of QD in sectioned tadpoles was visualised using an EVOS Cell Imaging System. Developmental metrics of living tadpoles were recorded until metamorphosis. Fluorescence intensity between controls and dosage groups were analysed by ANOVA-1, followed by Students l.s.d. test to evaluate the effects of QD concentration and exposure time. The threshold of significance was P<0.05. The rate of incorporation of QD into tadpoles was determined using the equation y=C+Ao*2(-x/t1/2), where t1/2 is the half-life of QD remaining in solution. The IVIS imaging revealed a rapid decrease of QD fluorescence (total flux) signals from the aqueous tadpole environment. Decreases in fluorescence occurred within 1h post-exposure and appeared dose and time dependent, with signal nearly gone within 48h. Half-life of total flux (time necessary for tadpoles to absorb half of the QD in solution) is 20.75h (R2=0.92) and 2.54h (R2=0.96) for 1nm and 2nm QD in solution, respectively. The EVOS imaging revealed integration of QD and localization into tadpole tissues. Fluorescence was exclusively found within the mouth, gills, and sections of the intestinal lumen of exposed tadpoles within the first hour. Dose-dependent increases in fluorescence within tissue were observed at each time-point. No signal was observed in controls. In remaining live tadpoles, QD treated tadpoles were smaller in size [t(34)=2.35, P=0.024] than controls. Findings reveal that (1) A. fowleri tadpoles integrate and accumulate nanoparticles, without detectable excretion within 72h post-exposure, and (2) nanoparticles impede normal tadpole development. Ongoing studies are determining the effects of QD exposure on complete tadpole metamorphosis.

Phenological changes in bamboo carbohydrates explain the preference for culm over leaves by giant pandas (Ailuropoda melanoleuca) during spring

Seasonal changes in the foodscape force herbivores to select different plant species or plant parts to meet nutritional requirements. We examined whether the search for calorie-rich carbohydrates explained giant panda’s selection for bamboo culm over leaves during spring. Leaves and culms were collected from four Phyllostachys bamboos (P. aurea, P. aureosulcata, P. glauca, and P. nuda) once per month over 18–27 months. Monthly changes in annual plant part nutrients were examined, and compared to seasonal foraging behaviors of captive giant pandas. Although total fiber was greater (p<0.0001) in culm (85.6 ± 0.5%) than leaves (55.3 ± 0.4%) throughout the year, culm fiber was at its lowest in spring (79–85%) when culm selection by giant pandas exceeded 70% of their overall diet. Culm starch also was greatest (p = 0.044) during spring (5.5 ± 1.1%) and 2.5-fold the percentage of starch in leaves (2.2 ± 0.6%). The free sugars in spring culm consisted of a high proportion of glucose (35%) and fructose (47%), whereas sucrose made up 42% of the total free sugar content of spring leaves. Bound sugars in culm consisted of 60% glucose and 38% xylose likely representative of hemicellulose. The concentrations of bound sugars (hemicelluloses) in spring culms (543.7 ± 13.0 mg/g) was greater (p<0.001) than in leaves (373.0 ± 14.8 mg/g). These data help explain a long-standing question in giant panda foraging ecology: why consume the plant part with the lowest protein and fat during the energetically intensive spring breeding season? Giant pandas likely prefer spring culm that contains abundant mono- and polysaccharides made more bioavailable as a result of reduced fiber content. These data suggest that phenological changes in bamboo plant part nutrition drive foraging decisions by giant pandas.

Giant panda physiology from faeces: sampling strategies optimised for a different kind of question

E ffective conservation management of endangered species requires a clear and up-to-date understanding of the population dynamics in the wild. This involves monitoring population size, sex ratio, age distribution and behavioural dispersal patterns. Faecal near infrared reflectance spectroscopy (FNIRS) is being developed for ecological monitoring of wildlife by asking questions about physiological status such as gender, reproductive state, disease and identity for these types of population surveys. Application of FNIRS in situ first requires that physiological characteristics are reflected in faecal matter and can be determined using spectroscopy, and second that these traits can be differentiated in minimally-processed samples. We are interested in the feasibility of FNIRS ecological monitoring specifically for endangered species that are otherwise difficult to track and or document. As such, we have focused on the flagship species of conservation, the giant panda (Ailuropoda melanoleuca).