Project description:Amphibian mast cells: barriers to deadly chytrid fungus infections

Project description:Amphibian populations around the world are threatened by an emerging infectious pathogen, the chytrid fungus Batrachochytrium dendrobatidis (Bd). How can a fungal skin infection kill such a broad range of amphibian hosts? And why are certain species particularly susceptible to the impacts of Bd? Here we use a genomics approach to understand the genetic response of multiple susceptible frog species to Bd infection. We characterize the transcriptomes of two closely-related endangered frog species (Rana muscosa and Rana sierrae) and analyze whole genome expression profiles from frogs in controlled Bd-infection experiments. We integrate the Rana results with a comparable dataset from a more distantly-related susceptible species (Silurana tropicalis). We demonstrate that Bd-infected frogs show massive disruption of skin function and show no evidence of a robust immune response. The genetic response to infection is shared across the focal susceptible species, suggesting a common effect of Bd on susceptible frogs.

Project description:Emerging infectious diseases are of great concern for both wildlife and humans. Several highly virulent fungal pathogens have recently been discovered in natural populations, highlighting the need for a better understanding of fungal-vertebrate host-pathogen interactions. Because most fungal pathogens are not fatal in the absence of other predisposing conditions, host-pathogen dynamics for deadly fungal pathogens are of particular interest. The chytrid fungus Batrachochytrium dendrobatidis (hereafter Bd) infects hundreds of species of frogs in the wild. It is found worldwide and is a significant contributor to the current global amphibian decline. However, the mechanism by which Bd causes death in amphibians, and the response of the host to Bd infection, remain largely unknown. Here we use whole-genome microarrays to monitor the transcriptional responses to Bd infection in the model frog species, Silurana (Xenopus) tropicalis, which is susceptible to chytridiomycosis. To elucidate the immune response to Bd and evaluate the physiological effects of chytridiomycosis, we measured gene expression changes in several tissues (liver, skin, spleen) following exposure to Bd. We detected a strong transcriptional response for genes involved in physiological processes that can help explain some clinical symptoms of chytridiomycosis at the organismal level. However, we detected surprisingly little evidence of an immune response to Bd exposure, suggesting that this susceptible species may not be mounting efficient innate and adaptive immune responses against Bd. The weak immune response may be partially explained by the thermal conditions of the experiment, which were optimal for Bd growth. However, many immune genes exhibited decreased expression in Bd-exposed frogs compared to control frogs, suggesting a more complex effect of Bd on the immune system than simple temperature-mediated immune suppression. This study generates important baseline data for ongoing efforts to understand differences in response to Bd between susceptible and resistant frog species and the effects of chytridiomycosis in natural populations.

Project description:Amphibian populations around the world are threatened by an emerging infectious pathogen, the chytrid fungus Batrachochytrium dendrobatidis (Bd). How can a fungal skin infection kill such a broad range of amphibian hosts? And why are certain species particularly susceptible to the impacts of Bd? Here we use a genomics approach to understand the genetic response of multiple susceptible frog species to Bd infection. We characterize the transcriptomes of two closely-related endangered frog species (Rana muscosa and Rana sierrae) and analyze whole genome expression profiles from frogs in controlled Bd-infection experiments. We integrate the Rana results with a comparable dataset from a more distantly-related susceptible species (Silurana tropicalis). We demonstrate that Bd-infected frogs show massive disruption of skin function and show no evidence of a robust immune response. The genetic response to infection is shared across the focal susceptible species, suggesting a common effect of Bd on susceptible frogs. A total of five (12-plex) chips were analyzed from 60 samples comprising 2 conditions (control and infected), 3 tissues (skin, liver and spleen) and 2 timepoints (early and late). Three biological replicates were used for each condition and tissue at each time point. Twentyfour arrays were analyzed for skin samples, 24 for liver, and 12 for spleen. The same dye, Cy5, was used for all samples.

Project description:Genome-Wide Transcriptional Response of Silurana (Xenopus) tropicalis to Infection with the Deadly Chytrid Fungus

Project description:Only skin deep: shared genetic response to the deadly chytrid fungus in susceptible frog species

Project description:FrogCap: A modular sequence capture probe set for phylogenomics and population genetics for all frogs, assessed across multiple phylogenetic scales

Project description:Comprehensive RNA-seq experiments to measure the expression of homoeologs across different tissues, as a part of the Xenopus laevis genome project. This work is funded by Agency Japanese Ministry of Education, Culture, Sports, Science and Technology (MEXT; "Genome Science" Grant ID 221S0002). Collect mRNA from whole tissue; two female frogs were used as donors for most tissues (Taira dataset for one frog, Ueno dataset for the other frog); testis samples were collected from two male frogs (sibling of two female donors)

Project description:Along with the prevalence of edible frog farming in China, the outbreak of a deadly infectious frog diseased, called frog meningitis (or cataracts and torticollis), has increased in frequency and geographical range dramatically. More than 10 bacterial species, belonging to 8 genera, has been reported as its potential pathogens. Diseased frogs typically manifest as torticollis, cataracts, edema and finally death, resulting in huge economic loss. Currently, the pathogenesis of this disease has not been investigated systematically. Here, we summarized the pathological stages of infected black-spotted frogs (Pelophylax nigromaculata) in Sichuan province according to their symptoms, typically progressing of pathological stage with only torticollis to stage with both torticollis and cataracts. On the basis, we analyzed the pathogenesis by a combination of comparative environmental analysis, microbiomics and transcriptomics. Results showed that more severely infected frog ponds tended to have lower water alkalinity. Elizabethkingia miricola was the only bacteria, whose abundance was positively correlated with the disease degree, and it has absolute dominance in the eyeball and brain of some torticollis-cataracts frogs. E. miricola and several other bacterial species, which belonged to pathogenic genera of meningitis, might be constitutively existed in the resident microbiome in frogs or their environment. Activations of infectious processes and immune responses related pathways were the major difference between health and diseased frogs at transcriptional level. Despite transcriptional activation of immunoglobulins was observed in both torticollis-only and torticollis-cataracts frogs, transcriptional activation of innate immune system (including MHC, toll-like receptor, and cathelicidins) in brain, inflammation system (including interleukins and receptors) in brain, and acute phase proteins (including transferrins and fibrinogens) in both liver and brain was only observed in torticollis-cataracts frogs. Activation of inflammation and the resulting higher vascular permeability in torticollis-cataracts frogs could explain the severe brain infection, cooccurrence of torticollis and cataracts, and systemic edema in torticollis-cataracts frogs. In addition, meningitis could also result in reduction in energy production in liver, and this was more severe in torticollis-cataracts frogs. In conclusion, our results suggested environment might have a role in susceptibility of frog meningitis. E. miricola was the most likely pathogen of meningitis of black-spotted frogs in Sichuan. Refer to the pathogenesis of human meningitis, excessive inflammation likely played a critical role in the progress of frog meningitis, and its resulted sepsis and organ failure might be the direct cause of infected frogs.

Project description:Skin bacterial community 16S amplicons of 3 species of Panamanian frogs exposed to a chytrid fungus