Publications
Found 32 results
Author Title [ Type
Filters: First Letter Of Last Name is H [Clear All Filters]
Host-pathogen dynamics of amphibian chytridiomycosis: the role of the skin microbiome in health and disease. Fungal diseases: an emerging challenge to human, animal, and plant health. :342–355.
.
2011. Using multi- response models to investigate pathogen coinfections across scales: Insights from emerging diseases of amphibians. Methods Ecol Evol.. 9:1120.
.
2017. Treatment of amphibians infected with chytrid fungus: learning from failed trials with itraconazole, antimicrobial peptides, bacteria, and heat therapy. Diseases of aquatic organisms. 98:11–25.
.
2012. Symbiotic bacteria contribute to innate immune defenses of the threatened mountain yellow-legged frog, Rana muscosa. Biological conservation. 138:390–398.
.
2007. Stabilizing effects in spatial parasitoid–host and predator–prey models: a review. Theoretical population biology. 65:299–315.
.
2004. Skin microbes on frogs prevent morbidity and mortality caused by a lethal skin fungus. The ISME journal. 3:818–824.
.
2009. Risk of vector tick exposure initially increases, then declines through time in response to wildfire in California. Ecosphere. 9(5):Articlee02227.
.
2018. Review. NATURE. 484:12.
.
2012. Recruitment Drives Spatial Variation in Recovery Rates of Resilient Coral Reefs. Scientific Reports. 8(7338)
.
2018. Probiotics Modulate a Novel Amphibian Skin Defense Peptide That Is Antifungal and Facilitates Growth of Antifungal Bacteria.. Microb Ecol.
.
2019. Probiotics modulate a novel amphibian skin defense peptide that is antifungal and facilitates growth of antifungal bacteria. Microbial Ecology. 79(1)
.
2020. Probiotics Modulate a Novel Amphibian Skin Defense Peptide That Is Antifungal and Facilitates Growth of Antifungal Bacteria.. Microb Ecol.
.
2019. Probiotics modulate a novel amphibian skin defense peptide that is antifungal and facilitates growth of antifungal bacteria. Microbial Ecology. 79(1)
.
2020. PREDATORS, PARASITOIDS, AND PATHOGENS: A CROSS-CUTTING EXAMINATION OF INTRAGUILD PREDATION THEORY. Ecology. 88:2681–2688.
.
2007. Of poisons and parasites: the defensive role of tetrodotoxin against infections in newts. Journal of Animal Ecology. DOI: 10.1111/1365-2656.12816
.
2018. The novel and endemic pathogen hypotheses: competing explanations for the origin of emerging infectious diseases of wildlife. Conservation Biology. 19:1441–1448.
.
2005. Modeling Virus Coinfection to Inform Management of Maize Lethal Necrosis in Kenya. Phytopathology. 107(10):1095-1108.
.
2017. Mechanisms underlying host persistence following amphibian disease emergence determine appropriate management strategies. Ecology Letters. 24(1)
.
2021. Macroalgae size refuge from herbivory promotes alternative stable states on coral reefs.. PLoS One. 13(9):e0202273.
.
2018. Lyme disease risk in southern California: abiotic and environmental drivers of Ixodes pacificus (Acari: Ixodidae) density and infection prevalence with Borrelia burgdorferi. Parasites & Vectors. 10(1):DOI10.1186/s13071-016-1938-y.
.
2017. The influence of landscape and environmental factors on ranavirus epidemiology in amphibian assemblage. Freshwater Biology. 63
.
2018. Inferring colonization processes from population dynamics in spatially structured predator–prey systems. Ecology. 81:3350–3361.
.
2000. Habitat structure and population persistence in an experimental community. Nature. 412:538–543.
.
2001. Emerging fungal threats to animal, plant and ecosystem health. Nature. 484:186–194.
.
2012. Effect of microenvironment on development of a gall midge. Environmental entomology. 36:441–450.
.
2007.