Detection of pathogenic Leptospira spp. in herpetofauna in Central Appalachia.

Leptospirosis is a water borne zoonotic disease of global significance that is caused by pathogenic species of the genus Leptospira. Pathogenic leptospires live in the kidneys of reservoir or infected animals and are shed in their urine contaminating water, soil, etc. Rodents are considered the primary reservoir of leptospirosis, but little is known about the role of herpetofauna (non-avian reptiles and amphibians) in the epidemiology of the disease. To address this, various species of amphibians and reptiles in the Cumberland Gap Region of the Central Appalachia were screened for the presence of Leptospira spp. Kidneys harvested from of a total of 116 amphibians and reptiles belonging to seven species of snakes, seven species of salamanders, seven species of frogs/toads, seven species of turtles and one species of lizards were tested using a highly specific TaqMan based qPCR that targets lipl32 gene of pathogenic Leptospira spp. Overall, 15 of the tested 116 amphibians and reptiles were positive (12.9%; 95% CI: 7.4%-20.4%). Of the 101 amphibians, 11 were positive (10.9%; 95% CI: 5.6%-18.7%), and 4 of the 15 reptiles tested positive (26.7%; 95% CI: 7.8%-55.1%). The amplified gene fragments of lipl32 from qPCR positive kidneys were sequenced and found to be identical with known pathogenic Leptospira spp. These results suggest that although the proportion of reptiles and amphibians transmitting pathogenic Leptospira spp. within the environment may be low as compared to rodents, they pose a risk to other susceptible hosts that share their habitats and may have role in maintaining a baseline infection in the environment.

Predicting antibacterial activity from snake venom proteomes.

The continued evolution of antibiotic resistance has increased the urgency for new antibiotic development, leading to exploration of non-traditional sources. In particular, snake venom has garnered attention for its potent antibacterial properties. Numerous studies describing snake venom proteomic composition as well as antibiotic efficacy have created an opportunity to synthesize relationships between venom proteomes and their antibacterial properties. Using literature reported values from peer-reviewed studies, our study generated models to predict efficacy given venom protein family composition, snake taxonomic family, bacterial Gram stain, bacterial morphology, and bacterial respiration strategy. We then applied our predictive models to untested snake species with known venom proteomic compositions. Overall, our results provide potential protein families that serve as accurate predictors of efficacy as well as promising organisms in terms of antibacterial properties of venom. The results from this study suggest potential future research trajectories for antibacterial properties in snake venom by offering hypotheses for a variety of taxa.

Analysis of snake venom composition and antimicrobial activity.

With the threat of a post-antibiotic era looming, the search for new and effective antibiotics from novel sources is imperative. Not only has crude snake venom been shown to be effective, but specific components within the venoms, such as Phospholipase A2s and l-amino acid oxidases have been isolated and demonstrated to be effective as well. Despite numerous studies being completed on snake venoms, there is a heavy bias towards utilizing the venoms from the highly toxic Elapidae and Viperidae species. Very few studies have been conducted on the less toxic, but taxonomically more diverse, Colubridae. Furthermore, an extensive review of the literature examining the efficacy and potential specificity of these venoms has not been completed. Therefore, the aims of this study were to elucidate any similarities in snake venoms as well as investigate the efficacy of snake venom antimicrobial properties towards morphologically and metabolically diverse microbial classes and the prevalence of snake species with antimicrobial properties within each snake family. The results indicate that snake venoms and their isolated components are powerful antimicrobial agents but vary in efficacy towards different microbial classes. Furthermore, due to similarities in venom composition, and limited preliminary studies, the less toxic Colubridae family may be a fruitful area of research to find novel antimicrobial agents that are less harmful to humans.