Assessing animal exposure to urticating caterpillar hairs and developing management strategies to reduce the consequence of foetal abortion in mares. Equine Amnionitis and Foetal Loss (EAFL) accounts for about a third of mares aborting in thoroughbred horse studs in southern Queensland, New South Wales and Victoria. Previous studies have shown that processionary caterpillars and their irritating setae (hairs) can cause EAFL. This project aims to determine the likelihood that other caterpillar sp ....Assessing animal exposure to urticating caterpillar hairs and developing management strategies to reduce the consequence of foetal abortion in mares. Equine Amnionitis and Foetal Loss (EAFL) accounts for about a third of mares aborting in thoroughbred horse studs in southern Queensland, New South Wales and Victoria. Previous studies have shown that processionary caterpillars and their irritating setae (hairs) can cause EAFL. This project aims to determine the likelihood that other caterpillar species are involved based on hair morphology and a surrogate model system. A full risk assessment of the exposure of mares to these hairs in situ will be undertaken, based on the ecology and biology of the species. Outcomes include a management strategy for EAFL-causing insects and a reduction of EAFL within the industry.Read moreRead less
New antiparasitics to protect Australian livestock. There is an urgent need for new antiparasitics to treat multi-drug resistant livestock infections. This project aims to explore the bacteria and fungi present in the microbiomes of heavily infected sheep faeces and pastures, challenging them with environmental cues, including those from associated parasites, to stimulate production of defensive chemicals hidden deep within their genomes. Enabled by an integrated pipeline of high throughput anal ....New antiparasitics to protect Australian livestock. There is an urgent need for new antiparasitics to treat multi-drug resistant livestock infections. This project aims to explore the bacteria and fungi present in the microbiomes of heavily infected sheep faeces and pastures, challenging them with environmental cues, including those from associated parasites, to stimulate production of defensive chemicals hidden deep within their genomes. Enabled by an integrated pipeline of high throughput analytical cultivation, molecular networking, and chemical and biological analyses, expected outcomes include an enhanced ability to explore and exploit valuable chemistry hidden within microbial genomes, leading to the discovery of new classes of natural antiparasitic to safeguard livestock.
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