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Natural Product HCV Drugs from Rare Plant-Microbe Interactions

$306,422R01FY2013ATNIH

University Of Mississippi, University MS

Investigators

Linked publications & trials

Abstract

The key objective of this project involves the exploration of US rare and endangered plants and their unique host-microbiome community. These communities will be studied for their biosynthesis and production of new classes of natural products (NPs) HCV drug leads with unique MOAs. The project involves a well established collaborative relationship with the laboratories of Prof Mark Hamann and at the University of Mississippi and Tony Whitaker with RFS Pharma and Raymond Schinazi at Emory University/Atlanta VA. The collective expertise provides a unique opportunity to explore new sources for treatments for HCV which are resistant to current forms of treatment. The specific aims of this program include: 1. A collection and phylogenetic analysis of 100 endangered plant associated bacteria and fungi strains each year. Phylogenetically diverse and unique US endangered plant species (20) will be evaluated for bacteria and fungi which inhibit HCV. This will provide 500 unique bacteria and fungi over the course of the five year project period. 2. Innovative epigenetic tools will be applied to stimulate production of secondary metabolites from silent genes. These will include regulatory tools available commercially as well as those derived from the host endangered plant itself. Each new strain will be subjected to 10 or more epigenetic tools. Highly sensitive HPLC with UV-TOF-ELS detection and small volume NMR will be utilized to evaluate NP production from genes silent under standard culture conditions. 3. A unique HCV real time PCR assay is featured in this grant application as a primary screen to identify extracts obtained from Aim 2 with HCV selectivity for fractionation in aim 4. 4. Active leads from Aim 3 will be purified using HPLC with MS, UV and ELSD detection. Repeated bioassays using real time PCR will be completed until HCV selective metabolites are generated. Natural product structures will be assigned using integrated NMR, HPLC-MS, UV, IR and X-ray crystallographic analysis.

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