Pharmacophore-Directed  Retrosynthesis Applied to Bioactive Natural Products Informing Mechanism of Action Studies

Information

  • Research Project
  • 10389199
  • ApplicationId
    10389199
  • Core Project Number
    R35GM134910
  • Full Project Number
    3R35GM134910-02S1
  • Serial Number
    134910
  • FOA Number
    PA-20-272
  • Sub Project Id
  • Project Start Date
    1/1/2020 - 4 years ago
  • Project End Date
    12/31/2024 - a month from now
  • Program Officer Name
    BOND, MICHELLE RUEFFER
  • Budget Start Date
    1/1/2021 - 3 years ago
  • Budget End Date
    12/31/2021 - 2 years ago
  • Fiscal Year
    2021
  • Support Year
    02
  • Suffix
    S1
  • Award Notice Date
    7/12/2021 - 3 years ago
Organizations

Pharmacophore-Directed  Retrosynthesis Applied to Bioactive Natural Products Informing Mechanism of Action Studies

Project Summary/Abstract While ?diversity-oriented,? ?biology-oriented,? and ?analogue-oriented? syntheses have contributed to Wender?s call for ?function-oriented synthesis,? the simultaneous alignment of total synthesis efforts with structure activity relationship (SAR) studies has not been fully realized. This is particularly true with natural products where little to no SAR information exists. Bringing hypotheses regarding a targeted natural product's pharmacophore into the retrosynthetic planning stages of a total synthesis effort would dramatically accelerate the identification of simplified, bioactive derivatives as lead compounds for therapeutic intervention. Our chemical and biological studies of natural products possessing a broad range of cellular effects will be guided by the following inquiry: Can total synthesis efforts, in particular with limited SAR and unknown cellular targets, be more closely aligned to biological studies by targeting designed derivatives possessing a hypothesized pharmacophore during the retrosynthetic planning stages to enable SAR studies to be conducted en route to the natural product? Our study will develop a type of innovative retrosynthetic analysis that more closely aligns total synthesis efforts with concurrent biological studies. We term this strategy ?pharmacophore- directed retrosynthesis? (PDR) to emphasize the importance of considering hypothesized pharmacophores at the retrosynthetic planning stage of a total synthesis effort. This approach will importantly lead to the identification of simplified versions of the natural product with similar potency or potentially new functions in route to the natural product. While this approach increases the challenges of natural product total synthesis beyond important, contemporary goals, including atom-economy, step and redox efficiency, and protecting group avoidance, significantly it will greatly accelerate harvesting of the vast information content of natural products for basic cell biology and medicine. This strategy begins with a hypothesized pharmacophore for a bioactive natural product which informs and directs the retrosynthetic strategy. Stepwise, methodical introduction of complexity to the hypothesized pharmacophore enables concurrent SAR data collection which in turn informs cellular probe synthesis. A fruitful group of ongoing collaborators, including molecular, cell, and cancer biologists and chemical biologists will utilize our natural product-based probes to contribute to fundamental advances in cell biology. Overall, our proposed synthetic studies, combined with collaborative biological studies, will both open new avenues for novel therapeutics, and contribute to a greater understanding of basic cellular mechanisms involved in human disease including bacterial infection, inflammation, cardiovascular, Alzheimer?s disease, and cancer. The proposed research will demonstrate the importance of closely engaging total synthesis efforts with biological studies of natural products at the retrosynthetic planning stages. We will demonstrate the utility of PDR for reverse chemical genetic explorations of natural products towards identification of new drug leads and novel cellular targets critical to uncovering new avenues to impact human health.

IC Name
NATIONAL INSTITUTE OF GENERAL MEDICAL SCIENCES
  • Activity
    R35
  • Administering IC
    GM
  • Application Type
    3
  • Direct Cost Amount
    99788
  • Indirect Cost Amount
  • Total Cost
    99788
  • Sub Project Total Cost
  • ARRA Funded
    False
  • CFDA Code
    859
  • Ed Inst. Type
  • Funding ICs
    NIGMS:99788\
  • Funding Mechanism
    Non-SBIR/STTR RPGs
  • Study Section
  • Study Section Name
  • Organization Name
    BAYLOR UNIVERSITY
  • Organization Department
  • Organization DUNS
    007516735
  • Organization City
    WACO
  • Organization State
    TX
  • Organization Country
    UNITED STATES
  • Organization Zip Code
    767987360
  • Organization District
    UNITED STATES