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The Mode of Action and Possible Target of Artemisinin

The Mode of Action and Possible Target of Artemisinin. Mike Van Linn Chemistry 496 23 April 2004. Outline. Introduction Malaria Artemisinin Rationale for Research Modes of Action Iron-Oxo route Epoxidation reactions Alkylation reactions The Target of Artemisinin. Introduction.

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The Mode of Action and Possible Target of Artemisinin

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  1. The Mode of Action and Possible Targetof Artemisinin Mike Van Linn Chemistry 496 23 April 2004

  2. Outline • Introduction • Malaria • Artemisinin • Rationale for Research • Modes of Action • Iron-Oxo route • Epoxidation reactions • Alkylation reactions • The Target of Artemisinin

  3. Introduction • Malaria • Four species of Plasmodium • Infects 200 million people annually • 1 million lethal • Resistance to current drugs

  4. Introduction • Artemisinin • Natural product extracted from sweet wormwood, Artemisia annua • Used by Chinese for over 2000 years • A. absinthium used to make absinthe

  5. Rationale for Research • Anti-malarial Activity of Artemisinin • Artemisinin Derivatives • Used currently for life threatening cases

  6. Rationale for Research • Anti-malarial Activity of Artemisinin • Artemisinin Derivatives • Used currently for life threatening cases • Drug Resistance of Plasmodium • Malaria spreading • Synthesis of new drugs

  7. Possible Modes of Action • Iron-Oxo Route • Epoxidation Reactions • Alkylation Reactions

  8. Iron-Oxo Route • Donation of Oxygen from Peroxide Bridge to Iron • Generate Fe(IV)=O • No Support from Raman Resonance Data • Signal/Noise < 2 • Should be ~10 or 20

  9. Epoxidation Reactions MnIITPP or FeCl2 NO EPOXIDE FORMATION + ARTEMISININ OR MnIITPP or FeCl2 + Na+-OCl EPOXIDE FORMATION

  10. Robert, et al

  11. Cazelles, et al

  12. Cazelles, et al

  13. 1,5 H Shift Possible??? • Critical Distance Calculated to be 2.1Å • Exceeded in Stable Conformation • Boat-like Conformation (High energy state) • Houk

  14. Comparing Route 1 and 2 • Route 1 Dominant to Route 2 • 90/10 ratio from isolated products • Artemisinin + MnIITPP • 1,5 H shift? • Route 1 Biologically Active • Route 2 Inactive • Stereochemistry Effecting Alkylation

  15. Robert, et al Cazelles, et al

  16. Mode of Action • Route 1 Dominant • Alkyl radical formation from reduction of peroxide bridge • Derivatives Used • Observe correlation of alkylating ability to drug activity • Alkylate MnIITPP Pharm. active

  17. The Target • Alkylation of Heme within Infected Erythrocytes (RBC’s) • Free heme in food vacuole of erythrocyte • Cleavage of peroxide bond • Alkylation of heme or specific parasite proteins can occur • Too General…

  18. The Target, More Specifically • Sarco/Endoplasmic Reticulum Ca2+-ATPase (SERCA) Enzyme • PfATP6 gene sequence • Testing the hypothesis • Heme Not Required? • Free heme blocked with Ro 40-4388 protease inhibitor • Localized in the Food Vacuole? • Fluorescent labeled artemisinin

  19. Conclusions • Malaria Remains as a Problem • Resistant strains • Anti-malarial Activity of Artemisinin • Mode of Action is Now Understood • Alkylation via route 1 • A Specific Target Found • PfATP6 gene sequence of the SERCA enzyme • Fe2+ is required • Activity not localized in the food vacuole

  20. References • Robert, Anne, et al. “From Mechanistic Studies on Artemisinin Derivatives to New Modular Antimalarial Drugs.” Accounts of Chemical Research, 2002,Vol. 35, pp. 167-174. • Cazelles, Jerome, et al. “Alkylating Capacity and Reaction Products of Antimalarial Trioxanes after Activation by a Heme Model.” The Journal of Organic Chemistry, 2002, Vol. 67, Number 3, pp. 609-619. • Wu, Wen-Min, et al. “Unified Mechanistic Framework for the Fe(II)-Induced Cleavage of Qinghaosu and Derivatives/Analogues. The First Spin-Trapping Evidence for the Previously Postulated Secondary C-4 Radical.” J. Am. Chem. Soc., 1998, Vol. 120, pp. 3316-3325. • Biot, Christophe, et al. “Synthesis and Antimalarial Activity in Vitro and in Vivo of a New Ferrocene-Chloroquine Analogue.” J. of Medicinal Chemistry, 1997, Vol. 40, pp. 3715-3718. • Yarnell, Amanda; “Rethinking How Artemisinin Kills,” Chemical and Engineering News, Aug. 25, 2003, Vol. 81 (24), pp. 6. • Eckstein-Ludwig, Ursula, et al. “Artemisinins Target the SERCA of Plasmodium falciparum,” Nature, 2003, Vol. 424, pp.957.

  21. Questions

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