BIOLOGICALLY ACTIVE COMPOUNDS FROM PLANTS: 40 YEARS OF SEARCHING FOR A
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BIOLOGICALLY ACTIVE COMPOUNDS FROM PLANTS: 40 YEARS OF SEARCHING FOR A SCIENTIFIC POT OF GOLD Second Professor Frank Fish Memorial Award Lecture School of Pharmacy University College London October 9, 2013 Prof. A. Douglas Kinghorn Professor and Jack L. Beal Chair College of Pharmacy The Ohio State University Professor Frank Fish, OBE (1924-2011) B. Pharm (London), 1946 Ph.D. (Glasgow), 1955 Established the M.Sc. Course in Forensic Science at the University of Strathclyde in 1966 Dean, School of Pharmaceutical Sciences, University of Strathclyde, 1977-1978 Dean, School of Pharmacy, University of London, 1978-1988 OUTLINE OF PRESENTATION Continued Importance of Natural ProductDerived Drugs in the 21st Century. The Crucial Role of Mentorship in Career Development – a Personal Perspective. Examples of Promising Lead Compounds from Tropical Plants: Hernandulcin, a Highly Sweet Sesquiterpenoid Silvestrol, a Potential Agent to Combat B-Cell Malignancies “Active Constituents” of Botanical Dietary Supplements, as Exemplified by 2-Methoxy-2,4,6trihydroxyanthraquinone from Noni and -Mangostin from Mangosteen Conclusions. CONTINUED IMPORTANCE OF NATURAL PRODUCT-DERIVED DRUGS IN THE 21ST CENTURY NUMBERS OF ORGANISMS FOR DRUG DISCOVERY Eubacteria (bacteria), cyanobacteria (blue-green algae) Archaea (halobacteria, cyanogens) Protoctista (e.g., protozoa, diatoms, “algae”, algae” and “green algae”) 4,000a Unknown 80,000 including “red Plantae (mosses and liverworts, ferns, seed plants)b Fungi (e.g., molds, lichens, yeasts, mushrooms)c 270,000 72,000 Animalia (e.g., mesozoa, sponges, jellyfish, corals, flatworms, 1,320,000 roundworms, sea urchins, mollusks, segmented worms, arthropods, insects, fish, amphibians, birds, mammals)d-f a b c d e f Figures are species described taxonomically to date in each group. Plants are the second largest group of classified organisms, representing 15% of the known biodiversity. Only a relatively small proportion (5%) of the estimated 1.5 m fungi have been classified taxonomically to date. The largest numbers of organisms are the arthropods, inclusive of insects (ca. 950,000 species). Of the 28 major animal phyla, 26 are found in a marine environment. Over 200,000 species of invertebrate animals and algal species occur in the sea. (Tan et al., Curr. Drug Targets 7, 265, 2006) NUMBER OF DRUGS APPROVED IN THE UNITED STATES (1981 TO 2007) (Li and Vederas, Science 325, 161, 2009) NATURAL PRODUCT-DERIVED DRUGS INTRODUCED IN THE U.S. (2000-2008) Source Organism Type Terrestrial Plants (apomorphine HCl, arteether, dronabinol/cannabidiol (mixture), galanthamine HBr, lisdexamfetamine, methylnatrexone Br, nitisinone, tiotropium Br) Terrestrial Microorganisms (amrubicin HCl, anidulafungin, biapenem, caspofungin acetate, cefditoren pivoxil, ceftobiprole medocaril, daptomycin, doripenem, ertapenem, everolimus, fumagillin, gentumazumab ozogamicin, ixabepilone, micafungin Na, miglustat, mycophenolate Na, pimecrolimus, pitavastatin, retapamulin, rosuvastatin Ca, telithromycin, temsirolimus, tigecycline, zotarolimus) Number 8 24 Marine Organisms (trabectidin, ziconotide) 2 Terrestrial Animals (bivalirudin; exenatide; synthetic versions of natural forms) 2 [Chin et al., AAPS J., 8 (2), E239-E253, (Article 28), 2006; http://www.aapsj.org; Butler, in Natural Product Chemistry for Drug Discovery, eds. A.D. Buss and M.S. Butler, RSC: Cambridge, U.K., 2010; p. 321] IXABEPILONE (IXEMPRATM) Ixabepilone R = NH Epothilone B R = O https://www.genetik.uni-bielefeld.de/GenoMik/cluster6.html http://www.nature.com/nrc/journal/v2/n2/slideshow/nrc723_F2.html Lead compound was epothilone B isolated from Sorangium cellulosum (a myxobacterium). Anticancer agent (refractory breast cancer) (B-MS, 2007). Interacts with tubulin. ECTEINASCIDIN 743: AN ANTICANCER AGENT FROM A MARINE TUNICATE Ecteinascidia turbinata Ecteinascidin 743; ET-743; trabectedin, Yondelis® [Soft tissue sarcoma (Europe)] www.pharmamar.com http://www.teridanielsbooks.com/States/reptile_lizard_gila_monster.jpg GILA MONSTER (HELODERMA SUSPECTUM) SOURCE OF EXENATIDE – ANTIDIABETIC AGENT PLANT NATURAL PRODUCTS AND DERIVATIVES APPROVED BY THE U.S. FDA FROM JANUARY 2001-FEBRUARY 2013a Year Approved 2001 2002 2003 2004 2004 2004 2005 Generic Name Natural Lead Compound Galantamineb Nitisinoneb Miglustatb Tiotropiumb bromide Trospiumb chloride Solifenacinb Paclitaxel (protein-bound) Galanthamine Leptospermone 1-Deoxynojirimycin Atropine Atropine Quinine Paclitaxel (taxol) Trade Name Razadyne Orfadin Zavesca Spiriva Sanctura VESIcare Abraxane 2006 2006d 2008 2008 2009 2009 2009 2010 2010 Green tea phenols Δ9-Tetrahydrocannabinol Morphine Emetine Artemesinin Colchicine Capsaicin Paclitaxel (taxol) Morphine and quinidine Veregen Cesamet Relistor Xenazine Coartem Colcrys Qutenza Jevtana Nuedexta 2011 Sinecatechinsb,c Nabiloneb Methylnaltrexoneb bromide Tetrabenazineb Artemetherb and lumefantrine Colchicined Capsaicin Cabazitaxelb Dextromethorphan and quinidine Ioflupane I-123b Cocaine Datscan 2011 Gabapentin enacarbilb -Aminobutyric acid (GABA) Horizant Brain imaging with syndromes Restless leg syndrome Ingenol-3-angelate Picato Actinic keratosis Ephedrine Belviq Obesity mebutateb Indication Dementia associated with Alzheimer's disease Hereditary tyrosinemia type 1 Type 1 Gaucher disease COPD and exacerbation of COPD Overactive bladder Overactive bladder Breast cancer (also approved for lung cancer in 2012 ) Genital and perianal warts Chemotherapy-induced nausea Opioid-induced constipation Huntington's-associated chorea Malaria Gout Postherpetic neuralgia Hormone-refractory metastatic prostate cancer Pseudobulbar Affect suspected Parkinsonian 2012 Ingenol 2012 Lorcaserinb 2012 Icosapent ethyl Eicosapentaenoic acid (EPA) Vascepa Hypertriglyceridemia 2012 Omacetaxine mepesuccinateb Homoharringtonine Synribo Chronic myeloid leukemia 2012 Crofelemerb,c Fulyzaq HIV/AIDS anti-retroviral-associated diarrhea 2013 Trastuzumab emtansine (antibody-conjugate) Ospemifeneb Croton lechleri oligomeric proanthocyanidin Maytansine Kadcyla Breast cancer Phytoestrogens Osphena Menopause-associated dyspareunia 2013 a hydrochloride Information taken from Drugs@FDA (http://www.accessdata.fda.gov/scripts/cder/drugsatfda/index.cfm) and Kinghorn, et al. J. Nat. Prod. 74, 1539, 2011 b New molecular entity. c Approved as a mixture of compounds as a “botanical drug”. d Originally approved in combination therapy in 1985; newly approved as a monotherapy. INGENOL MEBUTATE FOR THE TREATMENT OF ACTINIC KERATOSIS Euphorbia peplus (Euphorbiaceae) Ingenol mebutate (Ingenol-3-angelate) ( Picato ) http://www.discoverlife.org/mp/20q?search=Euphorbia+peplus&mobile=iPhone http://luirig.altervista.org/flora/taxa/index1.php?scientific-name=euphorbia+peplus Approved by U.S. FDA in 2012 for the treatment of actinic keratosis, a precursor to sun-related squamous cell carcinoma (used as a topical gel) (Lebwohl et al., N. Engl. J. Med. 366, 1010, 2012; Mason, Pharm. J. 290, 141, 2013). This compound was isolated from Euphorbia peplus (Hohmann et al., Planta Med. 66, 291, 2000). New 14-step synthesis: Jorgensen et al., Science 341, 878, 2013. DEFINITION OF A “BOTANICAL DRUG PRODUCT” In June 2004, the U.S. FDA issued the publication “Guidance for Industry. Botanical Drug Products” (http://www.fda.gov/cder/guidance/index.htm). A “botanical drug product” is defined as containing as ingredients vegetable materials, which may include plant materials, algae, macroscopic fungi, or combinations thereof, for use as a drug. It may be prepared, for example, as a solution (e.g., tea), powder, tablet, capsule, elixir, topical agent, or injectable. Excluded are: fermentation products, highly purified or chemically modified botanical substances, genetically modified plants, allergenic extracts, and vaccines that contain botanical ingredients. (J. Dou, U.S. FDA, CDER) OVERVIEW OF NDA PROCESS OF FDA FOR “BOTANICAL DRUGS” Purification to single active molecules is not required, although strict documentation of “chemistry, manufacturing, and controls” (CMC) must be carried out. Identification of “active principles” is not essential. The same requirements for safety assurance and clinical efficacy as for synthetic drugs are needed for NDA approval. Purification to single active molecules is not required. The same levels of safety requirements and clinical efficacy as non-botanical drugs are needed for NDA approval. Nearly 500 IND/pre-IND applications for botanical drugs have been submitted to CDER, FDA between 1999-2012. Most of these are in Phase 2, with a few in Phase 3. (J. Dou, U.S. FDA, CDER) SINECATECHINS FROM GREEN TEA (CAMELLIA SINENSIS) AS THE FIRST “BOTANICAL DRUG” Green tea contains mixtures of a sub-type of flavonoids (flavans) known as “catechins”, which are esterified with a small phenolic acid, gallic acid. Epigallocatechin gallate (EGCG), the major flavonoid ester in green tea, is one of the most highly studied natural product molecules in the biomedical literature. A mixture of green tea catechins (“sinecatechins”; Veregen) was the first “botanical drug” approved by the U.S. FDA in 2006 (used topically to treat venereal and perianal warts) (Chen et al., Nature Biotechnol. 26, 1077, 2008). CROFELEMER, THE FIRST FDA-APPROVED “BOTANICAL DRUG” TO BE TAKEN ORALLY J. Dou, CDER, FDA Crofelemer is a complex mixture of proanthocyanidins (literally thousands of compounds co-occur). The plant of origin is called “Dragon’s Blood”. Crofelemer (Fulyzaq) was approved as a “botanical drug” by the USA FDA in 2012 as an oral antidiarrheal agent. THE CRUCIAL ROLE OF MENTORSHIP IN CAREER DEVELOPMENT – A PERSONAL PERSPECTIVE B.PHARM. (SPECIAL IN PHARMACOGNOSY) AT BRADFORD (1966-1969) Dr. Peter A. Linley Dr. Keith J. Harkiss served as tutor and supervised a thee-part undergraduate thesis MASTER’S IN FORENSIC SCIENCE AT STRATHCLYDE (1969-1970) Prof. Frank Fish, Coordinator of the M.Sc. Course in Forensic Science (Thesis performed under the supervision of Mr. Peter F. Nelson) TEACHING FELLOWSHIP AND PH.D. STUDENTSHIP AT THE SQUARE (1971-1975) Late Prof. Evans, Supervisor Fred Ph.D. (Dissertation carried out on the skin-irritant diterpene esters of Euphorbia species) SENIOR PHARMACOGNOSY ACADEMIC STAFF AT “BRUNSWICK SQUARE” (1970s-1990s) LATE PROF. JAMES W. FAIRBAIRN (ANTHRAQUINONES; OPIUM POPPY; CANNABIS SATIVA) EMER. PROF. J. DAVID PHILLIPSON (ALKALOIDS; ANTIPROTOZOALS; TISSUE CULTURE) LATE PROF. FRED J. EVANS (PHORBOL ESTERS; CANNABIS SATIVA; PH.D. SUPERVISOR) DR. MARGARET F. ROBERTS (ALKALOID BIOSYNTHESIS; PAPAVER ALKALOIDS) U.K. PHARMACOGNOSISTS AT A CELEBRATION IN THE LATE 1970S Photograph Provided by Prof. J. David Phillipson PRESENT PHARMACOGNOSY LEADERS AT “BRUNSWICK SQUARE” PROF. MICHAEL HEINRICH (ETHNOBOTANY, PHYTOTHERAPY; PHARMACEUTICAL BIOLOGY) PROF. SIMON GIBBONS (ANTIINFECTIVE AGENTS FROM PLANTS; DRUGS OF ABUSE) M.SC. DEGREE IN PHARMACOGNOSY AT UCL SCHOOL OF PHARMACY Dr. Jose Prieto-Garcia Programme Director Prof. Simon Gibbons Deputy Programme Director Invited Guest Lecturers from outside UCL include Dr. Colin Wright (University of Bradford), Prof. Peter Houghton (King’s College London), Prof. Monique Simmonds (RBC, Kew), and Prof. Elizabeth Williamson (University of Reading) SABBATICAL OF PROFESSOR DAVE PHILLIPSON AT THE OHIO STATE UNIVERSITY IN THE LATE 1960s Late Professor Jack L. Beal The Ohio State University Emeritus Professor Raymond W. Doskotch The Ohio State University A NIGHT ON THE TOWN WITH PROFESSOR NORMAN R. FARNSWORTH AT “TRADER VICS” Photograph Provided by Prof. Norman R. Farnsworth DEPARTMENT OF PHARMAGNOSY, UNIVERSITY OF MISSISSIPPI, 1975 (HEAD: NORMAN J. DOORENBOS) THE ARROWS SHOW PROF. DOORENBOS AND THE FUTURE MRS. KINGHORN Late Dr. Norman R. Farnsworth University of Illinois at Chicago 1930-2011 Slide Provided by Professor J. David Phillipson DRS. MONROE WALL AND MANSUKH WANI – DISCOVERERS OF TAXOL AND CAMPOTHECIN (Photograph by Jimmy W. Crawford, RTI) EXAMPLES OF PROMISING LEAD COMPOUNDS FROM TROPICAL PLANTS EXAMPLES OF LEAD COMPOUNDS OF INTEREST FROM TROPICAL PLANTS Abrusoside A (Chem. Commun., 1989) α-Mangostin (Nutr. Res., 2012) Pervilleine A (Cancer Res., 2001) Betulinic acid (Nature Med., 1995) 2-Methoxy-1,3,6anthraquinone (J. Nat. Prod., 2005) trans-Resveratrol (Science, 1997) Hernandulcin (Science, 1985) Pentalinonsterol (Phytochemistry, 2012) Silvestrol (J. Org. Chem., 2004) TASTE AND THE TONGUE Humans have ca. 10,000 taste buds with each taste bud containing 50-100 taste receptor cells. The popular taste map of the tongue taste is based on faulty interpretation of a 1901 paper, in fact taste buds on many areas of the tongue can detect different tastes. Bitterness has a much lower taste threshold than sweetness due to the biological imperative to select for nutritious foods while avoiding toxins. Image from Lindeman Image from www.rickbakas.com Lindeman, B. Nature Med., 1999, 5, 381-382. Scott, K. Neuron, 2005, 48, 455-464 COMPARISON OF THE SWEETNESS INTENSITIES OF “LOWCALORIC” AND “REDUCED-CALORIE” NATURAL PRODUCT SWEETENERS (ALL OF HIGHER PLANT ORIGIN) “Low-Caloric” (“High Potency Sweeteners”) Compound Sweetness Intensity1 Glycyrrhizin 50-100 Lactitol 0.4 Stevioside 150-250 Isomalt 0.45-0.65 Perillartine2 370 Sorbitol 0.6 Phyllodulcin 400 Mannitol 0.7 Compound Sweetness Intensity1 Rebaudioside A 200-300 Maltitol 0.9 Mogroside V 250-450 Xylitol 1.0 High-Fructose Corn Syrup (90%) 1.0 MGGR2 941 Hernandulcin 1500 Monellin Neohesperidin dihydrochalcone2 Thaumatin 1 “Reduced-Calorie” (“Bulk Sweeteners”) 1500-2000 1800 2000-3000 Relative to sucrose (=1). Sweetness intensity varies with concentration being tasted. 2Semi-synthetic compound. HERNANDULCIN, A HIGHLY SWEET COMPOUND FROM LIPPIA DULCIS (VERBENACEAE) In Mexico, L. dulcis is used as an emmenagogue, to induce menses, as an abortifacient, and to treat coughs and stomachache. The plant was purchased in bulk at a marketplace in Mexico City, and collected in the field at Tlayacapan, Morelos, Mexico in May-June, 1982 by then graduate student Cesar M. Compadre. The compound was determined as a novel bisabolane sesquiterpene by spectroscopic methods. The structure was checked by synthesis in the (±)-form by directed-aldol condensation of the ketones 3-methyl-2cyclohexen-1-one (I) and 6-methyl-5hepten-2-one (II). (Compadre et al., Science 227, 417, 1985) Prof. Cesar M. Compadre IDEAL PROPERTIES OF A NONCALORIC AND NONCARIOGENIC SWEETENER FOR POTENTIAL USE AS A SUCROSE SUBSTITUTE Highly sweet, odorless, colorless, with taste characteristics similar to sucrose. Water soluble, stable. No toxicity nor cariogenicity, from either the parent substance or its metabolites. Easy to synthesize or to obtain by cultivation. Should fit existing techniques for the application of sweeteners. Economically competitive approved sweeteners. with currently (Hough et al., Eds. In Developments in Sweeteners – 1; Applied Science Publishers, London, 1979; p. v) STRUCTURAL CHARACTERIZATION OF SILVESTROL FROM AGLAIA FOVEOLATA Silvestrol X-ray Structure by Drs. Bernard Santarsiero and Andrew Mesecar (UIC) Drs. Bang Yeon Hwang and Baoning Su (Hwang et al., J. Org. Chem. 69, 3350, 2004; ibid., 69, 6156) COLLABORATIVE PROJECTS ON NATURAL PRODUCT ANTICANCER DRUG DISCOVERY National Cooperative Drug Discovery Group (NCDDG) Grant (U19 CA52956) Program Project Grant (P01 CA125066) Collaboration between: The Ohio State University, Columbus, OH; University of Illinois at Chicago, Chicago, IL; University of North Carolina at Greensboro, NC; Mycosynthetix Inc., NC; Bristol-Myers Squibb, Princeton, NJ. Funded by the United States National Cancer Institute, NIH (1990-2006; 2007-2013) [Most recent review: Kinghorn et al., Pure Appl. Chem. 81, 1051, 2009] NCDDG GROUP AT THE MEDICINAL PLANT GARDEN, UNIVERSITY OF ILLINOIS AT CHICAGO IN 2003 SHOWS LEFT TO RIGHT (UIC UNLESS STATED) MARCY BALUNAS, GEOFF CORDELL, STEVE SWANSON, DOEL SOEJARTO, YALI FU (NCI), NORM FARNSWORTH, GORDON CRAGG (NCI), MANSUKH WANI (RTI), DOUG KINGHORN, WILL JONES, NICK OBERLIES (RTI), TATIANA LOBO, AIKO ITO, YINGMEI TAN. GHEE TAN, BANG YEON HWANG, AND FAUSTO RIVERO-CRUZ IN VITRO CYTOTOXICITY OF SILVESTROL Compound Silvestrol Methyl rocaglateb Paclitaxelc Camptothecinc a b c Lu1 1.2 163 2.3 28.7 Cell linea LNCaP MCF-7 1.5 1.5 325 Not determined 4.7 0.7 28.7 28.7 HUVEC 4.6 203 105.5 258.6 ED50 values (nM) - Lu1 = human lung cancer; LNCaP = hormone-dependent human prostate cancer; MCF-7 = human breast cancer; HUVEC = human umbilical vein endothelial cells. Isolated in our previous work (Rivero-Cruz et al., J. Nat. Prod., 67, 343, 2004). Used as positive control. (Hwang et al., J. Org. Chem. 69, 3350, 2004) EFFECT OF SILVESTROL IN THE IN VIVO HOLLOW FIBER TEST AND IN THE MURINE P-388 LEUKEMIA MODEL Hollow fiber: Murine P-388 leukemia: Active at maximum tolerated dose of 2.5 mg/kg/inj, given by intraperitoneal injection daily for five consecutive days (qd5) in ip P388 model. Achieved maximum lifespan increase corresponding to T/C of 150%. Inactive (T/C = 100%) in iv P388 leukemia model when administered by either the iv or ip route using a daily times five schedule (qd5). Active (T/C = 129%) in same tumor model when injected iv on a twice-daily schedule (2qd5) using the same cumulative dose (2 mg/kg/day). (Hwang et al., J. Org. Chem. 69, 3350, 2004) % Live Cells Relative to Untreated EFFECTS OF SILVESTROL ON B AND T CELLS IN WHOLE BLOOD FROM CHRONIC LYMPHOCYTIC LEUKEMIA (CLL) PATIENTS B Cells T Cells 120 120 100 100 80 80 60 60 40 40 20 20 0 0 24 48 Incubation Time (hours) 72 80 nM Silvestrol 0 0 24 48 Incubation Time (hours) 1 µM 2-F-ara A (Lucas et al., Blood 113, 4656, 2009) 72 SILVESTROL SIGNIFICANTLY IMPROVED SURVIVAL IN AN ACUTE LYMPHOBLASTIC LEUKEMIA (ALL) XENOGRAFT MOUSE MODEL 100 Median survival difference P = 0.002 % Survival 80 Control (N=13) 60 Silvestrol (N=14) 40 1.5 mg/kg i.p. M, W, F; started 1 wk post-engraftment 20 Treatment stopped 0 0 5 10 15 20 25 30 35 40 45 85 Days Post Engraftment The remaining three mice appeared normal 12+ weeks postengraftment, 6 weeks after the last treatment. (Lucas et al., Blood 113, 4656, 2009) SILVESTROL: WORK PERFORMED BY OTHER GROUPS Silvestrol was totally synthesized by two groups in 2007, the groups of Porco (Boston University) (Gerard et al., Angew. Chem. Int. Ed., 46, 7831, 2007) and Rizzacasa (University of Melbourne) (El Sous et al., ibid., 46, 7835, 2007). Pelletier and co-workers have shown that silvestrol is a translation inhibitor by targeting eukaryotic initiation factor (eIF) 4A (Cencic et al., PLoS ONE 4(4), e5223, 2009). The figure shows the translation initiation complex and known inhibitors (Lucas et al., Curr. Drug Targets 11, 811, 2010); based in part on Cencic et al., 2009, as cited above). In very recent work, using biotinylated 5-epi-silvestrol, a specific interaction was shown with eIF4AI and eIF4AII (Chambers et al., Org. Lett. 15, 1406, 2013). SILVESTROL: A POTENTIAL NEW THERAPEUTIC AGENT FOR B-CELL MALIGNANCIES At The Ohio State University, silvestrol has shown promising in vivo activity in models of acute lymphoblastic leukemia, acute myeloid leukemia, EBV-driven lymphoma, and mantle cell lymphoma (Lucas et al., Blood 113, 4656, 2009; Alinari et al., Clin. Cancer Res. 18, 4600, 2012; Alahkar et al., J. Hematol. Oncol. 6, 21, 2013). Silvestrol was selected for preclinical development by NCI through the DDG IIA mechanism in 2007, and is now in the NCI NExT program having been subjected to additional peer and program review in August 2013. The mechanism of antileukemic action is being further investigated through Project 5 of a NCI/NIH SPORE (P50) award (J. C. Byrd, PI) (M.R. Grever, D.M. Lucas) (2009-2014). EFFECTS OF SILVESTROL ANALOGUES ON GROWTH INHIBITORY ACTIVITY OF HUMAN CANCER CELLS The presence of a 1,4-dioxanyloxy moiety at C-6 enhances activity dramatically The cyclopenta[b]benzofuran moiety and other aromatic units confer basic cytotoxicity to this compound class Esterification or change in configuration of the hydroxy group at C-1 diminishes cytotoxicity Esterification of the hydroxy groups at C-5''' and C-6''' decreases resultant cytotoxicity Inversion of configuration at C-2''' reduces cytotoxicity much more than when inverted at C-5''' Methyl ester group required for potency Absence of OCH3 at C-4' diminishes resultant cytotoxicity slightly The natural product silvestrol is the most potent of ca. 15 close analogues investigated (Hwang et al., J. Org. Chem. 69, 3350, 2004; Adams et al., J. Am. Chem. Soc. 131, 1607, 2009; Pan et al., J. Nat. Prod. 73, 1873, 2010; Woodard IV et al., Unpublished results) is AGREEMENT FOR DEVELOPMENT OF SILVESTROL FOR POTENTIAL TREATMENT OF B-CELL MALIGNANCIES In June 2012, after protracted negotiations, an agreement was signed to jointly develop silvestrol between The Ohio State University and the Sarawak Biodiversity Center, with the immediate goal of conducting preclinical toxicology. The U.S. NCI will be involved through the NExT program. This slide shows the two other faculty participants in this work at Ohio State, Drs. Michael Grever (top left) and David Lucas (top right), and Dr. Rita Manurung, Chief Operating Officer, Sarawak Biodiversity Center, Kuching, Sarawak, Malaysia (bottom). Silvestrol will be sourced from Aglaia stellatopilosa grown in Sarawak. DIETARY HEALTH SUPPLEMENT AND EDUCATION ACT (DSHEA) (1994) Defined terms “dietary supplement” (including herbal remedies) and “dietary ingredient”. These are taken orally and may be used as in forms such as tablets, capsules, soft gels, gel liquids, and powders. Exempted dietary supplements marketed before October 15, 1994 from new dietary ingredient (NDI) review. Established requirements for new dietary ingredients. A dietary supplement may be declared as a hazard to public health or safety. “Structure and function” claims may be made, but most labels have a disclaimer about health benefits. NONI AS A DIETARY SUPPLEMENT Marketed in the U.S. by several companies. Noni juice is available in many retail outlets, including supermarkets, healthfood stores, and pharmacies. Tahitian and Hawaiian noni juice are both available. Marketing toward layman primarily based on the likely fictitious alkaloid, “xeronine”. (Heinecke, Pac. Trop. Bot. Gard. Bull. 10, 15, 1985) NONI (MORINDA CITRIFOLIA) (RUBIACEAE) Occurs in tropical and subtropical regions. All parts (fruit, leaf, bark, flower, and seed) have been utilized medicinally. Roots and bark are used as a dye. In initial isolation work performed at The Ohio State University, a lignan (americanin A) and a flavonoid glycoside (narcissoside) were isolated as antioxidant constituents of noni fruits. No trace of xeronine was found! (Su et al., J. Nat. Prod. 68, 592, 2005). http://www.nps.gov/kaho/KAHOckLs/KAHOplnt/noni.htm Dr. Alison Pawlus (Review: Pawlus and Kinghorn, J. Pharm. Pharmacol. 59, 1587, 2007) QUINONE REDUCTASE-INDUCING ACTIVITY OF ISOLATED CONSTITUENTS OF NONI FRUITS Compound CDa, M (g/mL) IC50b, M (g/mL) CIc 1d 0.009 (0.0027) >69.9 (>20) >7770 2 1.67 (0.52) >66.6 (>20) >39.9 L-sulforaphane* 0.34 (0.061) 9.77 (1.73) 28.7 aCD = Concentration required to double quinone reductase induction. bIC50 = Concentration for 50% inhibition of cell viability. cCI = Chemopreventive Index. d Only 2 mg of 1,3,6trihydroxy-2-methoxyanthraquinone (1) isolated from ca. 9 kg dried noni fruits. * = Control. 1 (new, 2-methoxy-1,3,6,trihydroxyanthraquinone) 2 (Pawlus et al., J. Nat. Prod. 68, 1720, 2005) INHIBITORY EFFECT OF NONI FRUITS ON RAT ESOPHAGEAL TUMORIGENESIS Male F344 rats were fed a diet of 5% w/w dried powdered fruits of M. citrifolia (noni), and six other dried fruits, including black raspberry (Rubus occidentalis), in a comparison study. The standard carcinogen, NMBA (Nnitrosomethylbenzylamine was used to treat rats for five weeks, and the experiment was terminated after 35 weeks. All seven fruits had similar effects on reducing esophageal tumor incidence, size, and multiplicity, and also reduced the levels of two serum cytokines. Noni fruits have lower levels of anthocyanins and ellagitannins than black raspberries. (Stoner et al., Pharm. Res. 27, 1138, 2010) GARCINIA MANGOSTANA (MANGOSTEEN) (CLUSIACEAE) The tropical fruit Garcinia mangostana L. (Clusiaceae; Mangosteen), has become a major botanical dietary supplement in the U.S. Mangosteen extracts and/or their purified xanthone constituents, such as -mangostin, have antioxidant and e.g., putative anti-inflammatory and antimicrobial activities. In initial collaborative work with Dr. Bill Keller, several mangosteen xanthones were found to be potent antioxidants (Jung et al., J. Agric. Food Chem., 54, 2077, 2006). DR. WILLIAM J. KELLER NATURE’S SUNSHINE PRODUCTS, INC. XANTHONES ISOLATED FROM THE PERICARP OF MANGOSTEEN PROFILE OF XANTHONE CONTENT IN THE MANGOSTEEN JUICE USED IN THE STUDY When analyzed by HPLC, the 100% mangosteen juice used in the study provided 5.3 + 0.1 mM total xanthones, with -mangostin being the most abundant (59.9%), as indicated in the table opposite. -Mangostin Xanthone Content in juice (µM) Percentage of total xanthones identified (%) garcinone C 291 + 11.2 5.5 garcinone D 520 + 10.9 10.2 garcinone E 239 + 18.5 5.1 -mangostin 3190 + 123 59.9 β-mangostin 121 + 9.3 2.3 -mangostin 356 + 4.3 6.5 8-deoxygartanin 176 + 4.5 3.1 gartanin 157 + 6.9 2.8 tovophillin B 50 + 2.9 1.1 9-hydroxycalabaxanthone 193 + 7.4 3.6 Total 5290 + 166 100 Values are means + SD; n = 5 independent replicates (Chitchumroonchokchai et al., J. Nutr. 142, 675, 2012) DETERMINATION OF BIOAVAILABILITY IN HUMANS OF XANTHONES FROM MANGOSTEEN JUICE The bioavailability of mangosteen xanthones using human subjects is of interest, since milligram amounts are ingested on a daily basis. In a preliminary study, Kondo et al. administered ca. 60 mL of a supplement (mangosteen; aloe vera; green tea; multivitamins) to 20 fasted healthy human volunteers, and it was concluded that -mangostin is bioavailable (observed Cmax at tmax of ca. 1 hour) (Kondo et al. J. Agric. Food Chem., 57, 8788, 2009). In a study carried out at The Ohio State University, the bioavailability of xanthones was investigated in ten healthy adults (five females; five males), who consumed a single dose of 100% mangosteen juice along with a typical fast-food (high-fat) breakfast, which was supplemented with canola oil and soybean oil (Chitchumroonchokchai et al. J. Nutr., 142, 675, 2012). EFFECT OF DIETARY α-MANGOSTIN IN A MURINE HT-29 COLON CANCER CELL XENOGRAFT MODEL A 90 1200 a 1000 Tumor mass (mg) 80 b 70 60 50 40 30 20 Tumor mass (mg) 100 B a 800 b 600 Values are means + SD; n = 12 and 6 mice for panels A and B, respectively 400 200 10 0 AIN-93G AIN-93G + α-MG 0 AIN-93G AIN-93G + α-MG Balb/c nu/nu mice were fed either the control diet AIN-93G or the control diet with -mangostin (-MG; 900 mg/kg). After one week of acclimation to diet, mice were injected sc with HT-29 cells, and then fed the same diets. After two weeks (panel A) or four weeks (panel B) from the initial injection of HT29 cells, the tumor masses were 27% and 41% less, respectively, in mice fed the diet with -mangostin compared to those fed the control diet. Xanthones and their metabolites were found in the serum, liver, and feces. This work was carried out in collaboration with Professors Mark Failla and Steve Clinton at The Ohio State University. (Chitchumroonchokchai et al., Mol. Nutr. Food Res. 57, 203, 2013) CONCLUSIONS: COLLABORATIVE APPROACH TO THE DISCOVERY OF ANTICANCER AGENTS FROM TROPICAL PLANTS Tropical plants are more biodiverse than temperate plants, and thus hold the potential of offering greater chemical diversity for anticancer drug discovery. Plant collections for drug discovery must cover the source country in terms of intellectual property agreements. Efforts to harness plant compounds as potential cancer chemotherapeutic agents require a multidisciplinary approach with open and frequent communications. Photograph by Jon Gladden (April 2013) Shown (left to right) are Tony Gromovsky, Ben Naman, Lynette Bueno, Dr. Heebyung Chai, Dr. Li Pan, Ms. Anecie Benatrahina, Dr. Patrick Still, and Dr. Yulin Ren Support was obtained from NIH grants N01-DE-02425, R03-07560; R01-DE08937, U19 CA52956, and P01 CA125066 and faculty start-up funding from the Molecular Carcinogenesis and Chemoprevention Program of the OSUCCC. Many faculty, visiting scholars, postdoctorals, and graduate students at the University of Illinois at Chicago and The Ohio State University are thanked for very their kind collaboration. This is a long-running and well-respected book series that was established in 1938 by Laszlo Zechmeister. The series has featured contributions by nine Nobel laureates. The chapters refer to the origin, distribution, chemistry, synthesis, biochemistry, functions, and uses of naturally occurring substances, ranging from small molecules to biopolymers. College of Pharmacy and OSU Comprehensive Cancer Center
