George O. Morton

Bio: George O. Morton is an academic researcher from American Cyanamid. The author has contributed to research in topics: Beta (finance) & Bicyclic molecule. The author has an hindex of 24, co-authored 82 publications receiving 2037 citations.

LL-F28249 antibiotic complex: a new family of antiparasitic macrocyclic lactones ― Isolation, characterization and structures of LL-F28249 α, β, γ, λ

Abstract: A new family of antiparasitic macrolides has been isolated from Streptomyces cyaneogriseus sp. noncyanogenus. The compounds, designated LL-F28249 α, β, γ and λ, possess potent antiparasitic activity. The isolation, purification and structure determination by spectroscopic methods are presented.

Marine indole alkaloids: potential new drug leads for the control of depression and anxiety

Abstract: The marine environment has been explored in the search for new bioactive compounds over the last 50 years, becoming a highly important and rich source of potent molecules and drug leads reported to possess a wide scope of activities. Alkaloids constitute one of the largest classes of natural products and are synthesized by terrestrial and marine organisms on all evolutionary levels. Alkaloids are usually present in an organism as a mixture consisting of several major and a few minor compounds of the same biosynthetic origin and differing only in functional groups. This group of compounds has apparently evolved as a defense mechanism against predators and as a result alkaloids are often highly potent and toxic molecules.1 Marine invertebrates have proven to be an outstanding source of active molecules, one of the most promising being indole alkaloids. Although many of these marine alkaloids closely resemble the endogenous amines (serotonin, dopamine or histamine), their potential affinity to various neurological targets and consequential impact on animal behavior is virtually unexplored. Indole alkaloids, their activity, synthesis and potential use in medicine have been already reviewed in several articles.2 In this review we provide information on current and potential pharmaceuticals including small molecule natural indole alkaloids, their biological properties, structure-activity relationship studies, and especially their potential for the treatment of neurological disorders. 1.1. The indole moiety in drugs The indole moiety is present in a number of drugs currently on the market. Most of these belong to triptans which are used mainly in the treatment of migraine headaches (Fig. 1). All members of this group are agonists of migraine associated 5HT1B and 5HT1D serotonin receptors. Sumatriptan (Imitrex) was developed by Glaxo for the treatment of migraines and introduced into the market as the first member of the triptan family.3 Relative to the second generation triptans, sumatriptan has lower oral bioavailability and a shorter half-life. Frovatriptan (FROVA®) was developed by Vernalis for the treatment of menstruation associated headaches. Frovatriptan's affinity for migraine specific serotonin receptors 5HT1B is believed to be the highest among all triptans.4 In addition, frovatriptan binds to 5HT1D and 5HT7 receptor subtypes.5 Zolmitriptan marketed by AstraZeneca is used to treat acute migraine attacks and cluster headaches. GlaxoSmithKline's naratriptan (Amerge) is also used in the treatment of migraines and some of its side effects include dizziness, tiredness, tingling of the hands and feet and dry mouth. All available triptans are well tolerated and effective.6 The highest incidence of central nervous system (CNS) related side effects (dizziness, drowsiness) was reported for zolmitriptan (5 mg), rizatriptan (10 mg) and eletriptan (40 mg, 80 mg).7 The differences in side-effect profiles for triptans are not likely caused by their different affinity towards serotonin receptors or other neurological receptors in the CNS. There is a positive correlation between the lipophilicity coefficient and CNS side effects; these undesired effects are also dose-dependent. Figure 1 Currently available drugs from the triptan group. 1.2. Serotonin receptors – possible targets for neurologically active marine indole alkaloids Given that depression affects approximately 18 million Americans annually,8 it is crucial to develop new effective treatments for this disorder. Intensive studies are being conducted in the area of new targets for antidepressant drugs,9,10 but most antidepressant drugs still target the neurotransmitter systems, mainly serotonin, dopamine and noradrenaline. Serotonin is one of the neurotransmitters present in the central and peripheral nervous system which plays an important role in normal brain function and regulates sleep, mood, appetite, sexual function, memory, anxiety and many others.11 Serotonin exerts its effects through seven families of receptors (5-HT1 – 5-HT7) further divided into several subclasses. Except for 5-HT3 receptor which is a ligand-gated ion channel, the serotonin receptors belong to the G-protein coupled receptor family. Due to a lack of selective ligands, there is still little known about several 5-HT receptor subclasses.12 Marine monoindole alkaloids, sharing structure similarities with serotonin, are certain to become useful tools to facilitate the understanding of serotonin receptor function and generate new drug leads for the treatment of depression, anxiety, migraines and other 5HT receptor related disorders.

Natural product synthesis using multicomponent reaction strategies.

Abstract: The preparation of urea by Wöhler constituted a landmark achievement in organic chemistry, and it laid the ground for the early days of target-oriented organic synthesis.1 Since then, significant progress has been achieved in this discipline; many powerful single bond forming reactions and asymmetric variants have been developed. These discoveries have paved the way for the stereoselective assembly of complex organic molecules, a task deemed inconceivable by early practitioners. A great many strategies were invented by chemists in order to facilitate the synthesis of complex natural products.2 One avenue in emulating nature’s efficiency would * To whom correspondence should be addressed. E-mail: dennis.hall@ ualberta.ca. † Novartis Institute for Biomedical Research. ‡ Department of Chemistry, University of Alberta. Chem. Rev. 2009, 109, 4439–4486 4439

The Role of Natural Product Chemistry in Drug Discovery

Abstract: Although traditionally natural products have played an important role in drug discovery, in the past few years most Big Pharma companies have either terminated or considerably scaled down their natural product operations. This is despite a significant number of natural product-derived drugs being ranked in the top 35 worldwide selling ethical drugs in 2000, 2001, and 2002. There were 15 new natural product-derived drugs launched from 2000 to 2003, as well as 15 natural product-derived compounds in Phase III clinical trials or registration at the end of 2003. Recently, there has been a renewed interest in natural product research due to the failure of alternative drug discovery methods to deliver many lead compounds in key therapeutic areas such as immunosuppression, anti-infectives, and metabolic diseases. To continue to be competitive with other drug discovery methods, natural product research needs to continually improve the speed of the screening, isolation, and structure elucidation processes, as well addressing the suitability of screens for natural product extracts and dealing with issues involved with large-scale compound supply.

Lessons from natural molecules

Abstract: Natural products have inspired chemists and physicians for millennia. Their rich structural diversity and complexity has prompted synthetic chemists to produce them in the laboratory, often with therapeutic applications in mind, and many drugs used today are natural products or natural-product derivatives. Recent years have seen considerable advances in our understanding of natural-product biosynthesis. Coupled with improvements in approaches for natural-product isolation, characterization and synthesis, these could be opening the door to a new era in the investigation of natural products in academia and industry.