Current Medicinal Chemistry

ISSN: 0929-8673

Abstracts


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Pharmacology of cannabinoid receptor ligands
Pertwee, RG

Mammalian tissues contain at least two types of cannabinoid receptor, CB1 and CB2, both coupled to G proteins. CB1 receptors are expressed mainly by neurones of the central and peripheral nervous system whereas CB2 receptors occur in certain non-neuronal tissues, particularly in immune cells. The existence of endogenous ligands for cannabinoid receptors has also been demonstrated. The discovery of this 'endogenous cannabinoid system' has been paralleled by a renewed interest in possible therapeutic applications of cannabinoids, for example in the management of pain and in the suppression of muscle spasticity/spasm associated with multiple sclerosis or spinal cord injury. It has also prompted the development of a range of novel cannabinoid receptor ligands, including several that show marked selectivity for CB1 or CB2 receptors. This review summarizes current knowledge about the in vitro pharmacological properties of important CB1 and CB2 receptor ligands. Particular attention is paid to the binding properties of these ligands, to the efficacies of cannabinoid receptor agonists, as determined using cyclic AMP or [S-35]GTP gamma S binding assays, and to selected examples of how these pharmacological properties can be influenced by chemical structure. The in vitro pharmacological properties of ligands that can potently and selectively oppose the actions of CB1 or CB2 receptor agonists are also described. When administered by themselves, some of these ligands produce effects in certain tissue preparations that are opposite in direction to those produced by cannabinoid receptor agonists and the possibility that the ligands producing such 'inverse cannabimimetic effects' are inverse agonists rather than pure antagonists is discussed.


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Glutathione S-transferases - A review
Salinas, AE; Wong, MG

The Glutathione S-transferases (GSTs) form a group of multi-gene isoenzymes involved in the cellular detoxification of both xenobiotic and endobiotic compounds. GSTs have been divided into a number of subclasses, alpha (a), mu (mu), Pi (pi), and theta (theta). The classification was made on the basis of sequence similarity and immunological cross-reactivity. GSTs show a high level of specificity toward GSH but the electrophilic second substrate can vary significantly both between and within the Glasses in spite of their sequence similarity. X-ray crystallography and site-directed mutagenesis studies have together elucidated the structure and mechanism of GSTs. Catalysis occurs by conjugation with glutathione (GSH) and the less toxic and more hydrophilic products can then be partially metabolised and excreted. This invaluable service is however disadvantageous during chemotherapy where GSTs have been associated with multi-drug resistance of tumour cells. Levels of expression of different isoforms of GSTs are tissue specific. The variations in expression between normal and tumour cells are of interest and in most cases the levels of GSTs are increased, especially pi-GST. Understanding the complex role that GSTs play in drug resistance begins with determining the pattern of isoform expression and the substrate specificities of each isoform. The use of isozyme-specific, GSH analogues as inhibitors to modulate GST activity during chemotherapy is a promising strategy in the battle against cancer. This review attempts to provide a detailed overview of the literature concerning the different classes of GSTs, their function and mechanism and the use of GSTs as therapeutic targets for disease as current at the time of submission.


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Flavonoid antioxidants
Rice-Evans, C

In order to ascertain the role of dietary flavonoids as antioxidants in vivo it is necessary to understand the chemical nature of the absorbed forms in the circulation in vivo and how the multiplicity of research findings in vitro reflect the bioactivity of flavonoids in vivo. Only when we gain adequate information on the circulating forms can we begin to understand the targeting to the tissues, whether flavonoids cross the blood-brain barrier, for example, and in what forms. Flavonoids are powerful antioxidants in vitro, but their overall function in vivo has yet to be clarified, whether antioxidant, anti-inflammatory, enzyme inhibitor, enzyme inducer, inhibitor of cell division, or some other role. It should also be emphasised that the reducing properties of flavonoids might contribute to redox regulation in cells, independently of their antioxidant properties, and thus might protect against cell ageing, for example, by working together with the intracellular reductant network. To gain understanding of these issues the factors influencing the absorption of flavonoids in the gastrointestinal tract needs to be established, namely the questions of: de-glycosylation before absorption, conjugation in the small intestine through glucuronidation, sulphation or methylation etc, metabolism and degradation in the colon to smaller phenolic molecules. The forms in which they circulate in vivo will influence their polarity and, thus, their localization and bioactivities in vivo. Finally if antioxidant activities are important, the elucidation of how such properties in vitro relate to the potential for conjugates and metabolites in vivo to act as antioxidants is required. The absorbed flavonoid components might function in the aqueous phase (like vitamin C) or in the lipophilic milieu (as vitamin E) in vivo. This will depend on their polarity properties on uptake, how they are metabolised on absorption, and their resulting structural forms in the circulation.


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Metals, toxicity and oxidative stress
Valko, M; Morris, H; Cronin, MTD

other mechanisms, involving formation of hydrogen peroxide under physiological conditions, have been proposed. The unifying factor in determining toxicity and carcinogenicity for all these metals is the generation of reactive oxygen and nitrogen species. Common mechanisms involving the Fenton reaction, generation of the superoxide radical and the hydroxyl radical appear to be involved for iron, copper, chromium, vanadium and cobalt primarily associated with mitochondria, microsomes and peroxisomes. However, a recent discovery that the upper limit of "free pools" of copper is far less than a single atom per cell casts serious doubt on the in vivo role of copper in Fenton-like generation of free radicals. Nitric oxide (NO) seems to be involved in arsenite-induced DNA damage and pyrimidine excision inhibition. Various studies have confirmed that metals activate signalling pathways and the carcinogenic effect of metals has been related to activation of mainly redoxsensitive transcription factors, involving NF-kappaB, AP-1 and p53. Antioxidants (both enzymatic and nonenzymatic) provide protection against deleterious metal-mediated free radical attacks. Vitamin E and melatonin can prevent the majority of metal-mediated (iron, copper, cadmium) damage both in vitro systems and in metal-loaded animals. Toxicity studies involving chromium have shown that the protective effect of vitamin E against lipid peroxidation may be associated rather with the level of non-enzymatic antioxidants than the activity of enzymatic antioxidants. However, a very recent epidemiological study has shown that a daily intake of vitamin E of more than 400 IU increases the risk of death and should be avoided. While previous studies have proposed a deleterious pro-oxidant effect of vitamin C (ascorbate) in the presence of iron (or copper), recent results have shown that even in the presence of redox-active iron (or copper) and hydrogen peroxide, ascorbate acts as an antioxidant that prevents lipid peroxidation and does not promote protein oxidation in humans in vitro. Experimental results have also shown a link between vanadium and oxidative stress in the etiology of diabetes. The impact of zinc (Zn) on the immune system, the ability of zinc to act as an antioxidant in order to reduce oxidative stress and the neuroprotective and neurodegenerative role of zinc (and copper) in the etiology of Alzheimer's disease is also discussed. This review summarizes recent findings in the metal-induced formation of free radicals and the role of oxidative stress in the carcinogenicity and toxicity of metals.


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ATP-site directed inhibitors of cyclin-dependent kinases
Gray, N; Detivaud, L; Doerig, C; Meijer, L

Cyclin-dependent kinases trigger and coordinate transitions between different phases the cell division cycle (CDK1, 2, 3, 4, 6, 7). They also play a role in apoptosis (CDK2), in neuronal cells (CDK5) and in the control of transcription (CDK 7, 8, 9). Intensive screening has lead to the recent identification of a series of chemical inhibitors of CDKs: olomoucine, roscovitine, purvalanol, CVT-313, flavopiridol, gamma-butyrolactone, indirubins, paullones and staurosporine. Some of these compounds display remarkable selectivities and efficiencies (IC50 < 25 nM). Many have been co-crystallised with CDK2 and their interactions with the kinase have been analysed in atomic detail. These inhibitors all act by competing with ATP for binding at the catalytic site. Most inhibitors present a flat heterocyclic ring system that occupies the purine binding pocket as well as form 2 or 3 hydrogen bonds with Glu-81 and Leu-83. The binding modes of these inhibitors are reviewed in this article. Knowledge of the CDK/inhibitor interactions will be of great help to design inhibitors with improved selectivity our potency as well as to generate affinity chromatography matrices for the purification and identification of their cellular targets. The potential use of CDK inhibitors is being extensively evaluated in cancer chemotherapy and other fields such as the cardiovascular domain (restenosis), dermatology (psoriasis), nephrology (glomerulonephritis) parasitology (unicellular parasites such as Plasmodium, Trypanosomes, Toxoplasm,...etc.), neurology (Alzheimer's disease) and viral infections (cytomegalovirus, H.I.V., herpes).


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Multi-component reactions : Emerging chemistry in drug discovery 'From xylocain to crixivan'
Hulme, C; Gore, V

With the recent emergence of combinatorial chemistry and high-speed parallel synthesis for drug discovery applications, the multi-component reaction (MCR) has seen a resurgence of interest. Easily automated one-pot reactions, such as the Ugi and Passerini reactions, are powerful tools for producing diverse arrays of compounds, often in one step and high yield. Despite this synthetic potential, the Ugi reaction is limited by producing products that are flexible and peptide-like, often being classified as 'non drug-like'. This review details developments of new, highly atom-economic MCR derived chemical methods, which enable the fast and efficient production of chemical libraries comprised of a variety of biologically relevant templates. Representative examples will also be given demonstrating the successful impact of MCR combinatorial methods at different stages of the lead discovery, lead optimization and pre-clinical process development arenas. This will include applications spanning biological tools, natural products and natural product-like diversity, traditional small molecule and 'biotech' therapeutics respectively. In particular, this review will focus on applications of isocyanide based MCR (IMCR) reactions.


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Chemistry and biochemistry of oxidative stress in neurodegenerative disease
Sayre, LM; Smith, MA; Perry, G

The age-related neurodegenerative diseases exemplified by Alzheimer's disease (AD), Lewy body diseases such as Parkinson's disease (PD), amyotrophic lateral sclerosis (ALS), and Huntington's disease are characterized by the deposition of abnormal forms of specific proteins in the brain. Although several Factors appear to underlie the pathological depositions, the cause of neuronal death in each disease appears to be multifactorial. In this regard, evidence in each case for a role of oxidative stress is provided by the finding that the pathological deposits are immunoreactive to antibodies recognizing protein side-chains modified either directly by reactive oxygen or nitrogen species, or by products of lipid peroxidation or glycoxidation. Although the source(s) of increased oxidative damage are not entirely clear, the findings of increased localization of redox-active transition metals in the brain regions most affected is consistent with their contribution to oxidative stress. It is tempting to speculate that free radical oxygen chemistry plays a pathogenetic role in all these neurodegenerative conditions, though it is as yet undetermined what types of oxidative damage occur early in pathogenesis, and what types are secondary manifestations of dying neurons. Delineation of the profile of oxidative damage in each disease will provide clues to how the specific neuronal populations are differentially affected by the individual disease conditions.


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Beta-peptides: Twisting and turning
Gademann, K; Hintermann, T; Schreiber, JV

Oligomers of beta-amino acids (beta-peptides), which are readily available by standard methods either in solution or on solid support, adopt a large variety of different secondary structures in solution and in the solid state. beta-Peptides 4, 5 and 10 fold into a helix with 3 residues per turn and 14-membered H-bonded rings (3(14) helix) that is left-handed for 5 and 10 and right-handed for 2 (due to the reversal of the chirality of the building blocks), as was clearly demonstrated by two-dimensional NMR-spectroscopy, This helix thermally is very stable in methanol solution upon heating. As shown by NMR- and CD-spectroscopy, it is partially populated even at 100 degrees C (Figure 3). Another helix was discovered for, mixed' beta-peptide 8 in methanol solution: it is characterized by 12- and 10- membered turns (Figure 4, left) and its central 10-membered turn has been found in the solid state of a geminally disubtituted beta-peptide (Figure 4, right). This central 10-membered turn was used as a scaffold to attach beta-amino acid residues that prefer a linear (non-helical) conformation (beta-peptide 21): a hairpin (pleated sheet-turn-pleated sheet) structure was determined in solution by NMR-spectroscopy (Figure 5). In contrast to this antiparallel pleated-sheet, a parallel pleated sheet was found for a beta-tripeptide in the solid state. For the first time it was possible to observe reversible peptide folding in MD simulations by studying beta-peptides (Figure 6) and to determine folding pathways and intermediates. beta-Peptides are a new class of promising peptidomimetics. They are resistant against the degradation by proteolytic enzymes such as pepsin, elastase, carboxypeptidase A, pronase or proteasom 20S. A variety of beta-amino acids (27-34) was shown to be non- mutagenic by Ames tests and beta-peptides 47 and 48 reveal large elimination half-lives of 3 h (for 47) and 10 h (for 48) in the serum of rodents (Figure 7). Conjugates of alpha- and beta- peptides are efficient ligands for the HLA*B27 MHC Class I protein, a five fold increase of binding (2.0 mu M for 55) compared to a natural peptidic ligand 51 was observed. Furthermore, beta-peptides are able to mimic natural alpha-peptidic hormones such as somatostatin. The cyclo-beta-tetrapeptide 57 binds to the five human somatostatin receptors in the micromolar range. In addition, several other non-natural oligomers such as beta-peptide nucleic acids (built from 58 and 59), beta-peptoids (60), oligomers of anthranilic acids and beta-sulfonamido peptides are discussed.


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Biologically-Active cyclopropanes and cyclopropenes
Salaun, J; Baird, Ms

The variety of biological systems which are modulated by naturally occurring cyclopropanes has only been realized recently. They range from antibiotic, antiviral, antifungal and insecticidal activities, control of plant growth and fruit ripening, antimycotic, thyromimetic, hormonal, carcinogenic or antitumoral activities, enzyme and gluconeogenesis inhibitions, to neurochemical activity. Cyclopropanes are also major components of membranes, for instance in tuberculosis cells, and key intermediates in many biosynthetic processes. Many synthetic drugs include cyclopropanes in their structure and they are also widely used to probe the mechanisms of biological processes. Naturally occurring cyclopropenes are known to be potent enzyme inhibitors controlling key processes on the fatty acid desaturation cycle and, in one case, to be an antibacterial agent. Synthetic analogues similarly inhibit pheromone production in insects, and the production of bacterial membranes, and interfere with the behaviour of insects by blocking pheromone receptors. When they have been demonstrated, the mechanisms responsible for the specific bioactivity of these systems are also reviewed.


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Recent advances in the enantioselective synthesis of beta-amino acids
Juaristi, E; Lopez-Ruiz, H

The introductory section of this review presents some of the currently most compelling beta-amino acid targets, according to their structural types: (alpha- and beta-aryl substituted, olefinic and alkynyl, alpha,alpha- and alpha,beta-disubstituted, cyclic and conformationally restricted, fluorine-containing, and phosphonic analogous p-amino acids. The main section highlights some of the very new (1996-1998), promising methodology for the enantioselective synthesis of beta-amino acids, with especial emphasis on catalytic and enzymatic processes, as well as methods based on "chiral pool", "self-regeneration of stereogenic centers", diastereoselective nucleophilic additions to prochiral double bonds, and enantioselective reactions in the presence of chiral additives.