Marine Toxins with Spiroimine Rings: Total Synthesis of Pinnatoxin A

This microreview provides a compilation of synthetic approaches and total syntheses of pinnatoxin A in a survey of the literature up to early 2010. Pinnatoxin A is the first discovered and representative member of a fascinating group of potent marine toxins that share a spiroimine subunit as a unifying structural element.     

Feasibility of gymnodimine and 13-desmethyl C spirolide detection by fluorescence polarization using a receptor-based assay in shellfish matrixes

The detection of toxins in shellfish through reliable methods is essential for human health preservation and prevention of economic losses in the aquaculture industry. Although no human intoxication has been unequivocally linked to gymnodimines or spirolides, these phycotoxins are highly toxic by intraperitoneal injection causing false positives in lipophilic toxin detection by the mouse bioassay. Based on the detection of molecular interactions by fluorescence polarization an inhibition assay was developed using fluorescent α-bungarotoxin and nicotinic acetylcholine receptor-enriched membranes of Torpedo marmorata to detect gymnodimine and 13-desmethyl C spirolide. Both toxins, classified into the cyclic imine group, inhibit the interaction of α-bungarotoxin with Torpedo nicotinic acetylcholine receptors in the nM range. In this study we analyze the matrix effect of four shellfish species on the fluorescence polarization assay. Mussels, clams, cockles and scallops were extracted with acetone and sequentially partitioned with n-hexane and chloroform. The interference of these shellfish extracts with the α-bungarotoxin fluorescence or its binding to the nicotinic acetylcholine receptor was lower than 11%. The average recovery rates of gymnodimine and 13-desmethyl C spirolide using these solvents were 90.6 ± 7.8% and 89.6 ± 3.2%, respectively with variations among species. The quantification range of this fluorescence polarization assay for gymnodimine and 13-desmethyl C spirolide in all tested species was 80-2000 μg kg⁻¹ and 85-700 μg kg⁻¹ of shellfish meat, respectively. This assay format can be used to detect gymnodimine and 13-desmethyl C spirolide in shellfish as a screening assay.     

Ligand-binding assays for cyanobacterial neurotoxins targeting cholinergic receptors

Toxic cyanobacterial blooms are a threat to public health because of the capacity of some cyanobacterial species to produce potent hepatotoxins and neurotoxins. Cyanobacterial neurotoxins are involved in the rapid death of wild and domestic animals by targeting voltage gated sodium channels and cholinergic synapses, including the neuromuscular junction. Anatoxin-a and its methylene homologue homoanatoxin-a are potent agonists of nicotinic acetylcholine receptors. Since the structural determination of anatoxin-a, several mass spectrometry-based methods have been developed for detection of anatoxin-a and, later, homoanatoxin-a. Mass spectrometry-based techniques provide accuracy, precision, selectivity, sensitivity, reproducibility, adequate limit of detection, and structural and quantitative information for analyses of cyanobacterial anatoxins from cultured and environmental cyanobacterial samples. However, these physicochemical techniques will only detect known toxins for which toxin standards are commercially available, and they require highly specialized laboratory personnel and expensive equipment. Receptor-based assays are functional methods that are based on the mechanism of action of a class of toxins and are thus, suitable tools for survey of freshwater reservoirs for cyanobacterial anatoxins. The competition between cyanobacterial anatoxins and a labelled ligand for binding to nicotinic acetylcholine receptors is measured radioactively or non-radioactively providing high-throughput screening formats for routine detection of this class of neurotoxins. The mouse bioassay is the method of choice for marine toxin monitoring, but has to be replaced by fully validated functional methods. In this paper we review the ligand-binding assays developed for detection of cyanobacterial and algal neurotoxins targeting the nicotinic acetylcholine receptors and for high-throughput screening of novel nicotinic agents.     

A Rapid Synthesis of 4‐Oxazolidinones: Total Synthesis of Synoxazolidinones A and B

A five‐step total synthesis of the marine natural product synoxazolidinone A was achieved through a diastereoselective imine acylation/cyclization cascade. Synoxazolidinone B and a series of analogues were also prepared to explore the potential of these 4‐oxazolidinone natural products as antimicrobial agents. These studies confirmed the importance of the chlorine substituent for antimicrobial activity and revealed simplified dichloro derivatives that are equally potent against several bacterial strains.     

6,6-Spiroimine analogs of (-)-gymnodimine A: synthesis and biological evaluation on nicotinic acetylcholine receptors

Simple models of the spiroimine core of (-)-gymnodimine A have been synthesized in racemic and optically active forms. The quaternary carbon of the racemic spiroimines was created by Michael addition of a β-ketoester to acrolein, whereas the asymmetric allylic alkylation of the same β-ketoester was used to access the spiroimines in an enantioselective fashion. Both racemic and enantio-enriched mixtures were tested for their biological activities on Xenopus oocytes either expressing (human α4β2) or having incorporated (Torpedoα1(2)βγδ) nicotinic acetylcholine receptors (nAChRs). These spiroimine analogs of (-)-gymnodimine A inhibited acetylcholine-evoked nicotinic currents, but were less active than the phycotoxin. Our results reveal that the 6,6-spiroimine moiety is important for the blockade of nAChRs and support the hypothesis that it is one of the pharmacophores of this group of toxins.     

Design and synthesis of a trans-fused polycyclic ether skeleton as an α-helix mimetic scaffold

Inspired by the common skeletal feature of potent marine toxins, a ladder-like polycyclic ether scaffold was designed as the basis for the synthesis of structurally defined α-helix mimics. A synthetic route to trans-fused 6/6/6/6/6 pentacyclic ether skeletons is presented, involving the iterative assembly of tetrahydropyran rings via the SmI₂-mediated coupling reaction of α-sulfonyl ketones with aldehydes.     

Ion Channels as Sensing Elements-Investigations by Patch-Clamp Technique

Ion channels are transmembrane proteins. Their high recognition capability together with an intrinsic amplification effects makes them outstanding candidates as constituents of biosensors. The patch-clamp technique is an extremely powerful and versatile method for studying the functioning of ion channels reconstituted into biological or synthetic membranes. Two well characterized types of natural ion channels were studied, (i) the simple transmembrane protein gramicidin A and (ii) the rather complex ligand-gated nicotinic acetylcholine receptor.     

Total synthesis of potent antifungal marine bisoxazole natural products bengazoles A and B

The bengazoles are a family of marine natural products that display potent antifungal activity and a unique structure, containing two oxazole rings flanking a single carbon atom. Total syntheses of bengazole A and B are described, which contain a sensitive stereogenic centre at this position between the two oxazoles. Additionally, the synthesis of 10-epi-bengazole A is reported. Two parallel synthetic routes were investigated, relying on construction of the 2,4-disubstituted oxazole under mild conditions and a diastereoselective 1,3-dipolar cycloaddition. Our successful route is high yielding, provides rapid access to single stereoisomers of the complex natural products and allows the synthesis of analogues for biological evaluation.     

Actin-binding marine macrolides: total synthesis and biological importance

Marine organisms produce a fascinating range of structurally diverse secondary metabolites, which often possess unusual and sometimes unexpected biological activities. This structural diversity makes these marine natural products excellent molecular probes for the investigation of biochemical pathways. Recently, a number of novel and stereochemically complex macrolides, having a large macrolactone (22- to 44-membered) ring, that interact with the actin cycloskeleton have been isolated from different marine sources. Actin, like tubulin, is a major component of the cytoskeleton and has important cellular functions. Although the details of these interactions are still under investigation, these marine macrolides are becoming increasingly important as novel molecular probes to help elucidate the cellular functions of actin. Owing to their potent antitumor activities, these compounds, for example the aplyronines, also have potential for preclinical development in cancer chemotherapy. Their appealing molecular structures, with an abundance of stereochemistry, and biological significance, coupled with the extremely limited availability from the marine sources, have stimulated enormous interest in the synthesis of these compounds. This review summarizes the biological properties of these unusual marine natural products and features the recently completed total syntheses of swinholide A, scytophycin C, aplyronine A, mycalolide A--all of these being potent cytotoxic agents that target actin--and a diastereoisomer of ulapualide A. Rather than detailing each individual step of these multistep total syntheses, the different synthetic strategies, key reactions, and methods adopted for controlling the stereochemistry are compared.     

Synthesis of 5‐ and 8‐Deoxytetrodotoxin

Tetrodotoxin, a toxic principle of puffer fish intoxication, is one of the most famous marine natural products owing to its complex structure and potent biological activity, which leads to fatal poisoning. Continuous synthetic studies on tetrodotoxin and its analogues to elucidate biologically interesting issues associated with tetrodotoxin have led to the development of versatile routes for a variety of tetrodotoxin derivatives. With the aim of investigating the structure–activity relationship of tetrodotoxin with voltage‐gated sodium channels, this study describes the first total syntheses of 5‐deoxytetrodotoxin, a natural analogue of tetrodotoxin, and 8‐deoxytetrodotoxin, an unnatural analogue, from a newly designed, versatile intermediate in an efficient manner. An estimation of the biological activities of these compounds reveals the importance of the hydroxy groups at the C‐5 and C‐8 positions on the inhibition of voltage‐gated sodium channels.     

Synthetic routes and biological evaluation of largazole and its analogues as potent histone deacetylase inhibitors

Natural products with interesting biological properties and structural diversity have often served as valuable lead drug candidates for the treatment of various human diseases. Largazole, isolated from the marine cyanobacterium Symploca sp. has exhibited potent inhibitory activity against many cancer cell lines. Besides, it shows remarkable selectivity between transformed and nontransformed cells, which is the main disadvantage of other antitumor natural products such as paclitaxel and actinomycin D. Due to its potential as a potent and selective anticancer drug candidate, a great deal of attention has been focused on largazole and its analogues. It is the aim of this review to highlight synthetic aspects of largazole and its analogues as well as their preliminary structure-activity relationship studies.     

Studies toward (-)-gymnodimine: concise routes to the spirocyclic and tetrahydrofuran moieties

[formula: see text] (-)-Gymnodimine is a member of a unique class of potent marine toxins possessing imines within a spirocylic array. Herein we report the synthesis of the tetrahydrofuran fragment and a strategy toward the spirocyclic imine fragment of this family of toxins. Key reactions include an asymmetric anti-aldol reaction to set the stereochemistry of the tetrahydrofuran and a formal, intermolecular Diels-Alder reaction involving an alpha-methylene-delta-lactam and a dienyne.     

Synthesis of Cytotoxic Palmerolides

The chemical synthesis of the palmerolides is the subject of this review. The palmerolides are a family of Antarctic marine natural products, many of which display potent and selective cytotoxicity against melanoma cells. The confluence of promising bioactivities, limited natural supplies, and complex structures makes the palmerolides exciting targets for chemical synthesis. To date, several approaches have been reported, and a consensus strategy based on convergent fragment assembly has emerged. Collective wisdom from myriad approaches reviewed here may enable hybrid strategies capable of delivering larger amounts of synthetic palmerolides to support continued biological studies. Considering the relative lack of options for melanoma chemotherapy and the intriguing activity profile of the palmerolides, efforts aimed at developing an efficient, gram‐scale synthesis of palmerolide A and congeneric structures should be given a high priority.     

Diastereoselective one-pot Wittig olefination-Michael addition and olefin cross metathesis strategy for total synthesis of cytotoxic natural product (+)-varitriol and its higher analogues

A stereoselective route for the total synthesis of anticancer marine natural product (+)-varitriol (1) is detailed herein. The impressive biological activity and interesting structural features of natural (+)-varitriol fuelled us to undertake the synthesis of some higher analogues (1a-j) of this molecule. The key features of the synthetic strategy include one-pot Wittig olefination followed by a highly diastereoselective oxa-Michael addition to assemble stereochemically pure tetrasubstituted THF moiety of the natural varitriol and olefin cross metathesis to couple the aromatic part with tetrasubstituted THF moiety. The total synthesis of title natural product is efficient with 21.8% overall yield for 9 linear steps from D-ribose and thus facilitates the more scaled-up practical route for the synthesis of 1 and its analogues as well. The synthetic (+)-varitriol (1) and its analogues were screened for their cytotoxicity. The present synthetic approach paves the way for preparation of numerous analogues of the title natural product for drug development.     

Review and assessment of in vitro detection methods for algal toxins

Algal toxins produced by marine and freshwater microalgae present a significant analytical challenge because of their complex structures and frequent occurrence as mixtures of structural congeners, which differ in toxic potencies and are present at varying proportions in contaminated samples. Rapid, sensitive in vitro detection methods specific for each class of algal toxins have been developed over the past decade, including immunoassays, enzyme inhibition assays, receptor assays, and cell assays. This review discusses the conceptual approaches to assay development and provides a detailed assessment of the use of in vitro detection methods for marine and freshwater algal toxins.     

Medicinal Chemical Studies of Anti-Inflammatory and Analgesic Natural Products

Following the discovery of salicylates and its conversion to aspirin, natural products research has provided many promising leads for further modification as anti-inflammatory and analgesic agents. Recent studies have focused on biosynthesis inhibitors of eicosanoids and receptor antagonists of the platelet activating factor, including a new class of dual functional inhibitors derived from neolignans. The highly potent analgesic alkaloid epibatidine from the frog skin has been synthesized and recharacterized as a very strong acetylcholine nicotinic receptor agonist. Some novel epibatidine analogs have shown promise as potential CNS drugs and research probes for clarifying the anti-addictive property of the African alkaloid ibogaine.     

A survey of marine natural compounds and their derivatives with anti-cancer activity reported in 2010

Although considerable progress in oncology therapeutics has been achieved in the last century, cancer remains one of major death causes in the World and for this reason, the development of novel cancer drugs remains a pressing need. Natural marine compounds represent an interesting source of novel leads with potent chemotherapeutic or chemo-preventive activities. In the last decades, structure-activity-relationship studies have led to the development of naturally-derived or semi-synthetic analogues with improved bioactivity, a simplified synthetic target or less toxicity. We aim here to review a selection of natural compounds with reported anticancer activity isolated of marine sources and their associated analogues published in 2010.     

Synthesis of Tetrodotoxin,a Classic but Still Fascinating Natural Product

Tetrodotoxin, a toxic principle of puffer fish intoxication, is one of the most famous marine natural products due to its densely functionalized structure and potent toxicity. Despite its small molecular size (MW 319 g mol^?1), tetrodotoxin has long been well known as a formidable molecule in natural product synthesis. We have devoted more than twenty years to developing synthetic strategies for this molecule, resulting in the preparation of a variety of analogues of tetrodotoxin for biological experiments. This account describes a brief history of tetrodotoxin research and an overview of our synthetic efforts toward tetrodotoxin with the underlying logic and strategy.     

Synthesis,insecticidal activities,and molecular docking studies of 1,5‐disubstituted‐1,3,5‐hexahydrotriazine‐2‐(N‐nitro)imines

A series of novel neonicotinoids analogs were designed by modifying the pharmacophore of imidacloprid to 1,3,5‐hexahydrotriazine conjugated to nitroimine (?NNO₂) and introducing the phenyl or arylmethyl at the 5‐position, and their insecticidal activities were evaluated. Introducing a heterocyclic methyl at 5‐position increased the insecticidal activities, whereas other phenyl, phenylmethyl or phenylethyl substituents were unfavorable to activities. Molecular docking study was also performed to clarify the interactions of the most potent analog 1‐((6‐chloropyridin‐3‐yl)methyl)‐5‐(3‐pyridylmethyl)‐1,3,5‐hexahydrotriazine‐2‐(N‐nitro) imine ( 7s ) with the target nicotinic acetylcholine receptor, which explained the structure‐activity relationships observed in vitro, and revealed further possibilities for insecticide development. J. Heterocyclic Chem., (2011).