Simultaneous determination of total ergot alkaloids in wheat flour by Orbitrap mass spectrometry.

The optimization screening methods for total ergot alkaloids in wheat extracts involve transforming them into a single compound, which is then analyzed via high-resolution Orbitrap mass spectrometry (Orbitrap MS). Orbitrap MS provides highly sensitive and accurate mass measurements, enhancing the selectivity and sensitivity of the analysis. Various hydrolysis and reduction methods have been investigated, and the use of superhydrides has emerged as the most effective method for transforming ergopeptine alkaloids. This study also focused on the epimerization of ergot alkaloids, particularly the differences between R- and S-epimers and their impact on the mass spectra. We validated our method by assessing the linearity, sensitivity, recovery, matrix effects, repeatability, and stability. The limits of detection and quantitation were set at 0.43 and 1.30 µg LSA/kg wheat, respectively. The proposed method offers a robust analytical approach for screening and quantifying total ergot alkaloids in wheat samples, addressing important concerns about their presence in food and feed.

Ergot alkaloids in sclerotia collected in Japan: synthetic profiles and induction of apoptosis by Clavine-type compounds.

The genus Claviceps (Clavicipitaceae) is famous for producing ergot alkaloids (EAs) in sclerotia. EAs can cause ergotism, resulting in convulsions and necrosis when ingested, making these compounds a serious concern for food safety. Agroclavine (2), a typical Clavine-type EA, is a causative agent of ergotism and is listed as a compound to be monitored by the European Food Safety Authority. Clavine-type EAs are known to cause cytotoxicity, but the mechanism has not been elucidated. We performed annexin V and PI double-staining followed by flow cytometric analysis to detect apoptosis in HepG2 and PANC-1 cells after exposure to Clavine-type EAs. Clavine-type EAs reduced cell viability and induced apoptosis in both cell lines. We then performed LC-MS analysis of EAs from 41 sclerotia samples of Claviceps collected in Japan. 24 out of 41 sclerotia extracts include peptide-type EAs (ergosine/inine: 4/4', ergotamine: 5, ergocornine/inine: 6/6', α-ergocryptine/inine: 8/8', and ergocristine/inine: 9/9') and 19 sclerotia extracts among 24 sclerotia detected peptide type EAs include Clavine-type EAs (pyroclavine: 1, agroclavine: 2, festuclavine: 3) by LC-MS. We then performed a metabolomic analysis of the EAs in the sclerotia using principal component analysis (PCA). The PCA score plots calculated for EAs suggested the existence of four groups with different EA production patterns. One of the groups was formed by the contribution of Clavine-type EAs. These results suggest that Clavine-type EAs are a family of compounds requiring attention in food safety and livestock production in Japan.

Derivation of the multiply-branched ergot alkaloid pathway of fungi.

Ergot alkaloids are a large family of fungal specialized metabolites that are important as toxins in agriculture and as the foundation of powerful pharmaceuticals. Fungi from several lineages and diverse ecological niches produce ergot alkaloids from at least one of several branches of the ergot alkaloid pathway. The biochemical and genetic bases for the different branches have been established and are summarized briefly herein. Several pathway branches overlap among fungal lineages and ecological niches, indicating activities of ergot alkaloids benefit fungi in different environments and conditions. Understanding the functions of the multiple genes in each branch of the pathway allows researchers to parse the abundant genomic sequence data available in public databases in order to assess the ergot alkaloid biosynthesis capacity of previously unexplored fungi. Moreover, the characterization of the genes involved in the various branches provides opportunities and resources for the biotechnological manipulation of ergot alkaloids for experimentation and pharmaceutical development.

A Short Synthesis of Ergot Alkaloids and Evaluation of the 5-HT1/2 Receptor Selectivity of Lysergols and Isolysergols.

Key transformations in a four-step synthesis of the ergot alkaloid scaffold include a novel cesium carbonate-mediated hydrogen autotransfer alkylation to generate the C(3)-C(4) bond and an intramolecular Heck reaction that directly establishes the C(9)-C(10) alkene of methyl lysergate. An ester reduction and a streamlined experimental procedure establish a readily scalable, expedient total synthesis of all four stereoisomers of lysergol and isolysergol, including the previously unknown (-)-lysergol, for pharmacological evaluation at 5-HT1A and 5HT2A,B,C receptors. A bicyclic scaffold is also characterized for the first time in the intramolecular Heck coupling.

Sustained vascular contractile response induced by an R- and S-epimer of the ergot alkaloid ergocristine and attenuation by a noncompetitive antagonist.

Vasoconstriction is a known effect associated with ergot alkaloid consumption. The vascular contractile responses are often sustained for an extended period after exposure. Ergot alkaloids exist in two molecular configurations, the C-8-(R)-isomer (R-epimer) and the C-8-(S)-isomer (S-epimer). The sustained vascular contractile response to the R-epimers has been studied previously, unlike the S-epimers which are thought to be biologically inactive. Additionally, antagonists have been utilized to attenuate the vascular contraction associated with the R-epimers of ergot alkaloids utilizing ex vivo techniques. This study utilized an arterial tissue bath to examine and compare the sustained vascular contractile response attributed to ergocristine (R) and ergocristinine (S) using dissected bovine metatarsal arteries. The contractile blocking effect of a noncompetitive alpha-adrenergic antagonist, phenoxybenzamine (POB), was also investigated in precontracted arteries. Arteries (n = 6/epimer) were exposed to a single dose of ergocristine or ergocristinine (1 × 10-6 M in buffer). Each of the epimer doses was followed by a POB (1 × 10-3 M) or methanol (control) treatment at 90 min and the response was observed for another 90 min. Both epimers produced a sustained contractile response over the 180-min incubation period in the control groups. The R-epimer caused a greater sustained contractile response from 60 to 180 min post epimer exposure, compared to the S-epimer (P < 0.05, generalized estimating equations, independent t-test). Phenoxybenzamine caused a decrease in the contractile response induced by ergocristine and ergocristinine from 105 to 180 min, compared to the control (P < 0.05, generalized estimating equations, paired t-test). Overall, these results demonstrate the presence of a sustained vascular contractile response attributed to the R- and S-epimer of an ergot alkaloid with differences in contractile response between the epimers, suggesting differences in receptor binding mechanisms. Furthermore, this study demonstrated that a noncompetitive antagonist could attenuate the sustained arterial contractile effects of both ergot configurations ex vivo. Additional investigation into S-epimers of ergot alkaloids is needed. This research contributes to the understanding of the ergot epimer-vascular receptor binding mechanisms, which may support the investigation of different approaches of minimizing ergot toxicity in livestock.

Ergot alkaloids cause blood vessels to contract when contaminated feed is consumed by animals. Vascular contraction often remains for a prolonged period and involves the binding of ergot to specific receptors in the blood vessels. This study assessed and compared the sustained contraction of cow arteries after exposure to two forms of an ergot alkaloid, namely, ergocristine and ergocristinine. The effects of a specific receptor blocker, phenoxybenzamine, on the vascular contraction induced by these forms were also examined. This study showed that both forms of ergot caused a sustained contraction of cow arteries but to different magnitudes. Differences in contraction could be related to differences in how each form of ergot binds to receptors. The receptor blocker decreased the sustained contractile response of both forms of ergot. Further understanding of how the different forms of ergot bind to receptors, and how to decrease the adverse effects, may help mitigate the toxic effects of ergotism.

Alkaloid Biosynthetic Enzyme Generates Diastereomeric Pair via Two Distinct Mechanisms.

Ergopeptines constitute one of the representative classes of ergoline alkaloids and carry a tripeptide extension on the lysergic acid core. In the current study, we discovered and structurally characterized newly isolated ergopeptine-like compounds named lentopeptins from a filamentous fungus Aspergillus lentulus, a close relative of A. fumigatus. Interestingly, in lentopeptins, the common lysergic acid moiety of ergopeptines is replaced by a cinnamic acid moiety at the N-terminus of the peptide segment. Moreover, lentopeptins lack the C-terminal proline residue necessary for the spontaneous cyclization of the peptide extension. Herein, we report the atypical lentopeptin biosynthetic pathway identified through targeted deletion of the len cluster biosynthetic genes predicted from the genome sequence. Further in vitro characterizations of the thiolation-terminal condensation-like (T-CT) didomain of the nonribosomal peptide synthetase LenA and its site-specific mutants revealed the mechanism of peptide release via diketopiperazine formation, an activity previously unreported for CT domains. Most intriguingly, in vitro assays of the cytochrome P450 LenC illuminated the unique mechanisms to generate two diastereomeric products. Lentopeptin A forms via a stereospecific hydroxylation, followed by a spontaneous bicyclic lactam core formation, while lentopeptin B is produced through an initial dehydrogenation, followed by a bicyclic lactam core formation and stereospecific hydration. Our results showcase how nature exploits common biosynthetic enzymes to forge new complex natural products effectively (213/250).

Reconstituting the complete biosynthesis of D-lysergic acid in yeast.

The ergot alkaloids are a class of natural products known for their pharmacologically privileged molecular structure that are used in the treatment of neurological ailments, such as Parkinsonism and dementia. Their synthesis via chemical and biological routes are therefore of industrial relevance, but suffer from several challenges. Current chemical synthesis methods involve long, multi-step reactions with harsh conditions and are not enantioselective; biological methods utilizing ergot fungi, produce an assortment of products that complicate product recovery, and are susceptible to strain degradation. Reconstituting the ergot alkaloid pathway in a strain strongly amenable for liquid fermentation, could potentially resolve these issues. In this work, we report the production of the main ergoline therapeutic precursor, D-lysergic acid, to a titre of 1.7 mg L-1 in a 1 L bioreactor. Our work demonstrates the proof-of-concept for the biological production of ergoline-derived compounds from sugar in an engineered yeast chassis.

Determination of the Main Ergot Alkaloids and Their Epimers in Oat-Based Functional Foods by Ultra-High Performance Liquid Chromatography Tandem Mass Spectrometry.

An ultra-high performance liquid chromatography coupled to tandem mass spectrometry method is proposed for the determination of the major ergot alkaloids (ergometrine, ergosine, ergotamine, ergocornine, ergokryptine, ergocristine) and their epimers (ergometrinine, ergosinine, ergotaminine, ergocorninine, ergokryptinine, and ergocristinine) in oat-based foods and food supplements. A modified QuEChERS (quick, easy, cheap, effective, rugged, and safe) procedure was applied as sample treatment, reducing the consumption of organic solvent and increasing sensitivity. This method involved an extraction with acetonitrile and ammonium carbonate (85:15, v/v) and a clean-up step based on dispersive solid-phase extraction, employing a mixture of C18/Z-Sep+ as sorbents. Procedural calibration curves were established and limits of quantification were below 3.2 µg/kg for the studied compounds. Repeatability and intermediate precision (expressed as RSD%) were lower than 6.3% and 15%, respectively, with recoveries ranging between 89.7% and 109%. The method was applied to oat-based products (bran, flakes, flour, grass, hydroalcoholic extracts, juices, and tablets), finding a positive sample of oat bran contaminated with ergometrine, ergosine, ergometrinine, and ergosinine (total content of 10.7 µg/kg).

Cleaving Ergot Alkaloids by Hydrazinolysis-A Promising Approach for a Sum Parameter Screening Method.

Ergot alkaloids are mycotoxins formed by fungi of the Claviceps genus, which are some of the most common contaminants of food and feed worldwide. These toxins are a structurally heterogeneous group of compounds, sharing an ergoline backbone. Six structures and their corresponding stereoisomers are typically quantified by either HPLC-FLD or HPLC-MS/MS and the values subsequently summed up to determine the total ergot alkaloid content. For the development of a screening method targeting all ergot alkaloids simultaneously, the alkaloids need to be transferred to one homogeneous structure: a lysergic acid derivative. In this study, two promising cleaving methods-acidic esterification and hydrazinolysis-are compared, using dihydroergocristine as a model compound. While the acidic esterification proved to be unsuitable, due to long reaction times and oxidation sensitivity, hydrazinolysis reached a quantitative yield in 40‒60 min. Parallel workup of several samples is possible. An increasing effect on the reaction rate by the addition of ammonium iodide was demonstrated. Application of hydrazinolysis to a major ergot alkaloid mix solution showed that all ergopeptines were cleaved, but ergometrine/-inine was barely affected. Still, hydrazinolysis is a suitable tool for the development of a sum parameter screening method for ergot alkaloids in food and feed.

Biosynthesis, total synthesis, and biological profiles of Ergot alkaloids.

While the use of ergot alkaloids in folk medicine has been practiced for millennia, systematic investigations on their therapeutic potential began about 100 years ago. Subsequently, Albert Hofmann's discovery of lysergic acid diethylamide (LSD) and its intense psychedelic properties garnered worldwide attention and prompted further studies of this compound class. As a result, several natural ergot alkaloids were discovered and unnatural analogs were synthesized, and some were used to treat an array of maladies, including Alzheimer's and Parkinson's disease. While LSD was never commercially approved, recent clinical studies have found it can be an innovative and effective treatment option for several psychiatric disorders. Ongoing biosynthetic and total synthetic investigations aim to understand the natural origins of ergot alkaloids, help develop facile means to produce these natural products and enable their continued use as medicinal chemistry lead structures. This review recounts major developments over the past 20 years in biosynthetic, total synthetic, and pharmaceutical studies. Many ergot alkaloid biosynthetic pathways have been elucidated, with some of them subsequently applied toward "green" syntheses. New chemical methodologies have fostered a fast and efficient access to the ergoline scaffold, prompting some groups to investigate biological properties of natural product-like ergot alkaloids. Limited pharmaceutical applications have yet to completely bypass the undesirable side effects of ergotism, suggesting further studies of this drug class are likely needed and will potentially harness major therapeutic significance.

Overexpression of Trp-related genes in Claviceps purpurea leading to increased ergot alkaloid production.

The parasitic fungus Claviceps purpurea has been used for decades by the pharmaceutical industry as a valuable producer of ergot alkaloids. As the biosynthetic pathway of ergot alkaloids involves a common precursor L-tryptophan, targeted genetic modification of the related genes may improve production yield. In this work, the S76L mutated version of the trpE gene encoding anthranilate synthase was constitutively overexpressed in the fungus with the aim of overcoming feedback inhibition of the native enzyme by an excess of tryptophan. In another approach, the dmaW gene encoding dimethylallyltryptophan synthase, which produces a key intermediate for the biosynthesis of ergot alkaloids, was also constitutively overexpressed. Each of the above manipulations led to a significant increase (up to 7-fold) in the production of ergot alkaloids in submerged cultures.

Biomimetic Total Syntheses of Ergot Alkaloids via Decarboxylative Giese Coupling.

Biomimetic total syntheses of Festuclavine and Pyroclavine were achieved by a sequential radical coupling. The key steps include intramolecular decarboxylative Giese reaction to form the central C ring and 4-nitrobenzenesulfonyl (Ns)-directed indole C4-H olefination to introduce the indole C4 component. In addition, D-ring formation was completed by decarboxylative alkenylation and intramolecular SN2 reaction.

Interaction of fumigaclavine C with High Mobility Group Box 1 protein (HMGB1) and its DNA complex: A computational approach.

The fumigaclavines represent a small group of clavine-type alkaloids produced by the pathogenic fungus Aspergillus fumigatus. The leading compound in the family is fumigaclavine C (Fm-C) endowed with potent anti-inflammatory properties. Fm-C represses the production of several inflammatory cytokines in cells via a mechanism implicating a reduced nucleo-cytoplasmic transport and extracellular export of the alarmin protein HMGB1, through a direct drug-protein interaction, and a down-regulation of HMGB1 expression. We have investigated the interaction of Fm-C with HMGB1 using two complementary forms of the HMG-box protein, in its free and DNA-bound configurations, using molecular modeling. We identified up to six potential binding sites for Fm-C in the vicinity of the B-box of HMGB1, with the site designated Lys-103 being the most favored and maintained when the protein is bound to a 16-base pair DNA oligonucleotide. Structure-binding relationships have been explored through the comparison of the HMGB1-binding properties of fumigaclavines A, B and C, and the related alkaloid lysergic acid diethylamide (LSD). Both the C-9 acetyl group and C-2 dimethylallyl side chain of Fm-C contribute importantly to the protein interaction. LSD appears also to form stable complexes with free HMGB1. According to the calculated empirical energies of interaction (ΔE), the compounds rank in the order: Fm-C ∼ LSD < Fm-A < Fm-B, for binding to HMGB1. The study helps to better comprehend the mechanism of action of Fm-C, and its anti-inflammatory and anticancer properties.

Natural Ergot Alkaloids in Ocular Pharmacotherapy: Known Molecules for Novel Nanoparticle-Based Delivery Systems.

Several pharmacological properties are attributed to ergot alkaloids as a result of their antibacterial, antiproliferative, and antioxidant effects. Although known for their biomedical applications (e.g., for the treatment of glaucoma), most ergot alkaloids exhibit high toxicological risk and may even be lethal to humans and animals. Their pharmacological profile results from the structural similarity between lysergic acid-derived compounds and noradrenalin, dopamine, and serotonin neurotransmitters. To reduce their toxicological risk, while increasing their bioavailability, improved delivery systems were proposed. This review discusses the safety aspects of using ergot alkaloids in ocular pharmacology and proposes the development of lipid and polymeric nanoparticles for the topical administration of these drugs to enhance their therapeutic efficacy for the treatment of glaucoma.

Assessment of the vasoactive effects of the (S)-epimers of ergot alkaloids in vitro.

Ergot alkaloids are produced by the fungus Claviceps purpurea and their levels are carefully monitored in animal and human diets due to their harmful effects and widespread contamination of cereal crops. Ergot alkaloids exist in two forms known as the (R)- and (S)-epimers with only the former being monitored in diets in North America. The (S)-epimers of ergot alkaloids are thought to be biologically inactive and, therefore, harmless. A major mechanism by which the (R)-epimers of ergot alkaloids produce their toxic effect is through vasoconstriction. Therefore, the objective of this study was to examine the vasoactivity potential (contractile response) of four (S)-epimers, namely ergocryptinine, ergocristinine, ergocorninine, and ergotaminine utilizing an in vitro arterial tissue bath system. Bovine metatarsal arteries (n = 6, ergocryptinine and ergocorninine; n = 6, ergocristinine and ergotaminine; n = 6 arteries/(S)-epimer, total n = 12) were collected from healthy mixed-breed beef steers immediately after slaughter, cut into 3-mm arterial cross sections, and suspended in a tissue bath with continuously oxygenated Krebs-Henseleit buffer. To assess the contractile response of each (S)-epimer, a cumulative contractile dose-response curve was constructed by incubating arteries with increasing concentrations (1 × 10-11 to 1 × 10-6 M) of that (S)-epimer. Contractile responses were recorded as grams of tension and were normalized to an initial contraction of phenylephrine. Contrary to the widespread belief, all tested (S)-epimers were found vasoactive and produced a concentration-dependent arterial contractile response similar to what has been reported for the (R)-epimers. The arterial contractile response to ergotaminine was strongest and was significantly greater than that of ergocryptinine and ergocristinine at the highest concentration used (P ≤ 0.01). Our results indicate that the (S)-epimers are biologically active and are likely harmful similar to the (R)-epimers. The levels of (S)-epimers should be carefully monitored in human and animal diets worldwide.

Ergot alkaloid mycotoxins: physiological effects, metabolism and distribution of the residual toxin in mice.

The complex ergot alkaloids, ergovaline and ergotamine, cause dysregulation of physiological functions, characterised by vasoconstriction as well as thermoregulatory and cardiovascular effects in grazing livestock. To assess the effect of the mycotoxins, blood pressure and heart rate of male mice were measured, and metabolite profiling undertaken to determine relative abundances of both ergotamine and its metabolic products in body and brain tissue. Ergotamine showed similar cardiovascular effects to ergovaline, causing elevations in blood pressure and reduced heart rate. Bradycardia was preserved at low-levels of ergovaline despite no changes in blood pressure. Ergotamine was identified in kidney, liver and brainstem but not in other regions of the brain, which indicates region-specific effects of the toxin. The structural configuration of two biotransformation products of ergotamine were determined and identified in the liver and kidney, but not the brain. Thus, the dysregulation in respiratory, thermoregulatory, cardiac and vasomotor function, evoked by ergot alkaloids in animals observed in various studies, could be partially explained by dysfunction in the autonomic nervous system, located in the brainstem.

[Elucidation of Biological Mechanisms Using Synthetic Natural Products and Their Derivatives].

Natural products are useful sources in the search for biochemical probes and drug leads because of their unique biological activities. However, synthetic studies or functional analyses of polycyclic complex natural products or conjugated lipids (e.g., glycolipids) are often hampered because of their synthesis and handling are challenging. On the basis of rational designs, synthetic studies, and chemical modifications, natural products need to be optimized to more potent compounds with improved activities, selectivities and/or physical properties. We have been synthesizing natural products and their derivatives for the elucidation of their biological mechanisms and discovery of drug leads. This review describes three topics for developing functional compounds derived from natural products for prospective involvement in pharmaceutical research: 1) direct construction of the ergot alkaloid scaffold by palladium catalyzed domino cyclization of amino allenes; 2) identification of novel sphingosine kinase inhibitors through a structure-activity relationship study of jaspine B; and 3) design, synthesis and biological evaluation of novel CD1d glycolipid ligands containing modified lipid moieties.

Enzyme-Catalyzed Azepinoindole Formation in Clavine Alkaloid Biosynthesis.

(-)-Aurantioclavine (1), which contains a characteristic seven-membered ring fused to an indole ring, belongs to the azepinoindole class of fungal clavine alkaloids. Here we show that starting from a 4-dimethylallyl-l-tryptophan precursor, a flavin adenine dinucleotide (FAD)-binding oxidase and a catalase-like heme-containing protein are involved in the biosynthesis of 1. The function of these two enzymes was characterized by heterologous expression, in vitro characterization, and deuterium labeling experiments.

Crystallographic and NMR Investigation of Ergometrine and Methylergometrine, Two Alkaloids from Claviceps purpurea.

Ergometrine and methylergometrine are two alkaloids that are used as maleate salts for the prevention and control of postpartum hemorrhage. Although the two molecules have been known for a long time, few and discordant crystallographic and NMR spectroscopic data are available in the literature. With the aim of providing more conclusive data, we performed a careful NMR study for the complete assignment of the 1H, 13C, and 15N NMR signals of ergometrine, methylergometrine, and their maleate salts. This information allowed for a better definition of their conformational equilibria. In addition, the stereochemistry and the intermolecular interactions in the solid state of the two maleate salts were deeply investigated by means of single-crystal X-ray diffraction, showing the capability of these derivatives to act as both hydrogen-bond donors and acceptors, and evidencing a correlation between the number of intermolecular interactions and their different solubility.

Decreased Root-Knot Nematode Gall Formation in Roots of the Morning Glory Ipomoea tricolor Symbiotic with Ergot Alkaloid-Producing Fungal Periglandula Sp.

Many species of morning glories (Convolvulaceae) form symbioses with seed-transmitted Periglandula fungal endosymbionts, which produce ergot alkaloids and may contribute to defensive mutualism. Allocation of seed-borne ergot alkaloids to various tissues of several Ipomoea species has been demonstrated, including roots of I. tricolor. The goal of this study was to determine if infection of I. tricolor by the Periglandula sp. endosymbiont affects Southern root-knot nematode (Meloidogyne incognita) gall formation and host plant biomass. We hypothesized that I. tricolor plants infected by Periglandula (E+) would develop fewer nematode-induced galls compared to non-symbiotic plants (E-). E+ or E- status of plant lines was confirmed by testing methanol extracts from individual seeds for endosymbiont-produced ergot alkaloids. To test the effects of Periglandula on nematode colonization, E+ and E- I. tricolor seedlings were grown in soil infested with high densities of M. incognita nematodes (N+) or no nematodes (N-) for four weeks in the greenhouse before harvesting. After harvest, nematode colonization of roots was visualized microscopically, and total gall number and plant biomass were quantified. Four ergot alkaloids were detected in roots of E+ plants, but no alkaloids were found in E- plants. Gall formation was reduced by 50% in E+ plants compared to E- plants, independent of root biomass. Both N+ plants and E+ plants had significantly reduced biomass compared to N- and E- plants, respectively. These results demonstrate Periglandula's defensive role against biotic enemies, albeit with a potential trade-off with host plant growth.