Comparison of ergot alkaloid biosynthesis gene clusters in Claviceps species indicates loss of late pathway steps in evolution of C. fusiformis

The grass parasites Claviceps purpurea and Claviceps fusiformis produce ergot alkaloids (EA) in planta and in submerged culture. Whereas EA synthesis (EAS) in C. purpurea proceeds via clavine intermediates to lysergic acid and the complex ergopeptines, C. fusiformis produces only agroclavine and elymoclavine. In C. purpurea the EAS gene (EAS) cluster includes dmaW (encoding the first pathway step), cloA (elymoclavine oxidation to lysergic acid), and the lpsA/lpsB genes (ergopeptine formation). We analyzed the corresponding C. fusiformis EAS cluster to investigate the evolutionary basis for chemotypic differences between the Claviceps species. Other than three peptide synthetase genes (lpsC and the tandem paralogues lpsA1 and lpsA2), homologues of all C. purpurea EAS genes were identified in C. fusiformis, including homologues of lpsB and cloA, which in C. purpurea encode enzymes for steps after clavine synthesis. Rearrangement of the cluster was evident around lpsB, which is truncated in C. fusiformis. This and several frameshift mutations render CflpsB a pseudogene (CflpsB(Psi)). No obvious inactivating mutation was identified in CfcloA. All C. fusiformis EAS genes, including CflpsB(Psi) and CfcloA, were expressed in culture. Cross-complementation analyses demonstrated that CfcloA and CflpsB(Psi) were expressed in C. purpurea but did not encode functional enzymes. In contrast, CpcloA catalyzed lysergic acid biosynthesis in C. fusiformis, indicating that C. fusiformis terminates its EAS pathway at elymoclavine because the cloA gene product is inactive. We propose that the C. fusiformis EAS cluster evolved from a more complete cluster by loss of some lps genes and by rearrangements and mutations inactivating lpsB and cloA.     

A Complex Ergovaline Gene Cluster in Epichloë Endophytes of Grasses

Clavicipitaceous fungal endophytes of the genera Epichloë and Neotyphodium form symbioses with grasses of the subfamily Pooideae, in which they can synthesize an array of bioprotective alkaloids. Some strains produce the ergopeptine alkaloid ergovaline, which is implicated in livestock toxicoses caused by ingestion of endophyte-infected grasses. Cloning and analysis of a nonribosomal peptide synthetase (NRPS) gene from Neotyphodium lolii revealed a putative gene cluster for ergovaline biosynthesis containing a single-module NRPS gene, lpsB, and other genes orthologous to genes in the ergopeptine gene cluster of Claviceps purpurea and the clavine cluster of Aspergillus fumigatus. Despite conservation of gene sequence, gene order is substantially different between the N. lolii, C. purpurea, and A. fumigatus ergot alkaloid gene clusters. Southern analysis indicated that the N. lolii cluster was linked with previously identified ergovaline biosynthetic genes dmaW and lpsA. The ergovaline genes are closely associated with transposon relics, including retrotransposons and autonomous and nonautonomous DNA transposons. All genes in the cluster were highly expressed in planta, but expression was very low or undetectable in mycelia from axenic culture. This work provides a genetic foundation for elucidating biochemical steps in the ergovaline pathway, the ecological role of individual ergot alkaloid compounds, and the regulation of their synthesis in planta.     

The ergot alkaloid gene cluster: Functional analyses and evolutionary aspects

Ergot alkaloids and their derivatives have been traditionally used as therapeutic agents in migraine, blood pressure regulation and help in childbirth and abortion. Their production in submerse culture is a long established biotechnological process. Ergot alkaloids are produced mainly by members of the genus Claviceps, with Claviceps purpurea as best investigated species concerning the biochemistry of ergot alkaloid synthesis (EAS). Genes encoding enzymes involved in EAS have been shown to be clustered; functional analyses of EAS cluster genes have allowed to assign specific functions to several gene products. Various Claviceps species differ with respect to their host specificity and their alkaloid content; comparison of the ergot alkaloid clusters in these species (and of clavine alkaloid clusters in other genera) yields interesting insights into the evolution of cluster structure. This review focuses on recently published and also yet unpublished data on the structure and evolution of the EAS gene cluster and on the function and regulation of cluster genes. These analyses have also significant biotechnological implications: the characterization of non-ribosomal peptide synthetases (NRPS) involved in the synthesis of the peptide moiety of ergopeptines opened interesting perspectives for the synthesis of ergot alkaloids; on the other hand, defined mutants could be generated producing interesting intermediates or only single peptide alkaloids (instead of the alkaloid mixtures usually produced by industrial strains).     

Cell-free conversion of 4-γ,γ-dimethylallyltryptophan to 4-[4-hydroxy-3-methyl-Δ2-butenyl]-tryptophan in Claviceps purpurea PRL 1980

The conversion of 4-γ,γ-dimethylallyltryptophan to 4-[4-hydroxy-3-methyl-Δ²-butenyl]-tryptophan was catalyzed by the 60–80% ammonium sulphate fraction from Claviceps purpurea PRL 1980. The conversion was stimulated by NADPH. Two major unidentified products in the incubation mixture were not significantly incorporated into elymoclavine when they were added to cultures of C. purpurea PRL 1980.     

Formation of clavicipitic acid in cell-free systems of Claviceps sp.

4-Dimethylallyltryptophan-[3-¹⁴C] was converted to clavicipitic acid in cell-free extracts from Claviceps sp. SD 58 and Claviceps purpurea PRL 1980. Activity was concentrated in the microsomal fraction. Oxygen was required but there was no cofactor requirement. p-(Hydroxymercuri)benzoic acid strongly inhibited the conversion. Addition of diethyldithiocarbamate increased conversion 2·5 ×. Conversion was favored at high pH. Clavicipitic acid [¹⁴C] added to cultures of Claviceps sp. SD 58 was not significantly incorporated into elymoclavine.     

Pyridine nucleotide biosynthesis in Claviceps

Claviceps purpurea grown on synthetic medium incorporated labeled [7-¹⁴]nicotinic acid and [7-¹⁴C]nicotinamide into NaMN, des-NAD, NAD, and NADP. Label also appeared in NMN and N-methyl nicotinamide. The specific activities of NAD, NADP, and NMN are compatible with the operation of the Preiss-Handler pathway of NAD biosynthesis (nicotinic acid → NaMN → des-NAD → NAD → NADP). The relative amounts of NaMN:des-NAD:NAD and NADP were about 8:1:36:10 on incubation of Claviceps with nicotinic acid for 6 hr. The incorporation of nicotinamide into NAD proceeds mainly by conversion to nicotinic acid catalyzed by nicotinamide deamidase.Tryptophan ([U-¹⁴C]benzene ring) was incorporated into NAD demonstrating the presence of the tryptophan-nicotinic acid pathway. No qualitative difference in pyridine nucleotide intermediates was noted in C. purpurea CPM, which does not produce clavine alkaloids, and Claviceps 47A which does produce clavine alkaloids.     

Origin of sclerotia-like cells in submerged Claviceps purpurea producing clavine alkaloids

Ultrathin sectioning of submerged mycelium of Claviceps purpurea Tul. producing clavine alkaloids revealed yeast-like budding resulting in asexual sporesblastospores. These deciduous spores were born by extended hyphal cells and retained the same ultrastructure of cell organelles. Both the extended hyphae and the blastospores resembled the cells of ergot sclerotial tissue. A surface culture of C. purpurea Tul. producing no alkaloids was used as a reference.     

Overproduction of medicinal ergot alkaloids based on a fungal platform

Privileged ergot alkaloids (EAs) produced by the fungal genus Claviceps are used to treat a wide range of diseases. However, their use and research have been hampered by the challenging genetic engineering of Claviceps. Here we systematically refactored and rationally engineered the EA biosynthetic pathway in heterologous host Aspergillus nidulans by using a Fungal-Yeast-Shuttle-Vector protocol. The obtained strains allowed the production of diverse EAs and related intermediates, including prechanoclavine (PCC, 333.8 mg/L), chanoclavine (CC, 241.0 mg/L), agroclavine (AC, 78.7 mg/L), and festuclavine (FC, 99.2 mg/L), etc. This fungal platform also enabled the access to the methyl-oxidized EAs (MOEAs), including elymoclavine (EC), lysergic acid (LA), dihydroelysergol (DHLG), and dihydrolysergic acid (DHLA), by overexpressing a P450 enzyme CloA. Furthermore, by optimizing the P450 electron transfer (ET) pathway and using multi-copy of cloA, the titers of EC and DHLG have been improved by 17.3- and 9.4-fold, respectively. Beyond our demonstration of A. nidulans as a robust platform for EA overproduction, our study offers a proof of concept for engineering the eukaryotic P450s-contained biosynthetic pathways in a filamentous fungal host.     

Heterologous Expression of Lysergic Acid and Novel Ergot Alkaloids in Aspergillus fumigatus

Different lineages of fungi produce distinct classes of ergot alkaloids. Lysergic acid-derived ergot alkaloids produced by fungi in the Clavicipitaceae are particularly important in agriculture and medicine. The pathway to lysergic acid is partly elucidated, but the gene encoding the enzyme that oxidizes the intermediate agroclavine is unknown. We investigated two candidate agroclavine oxidase genes from the fungus Epichloë festucae var. lolii × Epichloë typhina isolate Lp1 (henceforth referred to as Epichloë sp. Lp1), which produces lysergic acid-derived ergot alkaloids. Candidate genes easH and cloA were expressed in a mutant strain of the mold Aspergillus fumigatus, which typically produces a subclass of ergot alkaloids not derived from agroclavine or lysergic acid. Candidate genes were coexpressed with the Epichloë sp. Lp1 allele of easA, which encodes an enzyme that catalyzed the synthesis of agroclavine from an A. fumigatus intermediate; the agroclavine then served as the substrate for the candidate agroclavine oxidases. Strains expressing easA and cloA from Epichloë sp. Lp1 produced lysergic acid from agroclavine, a process requiring a cumulative six-electron oxidation and a double-bond isomerization. Strains that accumulated excess agroclavine (as a result of Epichloë sp. Lp1 easA expression in the absence of cloA) metabolized it into two novel ergot alkaloids for which provisional structures were proposed on the basis of mass spectra and precursor feeding studies. Our data indicate that CloA catalyzes multiple reactions to produce lysergic acid from agroclavine and that combining genes from different ergot alkaloid pathways provides an effective strategy to engineer important pathway molecules and novel ergot alkaloids.     

Glycosylation of ergot alkaloids by free and immobilized cells of Claviceps purpurea

Summary A new strain, Claviceps purpurea 88-EP-47, with high invertase activity was selected. Free and Calginate immobilized cultures of this strain were used for fructosylation of ergot alkaloids. By bioconversion from their aglycones, elymoclavine-O--d-fructofuranosyl(21)-O--d-fructofuranoside, and elymoclavine-O--d-fructoside, the respective fructosides of chanoclavine, lysergol and dihydro-lysergol monofructosides were obtained. These substances are formed by -d-fructofuranosidase present in Claviceps cells. The bioconversion activity of the enzyme system (fructose transfer) is strongly dependent on pH, substrate (sucrose) concentration and the developmental profile of invertase activity. The pH optimum for elymoclavine fructosylation is 6.5, for chanoclavine 5.7, and the optimal sucrose concentration is 75 g/l. Fifteen-day-old production cultures had the best glycosylation activities. Fructosylation of alkaloids can be stimulated in production cultures of C. purpurea or C. fusiformis forming elymoclavine or chanoclavine by a pH shift to 6.5 at the end of the production phase. Glycosylating Claviceps strains producing elymoclavine eliminate the free alkaloid into glycosides. The feedback inhibition of alkaloid synthesis by elymoclavine is then strongly reduced, helping to further improve elymoclavine yields. Elymoclavine can be liberated simply by invertase activity of baker's yeast.Offprint requests to: V. Ken     

A complex ergovaline gene cluster in epichloe endophytes of grasses

Clavicipitaceous fungal endophytes of the genera Epichlo? and Neotyphodium form symbioses with grasses of the subfamily Pooideae, in which they can synthesize an array of bioprotective alkaloids. Some strains produce the ergopeptine alkaloid ergovaline, which is implicated in livestock toxicoses caused by ingestion of endophyte-infected grasses. Cloning and analysis of a nonribosomal peptide synthetase (NRPS) gene from Neotyphodium lolii revealed a putative gene cluster for ergovaline biosynthesis containing a single-module NRPS gene, lpsB, and other genes orthologous to genes in the ergopeptine gene cluster of Claviceps purpurea and the clavine cluster of Aspergillus fumigatus. Despite conservation of gene sequence, gene order is substantially different between the N. lolii, C. purpurea, and A. fumigatus ergot alkaloid gene clusters. Southern analysis indicated that the N. lolii cluster was linked with previously identified ergovaline biosynthetic genes dmaW and lpsA. The ergovaline genes are closely associated with transposon relics, including retrotransposons and autonomous and nonautonomous DNA transposons. All genes in the cluster were highly expressed in planta, but expression was very low or undetectable in mycelia from axenic culture. This work provides a genetic foundation for elucidating biochemical steps in the ergovaline pathway, the ecological role of individual ergot alkaloid compounds, and the regulation of their synthesis in planta.     

A mathematical model of growth and alkaloid production in the submerged culture of Claviceps purpurea

A mathematical model of the batch cultivation of Claviceps purpurea was formulated. The main attention was devoted to the effect of exocellular and intracellular phosphate on the growth of the mycelium and production of clavine alkaloid under experimental conditions without limitation by carbon and nitrogen sources. The method of nonlinear regression was used ot predict the optional technological regime of the phosphate addition in the batch culture at different time intervals of additions.     

The determinant step in ergot alkaloid biosynthesis by an endophyte of perennial ryegrass

Many cool-season grasses harbor fungal endophytes in the genus Neotyphodium, which enhance host fitness, but some also produce metabolites--such as ergovaline--believed to cause livestock toxicoses. In Claviceps species the first step in ergot alkaloid biosynthesis is thought to be dimethylallyltryptophan (DMAT) synthase, encoded by dmaW, previously cloned from Claviceps fusiformis. Here we report the cloning and characterization of dmaW from Neotyphodium sp. isolate Lp1, an endophyte of perennial ryegrass (Lolium perenne). The gene was then disrupted, and the mutant failed to produce any detectable ergovaline or simpler ergot and clavine alkaloids. The disruption was complemented with the C. fusiformis gene, which restored ergovaline production. Thus, the biosynthetic role of DMAT synthase was confirmed, and a mutant was generated for future studies of the ecological and agricultural importance of ergot alkaloids in endophytes of grasses.     

Physiological control and process kinetics of clavine alkaloid production byClaviceps purpurea

Summary Kinetic parameters of production of clavine alkaloids were evaluated in twoClaviceps purpurea strains. Mutagenesis brought about enhanced resistance of the biosynthetic system towards alkaloids. Addition of glucose into the fermentation medium altered the zero order kinetics of production to activation-inhibition kinetics. The glucose treatment allowed performance of both elymoclavine-inhibitionless and clavine alkaloid-decompositionless fermentations if a combination of fermentation and separation units in a closed loop was used.Nomenlacture k ₁ rate constant of agroclavine synthesis (mg Agro · mg Elymo/l·g DW·day for stage 1, mg Agro/g DW·day for stage 2) - k ₂ parameter describing inhibition of agroclavine formation rate by elymoclavine (mg Elymo/l) - k ₃ specific rate of agroclavine decay (l/g DW·day) - k ₄ maximal specific rate of elymoclavine synthesis (stage 1, 1/g DW·day, stage 2, mg Elymo/g DW·day) - k ₄ ^– maximal specific rate of elymoclavine synthesis in stage 1 (inhibition-activation mechanism) (mg Elymo/g DW·day) - k ₅ physiological constant describing the elymoclavine decay rate (l²/g DW·day·mg Elymo) - k ₅ ^– physiological constant describing the activation of elymoclavine biosynthesis by elymoclavine (mg Elymo/l) - k ₆ physiological constant describing the repression of elymoclavine biosynthesis by elymoclavine (mg Elymo/l) - k ₇ maximal specific growth rate (1/day) - k ₈ specific rate of biomass decay (l/g DW·day) - A agroclavine concentration (mg/l) - E elymoclavine concentration (mg/l) - r _A specific rate of agroclavine biosynthesis (mg Agro/g DW·day) - r _E specific rate of elymoclavine biosynthesis (mg Elymo/g DW·day) - r _i specific rate of alkaloid biosynthesis (mg alkaloid/g DW·day) - X dry biomass concentration (g/l) - specific growth rate (1/day) Abbreviations Agro agroclavine - Elymo elymoclavine - Chano chanoclavine - DW dry weight of biomass     

An Ergot Alkaloid Biosynthesis Gene and Clustered Hypothetical Genes from Aspergillus fumigatus

The ergot alkaloids are a family of indole-derived mycotoxins with a variety of significant biological activities. Aspergillus fumigatus, a common airborne fungus and opportunistic human pathogen, and several fungi in the relatively distant taxon Clavicipitaceae (clavicipitaceous fungi) produce different sets of ergot alkaloids. The ergot alkaloids of these divergent fungi share a four-member ergoline ring but differ in the number, type, and position of the side chains. Several genes required for ergot alkaloid production are known in the clavicipitaceous fungi, and these genes are clustered in the genome of the ergot fungus Claviceps purpurea. We investigated whether the ergot alkaloids of A. fumigatus have a common biosynthetic and genetic origin with those of the clavicipitaceous fungi. A homolog of dmaW, the gene controlling the determinant step in the ergot alkaloid pathway of clavicipitaceous fungi, was identified in the A. fumigatus genome. Knockout of dmaW eliminated all known ergot alkaloids from A. fumigatus, and complementation of the mutation restored ergot alkaloid production. Clustered with dmaW in the A. fumigatus genome are sequences corresponding to five genes previously proposed to encode steps in the ergot alkaloid pathway of C. purpurea, as well as additional sequences whose deduced protein products are consistent with their involvement in the ergot alkaloid pathway. The corresponding genes have similarities in their nucleotide sequences, but the orientations and positions within the cluster of several of these genes differ. The data indicate that the ergot alkaloid biosynthetic capabilities in A. fumigatus and the clavicipitaceous fungi had a common origin.     

Evidence for an ergot alkaloid gene cluster in Claviceps purpurea

A gene (cpd1) coding for the dimethylallyltryptophan synthase (DMATS) that catalyzes the first specific step in the biosynthesis of ergot alkaloids, was cloned from a strain of Claviceps purpurea that produces alkaloids in axenic culture. The derived gene product (CPD1) shows only 70% similarity to the corresponding gene previously isolated from Claviceps strain ATCC 26245, which is likely to be an isolate of C. fusiformis. Therefore, the related cpd1 most probably represents the first C. purpurea gene coding for an enzymatic step of the alkaloid biosynthetic pathway to be cloned. Analysis of the 3′-flanking region of cpd1 revealed a second, closely linked ergot alkaloid biosynthetic gene named cpps1, which codes for a 356-kDa polypeptide showing significant similiarity to fungal modular peptide synthetases. The protein contains three amino acid-activating modules, and in the second module a sequence is found which matches that of an internal peptide (17 amino acids in length) obtained from a tryptic digest of lysergyl peptide synthetase 1 (LPS1) of C. purpurea, thus confirming that cpps1 encodes LPS1. LPS1 activates the three amino acids of the peptide portion of ergot peptide alkaloids during D-lysergyl peptide assembly. Chromosome walking revealed the presence of additional genes upstream of cpd1 which are probably also involved in ergot alkaloid biosynthesis: cpox1 probably codes for an FAD-dependent oxidoreductase (which could represent the chanoclavine cyclase), and a second putative oxido-reductase gene, cpox2, is closely linked to it in inverse orientation. RT-PCR experiments confirm that all four genes are expressed under conditions of peptide alkaloid biosynthesis. These results strongly suggest that at least some genes of ergot alkaloid biosynthesis in C. purpurea are clustered, opening the way for a detailed molecular genetic analysis of the pathway. Received: 26 August 1998 / Accepted: 19 October 1998     

Transformation of Claviceps purpurea using a bleomycin resistance gene

Summary To develop a DNA-mediated transformation system for Claviceps purpurea a vector was constructed using a bleomycin-resistance gene (bleo ^R) fused in frame to the Aspergillus nidulans trp C promoter as a dominant selection marker. The construct was shown to be functional in Aspergillus nidulans and Aspergillus niger and used to transform a wild strain of Claviceps purpurea. Transformats were obtained at low frequencies; they were shown to contain transforming DNA integrated into the chromosomal DNA, probably in multimeric copies and at multiple sites. Combined Southern, Northern and resistance level analysis indicate that the A. nidulans promoter is functional in C. purpurea.Dedicated to Professor Dr. Dr. h. c. K. Esser on the occasion of his 65^th birthday     

Alkaloid Cluster Gene ccsA of the Ergot Fungus Claviceps purpurea Encodes Chanoclavine I Synthase,a Flavin Adenine Dinucleotide-Containing Oxidoreductase Mediating the Transformation of N-Methyl-Dimethylallyltryptophan to Chanoclavine I

Ergot alkaloids are indole-derived secondary metabolites synthesized by the phytopathogenic ascomycete Claviceps purpurea. In wild-type strains, they are exclusively produced in the sclerotium, a hibernation structure; for biotechnological applications, submerse production strains have been generated by mutagenesis. It was shown previously that the enzymes specific for alkaloid biosynthesis are encoded by a gene cluster of 68.5 kb. This ergot alkaloid cluster consists of 14 genes coregulated and expressed under alkaloid-producing conditions. Although the role of some of the cluster genes in alkaloid biosynthesis could be confirmed by a targeted knockout approach, further functional analyses are needed, especially concerning the early pathway-specific steps up to the production of clavine alkaloids. Therefore, the gene ccsA, originally named easE and preliminarily annotated as coding for a flavin adenine dinucleotide-containing oxidoreductase, was deleted in the C. purpurea strain P1, which is able to synthesize ergot alkaloids in axenic culture. Five independent knockout mutants were analyzed with regard to alkaloid-producing capability. Thin-layer chromatography (TLC), ultrapressure liquid chromatography (UPLC), and mass spectrometry (MS) analyses revealed accumulation of N-methyl-dimethylallyltryptophan (Me-DMAT) and traces of dimethylallyltryptophan (DMAT), the first pathway-specific intermediate. Since other alkaloid intermediates could not be detected, we conclude that deletion of ccsA led to a block in alkaloid biosynthesis beyond Me-DMAT formation. Complementation with a ccsA/gfp fusion construct restored alkaloid biosynthesis. These data indicate that ccsA encodes the chanoclavine I synthase or a component thereof catalyzing the conversion of N-methyl-dimethylallyltryptophan to chanoclavine I.The ergot fungus Claviceps purpurea is a phytopathogenic ascomycete which infects the ears of several grasses, replacing the ovary and producing a hibernation structure, the so-called sclerotium, in which the ergot alkaloids are formed. These substances show a high level of structural homology to some neurotransmitters like serotonin and dopamine and can therefore bind to the same receptors in the central nervous system (CNS), which is the basis for the application of ergot alkaloids in a variety of clinical conditions (15).The biochemistry of ergot alkaloid biosynthesis was first investigated by isolation of intermediates and postulation of a hypothetical pathway as well as enzymes needed for the successive biosynthetic steps of the production (Fig. ​(Fig.1).1). Most of the data were collected by pursuing the fate of radiolabeled precursors in feeding experiments (4). The first enzyme which could be assigned to alkaloid production was dimethylallyltryptophan synthetase (DMATS), which is the key enzyme of the pathway and is encoded by the gene dmaW (18). These analyses were performed with a Claviceps fusiformis strain, but a homolog of dmaW ({"type":"entrez-nucleotide","attrs":{"text":"AY259840","term_id":"32402653","term_text":"AY259840"}}AY259840) possessing a similar function could also be isolated in C. purpurea, as was confirmed by a knockout approach (N. Lorenz and P. Tudzynski, unpublished data). Using genome walking combined with cDNA screening, a 68.5-kb genomic region surrounding dmaW could be sequenced and revealed 14 open reading frames (ORFs) (putative genes) encoding, among others, nonribosomal peptide synthetases (NRPSs), a putative catalase, a CYP450-1 monooxygenase, a putative methyltransferase, and several oxidoreductases (6, 13, 19) (Fig. ​(Fig.2).2). Some of these genes were functionally and biochemically analyzed by a gene replacement approach which revealed their function within the pathway (2, 5, 7). However, there is still a deficit in functional analyses, especially with respect to the early steps within this pathway. The conversion from N-methyl-dimethylallyltryptophan (Me-DMAT) to agroclavine via chanoclavine I and chanoclavine I aldehyde includes successive oxidation and reduction steps mediated by a specific class of enzymes, the oxidoreductases (15) (Fig. ​(Fig.11).Open in a separate windowFIG. 1.Biosynthetic pathway of the ergot alkaloid biosynthesis of C. purpurea. Genes analyzed so far have been assigned to the corresponding enzyme at the corresponding position within the pathway. DMAPP, dimethylallyldiphosphate; DMAT, dimethylallyltryptophan; Me-DMAT, N-methyl-DMAT. (Adapted from reference 7 with permission of Wiley-VCH Verlag GmbH & Co. KGaA.)Open in a separate windowFIG. 2.Alkaloid biosynthesis gene cluster of C. purpurea. Highlighted in white is the gene of interest ccsA. (Adapted from reference 7 with permission of Wiley-VCH Verlag GmbH & Co. KGaA.)These enzymes are involved in the biosynthesis of many fungal secondary metabolites. A prominent example is the family of the cytochrome P450 monooxygenases (named after the characteristic peak of 450 nm when complexed with carbon monoxide). Cytochrome P450 (CYP450) monooxygenases catalyze the transfer of one oxygen atom from molecular oxygen to various substrates, mostly accomplished by the involvement of NAD(P)H as an electron donor. The eas cluster of C. purpurea also includes a gene encoding a CYP450 monooxygenase: cloA is involved in the oxidation of elymoclavine, leading to the formation of paspalic acid (7).No further monooxygenase-encoding genes seem to be present in the eas cluster, but several genes code for putative oxidoreductases (easA, easD, easE, easG, and easH). These oxidoreductases are most likely involved in the early steps within the pathway, but none of them has been functionally analyzed so far (15).We initiated a functional analysis of the putative oxidoreductase-encoding gene ccsA (formerly easE) (Fig. ​(Fig.2).2). The coding region of ccsA ({"type":"entrez-nucleotide","attrs":{"text":"AJ011965","term_id":"4499842","term_text":"AJ011965"}}AJ011965; 1,503 bp) is composed of two exons interrupted by an intron of 52 bp, yielding a coding capacity of 483 amino acids (aa). The gene product shows highest similarity to putative oxidoreductases of other ergot alkaloid-producing fungi: EasE of C. fusiformis (e⁻¹⁶⁰; {"type":"entrez-protein","attrs":{"text":"ABV57823","term_id":"157488556","term_text":"ABV57823"}}ABV57823), EasE of Neotyphodium lolii (e⁻¹¹⁸; {"type":"entrez-protein","attrs":{"text":"ABM91450","term_id":"124110194","term_text":"ABM91450"}}ABM91450) and CpoX1 of Aspergillus fumigatus (e⁻⁹⁶; {"type":"entrez-nucleotide","attrs":{"text":"XM_751049","term_id":"71002921","term_text":"XM_751049"}}XM_751049). Analyses of the protein sequence using the program PROSITE revealed a flavin adenine dinucleotide (FAD)-binding domain (pfam01565) spanning the region from amino acids 14 to 161 and a berberine bridge enzyme domain (BBE domain; pfam08031) from amino acids 412 to 457. The role of CcsA in the alkaloid biosynthesis pathway was investigated by knockout of the corresponding gene, followed by functional and biochemical analyses of the deletion mutants.     

Separation of ergot alkaloids by adsorption on silicates

A mixture of ergot alkaloids (agroclavine, elymoclavine, chanoclavine, and chanoclavine aldehyde) was separated from the Claviceps purpureafermentation broth by adsorption on inorganic adsorbents containing silica. The uptake of alkaloids depended on the concentration of adsorbent and pH. The adsorption capacity for of inorganic materials increased with increasing content of inorganic oxides such as MgO and CaO in the adsorbent. Using statistical thermodynamics, a simple mathematical model describing the multicomponent adsorption equilibrium is proposed and a numerical method suitable for fast computer simulation of multicomponent adsorption was developed.     

Glucose catabolism during alkaloid production in a strain ofClaviceps purpurea

Badiorespirometric experiments with glucose labelled in positions 1; 2; 3,4 and 6 were carried out inClaviceps purpurea strain pepty 695. The pattern of¹⁴CO₂ evolution from 5 – 50 mM glucose indicated the operation of the pentose phosphate cycle during alkaloid production. The authors thank Mrs. H. Pechfelder for her skilled technical assistance and Prof. Dr. H. Reinbothe and Dr. C. Wasternack for helpful discussions.