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.     

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.     

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.     

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.     

Accumulation of Ergot Alkaloids During Conidiophore Development in Aspergillus fumigatus

Production of ergot alkaloids in the opportunistic fungal pathogen Aspergillus fumigatus is restricted to conidiating cultures. These cultures typically accumulate several pathway intermediates at concentrations comparable to that of the pathway end product. We investigated the contribution of different cell types that constitute the multicellular conidiophore of A. fumigatus to the production of ergot alkaloid pathway intermediates versus the pathway end product, fumigaclavine C. A relatively minor share (11 %) of the ergot alkaloid yield on a molar basis was secreted into the medium, whereas the remainder was associated with the conidiating colonies. Entire conidiating cultures (containing hyphae, vesicle of conidiophore, phialides of conidiophore, and conidia) accumulated higher levels of the pathway intermediate festuclavine and lower levels of the pathway end product fumigaclavine C than did isolated, abscised conidia, indicating that conidiophores and/or hyphae have a quantitatively different ergot alkaloid profile compared to that of conidia. Differences in alkaloid accumulation among cell types also were indicated by studies with conidiophore development mutants. A ?medA mutant, in which conidiophores are numerous but develop poorly, accumulated higher levels of pathway intermediates than did the wildtype or a complemented ?medA mutant. A ?stuA mutant, which grows mainly as hyphae and produces very few, abnormal conidiophores, produced no detectable ergot alkaloids. The data indicated heterogeneous spatial distribution of ergot alkaloid pathway intermediates versus pathway end product in conidiating cultures of A. fumigatus. This skewed distribution may reflect differences in abundance or activity of pathway enzymes among cell types of those conidiating cultures.     

Molecular characterization of a seed transmitted clavicipitaceous fungus occurring on dicotyledoneous plants (Convolvulaceae)

Ergoline alkaloids (syn. ergot alkaloids) are constituents of clavicipitaceous fungi (Ascomycota) and of one particular dicotyledonous plant family, the Convolvulaceae. While the biology of fungal ergoline alkaloids is rather well understood, the evolutionary and biosynthetic origin of ergoline alkaloids within the family Convolvulaceae is unknown. To investigate the possible origin of ergoline alkaloids from a plant-associated fungus, 12 endophytic fungi and one epibiotic fungus were isolated from an ergoline alkaloid-containing Convolvulaceae plant, Ipomoea asarifolia Roem. & Schult. Phylogenetic trees constructed from 18S rDNA genes as well as internal transcribed spacer (ITS) revealed that the epibiotic fungus belongs to the family Clavicipitaceae (Ascomycota) whereas none of the endophytic fungi does. In vitro and in vivo cultivation on intact plants gave no evidence that the endophytic fungi are responsible for the accumulation of ergoline alkaloids in I. asarifolia whereas the epibiotic clavicipitaceous fungus very likely is equipped with the genetic material to synthesize these compounds. This fungus resisted in vitro and in vivo cultivation and is seed transmitted. Several observations strongly indicate that this plant-associated fungus and its hitherto unidentified relatives occurring on different Convolvulaceae plants are responsible for the isolated occurrence of ergoline alkaloids in Convolvulaceae. This is the first report of an ergot alkaloid producing clavicipitaceous fungus associated with a dicotyledonous plant.Data deposition: The sequences reported in this paper have been deposited in the GenBank (accession numbers are given in the text and in Fig. 3) Dedicated to Dr. Dr. h. c. mult. Albert Hofmann, the great pioneer of ergot research, on the occasion of his 100th birthday     

Use of polymerase chain reaction for searching for producers of ergot alkaloids from among microscopic fungi]

The potential of the polymerase chain reaction for the detection of ergot alkaloid producers among microscopic fungi of the genera Penicillium and Claviceps was evaluated. Twenty-three strains of various species of fungi with a previously studied capacity for alkaloid production were used. The internal fragment of the gene encoding 4-dimethylallyltryptophan synthase, the enzyme catalyzing the first step in the biosynthesis of ergot alkaloids, was amplified using degenerated primers. This approach revealed an about 1.2-kb specific DNA fragment in micromycetes synthesizing ergot alkaloids with complete tetracyclic ergoline system. Microorganisms that produce alkaloids with modified C or D ergoline rings, as well as alpha-cyclopiazonic acid, did not yield the PCR fragment of the expected size. This fragment was also not found in fungi incapable of ergot alkaloid production.     

Biotechnology and genetics of ergot alkaloids

Ergot alkaloids, i.e. ergoline-derived toxic metabolites, are produced by a wide range of fungi, predominantly by members of the grass-parasitizing family of the Clavicipitaceae. Naturally occurring alkaloids like the D-lysergic acid amides, produced by the "ergot fungus" Claviceps purpurea, have been used as medicinal agents for a long time. The pharmacological effects of the various ergot alkaloids and their derivatives are due to the structural similarity of the tetracyclic ring system to neurotransmitters such as noradrenaline, dopamine or serotonin. In addition to "classical" indications, e.g. migraine or blood pressure regulation, there is a wide spectrum of potential new applications of this interesting group of compounds. The biotechnology of ergot alkaloids has a long tradition, and efficient parasitic and submerse production processes have been developed; the biochemistry of the pathway and the physiology of production have been worked out in detail. The recent identification of a cluster of genes involved in ergot alkaloid biosynthesis in C. purpurea and the availability of molecular genetic techniques allow the development of strategies for rational drug design of ergoline-related drugs by enzyme engineering and by biocombinatorial approaches.     

Relationship between the Claviceps Life Cycle and Productivity of Ergot Alkaloids

Abstract

The morphology, biochemistry, and physiology studies during development of Claviceps purpurea fungi clearly demonstrate that alkaloid synthesis is linked to a specific stage of the fungal life cycle. In nature, ergot alkaloids are synthesized in the course of developing sclerotia, while in submerged cultures, lacking sexual reproduction, alkaloid synthesis proceeds in sclerotia-like cells. Highly active submerged strains could be obtained by combination of mutagens with a different mode of action as well as by somatic hyphal anastomoses or efficient protoplast fusions to obtain the parasexual cycle. Fused strains not only retained the biosynthetic activity of parent strains but produced even much higher amounts of alkaloids. In our strains, the appropriate morphology always corresponded to high productivity. Furthermore, the form of cell differentiation was typical for each particular strain. When comparing active and inactive strains, measurements of qualitative and quantitative changes in mycelium composition revealed different metabolic patterns and certain characteristics necessary for efficient alkaloid production. Evaluation of activities of some enzymes from the central metabolic pathways, which generate the basic intermediates for ergot alkaloid synthesis also contributed to the overall knowledge of mechanisms involved.     

Effect on microelements on biosynthes of secondary metabolites in the fungus Penicillium citrinum Thom VKM F-1079

Penicillium citrinum VKM F-1079 was found to produce clavine ergot alkaloids and citrinin, a secondary O-heterocyclic metabolite. Citrinin was produced in the idiophase, whereas the production of ergot alkaloids paralleled fungal growth. The addition of manganese ions to the growth medium stimulated the biosynthesis of both citrinin and ergot alkaloids. Zinc ions stimulated only citrinin synthesis. The presence of these microelements in the growth medium influenced the proportion between the ergot alkaloids synthesized. Copper, manganese, and iron ions affected but little fungal growth and alkaloid production. The effect of microelements on the main kinetic parameters of growth and alkaloid production was studied.     

Effect of microelements on the biosynthesis of secondary metabolites by the fungusPenicillium citrinum thom VKM F-1079

Penicillium citrinum VKM F-1079 was found to produce clavine ergot alkaloids and citrinin, a secondaryO-heterocyclic metabolite. Citrinin was produced in the idiophase, whereas the production of ergot alkaloids paralleled fungal growth. The addition of manganese ions to the growth medium stimulated the biosynthesis of both citrinin and ergot alkaloids. Zinc ions stimulated only citrinin synthesis. The presence of these microelements in the growth medium influenced the proportion between the ergot alkaloids synthesized. Copper, manganese, and iron ions slightly affected fungal growth and alkaloid production. The effect of microelements on the main kinetic parameters of growth and alkaloid production was studied.     

Biosynthesis of ergot alkaloids. Some new results on an old problem (Review)]

The biosynthetic pathway leading from L-tryptophan, mevalonic acid and methionine to the tetracyclic ergoline ring system of the ergot alkaloids in Claviceps species is reviewed. This pathway entails many mechanistically intriguing features. Recent studies are also discussed which reveal the stereochemical course of the isoprenylation of tryptophan and of the N-methylation of dimethylallyltryptophan (DMAT) and which shed some light on the likely steps leading from the open-chain precursors, N-methyl-DMAT to the tricyclic intermediate, chanoclavine-1. Finally, some plans are outlined to probe the evolutionary relationship of ergot alkaloid biosynthesis in fungi to that in higher plants of the family Convolvulaceae.     

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     

Screening for Ergot Alkaloid Producers among Microscopic Fungi by Means of the Polymerase Chain Reaction

The potential of the polymerase chain reaction for the detection of ergot alkaloid producers among microscopic fungi of the generaPenicilliumand Clavicepswas evaluated. Twenty-three strains of various species of fungi with a previously studied capacity for alkaloid production were used. The internal fragment of the gene encoding 4-dimethylallyltryptophan synthase, the enzyme catalyzing the first step in the biosynthesis of ergot alkaloids, was amplified using degenerate primers. This approach revealed an about 1.2-kb specific DNA fragment in micromycetes synthesizing ergot alkaloids with complete tetracyclic ergoline system. Microorganisms that produce alkaloids with modified C or D ergoline rings, as well as -cyclopiazonic acid, did not yield the PCR fragment of the expected size. This fragment was also not found in fungi incapable of ergot alkaloid production.     

Chemotypic and genotypic diversity in the ergot alkaloid pathway of Aspergillus fumigatus

Aspergillus fumigatus is an opportunistic human pathogen that synthesizes a group of mycotoxins via a branch of the ergot alkaloid pathway. This fungus is globally distributed, and genetic data indicate that isolates recombine freely over that range; however, previous work on ergot alkaloids has focused on a limited number of isolates. We hypothesized that A. fumigatus harbors variation in the chemotype of ergot alkaloids and genotype of the ergot alkaloid gene cluster. Analysis of 13 isolates by high performance liquid chromatography revealed four distinct ergot alkaloid profiles or chemotypes. Five isolates completed the A. fumigatus branch of the ergot alkaloid pathway to fumigaclavine C. Six independent isolates accumulated fumigaclavine A, the pathway intermediate immediately before fumigaclavine C. One isolate accumulated only the early pathway intermediates chanoclavine-i and chanocla-vine-i aldehyde, and one isolate lacked ergot alkaloids altogether. A genetic basis for each of the observed chemotypes was obtained either by PCR analysis of the ergot alkaloid gene cluster or through sequencing of easL, the gene encoding the prenyl transferase that reverse prenylates fumigaclavine A to fumigaclavine C. Isolates also exhibited differences in pigmentation and sporulation. The ergot alkaloid chemotypes were widely distributed geographically and among substrate of origin.     

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 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.     

An Old Yellow Enzyme Gene Controls the Branch Point between Aspergillus fumigatus and Claviceps purpurea Ergot Alkaloid Pathways

Ergot fungi in the genus Claviceps and several related fungal groups in the family Clavicipitaceae produce toxic ergot alkaloids. These fungi produce a variety of ergot alkaloids, including clavines as well as lysergic acid derivatives. Ergot alkaloids are also produced by the distantly related, opportunistic human pathogen Aspergillus fumigatus. However, this fungus produces festuclavine and fumigaclavines A, B, and C, which collectively differ from clavines of clavicipitaceous fungi in saturation of the last assembled of four rings in the ergoline ring structure. The two lineages are hypothesized to share early steps of the ergot alkaloid pathway before diverging at some point after the synthesis of the tricyclic intermediate chanoclavine-I. Disruption of easA, a gene predicted to encode a flavin-dependent oxidoreductase of the old yellow enzyme class, in A. fumigatus led to accumulation of chanoclavine-I and chanoclavine-I-aldehyde. Complementation of the A. fumigatus easA mutant with a wild-type allele from the same fungus restored the wild-type profile of ergot alkaloids. These data demonstrate that the product of A. fumigatus easA is required for incorporation of chanoclavine-I-aldehyde into more-complex ergot alkaloids, presumably by reducing the double bond conjugated to the aldehyde group, thus facilitating ring closure. Augmentation of the A. fumigatus easA mutant with a homologue of easA from Claviceps purpurea resulted in accumulation of ergot alkaloids typical of clavicipitaceous fungi (agroclavine, setoclavine, and its diastereoisomer isosetoclavine). These data indicate that functional differences in the easA-encoded old yellow enzymes of A. fumigatus and C. purpurea result in divergence of their respective ergot alkaloid pathways.Different classes of ergot alkaloids are produced by members of two distinct fungal lineages. Clavicipitaceous species, which include Claviceps spp. and Neotyphodium spp., are in the order Hypocreales and typically synthesize lysergic acid derivatives (13, 16, 18). These alkaloids have a double bond in the last assembled of four rings (D ring) of the tetracyclic ergoline ring structure. Ergot alkaloids are also produced by the distantly related opportunistic human pathogen Aspergillus fumigatus, a member of the order Eurotiales (8, 14, 16, 18). Ergot alkaloids of A. fumigatus are of the clavine class and differ from the more complex profile of Claviceps purpurea and Neotyphodium spp. One important distinction between the ergot alkaloids produced by these different fungi is the saturation of the fourth ring of the ergoline structure in A. fumigatus (Fig. ​(Fig.11).Open in a separate windowFIG. 1.Structures and relationships of relevant ergot alkaloids. (A) Chanoclavine-I is oxidized to its aldehyde form before being incorporated into festuclavine (and downstream alkaloids) in A. fumigatus or agroclavine (and downstream alkaloids) in C. purpurea. (B) Conventional ring labeling and atom numbering referred to in the text.Several genes involved in the ergot alkaloid pathways of A. fumigatus and clavicipitaceous fungi are found clustered together in the genome of each species (3, 4, 6, 18, 23). These distantly related fungi are hypothesized to share several early pathway steps, after which the pathways diverge to yield distinct sets of ergot alkaloids (3, 13, 16). The gene dmaW, which encodes dimethylallyltryptophan (DMAT) synthase, catalyzes the prenylation of tryptophan that initiates the ergot alkaloid pathway in clavicipitaceous fungi (22, 25) and functions similarly in A. fumigatus (3, 24). The region surrounding this gene in A. fumigatus contains homologues of genes also found in Neotyphodium lolii and C. purpurea ergot alkaloid gene clusters (3, 4, 6). One of the shared genes, easA, is predicted to encode a member of the old yellow enzyme (OYE) family of oxidoreductases. Old yellow enzymes are flavin-containing oxidoreductases initially found in the brewer''s bottom yeast Saccharomyces carlsbergensis (26). Enzymes in this family use a reduced flavin cofactor and an active-site tyrosine residue to reduce the carbon-carbon double bond in an α/β-unsaturated aldehyde or ketone (7, 10). Subsequently, the enzymes require NADPH to restore the flavin cofactor to its reduced state. OYEs catalyze multiple reactions useful for both biotechnological and pharmaceutical applications; however, physiological roles and natural substrates for many of these enzymes presently are unknown (26). On the basis of the apparent need in the ergot alkaloid pathway of A. fumigatus for reduction of a carbon-carbon double bond in the intermediate chanoclavine-I-aldehyde, we hypothesized that the OYE-encoding gene easA is required for ergot alkaloid biosynthesis (3, 16). In this study, easA in A. fumigatus was disrupted and complemented to ascertain the role of its gene product in ergot alkaloid biosynthesis.     

Biosynthesis of alkaloids by mycelial fungi (review of the literature)

Evidence for the occurrence of alkaloids in mycelial fungi, pathways of their biosynthesis and types of regulation are presented. The effect of some factors on the alkaloid production is discussed. In literature, the biosynthesis and the metabolism of diketopiperazine and ergot alkaloids in Penicillium fungi are covered most completely.     

Selection of fungal elicitors to increase indole alkaloid accumulation in catharanthus roseus suspension cell culture

Various fungal elicitors derived from 12 fungi were tested to improve indole alkaloid production in Catharanthus roseus cell suspension cultures. Results show that different fungal mycelium homogenates stimulate different kinds of indole alkaloid (ajmalicine, serpentine and catharanthine) accumulation, which ranged from 2- to 5-fold higher than the control. Some fungal culture filtrates also efficiently elicited the biosynthesis of different indole alkaloids. The optimal elicitor addition and exposure time for the maximal alkaloid production were on day 7 after subculture and for 3 days of treatment but different fungal elicitors showed the different optimal treatment dosages. Additions of elicitor at the doses ranging from 5 mg/l to 30 mg/l of carbon hydrate equivalent resulted in varieous amounts and kinds of indole alkaloid accumulation. Exposed to a same fungal elicitor, several different cell lines generated the different responses regarding as growth rate, culture color and alkaloid production.