Psychoactive Plant Database - Neuroactive Phytochemical Collection

1. Appl Environ Microbiol. 2024 Oct 23;90(10):e0105124. doi:
10.1128/aem.01051-24.  Epub 2024 Sep 27.

A gene regulating ergot alkaloid biosynthesis in Metarhizium brunneum.

Fabian SJ(1), Steen CR(1), Damron FH(2), DeRiggi CA(1), Panaccione DG(1).

Author information:
(1)Division of Plant and Soil Sciences, West Virginia University, Morgantown, 
West Virginia, USA.
(2)Department of Microbiology, Immunology, and Cell Biology, West Virginia 
University, Morgantown, West Virginia, USA.

Ergot alkaloid synthesis (eas) gene clusters found in several fungi encode 
biosynthesis of agriculturally and pharmaceutically important ergot alkaloids. 
Although the biosynthetic genes of the ergot alkaloid pathway have been well 
characterized, regulation of those genes is unknown. We characterized a gene 
with sequence similarity to a putative transcription factor and that was found 
adjacent to the eas cluster of Metarhizium brunneum, a plant symbiont and insect 
pathogen. Function of the novel gene, easR, was explored by CRISPR-Cas9-derived 
gene knockouts. To maximize potential for ergot alkaloid accumulation, strains 
of M. brunneum were injected into larvae of the insect Galleria mellonella. 
Larvae infected with the wild type contained abundant ergot alkaloids, but those 
infected with easR knockouts lacked detectable ergot alkaloids. The easR 
knockout strains had significantly reduced or no detectable mRNA from eas 
cluster genes in RNAseq and qualitative RT-PCR analyses, whereas the wild-type 
strain contained abundant mRNA from all eas genes. These data demonstrate that 
the product of easR is required for ergot alkaloid accumulation and provide 
evidence that it has a role in the expression of ergot alkaloid biosynthesis 
genes. Larvae infected with an easR knockout survived significantly longer than 
those infected with the wild type (P < 0.0001), indicating a role for EasR, and 
indirectly confirming a role for ergot alkaloids, in the virulence of M. 
brunneum to insects. Homologs of easR were found associated with eas clusters of 
at least 15 other ergot alkaloid-producing fungi, indicating that EasR homologs 
may contribute to regulation of ergot alkaloid synthesis in additional fungi.
IMPORTANCE: Ergot alkaloids produced by several species of fungi are important 
as contaminants of food and feed in agriculture and also as the foundation of 
numerous pharmaceuticals prescribed for dementia, migraines, hyperprolactinemia, 
and several other disorders. Information on control of the ergot alkaloid 
pathway may contribute to strategies to limit their production in agricultural 
settings or increase their yield for pharmaceutical production. Our results 
demonstrate that a previously uncharacterized gene clustered with the ergot 
alkaloid synthesis genes is required for the sufficient transcription of the 
ergot alkaloid biosynthesis genes. This observation suggests the gene encodes a 
factor regulating transcription of those biosynthetic genes.

DOI: 10.1128/aem.01051-24
PMCID: PMC11497822
PMID: 39329487 [Indexed for MEDLINE]

Conflict of interest statement: The authors declare no conflict of interest.


2. Appl Microbiol (Basel). 2024 Mar;4(1):406-417. doi: 
10.3390/applmicrobiol4010028. Epub 2024 Feb 20.

A Major Facilitator Superfamily Transporter Contributes to Ergot Alkaloid 
Accumulation but Not Secretion in Aspergillus leporis.

Jones AM(1), Davis KA(1), Panaccione DG(1).

Author information:
(1)Division of Plant and Soil Sciences, West Virginia University, Morgantown, WV 
26506, USA.

Ergot alkaloids are fungal natural products with important roles in agriculture 
and medicine. We used heterologous expression and gene knockout approaches to 
investigate potential roles for the product of a major facilitator superfamily 
transporter gene (easT) recently found in an ergot alkaloid biosynthetic gene 
cluster in Aspergillus leporis. A strain of Aspergillus fumigatus previously 
engineered to accumulate lysergic acid, but which did not convert the precursor 
agroclavine to lysergic acid efficiently or secrete lysergic acid well, was 
chosen as an expression host for easT. Expression of easT in this strain 
resulted in accumulation of significantly more pathway intermediates but no 
detectable lysergic acid. Secretion of ergot alkaloids was reduced in the 
easT-expressing strain. EasT localized to discrete vesicle-like structures in 
the cytosol of A. fumigatus, with no localization detected in the plasma 
membrane. When easT was knocked out in A. leporis, accumulation of lysergic acid 
amides was reduced relative to the wild type. There was no negative effect on 
secretion of ergot alkaloids in the knockout mutant. The data indicate that easT 
encodes a product that contributes to accumulation of ergot alkaloids, perhaps 
by transporting intermediates between cellular compartments, but does not have a 
significant role in secreting ergot alkaloids.

DOI: 10.3390/applmicrobiol4010028
PMCID: PMC11271707
PMID: 39055383

Conflict of interest statement: Conflicts of Interest: The authors declare no 
conflicts of interest. The funders had no role in the design of the study; in 
the collection, analyses, or interpretation of data; in the writing of the 
manuscript; or in the decision to publish the results.


3. Appl Environ Microbiol. 2023 Jun 28;89(6):e0041523. doi: 10.1128/aem.00415-23.
 Epub 2023 May 22.

Ergot Alkaloids Contribute to the Pathogenic Potential of the Fungus Aspergillus 
leporis.

Jones AM(1), Panaccione DG(1).

Author information:
(1)West Virginia University, Division of Plant and Soil Sciences, Morgantown, 
West Virginia, USA.

Opportunistically pathogenic fungi have varying potential to cause disease in 
animals. Factors contributing to their virulence include specialized 
metabolites, which in some cases evolved in contexts unrelated to pathogenesis. 
Specialized metabolites that increase fungal virulence in the model insect 
Galleria mellonella include the ergot alkaloids fumigaclavine C in Aspergillus 
fumigatus (syn. Neosartorya fumigata) and lysergic acid α-hydroxyethylamide 
(LAH) in the entomopathogen Metarhizium brunneum. Three species of Aspergillus 
recently found to accumulate high concentrations of LAH were investigated for 
their pathogenic potential in G. mellonella. Aspergillus leporis was most 
virulent, A. hancockii was intermediate, and A. homomorphus had very little 
pathogenic potential. Aspergillus leporis and A. hancockii emerged from and 
sporulated on dead insects, thus completing their asexual life cycles. 
Inoculation by injection resulted in more lethal infections than did topical 
inoculation, indicating that A. leporis and A. hancockii were preadapted for 
insect pathogenesis but lacked an effective means to breach the insect's 
cuticle. All three species accumulated LAH in infected insects, with A. leporis 
accumulating the most. Concentrations of LAH in A. leporis were similar to those 
observed in the entomopathogen M. brunneum. LAH was eliminated from A. leporis 
through a CRISPR/Cas9-based gene knockout, and the resulting strain had reduced 
virulence to G. mellonella. The data indicate that A. leporis and A. hancockii 
have considerable pathogenic potential and that LAH increases the virulence of 
A. leporis. IMPORTANCE Certain environmental fungi infect animals occasionally 
or conditionally, whereas others do not. Factors that affect the virulence of 
these opportunistically pathogenic fungi may have originally evolved to fill 
some other role for the fungus in its primary environmental niche. Among the 
factors that may improve the virulence of opportunistic fungi are specialized 
metabolites--chemicals that are not essential for basic life functions but 
provide producers with an advantage in particular environments or under specific 
conditions. Ergot alkaloids are a large family of fungal specialized metabolites 
that contaminate crops in agriculture and serve as the foundations of numerous 
pharmaceuticals. Our results show that two ergot alkaloid-producing fungi that 
were not previously known to be opportunistic pathogens can infect a model 
insect and that, in at least one of the species, an ergot alkaloid increases the 
virulence of the fungus.

DOI: 10.1128/aem.00415-23
PMCID: PMC10304750
PMID: 37212708 [Indexed for MEDLINE]

Conflict of interest statement: The authors declare no conflict of interest.


4. BMC Res Notes. 2022 May 18;15(1):183. doi: 10.1186/s13104-022-06068-2.

Contribution of a novel gene to lysergic acid amide synthesis in Metarhizium 
brunneum.

Britton KN(1), Steen CR(1), Davis KA(1), Sampson JK(1), Panaccione DG(2).

Author information:
(1)Division of Plant and Soil Sciences, West Virginia University, Morgantown, 
WV, 26506, USA.
(2)Division of Plant and Soil Sciences, West Virginia University, Morgantown, 
WV, 26506, USA. danpan@wvu.edu.

OBJECTIVE: The fungus Metarhizium brunneum produces ergot alkaloids of the 
lysergic acid amide class, most abundantly lysergic acid α-hydroxyethylamide 
(LAH). Genes for making ergot alkaloids are clustered in the genomes of 
producers. Gene clusters of LAH-producing fungi contain an α/β hydrolase fold 
protein-encoding gene named easP whose presence correlates with LAH production 
but whose contribution to LAH synthesis in unknown. We tested whether EasP 
contributes to LAH accumulation through gene knockout studies.
RESULTS: We knocked out easP in M. brunneum via a CRISPR/Cas9-based approach, 
and accumulation of LAH was reduced to less than half the amount observed in the 
wild type. Because LAH accumulation was reduced and not eliminated, we 
identified and mutated the only close homolog of easP in the M. brunneum genome, 
a gene we named estA. An easP/estA double mutant did not differ from the easP 
mutant in lysergic acid amide accumulation, indicating estA had no role in the 
pathway. We conclude EasP contributes to LAH accumulation but is not absolutely 
required. Either a gene encoding redundant function and lacking sequence 
identity with easP resides outside the ergot alkaloid synthesis gene cluster, or 
EasP plays an accessory role in the synthesis of LAH.

© 2022. The Author(s).

DOI: 10.1186/s13104-022-06068-2
PMCID: PMC9118626
PMID: 35585609 [Indexed for MEDLINE]

Conflict of interest statement: The authors have no competing interests, 
financial or otherwise, to declare.


5. Appl Environ Microbiol. 2021 Nov 24;87(24):e0180121. doi:
10.1128/AEM.01801-21.  Epub 2021 Sep 29.

Independent Evolution of a Lysergic Acid Amide in Aspergillus Species.

Jones AM(1), Steen CR(1), Panaccione DG(1).

Author information:
(1)West Virginia University, Division of Plant and Soil Sciences, Morgantown, 
West Virginia, USA.

Ergot alkaloids derived from lysergic acid have impacted humanity as 
contaminants of crops and as the bases of pharmaceuticals prescribed to treat 
dementia, migraines, and other disorders. Several plant-associated fungi in the 
Clavicipitaceae produce lysergic acid derivatives, but many of these fungi are 
difficult to culture and manipulate. Some Aspergillus species, which may be more 
ideal experimental and industrial organisms, contain an alternate branch of the 
ergot alkaloid pathway, but none were known to produce lysergic acid 
derivatives. We mined the genomes of Aspergillus species for ergot alkaloid 
synthesis (eas) gene clusters and discovered that three species, A. leporis, A. 
homomorphus, and A. hancockii, had eas clusters indicative of the capacity to 
produce a lysergic acid amide. In culture, A. leporis, A. homomorphus, and A. 
hancockii produced lysergic acid amides, predominantly lysergic acid 
α-hydroxyethylamide (LAH). Aspergillus leporis and A. homomorphus produced high 
concentrations of LAH and secreted most of their ergot alkaloid yield into the 
culture medium. Phylogenetic analyses indicated that genes encoding enzymes 
leading to the synthesis of lysergic acid were orthologous to those of the 
lysergic acid amide-producing Clavicipitaceae; however, genes to incorporate 
lysergic acid into an amide derivative evolved from different ancestral genes in 
the Aspergillus species. Our data demonstrate that fungi outside the 
Clavicipitaceae produce lysergic acid amides and indicate that the capacity to 
produce lysergic acid evolved once, but the ability to insert it into LAH 
evolved independently in Aspergillus species and the Clavicipitaceae. The 
LAH-producing Aspergillus species may be useful for the study and production of 
these pharmaceutically important compounds. IMPORTANCE Lysergic acid derivatives 
are specialized metabolites with historical, agricultural, and medical 
significance and were known heretofore only from fungi in one family, the 
Clavicipitaceae. Our data show that several Aspergillus species, representing a 
different family of fungi, also produce lysergic acid derivatives and that the 
ability to put lysergic acid into its amide forms evolved independently in the 
two lineages of fungi. From microbiological and pharmaceutical perspectives, the 
Aspergillus species may represent better experimental and industrial organisms 
than the currently employed lysergic acid producers of the plant-associated 
Clavicipitaceae. The observation that both lineages independently evolved the 
derivative lysergic acid α-hydroxyethylamide (LAH), among many possible lysergic 
acid amides, suggests selection for this metabolite.

DOI: 10.1128/AEM.01801-21
PMCID: PMC8612279
PMID: 34586904 [Indexed for MEDLINE]