ChemInform Abstract: Isolation of Paspaline B, an Indole-Diterpenoid from Penicillium paxilli

<p>Nature holds some of the greatest secrets in drug design and development and the ability to access these trade secrets has been revolutionised by modern bioengineering technologies. In order to exploit these technologies it is essential to understand what genes are involved in compound production and the enzymatic steps that limit flux to the desired product. This thesis describes the discovery of four secondary-metabolic enzymatic steps involved in the biosynthesis of a group of valuable natural products known as nodulisporic acids. Nodulisporic acids are known for their potent insecticidal activities; however, biosynthesis of these compounds by the natural fungal producer, Hypoxylon pulicicidum (Nodulisporium sp.), is exceptionally difficult and has prevented the commercial development of novel nodulisporic acid-containing veterinary medicines and crop protects. To discover how nodulisporic acids are biosynthesized: 1. the H. pulicicidum genome was sequenced 2. a gene cluster responsible for nodulisporic acid production was predicted 3. genes in the cluster were functionally characterised by pathway reconstitution in a common, fast growing mould, Penicillium paxilli In turn, four genes involved in the biosynthesis of the nodulisporic acid core compound, nodulisporic acid F, have been functionally characterised. The four genes encode a geranylgeranyl transferase (NodC), a flavin adenine dinucleotide-dependent oxygenase (NodM), an indole diterpene cyclase (NodB) and a cytochrome P450 oxygenase (NodW). Two of the gene products (NodM and NodW) catalyse two previously unreported reactions that provide the enzymatic basis of the biosynthetic branch point unique to nodulisporic acid biosynthesis. From here, future efforts will explore how these genes can be engineered to overcome flux bottlenecks and enable production of significantly increased, and even industrially relevant, product titres.</p>

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Molecular biology of Epichloe endophyte toxin biosynthesis

NZGA: Research and Practice Series ◽

10.33584/rps.7.1999.3385 ◽

1999 ◽

Vol 7 ◽

pp. 77-83

Author(s):

Barry Scott ◽

Carolyn Young ◽

Lisa Mcmillan

Keyword(s):

Molecular Biology ◽

Genetically Modify ◽

Livestock Grazing ◽

Important Group ◽

Homologous Genes ◽

Pasture Grasses ◽

Penicillium Paxilli ◽

Large Clusters ◽

Mutualistic Association ◽

Epichloë Endophyte

EpichloÃ« endophytes are an important group of filamentous fungi that confer on the grass host a range of biological benefits. However, endophyte synthesis of ergopeptine and indole-diterpene mammalian toxins in pasture grasses is detrimental to livestock grazing on that forage. The molecular cloning of the genes involved in the biosynthesis of these toxins will enhance our ability to maximise the beneficial attributes of this mutualistic association through the availability of DNA probes to screen and select for desirable endophytes and through our ability to genetically modify endophytes. Genes involved in the biosynthesis of both classes of alkaloids have recently been cloned from Claviceps purpurea and Penicillium paxilli. In both cases the genes are organised in large clusters; a feature that will facilitate a complete genetic analysis of each pathway and provide probes for isolating homologous genes from EpichloÃ« endophytes. This paper reviews recent research developments on the molecular biology of these two pathways. Keywords: EpichloÃ« endophytes, ergopeptines, gene cloning, gene manipulation, indole-diterpenes

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A new tremorgenic metabolite from Penicillium paxilli

Canadian Journal of Microbiology ◽

10.1139/m74-179 ◽

1974 ◽

Vol 20 (8) ◽

pp. 1159-1162 ◽

Cited By ~ 54

Author(s):

Richard J. Cole ◽

Jerry W. Kirksey ◽

John M. Wells

Keyword(s):

Molecular Formula ◽

Penicillium Paxilli

A new tremorgenic metabolite was found in the chloroform extracts of cultures of Penicillium paxilli. Purified tremorgen had a molecular formula of C27H33NO4 and data supported the presence of an indole moiety. Administration of the tremorgen orally to 1-day-old cockerels and intraperitoneally to mice caused sustained tremors that persisted for about 24 h. The tremorgen also caused mice to overreact to sound stimuli.

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Identification of Two Aflatrem Biosynthesis Gene Loci in Aspergillus flavus and Metabolic Engineering of Penicillium paxilli To Elucidate Their Function

Applied and Environmental Microbiology ◽

10.1128/aem.02146-08 ◽

2009 ◽

Vol 75 (23) ◽

pp. 7469-7481 ◽

Cited By ~ 102

Author(s):

Matthew J. Nicholson ◽

Albert Koulman ◽

Brendon J. Monahan ◽

Beth L. Pritchard ◽

Gary A. Payne ◽

...

Keyword(s):

Aspergillus Flavus ◽

Sequence Data ◽

Soil Fungus ◽

Gene Clusters ◽

Deletion Mutants ◽

Wild Type ◽

Functional Homolog ◽

Biosynthesis Gene ◽

Penicillium Paxilli ◽

Diterpene Biosynthesis

ABSTRACT Aflatrem is a potent tremorgenic toxin produced by the soil fungus Aspergillus flavus, and a member of a structurally diverse group of fungal secondary metabolites known as indole-diterpenes. Gene clusters for indole-diterpene biosynthesis have recently been described in several species of filamentous fungi. A search of Aspergillus complete genome sequence data identified putative aflatrem gene clusters in the genomes of A. flavus and Aspergillus oryzae. In both species the genes for aflatrem biosynthesis cluster at two discrete loci; the first, ATM1, is telomere proximal on chromosome 5 and contains a cluster of three genes, atmG, atmC, and atmM, and the second, ATM2, is telomere distal on chromosome 7 and contains five genes, atmD, atmQ, atmB, atmA, and atmP. Reverse transcriptase PCR in A. flavus demonstrated that aflatrem biosynthesis transcript levels increased with the onset of aflatrem production. Transfer of atmP and atmQ into Penicillium paxilli paxP and paxQ deletion mutants, known to accumulate paxilline intermediates paspaline and 13-desoxypaxilline, respectively, showed that AtmP is a functional homolog of PaxP and that AtmQ utilizes 13-desoxypaxilline as a substrate to synthesize aflatrem pathway-specific intermediates, paspalicine and paspalinine. We propose a scheme for aflatrem biosynthesis in A. flavus based on these reconstitution experiments in P. paxilli and identification of putative intermediates in wild-type cultures of A. flavus.

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Indole-Diterpene Gene Cluster from Aspergillus flavus

Applied and Environmental Microbiology ◽

10.1128/aem.70.11.6875-6883.2004 ◽

2004 ◽

Vol 70 (11) ◽

pp. 6875-6883 ◽

Cited By ~ 73

Author(s):

Shuguang Zhang ◽

Brendon J. Monahan ◽

Jan S. Tkacz ◽

Barry Scott

Keyword(s):

Aspergillus Flavus ◽

Biosynthetic Pathway ◽

Sequence Similarity ◽

Soil Fungus ◽

Amino Acid Sequence Similarity ◽

Degenerate Primers ◽

Functional Homolog ◽

Penicillium Paxilli ◽

Diterpene Biosynthesis ◽

Tremorgenic Mycotoxin

ABSTRACT Aflatrem is a potent tremorgenic mycotoxin produced by the soil fungus Aspergillus flavus and is a member of a large structurally diverse group of secondary metabolites known as indole-diterpenes. By using degenerate primers for conserved domains of fungal geranylgeranyl diphosphate synthases, we cloned two genes, atmG and ggsA (an apparent pseudogene), from A. flavus. Adjacent to atmG are two other genes, atmC and atmM. These three genes have 64 to 70% amino acid sequence similarity and conserved synteny with a cluster of orthologous genes, paxG, paxC, and paxM, from Penicillium paxilli which are required for indole-diterpene biosynthesis. atmG, atmC, and atmM are coordinately expressed, with transcript levels dramatically increasing at the onset of aflatrem biosynthesis. A genomic copy of atmM can complement a paxM deletion mutant of P. paxilli, demonstrating that atmM is a functional homolog of paxM. Thus, atmG, atmC, and atmM are necessary, but not sufficient, for aflatrem biosynthesis by A. flavus. This provides the first genetic evidence for the biosynthetic pathway of aflatrem in A. flavus.

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Formation and release of pectin lyase during growth of Penicillium paxilli

Biotechnology Letters ◽

10.1007/bf01026679 ◽

1985 ◽

Vol 7 (2) ◽

pp. 105-108 ◽

Cited By ~ 6

Author(s):

I. Szajer ◽

Cz. Czajer

Keyword(s):

Pectin Lyase ◽

Penicillium Paxilli

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Regiospecificities and Prenylation Mode Specificities of the Fungal Indole Diterpene Prenyltransferases AtmD and PaxD

Applied and Environmental Microbiology ◽

10.1128/aem.02496-13 ◽

2013 ◽

Vol 79 (23) ◽

pp. 7298-7304 ◽

Cited By ~ 13

Author(s):

Chengwei Liu ◽

Atsushi Minami ◽

Motoyoshi Noike ◽

Hiroaki Toshima ◽

Hideaki Oikawa ◽

...

Keyword(s):

Gene Cluster ◽

Biosynthetic Gene Cluster ◽

Amino Acid Identity ◽

Biosynthetic Gene ◽

Content Type ◽

Acid Identity ◽

Dimethylallyl Diphosphate ◽

Regular Type ◽

Penicillium Paxilli ◽

Related Compounds

ABSTRACTWe recently reported the function ofpaxD, which is involved in the paxilline (compound 1) biosynthetic gene cluster inPenicillium paxilli. Recombinant PaxD catalyzed a stepwise regular-type diprenylation at the 21 and 22 positions of compound 1 with dimethylallyl diphosphate (DMAPP) as the prenyl donor. In this study,atmD, which is located in the aflatrem (compound 2) biosynthetic gene cluster inAspergillus flavusand encodes an enzyme with 32% amino acid identity to PaxD, was characterized using recombinant enzyme. When compound 1 and DMAPP were used as substrates, two major products and a trace of minor product were formed. The structures of the two major products were determined to be reversely monoprenylated compound 1 at either the 20 or 21 position. Because compound 2 and β-aflatrem (compound 3), both of which are compound 1-related compounds produced byA. flavus, have the same prenyl moiety at the 20 and 21 position, respectively, AtmD should catalyze the prenylation in compound 2 and 3 biosynthesis. More importantly and surprisingly, AtmD accepted paspaline (compound 4), which is an intermediate of compound 1 biosynthesis that has a structure similar to that of compound 1, and catalyzed a regular monoprenylation of compound 4 at either the 21 or 22 position, though the reverse prenylation was observed with compound 1. This suggests that fungal indole diterpene prenyltransferases have the potential to alter their position and regular/reverse specificities for prenylation and could be applicable for the synthesis of industrially useful compounds.

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