A Branched Biosynthetic Pathway Is Involved in Production of Roquefortine and Related Compounds in Penicillium chrysogenum

Ali, Hazrat; Ries, Marco; Nijland, Jeroen G.; Lankhorst, Peter P.; Hankemeier, Thomas; Bovenberg, Roel A. L.; Vreeken, Rob J.; Driessen, Arnold J. M.

doi:10.1371/journal.pone.0065328

Cited by 81 publications

(112 citation statements)

References 36 publications

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“…The data obtained in this study suggest that the putative O-methyltransferase FmaD is responsible for methylation of the C6-hydroxyl group of β-trans-bergamotene during fumagillin biosynthesis. O-methyltransferases in a variety of secondary-metabolite gene clusters in different fungal species have been demonstrated to catalyze similar reactions (35)(36)(37). Identification of a fumagillinaldehyde derivative in the ΔfmaF mutant suggests that the putative phytanoyl-CoA-oxidase is involved in the final oxidation step of the tetraene chain.…”

Section: Discussionmentioning

confidence: 99%

Prototype of an intertwined secondary-metabolite supercluster

Wiemann

Guo²,

Palmer

et al. 2013

Proc. Natl. Acad. Sci. U.S.A.

184

196

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The hallmark trait of fungal secondary-metabolite gene clusters is well established, consisting of contiguous enzymatic and often regulatory gene(s) devoted to the production of a metabolite of a specific chemical class. Unexpectedly, we have found a deviation from this motif in a subtelomeric region of Aspergillus fumigatus. This region, under the control of the master regulator of secondary metabolism, LaeA, contains, in its entirety, the genetic machinery for three natural products (fumitremorgin, fumagillin, and pseurotin), where genes for fumagillin and pseurotin are physically intertwined in a single supercluster. Deletions of 29 adjoining genes revealed that fumagillin and pseurotin are coregulated by the supercluster-embedded regulatory gene with biosynthetic genes belonging to one of the two metabolic pathways in a noncontiguous manner. Comparative genomics indicates the fumagillin/pseurotin supercluster is maintained in a rapidly evolving region of diverse fungal genomes. This blended design confounds predictions from established secondary-metabolite cluster search algorithms and provides an expanded view of natural product evolution.gene regulation | Zn(II) 2 Cys 6 transcription factor | FapR | biosynthesis | cluster evolution F ilamentous fungi are well known for their ability to produce a variety of natural products, so-called secondary metabolites that are not essential for growth under laboratory conditions (reviewed in refs. 1 and 2). However, the maintenance of the genetic information allowing fungi to produce secondary metabolites suggests that these small molecules provide essential benefits in environmental niches ranging from protection from fungivory (reviewed in ref.3) to chemical shields from UV radiation (4). Apart from providing evolutionary fitness to the producing organism in their natural habitat, many secondary metabolites are of major importance to humans because of their beneficial and deleterious effects as drugs and toxins, respectively.Fungal secondary metabolism has been characterized by physical linkage of the genes required for synthesis of specific metabolites and the distinct enzymatic machinery encoded by these genes (1, 2, 5). For instance, most fungal secondary metabolites belong to one of four chemical classes that are characterized based on the key or backbone enzymes that consist of polyketide synthases (PKSs), nonribosomal peptide synthetases (NRPSs), terpene cyclases (TCs), and prenyltransferases (PTs). Typically, cluster genes adjacent to these backbone genes code for accessory enzymes involved in either modification of the chemical scaffold, transcriptional control of cluster genes, transport of substrates and/or products, and resistance mechanisms. The most common regulatory genes of clusters encode fungal-specific C6 zinc binuclear cluster (Zn(II) 2 Cys 6 ) transcription factors (6), which, in general, exert positive transcriptional regulation of most of the genes within a single cluster (7). In addition to cluster-specific transcription factors, a higher order...

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Section: Discussionmentioning

confidence: 99%

Prototype of an intertwined secondary-metabolite supercluster

Wiemann

Guo²,

Palmer

et al. 2013

Proc. Natl. Acad. Sci. U.S.A.

184

196

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“…However, BLAST analysis did not reveal an enzyme in the roquefortine/meleagrin pathway that is able to perform that reaction (6,7). Moreover, a 53 times higher concentration of 8 as compared with 10 in the host strain, but the absence of 8 in the roqO deletion strain with 10 still being present, leads to the conclusion that 8 is not a precursor of 10 (Fig.…”

Section: Discussionmentioning

confidence: 99%

“…Sample preparation was carried out as described previously (7). Metabolomic profiling was performed on an Agilent 1200 capillary pump (Agilent, Santa Clara, CA) coupled to a Surveyor photodiode array detector (Thermo Scientific) and an LTQ-FT-ICR-Ultra mass spectrometer (Thermo Scientific) equipped with an electrospray interface as described earlier (7).…”

Section: Methodsmentioning

confidence: 99%

“…Next to penicillins, secondary metabolites such as roquefortines and glandicolines were isolated from liquid cultures of P. chrysogenum, which show pharmaceutically interesting properties, such as neurotoxic (2), antimicrobial (3,4), and antitumor (5) activities. They are structurally closely related and arise from the roquefortine/meleagrin pathway, which contains a dimodular nonribosomal peptide synthetase flanked by six associated genes (6,7). Starting with histidyltryptophanyldiketopiperazine (HTD), 5 synthesized by the core synthetase enzyme RoqA using tryptophan and histidine as substrates, RoqD catalyzes the reversed prenylation of HTD at the C-3 of its indole moiety, utilizing dimethylallyl diphosphate to form roquefortine D. At the same time, RoqR, a cytochrome P450 oxidoreductase, oxidizes HTD at its histidinyl moiety to dehydrohistidyltryptophanyldiketo piperazine (DHTD).…”

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confidence: 99%

“…Although several labeling, silencing, and deletion experiments have been conducted, there is still ambiguity about the subsequent biosynthetic reactions and the genes involved. For instance, roquefortine C is supposed to be converted into glandicoline A and further to glandicoline B with RoqM and RoqO each catalyzing one reaction (6,7). However, their assignment to a particular reaction is still unclear.…”

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confidence: 99%

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Novel Key Metabolites Reveal Further Branching of the Roquefortine/Meleagrin Biosynthetic Pathway

Ries

Ali

Lankhorst

et al. 2013

Journal of Biological Chemistry

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Background:The fungal roquefortine/meleagrin gene cluster is a source of diverse bioactive molecules. Results: Novel metabolites of the roquefortine/meleagrin biosynthetic pathway were discovered, and synthetase genes were assigned to biosynthetic reactions. Conclusion: Distinctive unspecificity of modifying enzymes leads to excessive branching in the pathway, resulting in various intermediates and products. Significance: Metabolites from the roquefortine/meleagrin gene cluster have potential antimicrobial and chemotherapeutic application.

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