Final piece to the Fusarium pigmentation puzzle - Unraveling of the phenalenone biosynthetic pathway responsible for perithecial pigmentation in the Fusarium solani species complex.

The Fusarium solani species complex (FSSC) is comprised of important pathogens of plants and humans. A distinctive feature of FSSC species is perithecial pigmentation. While the dark perithecial pigments of other Fusarium species are derived from fusarubins synthesized by polyketide synthase 3 (PKS3), the perithecial pigments of FSSC are derived from an unknown metabolite synthesized by PKS35. Here, we confirm in FSSC species Fusarium vanettenii that PKS35 (fsnI) is required for perithecial pigment synthesis by deletion analysis and that fsnI is closely related to phnA from Penicillium herquei, as well as duxI from Talaromyces stipentatus, which produce prephenalenone as an early intermediate in herqueinone and duclauxin synthesis respectively. The production of prephenalenone by expression of fsnI in Saccharomyces cerevisiae indicates that it is also an early intermediate in perithecial pigment synthesis. We next identified a conserved cluster of 10 genes flanking fsnI in F. vanettenii that when expressed in F. graminearum led to the production of a novel corymbiferan lactone F as a likely end product of the phenalenone biosynthetic pathway in FSSC.

H3K27me3 is vital for fungal development and secondary metabolite gene silencing, and substitutes for the loss of H3K9me3 in the plant pathogen Fusarium proliferatum.

Facultative heterochromatin marked by histone H3 lysine 27 trimethylation (H3K27me3) is an important regulatory layer involved in secondary metabolite (SM) gene silencing and crucial for fungal development in the genus Fusarium. While this histone mark is essential in some (e.g., the rice pathogen Fusarium fujikuroi), it appears dispensable in other fusaria. Here, we show that deletion of FpKMT6 is detrimental but not lethal in the plant pathogen Fusarium proliferatum, a member of the Fusarium fujikuroi species complex (FFSC). Loss of FpKmt6 results in aberrant growth, and expression of a large set of previously H3K27me3-silenced genes is accompanied by increased H3K27 acetylation (H3K27ac) and an altered H3K36me3 pattern. Next, H3K9me3 patterns are affected in Δfpkmt6, indicating crosstalk between both heterochromatic marks that became even more obvious in a strain deleted for FpKMT1 encoding the H3K9-specific histone methyltransferase. In Δfpkmt1, all H3K9me3 marks present in the wild-type strain are replaced by H3K27me3, a finding that may explain the subtle phenotype of the Δfpkmt1 strain which stands in marked contrast to other filamentous fungi. A large proportion of SM-encoding genes is allocated with H3K27me3 in the wild-type strain and loss of H3K27me3 results in elevated expression of 49% of them. Interestingly, genes involved in the biosynthesis of the phytohormones gibberellins (GA) are among the most upregulated genes in Δfpkmt6. Although several FFSC members harbor GA biosynthetic genes, its production is largely restricted to F. fujikuroi, possibly outlining the distinct lifestyles of these notorious plant pathogens. We show that H3K27me3 is involved in GA gene silencing in F. proliferatum and at least one additional FFSC member, and thus, may serve as a regulatory layer for gene silencing under non-favoring conditions.

Filling out the gaps - identification of fugralins as products of the PKS2 cluster in Fusarium graminearum.

As one of the grain crop pathogenic fungi with the greatest impacts on agricultural economical as well as human health, an elaborate understanding of the life cycle and subsequent metabolome of Fusarium graminearum is of great interest. Throughout the lifetime of the fungus, it is known to produce a wide array of secondary metabolites, including polyketides. One of the F. graminearum polyketides which has remained a mystery until now has been elucidated in this work. Previously, it was suggested that the biosynthetic product of the PKS2 gene cluster was involved in active mycelial growth, the exact mechanism, however, remained unclear. In our work, disruption and overexpression of the PKS2 gene in F. graminearum enabled structural elucidation of a linear and a cyclic tetraketide with a double methyl group, named fugralin A and B, respectively. Further functional characterization showed that the compounds are not produced during infection, and that deletion and overexpression did not affect pathogenicity or visual growth. The compounds were shown to be volatile, which could point to possible functions that can be investigated further in future studies.

Proteomic Changes in Methicillin-Resistant Staphylococcus aureus Exposed to Cannabinoids.

Methicillin-resistant Staphylococcus aureus (MRSA) is a major human pathogen that causes a wide range of infections. Its resistance to ß-lactam antibiotics complicates treatment due to the limited number of antibiotics with activity against MRSA. To investigate development of alternative therapeutics, the mechanisms that mediate antibiotic resistance in MRSA need to be fully understood. In this study, MRSA cells were subjected to antibiotic stress from methicillin in combination with three cannabinoid compounds and analyzed using proteomics to assess the changes in physiology. Subjecting MRSA to nonlethal levels of methicillin resulted in an increased production of penicillin-binding protein 2 (PBP2). Exposure to cannabinoids showed antibiotic activity against MRSA, and differential proteomics revealed reduced levels of proteins involved in the energy production as well as PBP2 when used in combination with methicillin.

6-MSA, a secondary metabolite distribution hub with multiple fungal destinations.

6-methylsalicylic acid (6-MSA) is a small, simple polyketide produced by a broad spectrum of fungal species. Since fungi obtained the ability to synthesize 6-MSA from bacteria through a horizontal gene transfer event, it has developed into a multipurpose metabolic hub from where numerous complex compounds are produced. The most relevant metabolite from a human perspective is the small lactone patulin as it is one of the most potent mycotoxins. Other important end products derived from 6-MSA include the small quinone epoxide terreic acid and the prenylated yanuthones. The most advanced modification of 6-MSA is observed in the aculin biosynthetic pathway, which is mediated by a non-ribosomal peptide synthase and a terpene cyclase. In this short review, we summarize for the first time all the possible pathways that takes their onset from 6-MSA and provide a synopsis of the responsible gene clusters and derive the resulting biosynthetic pathways.

Speed dating for enzymes! Finding the perfect phosphopantetheinyl transferase partner for your polyketide synthase.

The biosynthetic pathways for the fungal polyketides bikaverin and bostrycoidin, from Fusarium verticillioides and Fusarium solani respectively, were reconstructed and heterologously expressed in S. cerevisiae alongside seven different phosphopantetheinyl transferases (PPTases) from a variety of origins spanning bacterial, yeast and fungal origins. In order to gauge the efficiency of the interaction between the ACP-domains of the polyketide synthases (PKS) and PPTases, each were co-expressed individually and the resulting production of target polyketides were determined after 48 h of growth. In co-expression with both biosynthetic pathways, the PPTase from Fusarium verticillioides (FvPPT1) proved most efficient at producing both bikaverin and bostrycoidin, at 1.4 mg/L and 5.9 mg/L respectively. Furthermore, the remaining PPTases showed the ability to interact with both PKS's, except for a single PKS-PPTase combination. The results indicate that it is possible to boost the production of a target polyketide, simply by utilizing a more optimal PPTase partner, instead of the commonly used PPTases; NpgA, Gsp and Sfp, from Aspergillus nidulans, Brevibacillus brevis and Bacillus subtilis respectively.

The effects of different potato dextrose agar media on secondary metabolite production in Fusarium.

Potatoes contain several nutrients essential for fungal growth, making them an excellent component of media such as the popular Potato Dextrose Agar (PDA) medium. Commercially, PDA is available from multiple retailers offering virtually the same product. These media, however, could contain small differences in composition of nutrients affecting the expression of secondary metabolites. This study aims to investigate the use of four PDA media from different manufacturers (Fluka, Oxoid, Sigma, and VWR) and their effect on the metabolite profile of four species of Fusarium (F. fujikuroi, F. graminearum, F. pseudograminearum and F. avenaceum). Secondary metabolites were analysed using HPLC-HRMS, from which statistically significant differences in intensities were observed for 9 out of 10 metabolites.

Heterologous Expression of the Core Genes in the Complex Fusarubin Gene Cluster of Fusarium Solani.

Through stepwise recreation of the biosynthetic gene cluster containing PKS3 from Fusarium solani, it was possible to produce the core scaffold compound of bostrycoidin, a red aza-anthraquinone pigment in Saccharomyces cerevisiae. This was achieved through sequential transformation associated recombination (TAR) cloning of FvPPT, fsr1, fsr2, and fsr3 into the pESC-vector system, utilizing the inducible bidirectional galactose promoter for heterologous expression in S. cerevisiae. The production of the core metabolite bostrycoidin was investigated through triplicate growth cultures for 1-4 days, where the maximum titer of bostrycoidin was achieved after 2 days of induction, yielding 2.2 mg/L.

Growth and single cell kinetics of the loricate choanoflagellate Diaphanoeca grandis.

Choanoflagellates are common members of planktonic communities. Some have complex life histories that involve transitions between multiple cell stages. We have grown the loricate choanoflagellate Diaphanoeca grandis on the bacterium Pantoea sp. and integrated kinetic observations at the culture level and at the single cell level. The life history of D. grandis includes a cell division cycle with a number of recognisable cell stages. Mature, loricate D. grandis were immobile and settled on the bottom substratum. Daughter cells were ejected from the lorica 30 min. after cell division, became motile and glided on the bottom substratum until they assembled a lorica. Single cell kinetics could explain overall growth kinetics in D. grandis cultures. The specific growth rate was 0.72 day-1 during exponential growth while mature D. grandis produced daughter cells at a rate of 0.9 day-1. Daughter cells took about 1.2 h to mature. D. grandis was able to abandon and replace its lorica, an event that delayed daughter cell formation by more than 2 days. The frequency of daughter cell formation varied considerably among individuals and single cell kinetics demonstrated an extensive degree of heterogeneity in D. grandis cultures, also when growth appeared to be balanced.

Characterization of Eight Novel Spiroleptosphols from Fusarium avenaceum.

Chemical analyses of Fusarium avenaceum grown on banana medium resulted in eight novel spiroleptosphols, T1, T2 and U-Z (1-8). The structures were elucidated by a combination of high-resolution mass spectrometric data and 1- and 2-D NMR experiments. The relative stereochemistry was assigned by 1H coupling and NOESY/ROESY experiments. Absolute stereochemistry established for 7 by vibrational circular dichroism was found analogous to that of the putative polyketide spiroleptosphol from Leptosphaeria doliolum.

Heterologous expression of intact biosynthetic gene clusters in Fusarium graminearum.

Filamentous fungi such as species from the genus Fusarium are capable of producing a wide palette of interesting metabolites relevant to health, agriculture and biotechnology. Secondary metabolites are formed from large synthase/synthetase enzymes often encoded in gene clusters containing additional enzymes cooperating in the metabolite's biosynthesis. The true potential of fungal metabolomes remain untapped as the majority of secondary metabolite gene clusters are silent under standard laboratory growth conditions. One way to achieve expression of biosynthetic pathways is to clone the responsible genes and express them in a well-suited heterologous host, which poses a challenge since Fusarium polyketide synthase and non-ribosomal peptide synthetase gene clusters can be large (e.g. as large as 80 kb) and comprise several genes necessary for product formation. The major challenge associated with heterologous expression of fungal biosynthesis pathways is thus handling and cloning large DNA sequences. In this paper we present the successful workflow for cloning, reconstruction and heterologous production of two previously characterized Fusarium pseudograminearum natural product pathways in Fusarium graminearum. In vivo yeast recombination enabled rapid assembly of the W493 (NRPS32-PKS40) and the Fusarium Cytokinin gene clusters. F. graminearum transformants were obtained through protoplast-mediated and Agrobacterium tumefaciens-mediated transformation. Whole genome sequencing revealed isolation of transformants carrying intact copies the gene clusters was possible. Known Fusarium cytokinin metabolites; fusatin, 8-oxo-fusatin, 8-oxo-isopentenyladenine, fusatinic acid together with cis- and trans-zeatin were detected by liquid chromatography and mass spectrometry, which confirmed gene functionality in F. graminearum. In addition the non-ribosomal lipopeptide products W493 A and B was heterologously produced in similar amounts to that observed in the F. pseudograminearum doner. The Fusarium pan-genome comprises more than 60 uncharacterized putative secondary metabolite gene clusters. We nominate the well-characterized F. graminearum as a heterologous expression platform for Fusarium secondary metabolite gene clusters, and present our experience cloning and introducing gene clusters into this species. We expect the presented methods will inspire future endevours in heterologous production of Fusarium metabolites and potentially aid the production and characterization of novel natural products.

Advances in linking polyketides and non-ribosomal peptides to their biosynthetic gene clusters in Fusarium.

The eukaryotic ascomycete genus Fusarium comprises many species capable of producing secondary metabolites important for agriculture, health, and biotechnology. Filamentous fungi share common physiological features, but even within Fusarium, there are significant differences that affect the success of biotechnological methods used to unravel biosynthetic pathways. The aim of this review is to describe the different methods that have successfully been used throughout the genus Fusarium to identify the products of novel biosynthetic pathways. The results are presented in tables to give the reader an overview and thereby enable the selection of the most appropriate method to the problem, regarding both species and target products. Significant work has gone into characterization of the underlying molecular genetics of secondary metabolites, but still, the products of only 25-30% of predicted gene clusters have been identified. In this review, we highlight existing knowledge and encourage the development of new techniques and strategies to provide access to the many unknown polyketide and non-ribosomal peptide products that await discovery in Fusarium.

Fusaoctaxin A, an Example of a Two-Step Mechanism for Non-Ribosomal Peptide Assembly and Maturation in Fungi.

Fungal non-ribosomal peptide synthetase (NRPS) clusters are spread across the chromosomes, where several modifying enzyme-encoding genes typically flank one NRPS. However, a recent study showed that the octapeptide fusaoctaxin A is tandemly synthesized by two NRPSs in Fusarium graminearum. Here, we illuminate parts of the biosynthetic route of fusaoctaxin A, which is cleaved into the tripeptide fusatrixin A and the pentapeptide fusapentaxin A during transport by a cluster-specific ABC transporter with peptidase activity. Further, we deleted the histone H3K27 methyltransferase kmt6, which induced the production of fusaoctaxin A.

19F-substituted amino acids as an alternative to fluorophore labels: monitoring of degradation and cellular uptake of analogues of penetratin by 19F NMR.

Current methods for assessment of cellular uptake of cell-penetrating peptides (CPPs) often rely on detection of fluorophore-labeled CPPs. However, introduction of the fluorescent probe often confers changed physicochemical properties, so that the fluorophore-CPP conjugate may exhibit cytotoxic effects and membrane damage not exerted by the native CPP. In the present study, introduction of fluorine probes was investigated as an alternative to fluorophore labeling of a CPP, since this only confers minor changes to its overall physicochemical properties. The high sensitivity of 19F NMR spectroscopy and the absence of background signals from naturally occurring fluorine enabled detection of internalized CPP. Also, degradation of fluorine-labeled peptides during exposure to Caco-2 cells could be followed by using 19F NMR spectroscopy. In total, five fluorinated analogues of the model CPP penetratin were synthesized by using commercially available fluorinated amino acids as labels, including one analogue also carrying an N-terminal fluorophore. The apparent cellular uptake was considerably higher for the fluorophore-penetratin conjugate indicating that the fluorophore moiety promoted uptake of the peptide. The use of 19F NMR spectroscopy enabled monitoring of the fate of the CPPs over time by establishing molar balances, and by verifying CPP integrity upon uptake. Thus, the NMR-based method offers several advantages over currently widespread methods relying on fluorescence detection. The present findings provide guidelines for improved labeling strategies for CPPs, thereby expanding the repertoire of analytical techniques available for studying degradation and uptake of CPPs.

Expression of NOTCH3 exon 16 differentiates Diffuse Large B-cell Lymphoma into molecular subtypes and is associated with prognosis.

Diffuse large B-cell lymphoma (DLBCL) is a heterogeneous disease with diverse clinical presentation and outcome. Bio-clinical prognostic models including oncogene expression and cell-of-origin phenotyping has been developed, however, approximately 30% of all patients still die from their disease, illustrating the need for additional prognostic biomarkers associating oncogenesis and phenotypic subclasses. Hence, we tested if alternative splice variations have biomarker potential. Initial alternative splicing analysis of human exon array from clinical DLBCL samples identified candidate genes. Experimental validation by ddPCR was performed in a DLBCL cohort classified into ABC/GCB subclasses, B-cell associated gene signatures (BAGS: naive, centroblast, centrocyte, memory, and plasmablast), and vincristine resistant gene signatures. Prognostic potential was assessed for aberrantly spliced transcripts. Thus, NOTCH3 was identified as alternatively spliced, with differential exon 16 depletion (-exon 16) between differentiation associated BAGS subtypes. Predicted vincristine resistant patients of the GCB subclass had significantly downregulated NOTCH3 -exon 16 transcript expression and tended to display adverse overall survival for R-CHOP treated patients. In conclusion, we have identified a specific alternatively spliced NOTCH3 event that differentiate molecular subtypes of DLBCL and display prognostic and predictive biomarker potential in GCB DLBCL.

There it is! Fusarium pseudograminearum did not lose the fusaristatin gene cluster after all.

Fusarium pseudograminearum is a significant pathogen of cereals in arid regions worldwide and has the ability to produce numerous bioactive secondary metabolites. The genome sequences of seven F. pseudograminearum strains have been published and in one of these strains, C5834, we identified an intact gene cluster responsible for biosynthesis of the cyclic lipopeptide fusaristatin A. The high level of sequence identity of the fusaristatin cluster remnant in strains that do not produce fusaristatin suggests that the absence of the cluster evolved once, and subsequently the resulting locus with the cluster fragments became widely dispersed among strains of F. pseudograminearum in Australia. We examined a selection of 99 Australian F. pseudograminearum isolates to determine how widespread the ability to produce fusaristatin A is in F. pseudograminearum. We identified 15 fusaristatin producing strains, all originating from Western Australia. Phylogenetic analyses could not support a division of F. pseudograminearum into fusaristatin producing and nonproducing populations, which could indicate the loss has occurred relatively recent.

A new vector system for targeted integration and overexpression of genes in the crop pathogen Fusarium solani.

BACKGROUND: Besides their ability to produce several interesting bioactive secondary metabolites, members of the Fusarium solani species complex comprise important pathogens of plants and humans. One of the major obstacles in understanding the biology of this species complex is the lack of efficient molecular tools for genetic manipulation. RESULTS: To remove this obstacle we here report the development of a reliable system where the vectors are generated through yeast recombinational cloning and inserted into a specific site in F. solani through Agrobacterium tumefaciens-mediated transformation. As proof-of-concept, the enhanced yellow fluorescent protein (eYFP) was inserted in a non-coding genomic position of F. solani and subsequent analyses showed that the resulting transformants were fluorescent on all tested media. In addition, we cloned and overexpressed the Zn(II)2Cys6 transcriptional factor fsr6 controlling mycelial pigmentation. A transformant displayed deep red/purple pigmentation stemming from bostrycoidin and javanicin. CONCLUSION: By creating streamlined plasmid construction and fungal transformation systems, we are now able to express genes in the crop pathogen F. solani in a reliable and fast manner. As a case study, we targeted and activated the fusarubin (PKS3: fsr) gene cluster, which is the first case study of secondary metabolites being directly associated with the responsible gene cluster in F. solani via targeted activation. The system provides an approach that in the future can be used by the community to understand the biochemistry and genetics of the Fusarium solani species complex, and is obtainable from Addgene catalog #133094.

Enhancing the Production of the Fungal Pigment Aurofusarin in Fusarium graminearum.

There is an increasing demand for products from natural sources, which includes a growing market for naturally-produced colorants. Filamentous fungi produce a vast number of chemically diverse pigments and are therefore explored as an easily accessible source. In this study we examine the positive regulatory effect of the transcription factor AurR1 on the aurofusarin gene cluster in Fusarium graminearum. Proteomic analyses showed that overexpression of AurR1 resulted in a significant increase of five of the eleven proteins belonging to the aurofusarin biosynthetic pathway. Further, the production of aurofusarin was increased more than threefold in the overexpression mutant compared to the wild type, reaching levels of 270 mg/L. In addition to biosynthesis of aurofusarin, several yet undescribed putative naphthoquinone/anthraquinone analogue compounds were observed in the overexpression mutant. Our results suggest that it is possible to enhance the aurofusarin production through genetic engineering.

Who Needs Neighbors? PKS8 Is a Stand-Alone Gene in Fusarium graminearum Responsible for Production of Gibepyrones and Prolipyrone B.

Genome sequencing of the genus Fusarium has revealed a great capacity for discovery of new natural products of potential economical and therapeutic importance. Several of these are unknown. In this study, we investigated the product of the PKS8 gene in Fusarium graminearum, which was recently linked to gibepyrones in F. fujikuroi. Genomic analyses showed that PKS8 constitutes a stand-alone gene in F. graminearum and related species. Overexpression of PKS8 resulted in production of gibepyrones A, B, D, G and prolipyrone B, which could not be detected in the wild type strain. Our results suggest that PKS8 produces the entry compound gibepyrone A, which is subsequently oxidized by one or several non-clustering cytochrome P450 monooxygenases ending with prolipyrone B.

Feeding and growth of the marine heterotrophic nanoflagellates, Procryptobia sorokini and Paraphysomonas imperforata on a bacterium, Pseudoalteromonas sp. with an inducible defence against grazing.

Heterotrophic marine nanoflagellates are important grazers on bacteria in the water column. Some marine bacteria appear more resistant to grazing than do others. Marine nanoflagellates can be grown in the laboratory in batch cultures fed specific bacterial isolates. In some cultures, the flagellates appear unable to completely deplete the bacterial prey even when the bacterial strain otherwise is an excellent prey. This may indicate that some marine bacteria are able to induce defence mechanisms if they are grazed by nanoflagellates. Four morphologically distinct marine heterotrophic nanoflagellates, of which 3 were still identified as Procryptobia sorokini (Kinetoplastea) and one as Paraphysomonas imperforata (Chrysophyceae) were isolated from a coastal location along with 3 isolates of the marine bacterium Pseudoalteromonas sp. Flagellate growth and grazing on bacterial prey were analysed in batch cultures. Pseudoalteromonas was a suitable prey for all 4 flagellate isolates. They grazed and grew on Pseudoalteromonas as sole prey with maximal cell-specific growth rates of 0.1-0.25 h-1 and gross growth efficiencies of 38-61%. Exposure to dense flagellate cultures or their supernatants did, however, cause a fraction of the Pseudoalteromonas cells to aggregate and the bacterium became apparently resistant to grazing. Concentrations of suspended Pseudoalteromonas cells were therefore not decreased below 1,700-7,500 cells µL-1 by any of the flagellate isolates. These results indicate that Pseudoalteromonas sp. can be an excellent prey to marine nanoflagellates but also that is in possession of inducible mechanisms that protect against flagellate grazing.