John L. Sorensen

Putative identification of the usnic acid biosynthetic gene cluster by de novo whole-genome sequencing of a lichen-forming fungus

To identify the biosynthetic gene cluster responsible for the biosynthesis of the polyketide usnic acid we carried out the de novo genome sequencing of the fungal partner of Cladonia uncialis. This was followed by comprehensive in silico annotation of polyketide synthase (PKS) genes. The biosynthesis of usnic acid requires a non-reducing PKS possessing a carbon methylation (CMeT) domain, a terminal Claisen cyclase (CLC) domain, and an accompanying oxidative enzyme that dimerizes methylphloracetophenone to usnic acid. Of the 32 candidate PKS genes identified in the mycobiont genome, only one was identified as consistent with these biosynthetic requirements. This gene cluster contains two genes encoding a non-reducing PKS and a cytochrome p450, which have been respectively named methylphloracetophenone synthase (MPAS) and methylphloracetophenone oxidase (MPAO). Both mpas and mpao were demonstrated to be transcriptionally active by reverse transcriptase-PCR of the mRNA in a lichen sample that was observed by HPLC to produce usnic acid. Phylogenetic analysis of the bioinformatically identified ketosynthase (KS) and CLC domains of MPAS demonstrated that mpas grouped within a unique clade and that mpas could be used as a phylogenetic probe to identify other MPAS genes.

The chemoenzymatic synthesis of usnic acid

Usnic acid, a highly functionalized dibenzofuran, is a polyketide secondary metabolite produced by several species of lichens. Synthesis of usnic acid from commercially available starting material was accomplished in two steps. The synthesis involves the methylation of phloracetophenone followed by oxidation with horseradish peroxidase. This work will lay the foundation for further biosynthetic studies on usnic acid.

Absence of a catalytic water confers resistance to the neurotoxin gabaculine

Gabaculine is a potent inhibitor of the vitamin B6‐dependent key enzyme in chlorophyll biosynthesis, glutamate‐1‐semialdehyde aminomutase (GSAM). The inhibition effect is caused by an enzymatic deprotonation of the neurotoxin and requires the aldimine (PLP) form of the cofactor at the active site. In this study, we show that a single‐point mutation confers resistance to gabaculine. A combined functional and structural analysis of wild‐type GSAM in complex with gabaculine and the GSAMM248I form allowed us to decipher in atomic detail the molecular basis of this unique resistance. Interestingly, the gabaculine tolerance is caused by the absence of an essential water molecule that has a dual functional role. It serves as a nucleophilic shuttle for the hydroxyl anion along the reaction pathway and holds active‐site Lys273 in a catalytically competent conformation. The single‐point mutant is not able to fix this catalytic water between the β‐branched side chain of Ile248 and Lys273. As a consequence, the mutant enzyme is trapped in a gabaculine‐insensitive but still enzymatically active amine (PMP) form.—Orriss, G. L., Patel, T. R., Sorensen, J., Stetefeld, J. Absence of a catalytic water confers resistance to the neurotoxin gabaculine. FASEB J. 24, 404–414 (2010). www.fasebj.org

Effect of aposymbiotic conditions on colony growth and secondary metabolite production in the lichen-forming fungus Ramalina dilacerata.

The production of secondary metabolites by aposymbiotic lichen-forming fungi in culture is thought to be influenced by environmental conditions. The effects of the environment may be studied by culturing fungi under defined growing parameters to provide a better understanding of the role of the large number of polyketide synthase (PKS) gene paralogs detected in the genomes of many fungi. The objectives of this study were to examine the effects of culture conditions (media composition and pH level) on the colony growth, the numbers of secondary products, and the expression of two PKS genes by the lichen-forming fungus Ramalina dilacerata. Four types of growth media at four different pH levels were prepared to culture spore isolates of R. dilacerata. Colony diameter and texture were recorded. The number of secondary compounds were determined by thin layer chromatography (TLC) and high performance liquid chromatography (HPLC). Expression of two PKS genes (non-reducing (NR) and 6-MSAS-type PKS) were compared with expression of an internal control mitochondrial small subunit gene (mtSSU). The results showed that media containing yeast extracts produced the largest colony diameters and the fewest number of secondary metabolites. Colony growth rates also varied with different media conditions, and a significant negative relationship occurred between colony diameter and number of secondary metabolites. Expression of the NR PKS gene was significantly higher at pH 6.5 on the glucose malt agar than any other media, and expression of the 6-MSAS-type (partially-reducing) PKS gene was significantly higher at pH 8.5 on (malt agar) malt agar than on the other types of agar. Gene expression was correlated with the pH level and media conditions that induced the production of the larger number of secondary substances. This is the first study to examine secondary metabolite production in R. dilacerata by comparing the number of polyketides detected with quantitative polymerase chain reaction (qPCR) of two PKS genes under different culture conditions.

The isolation of citric acid derivatives from Aspergillus niger

A strain of Aspergillus niger was cultured from a soil sample collected from Five Islands Provincial Park, Nova Scotia, Canada. Extraction of fermentation cultures revealed the production of significant levels of dimethyl citrate (1) and trimethyl citrate (2), as well as a small amount of dimethyl oxalate (3). This appears to be the first report of the production of methylated citric acid derivatives in a filamentous fungus.

Lichen Biosynthetic Gene Clusters. Part I. Genome Sequencing Reveals a Rich Biosynthetic Potential

Lichens are symbionts of fungi and algae that produce diverse secondary metabolites with useful properties. Little is known of lichen natural product biosynthesis because of the challenges of working with lichenizing fungi. We describe the first attempt to comprehensively profile the genetic secondary metabolome of a lichenizing fungus. An Illumina platform combined with the Antibiotics and Secondary Metabolites Analysis Shell (FungiSMASH, version 4.0) was used to sequence and annotate assembled contigs of the fungal partner of Cladonia uncialis. Up to 48 putative gene clusters are described comprising type I and type III polyketide synthases (PKS), nonribosomal peptide synthetases (NRPS), hybrid PKS-NRPS, and terpene synthases. The number of gene clusters revealed by this work dwarfs the number of known secondary metabolites from C. uncialis, suggesting that lichenizing fungi have an unexplored biosynthetic potential.

Lichen Biosynthetic Gene Clusters Part II: Homology Mapping Suggests a Functional Diversity

Lichens are renowned for their diverse natural products though little is known of the genetic programming dictating lichen natural product biosynthesis. We sequenced the genome of Cladonia uncialis and profiled its secondary metabolite biosynthetic gene clusters. Through a homology searching approach, we can now propose specific functions for gene products as well as the biosynthetic pathways that are encoded in several of these gene clusters. This analysis revealed that the lichen genome encodes the required enzymes for patulin and betaenones A-C biosynthesis, fungal toxins not known to be produced by lichens. Within several gene clusters, some (but not all) genes are genetically similar to genes devoted to secondary metabolite biosynthesis in Fungi. These lichen clusters also contain accessory tailoring genes without such genetic similarity, suggesting that the encoded tailoring enzymes perform distinct chemical transformations. We hypothesize that C. uncialis gene clusters have evolved by shuffling components of ancestral fungal clusters to create new series of chemical steps, leading to the production of hitherto undiscovered derivatives of fungal secondary metabolites.

Algal carbohydrates affect polyketide synthesis of the lichen-forming fungus Cladonia rangiferina

Lichen secondary metabolites (polyketides) are produced by the fungal partner, but the role of algal carbohydrates in polyketide biosynthesis is not clear. This study examined whether the type and concentration of algal carbohydrate explained differences in polyketide production and gene transcription by a lichen fungus (Cladonia rangiferina). The carbohydrates identified from a free-living cyanobacterium (Spirulina platensis; glucose), a lichen-forming alga (Diplosphaera chodatii; sorbitol) and the lichen alga that associates with C. rangiferina (Asterochloris sp.; ribitol) were used in each of 1%, 5% and 10% concentrations to enrich malt yeast extract media for culturing the mycobiont. Polyketides were determined by high performance liquid chromatography (HPLC), and polyketide synthase (PKS) gene transcription was measured by quantitative PCR of the ketosynthase domain of four PKS genes. The lower concentrations of carbohydrates induced the PKS gene expression where ribitol up-regulated CrPKS1 and CrPKS16 gene transcription and sorbitol up-regulated CrPKS3 and CrPKS7 gene transcription. The HPLC results revealed that lower concentrations of carbon sources increased polyketide production for three carbohydrates. One polyketide from the natural lichen thallus (fumarprotocetraric acid) also was produced by the fungal culture in ribitol supplemented media only. This study provides a better understanding of the role of the type and concentration of the carbon source in fungal polyketide biosynthesis in the lichen Cladonia rangiferina.

The attenuated virulence of a Burkholderia cenocepacia paaABCDE mutant is due to inhibition of quorum sensing by release of phenylacetic acid.

The phenylacetic acid degradation pathway of Burkholderia cenocepacia is active during cystic fibrosis‐like conditions and is necessary for full pathogenicity of B. cenocepacia in nematode and rat infection models; however, the reasons for such requirements are unknown. Here, we show that the attenuated virulence of a phenylacetic acid catabolism mutant is due to quorum sensing inhibition. Unlike wild‐type B. cenocepacia, a deletion mutant of the phenylacetyl‐CoA monooxygenase complex (ΔpaaABCDE) released phenylacetic acid in the medium that favours infection in Caenorhabditis elegans. Addition of phenylacetic acid further decreased the pathogenicity of the ΔpaaABCDE, which cannot metabolize phenylacetic acid, but did not affect the wild‐type, due to phenylacetic acid consumption. In line with reduced detection of acyl‐homoserine lactones in spent medium, the ΔpaaABCDE exhibited transcriptional inhibition of the quorum sensing system cepIR. Phenotypes repressed in ΔpaaABCDE, protease activity and pathogenicity against C. elegans, increased with exogenous N‐octanoyl‐L‐homoserine lactone. Thus, we demonstrate that the attenuated phenotype of B. cenocepacia ΔpaaABCDE is due to quorum sensing inhibition by release of phenylacetic acid, affecting N‐octanoyl‐L‐homoserine lactone signalling. Further, we propose that active degradation of phenylacetic acid by B. cenocepacia during growth in cystic fibrosis‐like conditions prevents accumulation of a quorum sensing inhibiting compound.

Kinemage of action - proposed reaction mechanism of glutamate-1-semialdehyde aminomutase at an atomic level.

Glutamate-1-semialdehyde aminomutase (GSAM), a key enzyme in tetrapyrrole cofactor biosynthesis, performs a unique transamination on a single substrate. The substrate, glutamate-1-semialdehyde (GSA), undergoes a reaction that exchanges the position of an amine and a carbonyl group to produce 5-aminolevulinic acid (ALA). This transamination reaction is unique in the fact that is does not require an external cofactor to act as a nitrogen donor or acceptor in this transamination reaction. One of the other remarkable features of the catalytic mechanism is the release free in the enzyme active site of the intermediate 4,5-diaminovaleric acid (DAVA). The action of a gating loop prevents the escape of DAVA from the active site. In a MD simulation approach, using snapshots provided by X-ray crystallography and protein crystal absorption spectrometry data, the individual catalytic steps in this unique intramolecular transamination have been elucidated.