Nelson L. Brock scite author profile

Species of the Fusarium fujikuroi species complex (FFC) cause a wide spectrum of often devastating diseases on diverse agricultural crops, including coffee, fig, mango, maize, rice, and sugarcane. Although species within the FFC are difficult to distinguish by morphology, and their genes often share 90% sequence similarity, they can differ in host plant specificity and life style. FFC species can also produce structurally diverse secondary metabolites (SMs), including the mycotoxins fumonisins, fusarins, fusaric acid, and beauvericin, and the phytohormones gibberellins, auxins, and cytokinins. The spectrum of SMs produced can differ among closely related species, suggesting that SMs might be determinants of host specificity. To date, genomes of only a limited number of FFC species have been sequenced. Here, we provide draft genome sequences of three more members of the FFC: a single isolate of F. mangiferae, the cause of mango malformation, and two isolates of F. proliferatum, one a pathogen of maize and the other an orchid endophyte. We compared these genomes to publicly available genome sequences of three other FFC species. The comparisons revealed species-specific and isolate-specific differences in the composition and expression (in vitro and in planta) of genes involved in SM production including those for phytohormome biosynthesis. Such differences have the potential to impact host specificity and, as in the case of F. proliferatum, the pathogenic versus endophytic life style.

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Biosynthesis of the antibiotic tropodithietic acid by the marine bacterium Phaeobacter inhibens

Brock¹,

Nikolay²,

Dickschat³

2014

Chem. Commun.

122

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Pathways and Substrate Specificity of DMSP Catabolism in Marine Bacteria of the Roseobacter Clade

2010

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The volatiles released by Phaeobacter gallaeciensis, Oceanibulbus indolifex and Dinoroseobacter shibae have been investigated by GC-MS, and several MeSH-derived sulfur volatiles have been identified. An important sulfur source in the oceans is the algal metabolite dimethylsulfoniopropionate (DMSP). Labelled [2H6]DMSP was fed to the bacteria to investigate the production of volatiles from this compound through the lysis pathway to [2H6]dimethylsulfide or the demethylation pathway to [2H3]-3-(methylmercapto)propionic acid and lysis to [2H3]MeSH. [2H6]DMSP was efficiently converted to [2H3]MeSH by all three species. Several DMSP derivatives were synthesised and used in feeding experiments. Strong dealkylation activity was observed for the methylated ethyl methyl sulfoniopropionate and dimethylseleniopropionate, as indicated by the formation of EtSH- and MeSeH-derived volatiles, whereas no volatiles were formed from dimethyltelluriopropionate. In contrast, the dealkylation activity for diethylsulfoniopropionate was strongly reduced, resulting in only small amounts of EtSH-derived volatiles accompanied by diethyl sulfide in P. gallaeciensis and O. indolifex, while D. shibae produced the related oxidation product diethyl sulfone. The formation of diethyl sulfide and diethyl sulfone requires the lysis pathway, which is not active for [2H6]DMSP. These observations can be explained by a shifted distribution between the two competing pathways due to a blocked dealkylation of ethylated substrates.

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A Detailed View of 2‐Methylisoborneol Biosynthesis

et al. 2013

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Odor of earth: Several homomonoterpenes were identified in actinomycetes that produce 2‐methylisoborneol (2‐MIB, see scheme, which is responsible for an earthy odor in drinking water). Their occurrence clarifies the 2‐MIB pathway, because they are derived from cationic intermediates that are otherwise difficult to detect. A highly sensitive method using feeding experiments with 13C‐labeled precursors gives detailed insights into 2‐MIB biosynthesis.

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Genetic Analysis of the Upper Phenylacetate Catabolic Pathway in the Production of Tropodithietic Acid by Phaeobacter gallaeciensis

Berger

Brock

Liesegang

et al. 2012

Appl Environ Microbiol

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ABSTRACTProduction of the antibiotic tropodithietic acid (TDA) depends on the central phenylacetate catabolic pathway, specifically on the oxygenase PaaABCDE, which catalyzes epoxidation of phenylacetyl-coenzyme A (CoA). Our study was focused on genes of the upper part of this pathway leading to phenylacetyl-CoA as precursor for TDA.Phaeobacter gallaeciensisDSM 17395 encodes two genes with homology to phenylacetyl-CoA ligases (paaK1andpaaK2), which were shown to be essential for phenylacetate catabolism but not for TDA biosynthesis and phenylalanine degradation. Thus, inP. gallaeciensisanother enzyme must produce phenylacetyl-CoA from phenylalanine. Using random transposon insertion mutagenesis of apaaK1-paaK2double mutant we identified a gene (ior1) with similarity toiorAandiorBin archaea, encoding an indolepyruvate:ferredoxin oxidoreductase (IOR). Theior1mutant was unable to grow on phenylalanine, and production of TDA was significantly reduced compared to the wild-type level (60%). Nuclear magnetic resonance (NMR) spectroscopic investigations using13C-labeled phenylalanine isotopomers demonstrated that phenylalanine is transformed into phenylacetyl-CoA by Ior1. Using quantitative real-time PCR, we could show that expression ofior1depends on the adjacent regulator IorR. Growth on phenylalanine promotes production of TDA, induces expression ofior1(27-fold) andpaaK1(61-fold), and regulates the production of TDA. Phylogenetic analysis showed that the aerobic type of IOR as found in many roseobacters is common within a number of different phylogenetic groups of aerobic bacteria such asBurkholderia,Cupriavidis, andRhizobia, where it may also contribute to the degradation of phenylalanine.

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Nelson L. Brock

Comparative “Omics” of theFusarium fujikuroiSpecies Complex Highlights Differences in Genetic Potential and Metabolite Synthesis

Biosynthesis of the antibiotic tropodithietic acid by the marine bacterium Phaeobacter inhibens

Pathways and Substrate Specificity of DMSP Catabolism in Marine Bacteria of the Roseobacter Clade

A Detailed View of 2‐Methylisoborneol Biosynthesis

Genetic Analysis of the Upper Phenylacetate Catabolic Pathway in the Production of Tropodithietic Acid by Phaeobacter gallaeciensis

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