Uwe Linne

Regeneration of misprimed nonribosomal peptide synthetases by type II thioesterases

Nonribosomal peptide synthetases (NRPSs) assemble structurally complex peptides from simple building blocks such as amino and carboxyl acids. Product release by macrocyclization or hydrolysis is catalyzed by a thioesterase domain that is an integrated part of the NRPS enzyme. A second thioesterase of type II (TEII) encoded by a distinct gene associated with the NRPS cluster was previously shown by means of gene disruption to be important for efficient product formation. However, the actual role of TEIIs in nonribosomal peptide synthesis remained obscure. Here we report the biochemical characterization of two such TEII enzymes that are associated with the synthetases of the peptide antibiotics surfactin (TEIIsrf) and bacitracin (TEIIbac). Both enzymes were shown to efficiently regenerate misacylated thiol groups of 4′-phosphopantetheine (4′PP) cofactors attached to the peptidyl carrier proteins (PCPs) of NRPSs. For TEIIsrf, a KM of 0.9 μM and a kcat of 95 min−1 was determined for acetyl-PCP hydrolysis. Both enzymes could also hydrolyze aminoacyl or peptidyl PCPs, intermediates of nonribosomal peptide synthesis. However, this reaction is unlikely to be of physiological relevance. Similar intermediates of the primary metabolism such as CoA derivatives and acetyl-acyl carrier proteins of fatty acid synthesis were also not significantly hydrolyzed, as investigated with TEIIsrf. These findings support a model in which the physiological role of TEIIs in nonribosomal peptide synthesis is the regeneration of misacylated NRPS, which result from the apo to holo conversion of NRPS enzymes because of the promiscuity of dedicated 4′PP transferases that use not only free CoA, but also acyl-CoAs as 4′PP donors.

Isolation and Structural Characterization of Capistruin, a Lasso Peptide Predicted from the Genome Sequence of Burkholderia thailandensis E264

Lasso peptides are a structurally unique class of bioactive peptides characterized by a knotted arrangement, where the C-terminus threads through an N-terminal macrolactam ring. Although ribosomally synthesized, only the gene cluster for the best studied lasso peptide MccJ25 from Escherichia coli consisting of the precursor protein McjA and the processing and immunity proteins McjB, McjC, and McjD is known. Through genome mining studies, we have identified homologues of all four proteins in Burkholderia thailandensis E264 and predicted this strain to produce a lasso peptide. Here we report the successful isolation of the predicted peptide, named capistruin. Upon optimization of the fermentation conditions, mass spectrometric and NMR structural studies proved capistruin to adopt a novel lasso fold. Heterologous production of the lasso peptide in Escherichia coli showed that the identified genes are sufficient for the biosynthesis of capistruin, which exhibits antimicrobial activity against closely related Burkholderia and Pseudomonas strains. In general, our rational approach should be widely applicable for the isolation of new lasso peptides to explore their high structural stability and diverse biological activity.

A biosynthetic gene cluster for a secreted cellobiose lipid with antifungal activity from Ustilago maydis

The phytopathogenic basidiomycetous fungus Ustilago maydis secretes large amounts of the glycolipid biosurfactant ustilagic acid (UA). UA consists of 15,16‐dihydroxypalmitic or 2,15,16‐trihydroxypalmitic acid, which is O‐glycosidically linked to cellobiose at its terminal hydroxyl group. In addition, the cellobiose moiety is acetylated and acylated with a short‐chain hydroxy fatty acid. We have identified a 58 kb spanning gene cluster that contains 12 open reading frames coding for most, if not all, enzymes needed for UA biosynthesis. Using a combination of genetic and mass spectrometric analysis we were able to assign functional roles to three of the proteins encoded by the gene cluster. This allowed us to propose a biosynthesis route for UA. The Ahd1 protein belongs to the family of non‐haem diiron reductases and is required for α‐hydroxylation of palmitic acid. Two P450 monooxygenases, Cyp1 and Cyp2, catalyse terminal and subterminal hydroxylation of palmitic acid. We could demonstrate that infection of tomato leaves by the plant pathogenic fungus Botrytis cinerea is prevented by co‐inoculation with wild‐type U. maydis sporidia. U. maydis mutants defective in UA biosynthesis were unable to inhibit B. cinerea infection indicating that UA secretion is critical for antagonistic activity.

The radical SAM enzyme AlbA catalyzes thioether bond formation in subtilosin A

Subtilosin A is a 35-residue, ribosomally synthesized bacteriocin encoded by the sbo-alb operon of Bacillus subtilis. It is composed of a head-to-tail circular peptide backbone that is additionally restrained by three unusual thioether bonds between three cysteines and the α-carbon of one threonine and two phenylalanines, respectively. In this study, we demonstrate that these bonds are synthesized by the radical S-adenosylmethionine enzyme AlbA, which is encoded by the sbo-alb operon and comprises two [4Fe-4S] clusters. One [4Fe-4S] cluster is coordinated by the prototypical CXXXCXXC motif and is responsible for the observed S-adenosylmethionine cleavage reaction, whereas the second [4Fe-4S] cluster is required for the generation of all three thioether linkages. On the basis of the obtained results, we propose a new radical mechanism for thioether bond formation. In addition, we show that AlbA-directed substrate transformation is leader-peptide dependent, suggesting that thioether bond formation is the first step during subtilosin A maturation.

Physical-chemical plant-derived signals induce differentiation in Ustilago maydis.

Ustilago maydis is able to initiate pathogenic development after fusion of two haploid cells with different mating type. On the maize leaf surface, the resulting dikaryon switches to filamentous growth, differentiates appressoria and penetrates the host. Here, we report on the plant signals required for filament formation and appressorium development in U. maydis. In vitro, hydroxy‐fatty acids stimulate filament formation via the induction of pheromone genes and this signal can be bypassed by genetically activating the downstream MAP kinase module. Hydrophobicity also induces filaments and these resemble the dikaryotic filaments formed on the plant surface. With the help of a marker gene that is specifically expressed in the tip cell of those hyphae that have formed an appressorium, hydrophobicity is shown to be essential for appressorium development in vitro. Hydroxy‐fatty acids or a cutin monomer mixture isolated from maize leaves have a stimulatory role when a hydrophobic surface is provided. Our results suggest that the early phase of communication between U. maydis and its host plant is governed by two different stimuli.

Identification of a Gene Cluster for Biosynthesis of Mannosylerythritol Lipids in the Basidiomycetous Fungus Ustilago maydis

ABSTRACT Many microorganisms produce surface-active substances that enhance the availability of water-insoluble substrates. Although many of these biosurfactants have interesting potential applications, very little is known about their biosynthesis. The basidiomycetous fungus Ustilago maydis secretes large amounts of mannosylerythritol lipids (MELs) under conditions of nitrogen starvation. We recently described a putative glycosyltransferase, Emt1, which is essential for MEL biosynthesis and whose expression is strongly induced by nitrogen limitation. We used DNA microarray analysis to identify additional genes involved in MEL biosynthesis. Here we show that emt1 is part of a gene cluster which comprises five open reading frames. Three of the newly identified proteins, Mac1, Mac2, and Mat1, contain short sequence motifs characteristic for acyl- and acetyltransferases. Mutational analysis revealed that Mac1 and Mac2 are essential for MEL production, which suggests that they are involved in the acylation of mannosylerythritol. Deletion of mat1 resulted in the secretion of completely deacetylated MELs, as determined by mass spectrometry. We overexpressed Mat1 in Escherichia coli and demonstrated that this enzyme acts as an acetyl coenzyme A-dependent acetyltransferase. Remarkably, Mat1 displays relaxed regioselectivity and is able to acetylate mannosylerythritol at both the C-4 and C-6 hydroxyl groups. Based on these results, we propose a biosynthesis pathway for the generation of mannosylerythritol lipids in U. maydis.

Bacterial translation elongation factor EF-Tu interacts and colocalizes with actin-like MreB protein

We show that translation initiation factor EF-Tu plays a second important role in cell shape maintenance in the bacterium Bacillus subtilis. EF-Tu localizes in a helical pattern underneath the cell membrane and colocalizes with MreB, an actin-like cytoskeletal element setting up rod cell shape. The localization of MreB and of EF-Tu is interdependent, but in contrast to the dynamic MreB filaments, EF-Tu structures are more static and may serve as tracks for MreB filaments. In agreement with this idea, EF-Tu and MreB interact in vivo and in vitro. Lowering of the EF-Tu levels had a minor effect on translation but a strong effect on cell shape and on the localization of MreB, and blocking of the function of EF-Tu in translation did not interfere with the localization of MreB, showing that, directly or indirectly, EF-Tu affects the cytoskeletal MreB structure and thus serves two important functions in a bacterium.

Ferri-bacillibactin uptake and hydrolysis in Bacillus subtilis.

Upon iron limitation, Bacillus subtilis secretes the catecholic trilactone (2,3‐dihydroxybenzoate‐glycine‐threonine)3 siderophore bacillibactin (BB) for ferric iron scavenging. Here, we show that ferri‐BB uptake is mediated by the FeuABC transporter and that YuiI, a novel trilactone hydrolase, catalyses ferri‐BB hydrolysis leading to cytosolic iron release. Among several Fur‐regulated ABC transport mutants, only ΔfeuABC exhibited impaired growth during iron starvation. Quantification of intra‐ and extracellular (ferri)‐BB in iron‐depleted ΔfeuABC cultures revealed a fourfold increase of the extracellular siderophore concentration, confirming a blocked ferri‐BB uptake in the absence of FeuABC. Ferri‐BB was found to bind selectively to the periplasmic binding protein FeuA (Kd = 57 ± 1 nM), proving high‐affinity transport of the iron‐charged siderophore. During iron starvation, a ΔyuiI mutant displayed impaired growth and strong intracellular (30‐fold) and extracellular (6.5‐fold) (ferri)‐BB accumulation. Kinetic studies in vitro revealed that YuiI hydrolyses both BB and ferri‐BB. While BB hydrolysis led to strong accumulation of the tri‐ and dimeric reaction intermediates, ferri‐BB hydrolysis yielded exclusively the monomeric reaction product and occurred with a 25‐fold higher catalytic efficiency than BB single hydrolysis. Thus, ferri‐BB was the preferred substrate of the YuiI esterase whose gene locus was designated besA.

Insights into the Biosynthesis and Stability of the Lasso Peptide Capistruin

Capistruin is a 19-residue ribosomally synthesized lasso peptide encoded by the capABCD gene cluster in Burkholderia thailandensis. It is composed of an N-terminal 9-residue macrolactam ring, through which the 10-residue C-terminal tail is threaded. Using a heterologous capistruin production system in Escherichia coli, we have generated 48 mutants of the precursor protein CapA to gain insights into capistruin biosynthesis. Only 4 residues (Gly1, Arg11, Val12, and Ile13) of the lasso sequence were found to be critical for maturation. Tandem mass spectrometric fragmentation studies of capistruin F16A/F18A proved Arg15 to be responsible for the trapping of the C-terminal tail. Substituting Arg15 and Phe16 by alanine revealed a temperature-sensitive capistruin derivative, which unfolds into a branched cyclic peptide upon heating. In conclusion, our global mutagenic approach revealed a low overall specificity of the biosynthetic machinery and important structure-stability correlations.

The Linear Pentadecapeptide Gramicidin Is Assembled by Four Multimodular Nonribosomal Peptide Synthetases That Comprise 16 Modules with 56 Catalytic Domains

Linear gramicidin is a membrane channel forming pentadecapeptide that is produced via the nonribosomal pathway. It consists of 15 hydrophobic amino acids with alternating l- and d-configuration forming a β-helix-like structure. It has an N-formylated valine and a C-terminal ethanolamine. Here we report cloning and sequencing of the entire biosynthetic gene cluster as well as initial biochemical analysis of a new reductase domain. The biosynthetic gene cluster was identified on two nonoverlapping fosmids and a 13-kilobase pair (kbp) interbridge fragment covering a region of 74 kbp. Four very large open reading frames, lgrA, lgrB, lgrC, and lgrD with 6.8, 15.5, 23.3, and 15.3 kbp, were identified and shown to encode nonribosomal peptide synthetases with two, four, six, and four modules, respectively. Within the 16 modules identified, seven epimerization domains in alternating positions were detected as well as a putative formylation domain fused to the first module LgrA and a putative reductase domain attached to the C-terminal module of LgrD. Analysis of the substrate specificity by phylogenetic studies using the residues of the substrate-binding pockets of all 16 adenylation domains revealed a good agreement of the substrate amino acids predicted with the sequence of linear gramicidin. Additional biochemical analysis of the three adenylation domains of modules 1, 2, and 3 confirmed the colinearity of this nonribosomal peptide synthetase assembly line. Module 16 was predicted to activate glycine, which would then, being the C-terminal residue of the peptide chain, be reduced by the adjacent reductase domain to give ethanolamine, thereby releasing the final product N-formyl-pentadecapeptide-ethanolamine. However, initial biochemical analysis of this reductase showed only a one-step reduction yielding the corresponding aldehyde in vitro.