Project description:On the example of the biosynthetically exhausted landomycin A cluster we demonstrate unbalancing of gene transcription as an efficient method for the generation of new compounds. Decoupled from the native regulators LanI and LanK, all landomycin A structural genes were set under the control of a single synthetic promoter and expressed in a heterologous host Streptomyces albus J1074. Previously being both temporarily and quantitatively regulated, these genes were transcribed as a single polycistronic mRNA leading to the production of four novel and two known compounds. No glycosylated landomycins were detected though the entire biosynthetic cluster was transcribed, showing the crucial role of the balanced gene expression for the production of landomycin A. Two new compounds, fridamycin F and G, isolated in this study were shown to originate from the interplay between the expressed biosynthetic pathway and metabolic network of the heterologous host. Structure activity studies of the isolated compounds as well as results of transcriptome sequencing are discussed in this article. Comparison of gene expression of the H2-26 cosmid (encoding landomycin A biosynthetic genes) with H2-26-act, where an additional constitutive promoter cassette was integrated to drive biosynthetic genes transcription.

Project description:Biosynthetic Gene Cluster Encoding X-14952B from Streptomyces sp.135

Project description:On the example of the biosynthetically exhausted landomycin A cluster we demonstrate unbalancing of gene transcription as an efficient method for the generation of new compounds. Decoupled from the native regulators LanI and LanK, all landomycin A structural genes were set under the control of a single synthetic promoter and expressed in a heterologous host Streptomyces albus J1074. Previously being both temporarily and quantitatively regulated, these genes were transcribed as a single polycistronic mRNA leading to the production of four novel and two known compounds. No glycosylated landomycins were detected though the entire biosynthetic cluster was transcribed, showing the crucial role of the balanced gene expression for the production of landomycin A. Two new compounds, fridamycin F and G, isolated in this study were shown to originate from the interplay between the expressed biosynthetic pathway and metabolic network of the heterologous host. Structure activity studies of the isolated compounds as well as results of transcriptome sequencing are discussed in this article.

Project description:Actinopyrone biosynthetic gene cluster

Project description:L-alanosine biosynthetic gene cluster

Project description:Biosynthetic gene clusters (BGCs) encoding the production of bacteriocins are widespread amongst bacterial isolates and are important genetic determinants of competitive fitness. Staphylococci produce a tremendous diversity of compounds and the corresponding gene clusters (Staphylococcal Antibiosis Islands - SAbIs) are frequently associated with mobile genetic elements, suggesting acquisition and loss of biosynthetic capacity. Pharmaceutical biology has shown that transfer of BGCs between bacterial species is frequently challenging and production by the heterologous hosts often depends on optimal precursor supplies. It is unknown if transfer of SAbIs has similar effects. We modelled SAbItransfer between closely related S. aureus strains based on the SAbI encoding the ribosomally synthesized and post-translationally modified peptide (RiPP) Micrococcin P1 (MP1). Our results indicate that acquisition of SAbIs can represent a mixed blessing for the recipient strain and its genetic and metabolic predispositions are of crucial importance to integrate bacteriocin production into the cellular metabolism.

Project description:Streptomyces has the largest repertoire of natural product biosynthetic gene clusters (BGCs), yet developing a universal engineering strategy for each Streptomyces species is challenging. Given that some Streptomyces species have larger BGC repertoires than others, we hypothesized that a set of genes co-evolved with BGCs to support biosynthetic proficiency must exist in those strains, and that their identification may provide universal strategies to improve the productivity of other strains. We show here that genes co-evolved with natural product BGCs in Streptomyces can be identified by phylogenomics analysis. Among the 597 genes that co-evolved with polyketide BGCs, 11 genes in the “coenzyme” category have been examined, including a gene cluster encoding for the co-factor pyrroloquinoline quinone (PQQ). When the pqq gene cluster was engineered into 11 Streptomyces strains, it enhanced production of 16,385 metabolites, including 36 known natural products with up to 40-fold improvement and several activated silent gene clusters. This study provides a new engineering strategy for improving polyketide production and discovering new biosynthetic gene clusters.

Project description:In response to biotic stress, plants produce suites of highly modified fatty acids that bear unusual chemical functionalities. Despite their chemical complexity and proposed roles in pathogen defense, little is known about the biosynthesis of decorated fatty acids in plants. Falcarindiol is a prototypical acetylenic lipid present in carrot, tomato, and celery that inhibits growth of fungi and human cancer cell lines. Using a combination of untargeted metabolomics and RNA sequencing, we discovered a biosynthetic gene cluster in tomato (Solanum lycopersicum) required for falcarindiol production. By reconstituting initial biosynthetic steps in a heterologous host and generating transgenic pathway mutants in tomato, we demonstrate a direct role of the cluster in falcarindiol biosynthesis and resistance to fungal and bacterial pathogens in tomato leaves. This work reveals a mechanism by which plants sculpt their lipid pool in response to pathogens and provides critical insight into the complex biochemistry of alkynyl lipid production.

Project description:A previously reported gene cluster encoding four nisin-like peptides, three with the same sequence (NsoA1-3) and the unique NsoA4, produced antimicrobial activity in the presence of trypsin after heterologous expression in Lactococcus lactis. Protein extracts were prepared by SDS gel electrophoresis or immunoprecipitation using an antibody to the NsoA2 leader. The tryptic peptides observed by LC-MS/MS covered the complete sequence of preNsoA1-3 and part of the leader sequence of preNsoA4 and confirmed the expression and the predicted sequences of the preNsoA peptides. Further, the data revealed that the preNsoA1-3 peptides were partly modified with dehydrations and formation of lanthionine rings. A certain amount of fully modified preNsoA1-3 was observed. Details of modifications of the core peptide and the C-terminal tryptic peptide TATCGCHITGK covering rings D and E indicated that 22% of these preNsoA1-3 peptides were completely modified. A lower amount is estimated for rings A-C. Intact masses of immunoprecipitation derived peptides determined by LC-MS accurately matched the expected preNsoA precursor peptides. The most abundant peptides detected were preNsoA2-3-8H2O followed by preNsoA1-8H2O and other states of dehydration. The results indicate that processing occurs but is incomplete for preNsoA peptides in the heterologous system with the formation of a certain amount of fully modified and active peptides.

Project description:Heterologous gene expression to expand the native genetic capability of E. coli is the backbone of protein expression and metabolic engineering. The goal of this study was to determine how the identity of the heterologous gene expressed affected the host cell transcriptome. We generated a library of E. coli expressing 46 heterologous genes through an identical rhamnose inducible expression system and perform high throughput RNAseq as well as independent component analysis to elucidate the major variances in the transcriptome. We find that the major variations during heterologous gene expression can be divided into 5 main cellular responses: Fear vs greed, metal homeostasis, respiration, protein folding and amino acid and nucleotide metabolism.