Project description:We studied the influence of copper in physiological and morphological differentiation of Streptomyces coelicolor. We demonstrate differences in phenotype (germination, growth rate, antibiotic production) and genetic expression between a strain mutated at copper chaperone CopZ (SCO2730::Tn5062), the wild-type strain and a wild-type strain sporulated in a media with 80µM CuSO4. These differences are correlated with the cytosolic copper. Our results demonstrate a pleiotropic effect of copper modulating S. coelicolor development.

Project description:Cytosolic copper concentration modulates spore germination and secondary metabolism in Streptomyces coelicolor

Project description:BackgroundStreptomyces species produce a vast diversity of secondary metabolites of clinical and biotechnological importance, in particular antibiotics. Recent developments in metabolic engineering, synthetic and systems biology have opened new opportunities to exploit Streptomyces secondary metabolism, but achieving industry-level production without time-consuming optimization has remained challenging. Genome-scale metabolic modelling has been shown to be a powerful tool to guide metabolic engineering strategies for accelerated strain optimization, and several generations of models of Streptomyces metabolism have been developed for this purpose.ResultsHere, we present the most recent update of a genome-scale stoichiometric constraint-based model of the metabolism of Streptomyces coelicolor, the major model organism for the production of antibiotics in the genus. We show that the updated model enables better metabolic flux and biomass predictions and facilitates the integrative analysis of multi-omics data such as transcriptomics, proteomics and metabolomics.ConclusionsThe updated model presented here provides an enhanced basis for the next generation of metabolic engineering attempts in Streptomyces.

Project description:Streptomyces species produce many clinically important secondary metabolites, including antibiotics and antitumorals. They have a complex developmental cycle, including programmed cell death phenomena, that makes this bacterium a multicellular prokaryotic model. There are two differentiated mycelial stages: an early compartmentalized vegetative mycelium (first mycelium) and a multinucleated reproductive mycelium (second mycelium) arising after programmed cell death processes. In the present study, we made a detailed proteomics analysis of the distinct developmental stages of solid confluent Streptomyces coelicolor cultures using iTRAQ (isobaric tags for relative and absolute quantitation) labeling and LC-MS/MS. A new experimental approach was developed to obtain homogeneous samples at each developmental stage (temporal protein analysis) and also to obtain membrane and cytosolic protein fractions (spatial protein analysis). A total of 345 proteins were quantified in two biological replicates. Comparative bioinformatics analyses revealed the switch from primary to secondary metabolism between the initial compartmentalized mycelium and the multinucleated hyphae.

Project description:Transcriptome time-courses during the S. coelicolor germination were used to reveal processes that underlie the gene expression at the transcriptional level within transition from dormancy to vegetative growth.

Project description:BackgroundBacterial two-component signal transduction regulatory systems are the major set of signalling proteins frequently mediating responses to changes in the environment. They typically consist of a sensor, a membrane-associated histidine kinase and a cytoplasmic response regulator. The membrane-associated sensor detects the environmental signal or stress, whereas the cytoplasmic regulatory protein controls the cellular response usually by gene transcription modulation. METHODOLOGY/PRINCIPALFINDINGS: The Streptomyces coelicolor two genes operon SCO5784-SCO5785 encodes a two-component system, where SCO5784 encodes a histidine-kinase sensor and SCO5785 encodes a response regulator protein. When the expression level of the regulator gene decreases, the antibiotic synthesis and sporulation is delayed temporarily in addition to some ribosomal genes became up regulated, whereas the propagation of the regulatory gene in high copy number results in the earlier synthesis of antibiotics and sporulation, as well as the down regulation of some ribosomal genes and, moreover, in the overproduction of several extracellular proteins. Therefore, this two-component system in S. coelicolor seems to influence various processes characterised by the transition from primary to secondary metabolism, as determined by proteomic and transcriptomic analyses.Conclusions/significancePropagation of SCO5785 in multicopy enhances the production of antibiotics as well as secretory proteins. In particular, the increase in the expression level of secretory protein encoding genes, either as an artefactual or real effect of the regulator, could be of potential usefulness when using Streptomyces strains as hosts for homologous or heterologous extracellular protein production.

Project description:We report here the physiological and genetic characterization of an orphan histidine kinase (HK) (OhkA, SCO1596) in Streptomyces coelicolor and its homolog (OhkAsav, SAV_6741) in Streptomyces avermitilis. The physiological analysis showed that the ohkA mutant of S. coelicolor exhibits impaired aerial mycelium formation and sporulation and overproduction of multiple antibiotics on mannitol-soy flour (MS) medium, especially actinorhodin (ACT) and calcium-dependent antibiotic (CDA), and disruption of ohkAsav in S. avermitilis also led to the similar phenotypes of impaired morphological differentiation and significantly increased oligomycin A production. DNA microarray analysis combined with real-time reverse transcription-PCR (RT-PCR) and RNA dot blot assay in the S. coelicolor ohkA deletion mutant confirmed the physiological results by showing the upregulation of genes involved in the biosynthesis of ACT, CDA, undecylprodigiosin (RED), a yellow type I polyketide (CPK, SCO6273-6289), and a sesquiterpene antibiotic, albaflavenone (SCO5222-5223). The results also suggested that the increased production of ACT and RED in the mutant could be partly ascribed to the enhanced precursor malonyl coenzyme A (malonyl-CoA) supply through increased transcription of genes encoding acetyl-CoA carboxylase (ACCase). Interestingly, DNA microarray analysis also showed that deletion of ohkA greatly downregulated the transcription of chpABCDEFGH genes essential for aerial mycelium formation by S. coelicolor on MS medium but significantly increased transcription of ramS/C/R, which is responsible for SapB formation and regulation and is normally absent on MS medium. Moreover, many other genes involved in development, such as bldM/N, whiG/H/I, ssgA/B/E/G/R, and whiE, were also significantly downregulated upon ohkA deletion. The results clearly demonstrated that OhkA is an important global regulator for both morphological differentiation and secondary metabolism in S. coelicolor and S. avermitilis.

Project description:Extracytoplasmic function (ECF) sigma factors are a major type of bacterial signal transducer whose biological functions remain poorly characterised in streptomycetes. In this work, we studied SCO4117, a conserved ECF sigma factor from the ECF52 family, a class of ECF sigma factors exclusive to Actinobacteria. We demonstrate that SCO4117 is a pleiotropic activator of secondary metabolism, germination, aerial mycelium differentiation and sporulation. The expression of genes encoding secondary metabolism pathways (deoxysugar synthases, actinorhodin biosynthetic genes), and genes involved in differentiation (bld, whi, rdl, chp, nepA, ssgB, scbR), was dramatically reduced (up to 300-fold) in a SCO4117 knockout strain. SCO4117 expression depends on its position in the chromosome, as the knockout mutant phenotype can only be fully complemented when the SCO4117 ORF is restored in the chromosome. A strain expressing a truncated version of SCO4117 harbouring only the ECF sigma factor domain, has an opposite phenotype to that observed in the knockout strain, consisting of overproduction of antibiotics (actinorhodin, CDA, cryptic antibiotics) and acceleration of differentiation (aerial mycelium differentiation and sporulation), suggesting a complex interaction between the SCO4117 domains that affects protein activity. Some genes from predicted secondary metabolite clusters (cryptic pathways) were up-regulated compared to the wild strain, indicating that this truncated version of the SCO4117 protein might be useful to activate cryptic pathways. Overall, in this work we demonstrate the pleiotropic effects on the regulation of secondary metabolism and differentiation of SCO4117, the first member of the ECF52 family to be characterised. SCO4117 is a conserved gene overexpressed during the substrate and aerial mycelium stages, showing complex regulation at the transcriptional and post-translational levels.

Project description:Extracytoplasmic function (ECF) sigma factors are a major type of bacterial signal-transducers whose biological functions remain poorly characterized in streptomycetes. In this work we studied SCO4117, a conserved ECF sigma factor from the ECF52 family overexpressed during substrate and aerial mycelium stages. The ECF52 sigma factors harbor, in addition to the ECF sigma factor domain, a zinc finger domain, a transmembrane region, a proline-rich C-terminal extension, and a carbohydrate-binding domain. This class of ECF sigma factors is exclusive to Actinobacteria. We demonstrate that SCO4117 is an activator of secondary metabolism, aerial mycelium differentiation, and sporulation, in all the culture media (sucrose-free R5A, GYM, MM, and SFM) analyzed. Aerial mycelium formation and sporulation are delayed in a SCO4117 knockout strain. Actinorhodin production is delayed and calcium-dependent antibiotic production is diminished, in the ΔSCO4117 mutant. By contast, undecylprodigiosin production do not show significant variations. The expression of genes encoding secondary metabolism pathways (deoxysugar synthases, actinorhodin biosynthetic genes) and genes involved in differentiation (rdl, chp, nepA, ssgB) was dramatically reduced (up to 300-fold) in the SCO4117 knockout. A putative motif bound, with the consensus "CSGYN-17bps-SRHA" sequence, was identified in the promoter region of 29 genes showing affected transcription in the SCO4117 mutant, including one of the SCO4117 promoters. SCO4117 is a conserved gene with complex regulation at the transcriptional and post-translational levels and the first member of the ECF52 family characterized.

Project description:Peptidoglycan is a major cell wall constituent of gram-positive bacteria. It is a dynamic macromolecule that is actively remodeled to enable cell growth and differentiation through a tightly choreographed interplay of hydrolytic and biosynthetic enzyme activities. The filamentous bacterium Streptomyces coelicolor has a complex life cycle that likely requires considerable cell wall remodeling to enable both extension of vegetative hyphae and formation of differentiated cell types. In silico analysis of the S. coelicolor genome enabled identification of 56 candidate cell wall hydrolase genes. We found that seven of these genes shared a highly conserved 5' untranslated region and were expressed during both vegetative growth and sporulation; four of these genes were selected for more extensive biochemical and biological characterization. The proteins encoded by these genes, termed RpfA, SwlA, SwlB, and SwlC, were confirmed to be hydrolytic enzymes, as they could efficiently cleave S. coelicolor cell walls. Phenotypic analyses revealed that these enzymes are important throughout development; deletion of each hydrolase gene resulted in a mutant strain that was heat sensitive, defective in spore formation, and either altered in vegetative growth or delayed in spore germination. Our results indicate that these enzymes play key roles at multiple stages in the growth and development of S. coelicolor, highlighting both the lack of redundancy in hydrolase activity and the importance of cell wall remodeling in the S. coelicolor life cycle.