A New Family of Transcriptional Regulators Activating Biosynthetic Gene Clusters for Secondary Metabolites.

We previously identified the aur1 biosynthetic gene cluster (BGC) in Streptomyceslavendulae subsp. lavendulae CCM 3239 (formerly Streptomycesaureofaciens CCM 3239), which is responsible for the production of the unusual angucycline-like antibiotic auricin. Auricin is produced in a narrow interval of the growth phase after entering the stationary phase, after which it is degraded due to its instability at the high pH values reached after the production phase. The complex regulation of auricin BGC is responsible for this specific production by several regulators, including the key activator Aur1P, which belongs to the family of atypical response regulators. The aur1P gene forms an operon with the downstream aur1O gene, which encodes an unknown protein without any conserved domain. Homologous aur1O genes have been found in several BGCs, which are mainly responsible for the production of angucycline antibiotics. Deletion of the aur1O gene led to a dramatic reduction in auricin production. Transcription from the previously characterized Aur1P-dependent biosynthetic aur1Ap promoter was similarly reduced in the S. lavendulaeaur1O mutant strain. The aur1O-specific coactivation of the aur1Ap promoter was demonstrated in a heterologous system using a luciferase reporter gene. In addition, the interaction between Aur1O and Aur1P has been demonstrated by a bacterial two-hybrid system. These results suggest that Aur1O is a specific coactivator of this key auricin-specific positive regulator Aur1P. Bioinformatics analysis of Aur1O and its homologues in other BGCs revealed that they represent a new family of transcriptional coactivators involved in the regulation of secondary metabolite biosynthesis. However, they are divided into two distinct sequence-specific subclasses, each of which is likely to interact with a different family of positive regulators.

Activation and Identification of a Griseusin Cluster in Streptomyces sp. CA-256286 by Employing Transcriptional Regulators and Multi-Omics Methods.

Streptomyces are well-known producers of a range of different secondary metabolites, including antibiotics and other bioactive compounds. Recently, it has been demonstrated that "silent" biosynthetic gene clusters (BGCs) can be activated by heterologously expressing transcriptional regulators from other BGCs. Here, we have activated a silent BGC in Streptomyces sp. CA-256286 by overexpression of a set of SARP family transcriptional regulators. The structure of the produced compound was elucidated by NMR and found to be an N-acetyl cysteine adduct of the pyranonaphtoquinone polyketide 3'-O-α-d-forosaminyl-(+)-griseusin A. Employing a combination of multi-omics and metabolic engineering techniques, we identified the responsible BGC. These methods include genome mining, proteomics and transcriptomics analyses, in combination with CRISPR induced gene inactivations and expression of the BGC in a heterologous host strain. This work demonstrates an easy-to-implement workflow of how silent BGCs can be activated, followed by the identification and characterization of the produced compound, the responsible BGC, and hints of its biosynthetic pathway.

A Regulator Based "Semi-Targeted" Approach to Activate Silent Biosynthetic Gene Clusters.

By culturing microorganisms under standard laboratory conditions, most biosynthetic gene clusters (BGCs) are not expressed, and thus, the products are not produced. To explore this biosynthetic potential, we developed a novel "semi-targeted" approach focusing on activating "silent" BGCs by concurrently introducing a group of regulator genes into streptomycetes of the Tübingen strain collection. We constructed integrative plasmids containing two classes of regulatory genes under the control of the constitutive promoter ermE*p (cluster situated regulators (CSR) and Streptomyces antibiotic regulatory proteins (SARPs)). These plasmids were introduced into Streptomyces sp. TÜ17, Streptomyces sp. TÜ10 and Streptomyces sp. TÜ102. Introduction of the CSRs-plasmid into strain S. sp. TÜ17 activated the production of mayamycin A. By using the individual regulator genes, we proved that Aur1P, was responsible for the activation. In strain S. sp. TÜ102, the introduction of the SARP-plasmid triggered the production of a chartreusin-like compound. Insertion of the CSRs-plasmid into strain S. sp. TÜ10 resulted in activating the warkmycin-BGC. In both recombinants, activation of the BGCs was only possible through the simultaneous expression of aur1PR3 and griR in S. sp. TÜ102 and aur1P and pntR in of S. sp. TÜ10.

Pleiotropic anti-anti-sigma factor BldG is phosphorylated by several anti-sigma factor kinases in the process of activating multiple sigma factors in Streptomyces coelicolor A3(2).

The anti-anti-sigma factor BldG has a pleiotropic function in Streptomyces coelicolor A3(2), regulating both morphological and physiological differentiation. Together with the anti-sigma factor UshX, it participates in a partner-switching activation of the sigma factor σH, which has a dual role in the osmotic stress response and morphological differentiation in S. coelicolor A3(2). In addition to UshX, BldG also interacts with the anti-sigma factor ApgA, although no target sigma factor has yet been identified. However, neither UshX nor ApgA phosphorylates BldG. This phosphorylation is provided by the anti-sigma factor RsfA, which is specific for the late developmental sigma factor σF. However, BldG is phosphorylated in the rsfA mutant, suggesting that some other anti-sigma factors containing HATPase_c kinase domain are capable to phosphorylate BldG in vivo. Bacterial two-hybrid system (BACTH) was therefore used to investigate the interactions of all suitable anti-sigma factors of S. coelicolor A3(2) with BldG. At least 15 anti-sigma factors were found to interact with BldG. These interactions were confirmed by native PAGE. In addition to RsfA, BldG is specifically phosphorylated on the conserved phosphorylation Ser57 residue by at least seven additional anti-sigma factors. However, only one of them, SCO7328, has been shown to interact with three sigma factors, σG, σK and σM. A mutant with deleted SCO7328 gene was prepared in S. coelicolor A3(2), however, no specific function of SCO7328 in growth, differentiation or stress response could be attributed to this anti-sigma factor. These results suggest that BldG is specifically phosphorylated by several anti-sigma factors and it plays a role in the regulation of several sigma factors in S. coelicolor A3(2). This suggests a complex regulation of the stress response and differentiation in S. coelicolor A3(2) through this pleiotropic anti-sigma factor.

SYN-View: A Phylogeny-Based Synteny Exploration Tool for the Identification of Gene Clusters Linked to Antibiotic Resistance.

The development of new antibacterial drugs has become one of the most important tasks of the century in order to overcome the posing threat of drug resistance in pathogenic bacteria. Many antibiotics originate from natural products produced by various microorganisms. Over the last decades, bioinformatical approaches have facilitated the discovery and characterization of these small compounds using genome mining methodologies. A key part of this process is the identification of the most promising biosynthetic gene clusters (BGCs), which encode novel natural products. In 2017, the Antibiotic Resistant Target Seeker (ARTS) was developed in order to enable an automated target-directed genome mining approach. ARTS identifies possible resistant target genes within antibiotic gene clusters, in order to detect promising BGCs encoding antibiotics with novel modes of action. Although ARTS can predict promising targets based on multiple criteria, it provides little information about the cluster structures of possible resistant genes. Here, we present SYN-view. Based on a phylogenetic approach, SYN-view allows for easy comparison of gene clusters of interest and distinguishing genes with regular housekeeping functions from genes functioning as antibiotic resistant targets. Our aim is to implement our proposed method into the ARTS web-server, further improving the target-directed genome mining strategy of the ARTS pipeline.

A Structural Analysis of the Angucycline-Like Antibiotic Auricin from Streptomyces lavendulae Subsp. Lavendulae CCM 3239 Revealed Its High Similarity to Griseusins.

We previously identified the aur1 gene cluster in Streptomyces lavendulae subsp. lavendulae CCM 3239 (formerly Streptomyces aureofaciens CCM 3239), which is responsible for the production of the angucycline-like antibiotic auricin (1). Preliminary characterization of 1 revealed that it possesses an aminodeoxyhexose d-forosamine and is active against Gram-positive bacteria. Here we determined the structure of 1, finding that it possesses intriguing structural features, which distinguish it from other known angucyclines. In addition to d-forosamine, compound 1 also contains a unique, highly oxygenated aglycone similar to those of spiroketal pyranonaphthoquinones griseusins. Like several other griseusins, 1 also undergoes methanolysis and displays modest cytotoxicity against several human tumor cell lines. Moreover, the central core of the aur1 cluster is highly similar to the partial gris gene cluster responsible for the biosynthesis of griseusin A and B in both the nature of the encoded proteins and the gene organization.

Complete Genome Sequence of Streptomyces lavendulae subsp. lavendulae CCM 3239 (Formerly "Streptomyces aureofaciens CCM 3239"), a Producer of the Angucycline-Type Antibiotic Auricin.

Streptomyces lavendulae subsp. lavendulae CCM 3239 produces the angucycline antibiotic auricin and was thought to be the type strain of Streptomyces aureofaciens We report the complete genome sequence of this strain, which consists of a linear chromosome and the linear plasmid pSA3239, and demonstrate it to be S. lavendulae subsp. lavendulae.

Unusual features of the large linear plasmid pSA3239 from Streptomyces aureofaciens CCM 3239.

We previously identified the aur1 gene cluster, responsible for the production of the angucycline antibiotic auricin in Streptomyces aureofaciens CCM 3239. Pulse-field gel electrophoresis showed a single, 241kb linear plasmid, pSA3239, in this strain, and several approaches confirmed the presence of the aur1 cluster in this plasmid. We report here the nucleotide sequence of this 241,076-bp plasmid. pSA3239 contains an unprecedentedly small (13bp) telomeric sequence CCCGCGGAGCGGG, which is identical to the conserved Palindrome I sequence involved in the priming of end-patching replication. A bioinformatics analysis revealed 234 open reading frames with high number (28) of regulatory genes from various families. In contrast to most other linear plasmids, pSA3239 contains a pair of replication initiation genes (sa76 and sa75) located at its extreme left end, adjacent to the telomere. Together with similar proteins from several other linear plasmids (pFRL2, pSLA2-M, pSV2, pSDA1, and SAP1), they constitute a new family of replication initiation proteins. This left end also contains two genes, tpgSa and tapSa, encoding the terminal protein and the telomere associated-protein involved in telomere end-patching replication. pSA3239 also contains two genes homologous to the parAB partitioning system, and deletion of the parA homologue (sa43) affects structural stability of the plasmid. pSA3239 carries five potential secondary metabolite gene clusters. In addition to aur1 and a non-ribosomal peptide synthase (NRPS) gene cluster for the blue pigment indigoidine, it also contains a partial type II polyketide synthase (PKS) gene cluster, a partial type I PKS gene cluster, and a NRPS/PKSI gene cluster for unknown secondary metabolites. The last gene cluster contains a subcluster of seven genes (sa91-sa97), highly similar to part of the valanimycin biosynthetic cluster vlm. A S. aureofaciens strain lacking pSA3239 was prepared. This deletion did not substantially affect growth and differentiation. A comparative analysis of secondary metabolites between both strains did not identify any product, except auricin and indigoidine, which is dependent upon pSA3239. Thus, the other three identified gene clusters are likely silent under these conditions.

Characterisation of the genes involved in the biosynthesis and attachment of the aminodeoxysugar D-forosamine in the auricin gene cluster of Streptomyces aureofaciens CCM3239.

We previously identified the aur1 gene cluster which produces the angucycline antibiotic auricin. Preliminary characterisation of auricin revealed that it is modified by a single aminodeoxysugar, D-forosamine. Here we characterise the D-forosamine-specific genes. The four close tandem genes, aur1TQSV, encoding enzymes involved in the initial steps of the deoxysugar biosynthesis, were located on a large operon with other core auricin biosynthetic genes. Deleting these genes resulted in the absence of auricin and the production of deglycosylated auricin intermediates. The two final D-forosamine biosynthetic genes, sa59, an NDP-hexose aminotransferase, and sa52, an NDP-aminohexose N-dimethyltransferase, are located in a region rather distant from the core auricin genes. A deletion analysis of these genes confirmed their role in D-forosamine biosynthesis. The Δsa59 mutant had a phenotype similar to that of the cluster deletion mutant, while the Δsa52 mutant produced an auricin with a demethylated D-forosamine. Although auricin contains a single deoxyhexose, two glycosyltransferase genes were found to participate in the attachment of D-forosamine to the auricin aglycon. An analysis of the expression of the D-forosamine biosynthesis genes revealed that the initial D-forosamine biosynthetic genes aur1TQSV are regulated together with the other auricin core genes by the aur1Ap promoter under the control of the auricin-specific activator Aur1P. The expression of the other D-forosamine genes, however, is governed by promoters differentially dependent upon the two SARP family auricin-specific activators Aur1PR3 and Aur1PR4. These promoters contain direct repeats similar to the SARP consensus sequence and are involved in the interaction with both regulators.

Utilization of a reporter system based on the blue pigment indigoidine biosynthetic gene bpsA for detection of promoter activity and deletion of genes in Streptomyces.

The integrative promoter-probe plasmid pBPSA1 was constructed using a promoterless Streptomyces aureofaciens CCM3239 bpsA gene encoding a non-ribosomal peptide synthase for the biosynthesis of a blue pigment, indigoidine. bpsA was also used to prepare pAMR4 plasmid for the deletion of genes in Streptomyces with facile identification of double crossover recombination.

A γ-butyrolactone autoregulator-receptor system involved in the regulation of auricin production in Streptomyces aureofaciens CCM 3239.

The γ-butyrolactone (GBL) autoregulator-receptor systems play a role in controlling secondary metabolism and/or morphological differentiation in many Streptomyces species. We previously identified the aur1 gene cluster, located on the Streptomyces aureofaciens CCM 3239 large linear plasmid pSA3239, which is responsible for the production of the angucycline antibiotic auricin. Here, we describe the characterisation of two genes, sagA and sagR, encoding GBL autoregulatory signalling homologues, which lie in the upstream part of the aur1 cluster. SagA was similar to GBL synthases and SagR to GBL receptors. The expression of each gene is directed by its own promoter, sagAp for sagA and sagRp for sagR. Both genes were active mainly during the exponential phase, and their transcription was interdependent. The disruption of sagA abolished auricin production, while the disruption of sagR resulted in precocious but dramatically reduced auricin production. Transcription from the aur1Pp and aur1Rp promoters, which direct the expression of auricin-specific cluster-situated regulators (CSRs), was also precocious and increased in the sagR mutant strain. In addition, SagR was also shown to specifically bind both promoters in vitro. These results indicated that the SagA-SagR GBL system regulates auricin production. Unlike many other GBL receptors, SagR does not bind its own promoter, but Aur1R, an auricin-specific repressor from the family of pseudo GBL receptors, does bind both sagAp and sagRp promoters. Moreover, the expression of both promoters was deregulated in an aur1R mutant, indicating that the SagA-SagR GBL system is regulated by a feedback mechanism involving the auricin-specific CSR Aur1R, which regulates downstream.

The σ(F)-specific anti-sigma factor RsfA is one of the protein kinases that phosphorylates the pleiotropic anti-anti-sigma factor BldG in Streptomyces coelicolor A3(2).

The anti-anti-sigma factor BldG has a role in the morphological differentiation and antibiotic production of Streptomyces coelicolor A3(2). Together with the anti-sigma factor UshX it is involved in the "partner-switching"-like activation of the sigma factor σ(H) that has a dual role in the osmotic stress response and morphological differentiation in S. coelicolor A3(2). Although BldG is phosphorylated in vivo in S. coelicolor, neither of the interacting anti-sigma factors UshX and ApgA is found to phosphorylate it. By using a combination of several approaches, we demonstrated a direct interaction between BldG and the anti-sigma factor RsfA, which has been previously shown to regulate antibiotic production and morphological differentiation in S. coelicolor and to specifically interact with the sporulation-specific sigma factor σ(F). RsfA phosphorylates BldG in vitro, demonstrating that RsfA is a specific kinase for BldG and negatively regulates its activity. However, another interacting anti-anti-sigma factor homolog, SCO0869, was not phosphorylated by RsfA. Transcriptional analyses of rsfA revealed a single promoter, the activity of which was repressed by osmotic stress and decreased during differentiation. These data suggested that BldG has a pleiotropic role in the regulation of at least two sigma factors, σ(H) and σ(F), in S. coelicolor.

Intriguing properties of the angucycline antibiotic auricin and complex regulation of its biosynthesis.

Streptomyces bacteria are major producers of bioactive natural products, including many antibiotics. We identified a gene cluster, aur1, in a large linear plasmid of Streptomyces aureofaciens CCM3239. The cluster is responsible for the production of a new angucycline polyketide antibiotic auricin. Several tailoring biosynthetic genes were scatted in rather distant aur1 flanking regions. Auricin was produced in a very narrow growth phase interval of several hours after entry into stationary phase, after which it was degraded to non-active metabolites because of its instability at the high pH values reached after the production stage. Strict transcriptional regulation of the auricin biosynthetic gene cluster has been demonstrated, including feed-forward and feedback control by auricin intermediates via several of the huge number of regulatory genes present in the aur1 cluster. The complex mechanism may ensure strict confinement of auricin production to a specific growth stage.

A gene determining a new member of the SARP family contributes to transcription of genes for the synthesis of the angucycline polyketide auricin in Streptomyces aureofaciens CCM 3239.

Three regulators, Aur1P, Aur1R and a SARP-family Aur1PR3, have been previously found to control expression of the aur1 cluster for the angucycline antibiotic auricin in Streptomyces aureofaciens CCM 3239. Here, we describe an additional regulatory gene, aur1PR4, encoding a homologue from the SARP-family regulators. Its role in auricin regulation was confirmed by its disruption that dramatically affected auricin production. However, transcription from the aur1Ap promoter, directing expression of 22 auricin biosynthetic genes, was not substantially affected in the Δaur1PR4 mutant. A new promoter, sa13p, directing transcription of four putative auricin tailoring genes, was found to be dependent on aur1PR4. Moreover, analysis of the sa13p promoter region revealed the presence of three heptameric repeat sequences corresponding to putative SARP-binding sites. Expression of aur1PR4 is directed by a single promoter, aur1PR4p, which is induced after entry into stationary phase. Transcription from aur1PR4p was absent in a S. aureofaciens Δaur1P mutant strain, and Aur1P was shown to bind specifically to the aur1PR4p promoter. These results indicate a complex network of regulation of the auricin gene cluster. Both Aur1P and Aur1PR3 are involved in regulation of the core aur1A-U biosynthetic genes, and Aur1PR4 in regulation of putative auricin tailoring genes.

The gene cluster aur1 for the angucycline antibiotic auricin is located on a large linear plasmid pSA3239 in Streptomyces aureofaciens CCM 3239.

We previously identified a polyketide synthase gene cluster, aur1, responsible for the production of the angucycline antibiotic auricin in Streptomyces aureofaciens CCM 3239. A sequence analysis of the aur1 flanking regions revealed the presence of several genes encoding proteins homologous to those for Streptomyces linear plasmid replication, partitioning and telomere-binding. Pulse-field gel electrophoresis detected the single, 240-kb linear plasmid, pSA3239, in S. aureofaciens CCM3239. The presence of the auricin cluster in pSA3239 was confirmed by several approaches. In addition to aur1, pSA3239 also carries a large number of regulatory genes, and two gene clusters involved in the production of secondary metabolites: the aur2 cluster for an unknown secondary metabolite and the bpsA cluster for the blue pigment indigoidine.

Strict control of auricin production in Streptomyces aureofaciens CCM 3239 involves a feedback mechanism.

The polyketide gene cluster aur1 is responsible for the production of the angucycline antibiotic auricin in Streptomyces aureofaciens CCM 3239. Auricin production is regulated in a complex manner involving several regulators, including a key pathway-specific positive regulator Aur1P that belongs to the family of 'atypical' response regulators. Production of auricin is induced after entry into stationary phase. However, auricin was produced in only a short time interval of several hours. We found that the decrease of auricin production was due to a strict regulation of auricin biosynthetic genes at the transcriptional level by a feedback mechanism; auricin and/or its intermediate(s) inhibited binding of Aur1P to its cognate biosynthetic promoter aur1Ap and consequently stopped its activation. In addition, we also determined that synthesised auricin is unstable during growth of S. aureofaciens CCM3239 in the production medium even though purified auricin is stable for days in various organic solvents. The critical parameter affecting its stability was pH. Auricin is stable at acid pH and unstable at neutral and alkaline pH. The drop in auricin concentration was due to an increase of pH shortly after induction of auricin production during cultivation of S. aureofaciens CCM3239.