A butenolide signaling system synergized with biosynthetic gene modules led to effective activation and enhancement of silent oviedomycin production in Streptomyces

Optimized expression of oxazolomycins in engineered Streptomyces longshengensis and their activity evaluation

BACKGROUND

To cope with the growing number of severe diseases and intractable pathogens, drug innovation in both chemical structures and pharmacological efficiency has become an imperative global mission. Oxazolomycins are a unique family of polyketide-polypeptide antibiotics from Streptomyces with diverse functional groups in their structures, conferring them multifarious activities. But further development into clinical applications has been hindered for decades for many reasons. Among them, the yield improvement is a critical basis for activity evaluation and drug-like property optimization. This study aims to enhance the production of oxazolomycins in Streptomyces longshengensis through metabolic engineering and evaluate their bioactivity against clinically relevant pathogens.

RESULTS

Co-transcriptional analyses suggested that two operons (the transcriptional unit from gene oxaG to oxaB, and that from gene oxaH to oxaQ) could be included in the oxazolomycin biosynthetic gene cluster (oxa BGC) of S. longshengensis. So a strategy was designed to replace the native promoter regions between oxaG and oxaH with constitutive promoters Pneo and PkasO* following functional module evaluation. In the resultant strain (SLOE), the production of oxazolomycin component Toxa5 was increased to 4-fold of that in the wild-type strain. Accordingly, the transcription of all related genes in oxa was clearly promoted. SLOE was then subjected to sublethal dose of gentamicin to induce mutagenesis for optimizing the genetic background, generating a resistant mutant SLROE. With the introduction of transporter genes (ozmS and oxaA) into SLROE, 175 mg/L of Toxa5 was achieved, representing the highest yield in shake-flask fermentation to the best of our knowledge. Finally, the purified Toxa5 showed significant inhibition on the growth of clinically important Gram-negative pathogenic bacterium, Pseudomonas aeruginosa, and the biofilm formation of Bacillus subtilis. Intriguingly, an unprecedented antioxidant activity was also demonstrated.

CONCLUSIONS

An oxazolomycin high-producing system of S. longshengensis was established by employing genetic engineering strategies to facilitate the bioactivity exploitation. Oxazolomycin Toxa5 showed interesting inhibitory effects against multiple Gram-negative and -positive pathogens as well as antioxidant capacity, indicating its great potential in clinical applications. The findings provide an efficient strategy for the overproduction and activity evaluation of oxazolomycins.

Combinatorial metabolic engineering strategy of precursor pools for the yield improvement of spinosad in Saccharopolyspora spinosa

Spinosad is an insecticide produced by Saccharopolyspora spinosa, and its larvicidal activity is considered a promising approach to combat crop pests. The aim of this study was to enhance the synthesis of spinosad through increasing the supply of acyl-CoAs precursor by the following steps. (i) Engineering the β-oxidation pathway by overexpressing key genes within the pathway to promote the synthesis of spinosad. The results showed that the overexpression of fadD, fadE, and fadA1 genes, as well as the co-expression of fadA1 and fadE genes, increased the yield of spinosad by 0.36-fold, 0.89-fold, 0.75-fold and 1.25-fold respectively. (ii) Employing combinatorial engineering of the β-oxidation pathway and ACC/PCC pathway to promote the synthesis of spinosad. The results showed that the co-expression of fadE and pccA, as well as accC and fadE, resulted in a 1.77-fold and 1.43-fold increase in spinosad production respectively. (iii) When exogenous triacylglycerol was added to the fermentation medium, the solely engineering of the β-oxidation pathway increased the yield of spinosad by 7.13-fold, reaching 427.23 mg/L. While the combinatorial engineering of both the β-oxidation pathway and ACC/PCC pathway increased the yield of spinosad by 9.61-fold, reaching 625.17 mg/L, and further optimization of the culture medium resulted in an even higher yield of spinosad, reaching 1293.43 mg/L. The results of this study indicate that the above combination strategy can promote the efficient biosynthesis of spinosad.

Cinnamoyl lipids as novel signaling molecules modulate the physiological metabolism of cross-phylum microorganisms

Signaling systems of microorganisms are responsible for regulating the physiological and metabolic processes and also play vital roles in the communications of cells. Identifying signaling molecules mediating the cross-talks is challenging yet highly desirable for comprehending the microbial interactions. Here, we demonstrate that a pathogenic Gram-negative Chromobacterium violaceum exerts significant influence on the morphological differentiation and secondary metabolism of Gram-positive Streptomyces. The physiological metabolisms are directly modulated by three novel cinnamoyl lipids (CVCL1, 2, and 3) from C. violaceum CV12472, whose biosynthesis is under the control of N-acylhomoserine lactone signaling system. Furthermore, a receptor of CVCLs in Streptomyces ansochromogenes 7100 is determined to be SabR1, the cognate receptor of γ-butenolide signaling molecules. This study reveals an unprecedented mode of microbial interactions, and the quorum sensing signaling systems in these two groups of bacteria can be bridged via CVCLs, suggesting that CVCLs can modulate the physiological metabolism of cross-phylum microorganisms.

DNA Molecular Glue Assisted Bacterial Conjugative Transfer

Bacterial conjugation, a commonly used method to horizontally transfer functional genes from donor to recipient strains, plays an important role in the genetic manipulation of bacteria for basic research and industrial production. Successful conjugation depends on the donor-recipient cell recognition and a tight mating junction formation. However, the efficiency of conjugative transfer is usually very low. In this work, we developed a new technique that employed DNA molecule "glue" to increase the match frequency and the interaction stability between the donor and recipient cells. We used two E. coli strains, ETZ and BL21, as a model system, and modified them with the complementary ssDNA oligonucleotides by click chemistry. The conjugation efficiency of the modified bacteria was improved more than 4 times from 10 %-46 %. This technique is simple and generalizable as it only relies on the active amino groups on the bacterial surface. It is expected to have broad applications in constructing engineered bacteria.

New insights into the dihydro-mureidomycin biosynthesis controlled by two unusual proteins in Streptomyces roseosporus

BACKGROUND

Uridyl peptide compounds are renowned as a subclass of nucleoside antibiotics for their highly specific antibacterial activity against Gram-negative bacteria and the unique target of action. We previously activated the biosynthetic gene cluster of a uridyl peptide antibiotic, mureidomycin, in Streptomyces roseosporus NRRL 15998 by introducing an exogenous positive regulator gene ssaA, and the generated strain was designated as Sr-hA. This study aims to further explore mureidomycin analogs from Sr-hA as well as the collaborative roles of two wide-spread genes, SSGG-02980 and SSGG-03002 encoding putative nuclease/phosphatase and oxidoreductase respectively, in mureidomycin diversification.

RESULTS

In order to understand how SSGG-02980 and SSGG-03002 contribute to mureidomycin biosynthesis, the gene disruption mutants and complementary strains were constructed. Mass spectrometry analyses revealed that two series of pairwise mureidomycin analogs were synthesized in Sr-hA with a two-dalton difference in molecular weight for each pair. By disruption of SSGG-03002, only mureidomycins with lower molecular weight (MRDs, 1-6) could be specifically accumulated in the mutant (∆03002-hA), whereas the other series of products with molecular weight plus 2 Da (rMRDs, 1'-6') became dominant in SSGG-02980 disruption mutant (∆02980-hA). Further comprehensive NMR analyses were performed to elucidate the structures, and three MRDs (3, 4, 5) with unsaturated double bond at C5-C6 of uracil group were characterized from ∆03002-hA. In contrast, the paired rMRDs analogs (3', 4', 5') from ∆SSGG-02980 corresponding to 3, 4 and 5 were shown to contain a single bond at this position. The results verified that SSGG-03002 participates in the reduction of uracil ring, whereas SSGG-02980 antagonizes the effect of SSGG-03002, which has been rarely recognized for a phosphatase.

CONCLUSIONS

Overall, this study revealed the key roles of two wide-spread families of enzymes in Streptomyces. Of them, oxidoreductase, SSGG-03002, is involved in dihydro-mureidomycin biosynthesis of S. roseosporus, whereas nuclease/phosphatase, SSGG-02980, has an adverse effect on SSGG-03002. This kind of unusual regulation model between nuclease/phosphatase and oxidoreductase is unprecedented, providing new insights into the biosynthesis of mureidomycins in Streptomyces. The findings would be of significance for structural diversification of more uridyl peptide antibiotics against Gram-negative bacteria.

Heterologous overproduction of oviedomycin by refactoring biosynthetic gene cluster and metabolic engineering of host strain Streptomyces coelicolor

BACKGROUND

Oviedomycin is one among several polyketides known for their potential as anticancer agents. The biosynthetic gene cluster (BGC) for oviedomycin is primarily found in Streptomyces antibioticus. However, because this BGC is usually inactive under normal laboratory conditions, it is necessary to employ systematic metabolic engineering methods, such as heterologous expression, refactoring of BGCs, and optimization of precursor biosynthesis, to allow efficient production of these compounds.

RESULTS

Oviedomycin BGC was captured from the genome of Streptomyces antibioticus by a newly constructed plasmid, pCBA, and conjugated into the heterologous strain, S. coelicolor M1152. To increase the production of oviedomycin, clustered regularly interspaced short palindromic repeats/CRISPR-associated protein 9 (CRISPR/Cas9) system was utilized in an in vitro setting to refactor the native promoters within the ovm BGC. The target promoters of refactoring were selected based on examination of factors such as transcription levels and metabolite profiling. Furthermore, genome-scale metabolic simulation was applied to find overexpression targets that could enhance the biosynthesis of precursors or cofactors related to oviedomycin production. The combined approach led to a significant increase in oviedomycin production, reaching up to 670 mg/L, which is the highest titer reported to date. This demonstrates the potential of the approach undertaken in this study.

CONCLUSIONS

The metabolic engineering approach used in this study led to the successful production of a valuable polyketide, oviedomycin, via BGC cloning, promoter refactoring, and gene manipulation of host metabolism aided by genome-scale metabolic simulation. This approach can be also useful for the efficient production of other secondary molecules encoded by 'silent' BGCs.

An intricate regulation of WblA controlling production of silent tylosin analogues and abolishment of expressible nikkomycin

Genome sequencing has revealed that actinomycetes possess the potential to produce many more secondary metabolites than previously thought. The existing challenge is to devise efficient methods to activate these silent biosynthetic gene clusters (BGCs). In Streptomyces ansochromogenes, disruption of wblA, a pleiotropic regulatory gene, activated the expression of cryptic tylosin analogues and abolished nikkomycin production simultaneously. Overexpressing pathway-specific regulatory genes tylR1 and tylR2 can also trigger the biosynthesis of silent tylosin analogues, in which TylR1 exerted its function via enhancing tylR2 expression. Bacterial one-hybrid system experiments unveiled that WblA directly inhibits the transcription of tylR1 and tylR2 to result in the silence of tylosin analogues BGC. Furthermore, WblA can activate the nikkomycin production through up-regulating the transcription of pleiotropic regulatory gene adpA. More interestingly, AdpA can activate sanG (an activator gene in nikkomycin BGC) but repress wblA. Our studies provide a valuable insight into the complex functions of pleiotropic regulators.

A visualization reporter system for characterizing antibiotic biosynthetic gene clusters expression with high-sensitivity

The crisis of antibiotic resistance has become an impending global problem. Genome sequencing reveals that streptomycetes have the potential to produce many more bioactive compounds that may combat the emerging pathogens. The existing challenge is to devise sensitive reporter systems for mining valuable antibiotics. Here, we report a visualization reporter system based on Gram-negative bacterial acyl-homoserine lactone quorum-sensing (VRS-bAHL). AHL synthase gene (cviI) of Chromobacterium violaceum as reporter gene is expressed in Gram-positive Streptomyces to synthesize AHL, which is detected with CV026, an AHL deficient mutant of C. violaceum, via its violacein production upon AHL induction. Validation assays prove that VRS-bAHL can be widely used for characterizing gene expression in Streptomyces. With the guidance of VRS-bAHL, a novel oxazolomycin derivative is discovered to the best of our knowledge. The results demonstrate that VRS-bAHL is a powerful tool for advancing genetic regulation studies and discovering valuable active metabolites in microorganisms.

A quorum sensing based visualization reporter system is presented for the characterization of promoters in Gram-positive bacteria, utilizing violacein production, especially for use in the identification of secondary metabolites.