Three 4-monosubstituted butyrolactones from a regulatory gene mutant of Streptomyces rochei 7434AN4.

Extensive metabolite analysis of Streptomyces rochei 7434AN4 was performed to discover uncharacterized secondary metabolites. A mutant strain of S. rochei, in which two regulatory genes srrC (a tetR-type repressor) and srrY (SARP-type activator) were inactivated, accumulated three 4-monosubstituted γ-butyrolactones YT02-A, YT02-B, and KH01-A, which were not detected in the parent strain. Their structures were identified as 4,10-dihydroxy-10-methyldodecan-4-olide, 4,10-dihydroxy-10-methylundecan-4-olide, and 4-hydroxy-11-oxo-10-methyldodecan-4-olide. A structural comparison indicated that the three butanolides and the signaling molecules, termed S. rochei butenolides (SRBs), could share common C12 or C13 fatty acids for their biosynthesis intermediates, however, these three butanolides did not induce antibiotic production even at 50 µM concentration (1000-folds of the minimum antibiotic-inducing concentration of SRBs) in S. rochei.

Overexpression of SRO_3163, a homolog of Streptomyces antibiotic regulatory protein, induces the production of novel cyclohexene-containing enamide in Streptomyces rochei.

Streptomyces antibiotic regulatory proteins (SARPs) are well characterized as transcriptional activators for secondary metabolites in Streptomyces species. Streptomyces rochei 7434AN4 harbors 15 SARP genes, among which 3 were located on a giant linear plasmid pSLA2-L and others were on the chromosome. Some SARP genes were cloned into an integrative thiostrepton-inducible vector pIJ8600, and their recombinants were cultivated. The recombinant of SARP gene, SRO_3163, accumulated a UV-active compound YM3163-A, which was not detected in the parent strain and other SARP recombinants. Its molecular formula was established to be C8H11NO. Extensive NMR analysis revealed that YM3163-A is a novel enamide, 2-(cyclohex-2-en-1-ylidene)acetamide, and its structure was confirmed by chemical synthesis including Horner-Wadsworth-Emmons reaction and ammonolysis.

Genetically engineered rpsL merodiploidy impacts secondary metabolism and antibiotic resistance in Streptomyces.

Certain point mutations within gene for ribosomal protein S12, rpsL, are known to dramatically change physiological traits of bacteria, most prominently antibiotic resistance and production of various metabolites. The rpsL mutants are usually searched among spontaneous mutants resistant to aminoglycoside antibiotics, such as streptomycin or paromomycin. The shortcomings of traditional selection are as follows: random rpsL mutants may carry undesired genome alterations; many rpsL mutations cannot be isolated because they are either not associated with increased antibiotic resistance or non-viable in the absence of intact rpsLWT gene. Introduction of mutant rpsL alleles in the rpsLWT background can be used to circumvent these obstacles. Here we take the latter approach and report the generation and properties of a set of stable rpsL merodiploids for Streptomyces albus J1074. We identified several rpsL alleles that enhance endogenous and heterologous antibiotic production by this strain and show that rpsLWTrpsLK88E merodiploid displays increased streptomycin resistance. We further tested several promising rpsL alleles in two more strains, Streptomyces cyanogenus S136 and Streptomyces ghanaensis ATCC14672. In S136, plasmid-borne rpsLK88E+P91S and rpsLK88R led to elevated landomycin production; no changes were detected for ATCC14672 merodiploids. Our data outline the prospects for and limitations to rpsL merodiploids as a tool for rapid enhancement of secondary metabolism in Streptomyces.

Substrate specificity of two cytochrome P450 monooxygenases involved in lankamycin biosynthesis.

To elucidate the gross lankamycin biosynthetic pathway including two cytochrome P450 monooxygenases, LkmK and LkmF, we constructed two double mutants of P450 genes in combination with glycosyltransferase genes, lkmL and lkmI. An aglycon 8,15-dideoxylankanolide, a possible substrate for LkmK, was prepared from an lkmK-lkmL double mutant, while a monoglycoside 3-O-l-arcanosyl-8-deoxylankanolide, a substrate for LkmF, was from an lkmF-lkmI double mutant. Bioconversion of lankamycin derivatives was performed in the Escherichia coli recombinant for LkmK and the Streptomyces lividans recombinant for LkmF, respectively. LkmK catalyzes the C-15 hydroxylation on all 15-deoxy derivatives, including 8,15-dideoxylankanolide (a possible substrate), 8,15-dideoxylankamycin, and 15-deoxylankamycin, suggesting the relaxed substrate specificity of LkmK. On the other hand, LkmF hydroxylates the C-8 methine of 3-O-l-anosyl-8-deoxylankanolide. Other 8-deoxy lankamycin/lankanolide derivatives were not oxidized, suggesting the importance of a C-3 l-arcanosyl moiety for substrate recognition by LkmF in lankamycin biosynthesis. Thus, LkmF has a strict substrate specificity in lankamycin biosynthesis.

SrrB, a Pseudo-Receptor Protein, Acts as a Negative Regulator for Lankacidin and Lankamycin Production in Streptomyces rochei.

Streptomyces rochei 7434AN4, a producer of lankacidin (LC) and lankamycin (LM), carries many regulatory genes including a biosynthesis gene for signaling molecules SRBs (srrX), an SRB receptor gene (srrA), and a SARP (Streptomyces antibiotic regulatory protein) family activator gene (srrY). Our previous study revealed that the main regulatory cascade goes from srrX through srrA to srrY, leading to LC production, whereas srrY further regulates a second SARP gene srrZ to synthesize LM. In this study we extensively investigated the function of srrB, a pseudo-receptor gene, by analyzing antibiotic production and transcription. Metabolite analysis showed that the srrB mutation increased both LC and LM production over four-folds. Transcription, gel shift, and DNase I footprinting experiments revealed that srrB and srrY are expressed under the SRB/SrrA regulatory system, and at the later stage, SrrB represses srrY expression by binding to the promoter region of srrY. These findings confirmed that SrrB acts as a negative regulator of the activator gene srrY to control LC and LM production at the later stage of fermentation in S. rochei.

The genome sequence of Streptomyces rochei 7434AN4, which carries a linear chromosome and three characteristic linear plasmids.

Streptomyces rochei 7434AN4 produces two structurally unrelated polyketide antibiotics, lankacidin and lankamycin, and carries three linear plasmids, pSLA2-L (211 kb), -M (113 kb), and -S (18 kb), whose nucleotide sequences were previously reported. The complete nucleotide sequence of the S. rochei chromosome has now been determined using the long-read PacBio RS-II sequencing together with short-read Illumina Genome Analyzer IIx sequencing and Roche 454 pyrosequencing techniques. The assembled sequence revealed an 8,364,802-bp linear chromosome with a high G + C content of 71.7% and 7,568 protein-coding ORFs. Thus, the gross genome size of S. rochei 7434AN4 was confirmed to be 8,706,406 bp including the three linear plasmids. Consistent with our previous study, a tap-tpg gene pair, which is essential for the maintenance of a linear topology of Streptomyces genomes, was not found on the chromosome. Remarkably, the S. rochei chromosome contains seven ribosomal RNA (rrn) operons (16S-23S-5S), although Streptomyces species generally contain six rrn operons. Based on 2ndFind and antiSMASH platforms, the S. rochei chromosome harbors at least 35 secondary metabolite biosynthetic gene clusters, including those for the 28-membered polyene macrolide pentamycin and the azoxyalkene compound KA57-A.

Metabolic perturbation to enhance polyketide and nonribosomal peptide antibiotic production using triclosan and ribosome-targeting drugs.

Although transcriptional activation of pathwayspecific positive regulatory genes and/or biosynthetic genes is primarily important for enhancing secondary metabolite production, reinforcement of substrate supply, as represented by primary metabolites, is also effective. For example, partial inhibition of fatty acid synthesis with ARC2 (an analog of triclosan) was found to enhance polyketide antibiotic production. Here, we demonstrate that this approach is effective even for industrial high-producing strains, for example enhancing salinomycin production by 40%, reaching 30.4 g/l of salinomycin in an industrial Streptomyces albus strain. We also hypothesized that a similar approach would be applicable to another important antibiotic group, nonribosomal peptide (NRP) antibiotics. We therefore attempted to partially inhibit protein synthesis by using ribosome-targeting drugs at subinhibitory concentrations (1/50∼1/2 of MICs), which may result in the preferential recruitment of intracellular amino acids to the biosynthesis of NRP antibiotics rather than to protein synthesis. Among the ribosome-targeting drugs examined, chloramphenicol at subinhibitory concentrations was most effective at enhancing the production by Streptomyces of NRP antibiotics such as actinomycin, calcium-dependent antibiotic (CDA), and piperidamycin, often resulting in an almost 2-fold increase in antibiotic production. Chloramphenicol activated biosynthetic genes at the transcriptional level and increased amino acid pool sizes 1.5- to 6-fold, enhancing the production of actinomycin and CDA. This "metabolic perturbation" approach using subinhibitory concentrations of ribosome-targeting drugs is a rational method of enhancing NRP antibiotic production, being especially effective in transcriptionally activated (e.g., rpoB mutant) strains. Because this approach does not require prior genetic information, it may be widely applicable for enhancing bacterial production of NRP antibiotics and bioactive peptides.