For the deletion of BGC 42, CRISPR-Cas9 was used (11). A 10 kb DNA fragment inside BGC 42, located between the WT5260_078570 (transcription regulator) and WT5260_078640 (polyketide synthase (PKS)) genes, was selected for the deletion experiment. The Geneious tool (18) was used to design guide RNAs (gRNAs) in situ with a protospacer adjacent motif (PAM) sequence of 5'-NGG-3'. For the knockout, two gRNAs (named 1a and 1b) located at the 5' and 3' ends of the target region for deletion were used. In addition to the gRNA sequences, homologous regions (≈1 kb) at the edge regions were also designed and cloned into the final vectors. The gene for resistance to thiostrepton was inserted into the pREP_P1_cas9 vector by amplifying the gene with the oligonucleotide primers tsr_Fw_ClaI (5'-AAAAATCGATGCTAGCTAGAGTCGACCTGC-3') and tsr_Rw_BspOI (5'-AAAAGCTAGCGGGTGCGCGTGATTGCCA-3'). The PCR product was purified from the gel, cut with the restriction enzymes ClaI and BspoI, and ligated into the pREP_P1_cas9 vector cut with the same enzymes. The resulting pREP_P1_cas9_tio vector was verified with restriction enzymes. The gRNA sequences (1a and 1b) and homologous regions were obtained in the pGH_GBG42_1a+1b+homology vector from DNA synthesis (ATG:Biosynthetics GmbH, Merzhausen, Germany). The entire sequence of the homologous regions and the gRNA region were excised from the pGH_GBG42_1a1b+homology vectors with the XbaI and BstBI enzymes and ligated into the pREP_P1_cas9_tio vector, linearized with the same enzymes. The resulting vector was named pREP_GBG42_1a1b and verified by restriction reaction after isolation from E. coli DH10β.

The plasmid pAB04ErmE*EIBVYU contains all genes for isorenieratene biosynthesis under the control of the strong constitutive promoter ermE*. The pAB04 vector was linearized with the restriction enzymes XbaI and NdeI and dephosphorylated with alkaline phosphatase. The isorenieratene BGC 3 was amplified by PCR in two parts, which contained the crtEIBV (EIBV_Fw TGTCGTACACTCACCCCGGAAACCTCCC; EIBV_Rw ACTCCAAGGAGGACCCCACAATGCGCCCTATCCGGGCA) and crtYU (YU_Fw GCTTGGGCTGCAGGTCGACTTCAGGCTCCCGCCACCCG; YU_Rw TCCGGGGTGAGTGTACGACACGGAGGTGGCC) genes, respectively. The oligonucleotide primers for the EIBV (CrtEIBV_Fw and CrtEIBV_Rw) and YU (CrtYU_Fw and CrtYU_Rw) parts were designed to introduce a 20–25 bp long homology at both ends of the fragments, which is necessary for the Gibson method of DNA fragment assembly. Genomic DNA isolated from ATCC 10970 using a bacterial genomic DNA isolation kit (Sigma Aldrich, Merck, St. Louis, MO, USA) was used as the template for the PCR reaction. The three fragments, EIBV, YU and pAB04, were then assembled using the Gibson DNA assembly kit (New England Biolabs, Ipswich, MA, USA).

BGC 42 in S. rimosus was deleted using a CRISPR-Cas9 system. The gRNAs targeting the cluster and homologous flanking sequences were cloned into plasmid pREP_P1_Cas9_tio by restriction cloning. S. rimosus transformants were selected on MS agar supplemented with thiostrepton (30 µg/mL) and theophylline (4 mM). The latter acts as an inducer of the theophylline-responsive riboswitch controlling Cas9 expression. Colonies were then restreaked onto MS agar with theophylline, and the presence of the desired deletion was confirmed by colony PCR. Positive clones were transferred to MS plates without antibiotics and, as a control, to MS plates with thiostrepton. Colonies that lost the plasmid did not grow under thiostrepton selection, consistent with the instability of the pIJ101 replicon present in pREP_P1_Cas9_tio.

The genome sequence of ATCC 10970 revealed that, like other streptomycetes (39), this strain encodes numerous genes predicted to play regulatory roles in various cellular processes. Over 10 % of the genome consists of genes involved in regulation. We recently reported dynamic changes in the synthesis and post-translational modification of numerous regulatory proteins, highlighting their prominent role in complex and dynamic signalling networks linked to growth arrest, metabolic switching, antibiotic production, and bacterial responses to nutrient deprivation and other stressors in this strain (41). However, to date, relatively few regulatory genes in S. rimosus have been studied in detail. The following section describes the experimentally characterized regulatory genes located within the OTC cluster (10, 42, 43).

Yin et al. (42) identified the regulatory protein SARP (Streptomyces antibiotic regulatory protein), which acts as a transcription activator, OtcR, whose gene is located immediately adjacent to the resistance gene otrB (Fig. S1). OtcR acts as a positive pathway-specific activator of OTC biosynthesis and increases OTC production when overexpressed at the appropriate level (42).

The second regulatory element, OtcG, was identified by Lešnik et al. (43). OtcG belongs to the LAL (large ATP-binding regulator of LuxR) family of transcriptional regulators and is located on the other side of the otc BGC, near the otrA resistance gene (Fig. S1). OtcG plays a conditionally positive role in OTC biosynthesis, as inactivation of the otcG gene in the industrial strain S. rimosus 4018 (progenitor of ATCC 10970) reduces OTC production by >40 %. However, overexpression of otcG, by introducing a second copy of the gene under the strong constitutive promoter ermE*, did not significantly alter OTC production (43).

In addition to these regulators, the otc cluster contains the oxyTA1 gene, which encodes a MarR-family repressor proposed to control the expression of the resistance gene otrB. These two genes are located immediately adjacent to each other (Fig. 6 and Fig. S1).

To further elucidate the otc BGC regulation in ATCC 10970, we analysed the transcriptome raw data generated by Pšeničnik et al. (12) and focused specifically on the expression profile of each gene in the otc BGC after 24 and 50 h (Fig. 6).

Not surprisingly, gene expression increased significantly after 50 h of incubation, which correlates well with the significant increase in OTC concentration (see raw data in (12)). Interestingly, only oxyTA1 expression did not increase significantly after 50 h. This is not surprising, considering that the product of oxyTA1 is a putative MarR family repressor protein that negatively regulates the expression of the tetracycline efflux pump gene otrB. The oxyTA1 gene is divergently transcribed from otrB, which encodes a membrane protein responsible for OTC efflux, thereby contributing to antibiotic resistance. Thus, oxyTA1 acts as a repressor by controlling the expression of the OTC efflux pump and modulates resistance in S. rimosus. Therefore, it is advantageous for S. rimosus to promote efflux pump activity during intensive OTC biosynthesis in the cell.

Beyond pathway-specific regulation, experimentally investigated regulatory elements located distantly from the OTC cluster have also been shown to modulate its expression. Bioinformatic analysis has identified 53 typical two-component systems (TCS) in S. rimosus, of which two were selected for experimental characterization based on their high similarity to the antibiotic-positive regulators AfsQ1/Q2 and RapA1/A2 from S. coelicolor. Both TCS were studied in S. rimosus 4018, a derivative of the parental strain 10970. The first system, designated AfrQ1Q2 (44), showed the highest similarity to the AfsQ1/Q2 system of S. coelicolor. Disruption of the response regulator afrQ1 significantly upregulated the transcription of five genes: oxyB (involved in OTC biosynthesis), otrB and the extra-cluster otrC (resistance genes), and the cluster-situated regulatory genes otcG and otcR (Fig. 7). These effects were specifically observed during cultivation in minimal medium with glycine as the sole nitrogen source.

Similarly, the second system, RimA1/A2, which shares high similarity with the TCS RapA1/A2, was identified as a negative regulator of OTC production under the same nutritional conditions (44, 45). Disruption of rimA1 resulted in an identical phenotype of increased yellow-pigmented OTC production and a similar transcriptional profile to the afrQ1 mutant. Notably, the only significant difference in the transcriptional analysis was that the rimA1 deletion led to a several-fold higher upregulation of the regulatory gene otcG compared to the afrQ1 mutant.

Altogether, the reported data show that both studied TCS act as negative regulators of OTC biosynthesis in S. rimosus (Fig. 7). Their overlapping phenotypes and transcriptional targets suggest they may converge on a common global regulatory node to modulate OTC biosynthesis in response to nitrogen availability.

Control of antibiotic biosynthesis by phosphate via the two-component PhoR/PhoP system has been well studied in several Streptomyces species (46, 47). Early physiological studies showed that S. rimosus produces OTC abundantly when mycelial growth is limited by phosphate depletion. A pivotal study by McDowall et al. (48) established that this phosphate-dependent regulation occurs at the transcriptional level. They demonstrated that phosphate limitation triggers the increased expression of genes within the cluster, specifically the reductase gene oxyR (formerly otcX1) and the monooxygenase oxyS (formerly otcC). Furthermore, evidence suggests that the resistance gene otrA is co-transcribed with oxyS as part of a polycistronic message, providing a coordinated mechanism that ensures OTC resistance increases in proportion to antibiotic production. While these early studies established a transcriptional link to phosphate availability, the specific role of the PhoR/PhoP system in S. rimosus has yet to be experimentally validated, as no studies involving the genetic manipulation of this system have been reported to date.

Although ATCC 10970 produces both OTC and RIM under laboratory conditions, genes involved in the regulation of RIM synthesis have mainly been studied in S. rimosus M527. Interestingly, although this strain carries a BGC for OTC production that is highly similar (>90 %) to that of ATCC 10970, it does not produce OTC under the tested laboratory conditions (49). The S. rimosus M527 strain was classified as S. rimosus based on 16S rRNA gene sequence analysis. Thus, we first compared the S. rimosus M527 genome with that of ATCC 10970 (50) to assess the conservation of genes involved in rim BGC regulation.

A whole-genome alignment between ATCC 10970 (assembly NZ_CP048261.1; 23) and S. rimosus M527 was performed using D-Genies (51) (Fig. 8). The dot plot visualization of this comparison (Fig. 8) reveals a high degree of collinearity between the two genomes, indicated by the strong diagonal line. This suggests large syntenic blocks and a conserved gene order across most chromosomes.

Some minor breaks in the main diagonal and smaller off-diagonal alignments are visible, indicating potential genomic rearrangements such as inversions, translocations, or insertions/deletions (indels) that differentiate the two strains. The alignment statistics (Fig. 8) show that 92.12 % of the queried genome (M527 against ATCC 10970, as reference) aligns with over 75 % sequence identity. A small fraction, 7.73 %, shows no match, and 0.15 % aligns with less than 25 % identity, highlighting regions of significant divergence or unique genomic content in one of the strains. Given the high genomic similarity between the two strains, we next closely examined the presence and similarity of all experimentally characterized regulatory genes known to influence OTC and RIM production in both strains.

Analysis of the regulatory genes otcG, oxyTA1, and otcR in the otc BGC (Fig. 7) showed that they are 100 % identical in both strains. Our results indicate that the otc BGCs of the two S. rimosus strains share high overall similarity (>90 %), and OTC production was successfully activated in M527 (49). Thus, we propose that the lack of OTC production in wild-type S. rimosus M527 is most likely due to differences in the global regulation of OTC biosynthesis and may be triggered under different environmental conditions.

As mentioned earlier, ATCC 10970 and M527 strains produce RIM in cultivation medium favouring OTC production (17). Genome sequence analysis of S. rimosus M527 revealed a BGC responsible for RIM production and, based on sequence similarity, predicted four regulatory genes (rim1 to rim4) located in this cluster (52). Phylogenetic analysis showed that Rim2, Rim3 and Rim4 share high similarity with the well-characterized LAL subfamily of LuxR transcriptional regulators, while Rim1 is more closely related to the PAS-LuxR family (Fig. 7. (52-54)). In addition, rim2 overexpression most significantly increased antibiotic production, while deletion of this gene showed that it is essential for RIM biosynthesis. Thus, it is not surprising that its regulatory role in rim BGC is the best characterized so far. RIM2 specifically binds to the promoter regions of PKS rimA, rimC and rimR2, thereby activating the transcription of structural genes while simultaneously regulating its own expression, which exerts a positive effect on antibiotic production (52). All regulatory proteins in ATCC 10970 show nearly 100 % identity to their orthologues in the S. rimosus M527 strain; Rim1, Rim3 and Rim4 show 100 % identity, while Rim2 shows 99.13 % similarity. In addition, inspection of the promoter regions (300 bp) of the rim1–rim4 genes revealed over 99.3 % sequence identity, strongly suggesting that regulation of these genes is also conserved in both strains (Fig. 7).

In addition to the regulatory genes within the rim BGC, several studies have reported other regulatory genes located distantly from this BGC in strain M527. Among them is the recently discovered gene encoding the transcriptional regulator TetR24 (55), assigned to the TetR family based on its sequence and structure. We also identified the gene encoding an identical protein in ATCC 10970 (Fig. 7). This finding is not surprising, as the members of this family regulate diverse processes in bacteria, including antibiotic biosynthesis, and are commonly found in Streptomyces genomes (56). Deletion of tetR24 in the M527 strain and transcriptional analysis showed that TetR24 acts as a negative regulator of RIM biosynthesis. It has been reported that TetR24 binds to the rimR2 and rimA promoter regions, where two binding sites with a conserved motif (GGAG/ACTCG/C) were identified (55). Our analysis of the rimR2 and rimA promoter regions in ATCC 10970 revealed complete conservation of the TetR24 binding sites upstream of both genes, matching the previously reported sequences containing a conserved motif: TGCGTATCACCTCACGCAAGGAACTCC for rimR2 and AGGAGCTCGTGTCCGAACCCCGG for rimA. Given that the tetR24 genes in both strains encode identical TetR24 proteins and that the binding motif is conserved, it is likely that TetR24 regulates rimR2 transcription in the same manner in both strains.

An additional gene, nsdA, a negative regulator of RIM antibiotic production and sporulation, has also been identified in S. rimosus M527 (53), based on its sequence similarity with NsdA from S. coelicolor. NsdA is conserved and widely distributed across Streptomyces species (57), suggesting an important role in regulating morphological and physiological differentiation, at least in sporulating Streptomyces species. Thus, it is not surprising that we identified a 100 % conserved orthologous nsdA gene in the genome of the reference strain ATCC 10970, when using the nsdA_sr sequence from strain M527 as a query.

Additionally, the 300 bp upstream region of nsdA was also 100 % conserved, suggesting that the transcriptional regulation of this gene is conserved between the two strains. In S. coelicolor, BldD binds the promoter region of nsdA, placing nsdA within the BldD regulon and identifying it as part of a complex regulatory cascade governed by this global regulator. Here, we did not identify a motif matching the BldD binding site in the upstream region of nsdAsr. However, the possibility that this regulatory cascade is conserved in S. rimosus cannot be excluded, as not all known BldD-regulated genes contain recognizable BldD motifs in their promoter regions (58). Disruption of the nsdA gene in S. rimosus M527 increases antibiotic production and accelerates sporulation (53), consistent with previous findings in other Streptomyces species, including S. coelicolor, S. lividans and S. bingchenggensis (59). Recent transcriptomic and ChIP-seq analyses have provided new insights into the regulatory mechanisms controlled by NsdA_sr. This repressor downregulates metabolic pathways involved in butyryl-CoA and malonyl-CoA biosynthesis, precursors of rimocidin biosynthesis, as well as global protein synthesis, thereby modulating antibiotic production (54). Given the ubiquity of this regulator in streptomycetes, all these findings indicate that nsdA is a promising target for genetic manipulation in industrial strain improvement programs (57).

Finally, two additional genes, rrt and hyp, involved in the regulation of the rim operon in S. rimosus M527 (60), have recently been reported. Both genes are located outside the rim BGC. The first encodes the Rrt protein, which functions as a positive regulator of RIM production. Notably, identical or highly similar Rrt protein sequences have been identified in several Streptomyces strains, including S. rimosus R6-500 and WT5260 (also designated as ATCC 10970) (60). Therefore, our discovery of a gene encoding a 100 % identical Rrt protein in the reference strain ATCC 10970 (Fig. 7) was not surprising, suggesting a conserved biological role for this protein in the regulation of antibiotic production in many Streptomyces strains. In contrast to this positive regulator, the Hyp (from hypothetical) protein negatively regulates RIM synthesis (60). A 100 % identical Hyp protein, encoded outside the rim BGC (Fig. 7), is also present in the reference strain ATCC 10970. This conservation suggests that it plays the same regulatory role in repressing RIM biosynthesis in both S. rimosus strains, ATCC 10970 and M527. Interestingly, transcriptional analyses of RIM biosynthetic genes (rimA, rimB, rimE, rimG) and regulatory genes (rim1, rim2) revealed coordinated expression changes, with decreases in the absence of the Rrt activator and increases in the absence of the Hyp repressor, respectively (60). This conserved trend in transcriptional profiles suggests that Rrt and Hyp either regulate the same cluster regulators (rim1 and rim2) or act through a shared signalling pathway involving an as-yet-undiscovered intermediate regulator. In conclusion, analyses of all regulatory elements described in the literature (Fig. 7) do not suggest ‘cross-regulation’ between OTC and RIM BGCs. This may be the main reason why the inactivation of the rim BGC does not affect OTC biosynthesis.